diff options
Diffstat (limited to 'unsupported')
90 files changed, 22034 insertions, 256 deletions
diff --git a/unsupported/Eigen/CXX11/Core b/unsupported/Eigen/CXX11/Core index 4dc4ab224..292f09564 100644 --- a/unsupported/Eigen/CXX11/Core +++ b/unsupported/Eigen/CXX11/Core @@ -2,6 +2,7 @@ // for linear algebra. // // Copyright (C) 2013 Christian Seiler <christian@iwakd.de> +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed @@ -21,20 +22,26 @@ * module. Note that at this stage, you should not need to include * this module directly. * + * It also provides a limited fallback for compilers that don't support + * CXX11 yet, such as nvcc. + * * \code * #include <Eigen/CXX11/Core> * \endcode */ -#include <array> +#include <vector> +// Emulate the cxx11 functionality that we need if the compiler doesn't support it. +#if __cplusplus <= 199711L +#include "src/Core/util/EmulateCXX11Meta.h" +#else +#include <array> #include "src/Core/util/CXX11Workarounds.h" #include "src/Core/util/CXX11Meta.h" +#endif #include <Eigen/src/Core/util/ReenableStupidWarnings.h> #endif // EIGEN_CXX11_CORE_MODULE -/* - * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle; - */ diff --git a/unsupported/Eigen/CXX11/Tensor b/unsupported/Eigen/CXX11/Tensor index 049ce5596..34107ae71 100644 --- a/unsupported/Eigen/CXX11/Tensor +++ b/unsupported/Eigen/CXX11/Tensor @@ -1,6 +1,7 @@ // This file is part of Eigen, a lightweight C++ template library // for linear algebra. // +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> // Copyright (C) 2013 Christian Seiler <christian@iwakd.de> // // This Source Code Form is subject to the terms of the Mozilla @@ -10,9 +11,10 @@ #ifndef EIGEN_CXX11_TENSOR_MODULE #define EIGEN_CXX11_TENSOR_MODULE -#include <unsupported/Eigen/CXX11/Core> +#include "Eigen/src/Core/util/StaticAssert.h" +#include "unsupported/Eigen/CXX11/Core" -#include <Eigen/src/Core/util/DisableStupidWarnings.h> +#include "Eigen/src/Core/util/DisableStupidWarnings.h" /** \defgroup CXX11_Tensor_Module Tensor Module * @@ -26,14 +28,69 @@ #include <cstddef> #include <cstring> +#include <stdint.h> -#include "src/Tensor/TensorStorage.h" -#include "src/Tensor/Tensor.h" +#if __cplusplus > 199711 +#include <random> +#endif -#include <Eigen/src/Core/util/ReenableStupidWarnings.h> +#ifdef EIGEN_USE_THREADS +#include <future> +#endif -#endif // EIGEN_CXX11_TENSOR_MODULE +#ifdef EIGEN_USE_GPU +#include <cuda_runtime.h> +#if defined(__CUDACC__) +#include <curand_kernel.h> +#endif +#endif + +#include "Eigen/Core" + +#include "unsupported/Eigen/CXX11/src/Tensor/TensorForwardDeclarations.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorDeviceType.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorDimensions.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorIndexList.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorInitializer.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorTraits.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorFunctors.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorIntDiv.h" + +#include "unsupported/Eigen/CXX11/src/Tensor/TensorBase.h" + +#include "unsupported/Eigen/CXX11/src/Tensor/TensorEvaluator.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorExpr.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorReduction.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorConcatenation.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorContraction.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorContractionThreadPool.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorContractionCuda.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorConvolution.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorPatch.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorImagePatch.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorBroadcasting.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorChipping.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorLayoutSwap.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorMorphing.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorPadding.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorReverse.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorShuffling.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorStriding.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorEvalTo.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorForcedEval.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorAssign.h" -/* - * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle; - */ +#include "unsupported/Eigen/CXX11/src/Tensor/TensorDevice.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorExecutor.h" + +#include "unsupported/Eigen/CXX11/src/Tensor/TensorStorage.h" +#include "unsupported/Eigen/CXX11/src/Tensor/Tensor.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorFixedSize.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorMap.h" +#include "unsupported/Eigen/CXX11/src/Tensor/TensorRef.h" + +#include "unsupported/Eigen/CXX11/src/Tensor/TensorIO.h" + +#include "Eigen/src/Core/util/ReenableStupidWarnings.h" + +#endif // EIGEN_CXX11_TENSOR_MODULE diff --git a/unsupported/Eigen/CXX11/src/Core/util/CXX11Meta.h b/unsupported/Eigen/CXX11/src/Core/util/CXX11Meta.h index 0e274b801..3a08628be 100644 --- a/unsupported/Eigen/CXX11/src/Core/util/CXX11Meta.h +++ b/unsupported/Eigen/CXX11/src/Core/util/CXX11Meta.h @@ -317,7 +317,7 @@ constexpr inline decltype(reduce<sum_op, Ts...>::run((*((Ts*)0))...)) arg_sum(Ts template<typename Array, int... n> constexpr inline Array h_array_reverse(Array arr, numeric_list<int, n...>) { - return {{std_array_get<sizeof...(n) - n - 1>(arr)...}}; + return {{array_get<sizeof...(n) - n - 1>(arr)...}}; } template<typename T, std::size_t N> @@ -335,9 +335,9 @@ constexpr inline std::array<T, N> array_reverse(std::array<T, N> arr) // an infinite loop) template<typename Reducer, typename T, std::size_t N, std::size_t n = N - 1> struct h_array_reduce { - constexpr static inline auto run(std::array<T, N> arr) -> decltype(Reducer::run(h_array_reduce<Reducer, T, N, n - 1>::run(arr), std_array_get<n>(arr))) + constexpr static inline auto run(std::array<T, N> arr) -> decltype(Reducer::run(h_array_reduce<Reducer, T, N, n - 1>::run(arr), array_get<n>(arr))) { - return Reducer::run(h_array_reduce<Reducer, T, N, n - 1>::run(arr), std_array_get<n>(arr)); + return Reducer::run(h_array_reduce<Reducer, T, N, n - 1>::run(arr), array_get<n>(arr)); } }; @@ -346,7 +346,7 @@ struct h_array_reduce<Reducer, T, N, 0> { constexpr static inline T run(std::array<T, N> arr) { - return std_array_get<0>(arr); + return array_get<0>(arr); } }; @@ -370,12 +370,20 @@ constexpr inline auto array_prod(std::array<T, N> arr) -> decltype(array_reduce< return array_reduce<product_op, T, N>(arr); } +template<typename t> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE t array_prod(const std::vector<t>& a) { + eigen_assert(a.size() > 0); + t prod = 1; + for (size_t i = 0; i < a.size(); ++i) { prod *= a[i]; } + return prod; +} + /* zip an array */ template<typename Op, typename A, typename B, std::size_t N, int... n> constexpr inline std::array<decltype(Op::run(A(), B())),N> h_array_zip(std::array<A, N> a, std::array<B, N> b, numeric_list<int, n...>) { - return std::array<decltype(Op::run(A(), B())),N>{{ Op::run(std_array_get<n>(a), std_array_get<n>(b))... }}; + return std::array<decltype(Op::run(A(), B())),N>{{ Op::run(array_get<n>(a), array_get<n>(b))... }}; } template<typename Op, typename A, typename B, std::size_t N> @@ -387,9 +395,9 @@ constexpr inline std::array<decltype(Op::run(A(), B())),N> array_zip(std::array< /* zip an array and reduce the result */ template<typename Reducer, typename Op, typename A, typename B, std::size_t N, int... n> -constexpr inline auto h_array_zip_and_reduce(std::array<A, N> a, std::array<B, N> b, numeric_list<int, n...>) -> decltype(reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A(), B()))>::type...>::run(Op::run(std_array_get<n>(a), std_array_get<n>(b))...)) +constexpr inline auto h_array_zip_and_reduce(std::array<A, N> a, std::array<B, N> b, numeric_list<int, n...>) -> decltype(reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A(), B()))>::type...>::run(Op::run(array_get<n>(a), array_get<n>(b))...)) { - return reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A(), B()))>::type...>::run(Op::run(std_array_get<n>(a), std_array_get<n>(b))...); + return reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A(), B()))>::type...>::run(Op::run(array_get<n>(a), array_get<n>(b))...); } template<typename Reducer, typename Op, typename A, typename B, std::size_t N> @@ -403,7 +411,7 @@ constexpr inline auto array_zip_and_reduce(std::array<A, N> a, std::array<B, N> template<typename Op, typename A, std::size_t N, int... n> constexpr inline std::array<decltype(Op::run(A())),N> h_array_apply(std::array<A, N> a, numeric_list<int, n...>) { - return std::array<decltype(Op::run(A())),N>{{ Op::run(std_array_get<n>(a))... }}; + return std::array<decltype(Op::run(A())),N>{{ Op::run(array_get<n>(a))... }}; } template<typename Op, typename A, std::size_t N> @@ -415,9 +423,9 @@ constexpr inline std::array<decltype(Op::run(A())),N> array_apply(std::array<A, /* apply stuff to an array and reduce */ template<typename Reducer, typename Op, typename A, std::size_t N, int... n> -constexpr inline auto h_array_apply_and_reduce(std::array<A, N> arr, numeric_list<int, n...>) -> decltype(reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A()))>::type...>::run(Op::run(std_array_get<n>(arr))...)) +constexpr inline auto h_array_apply_and_reduce(std::array<A, N> arr, numeric_list<int, n...>) -> decltype(reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A()))>::type...>::run(Op::run(array_get<n>(arr))...)) { - return reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A()))>::type...>::run(Op::run(std_array_get<n>(arr))...); + return reduce<Reducer, typename id_numeric<int,n,decltype(Op::run(A()))>::type...>::run(Op::run(array_get<n>(arr))...); } template<typename Reducer, typename Op, typename A, std::size_t N> @@ -497,7 +505,3 @@ InstType instantiate_by_c_array(ArrType* arr) } // end namespace Eigen #endif // EIGEN_CXX11META_H - -/* - * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle; - */ diff --git a/unsupported/Eigen/CXX11/src/Core/util/CXX11Workarounds.h b/unsupported/Eigen/CXX11/src/Core/util/CXX11Workarounds.h index d71a67590..a590cf4e1 100644 --- a/unsupported/Eigen/CXX11/src/Core/util/CXX11Workarounds.h +++ b/unsupported/Eigen/CXX11/src/Core/util/CXX11Workarounds.h @@ -17,9 +17,6 @@ #error Intel Compiler only supports required C++ features since version 13.1. // note that most stuff in principle works with 13.0 but when combining // some features, at some point 13.0 will just fail with an internal assertion -#elif defined(__clang__) && (__clang_major__ < 3 || (__clang_major__ == 3 && __clang_minor__ < 1)) -// note that it _should_ work with 3.1 but it was only tested with 3.2 -#error Clang C++ Compiler (clang++) only supports required C++ features since version 3.1. #elif defined(__GNUC__) && !defined(__clang__) && !defined(__INTEL_COMPILER) && (__GNUC__ < 4 || (__GNUC__ == 4 && __GNUC_MINOR__ < 6)) // G++ < 4.6 by default will continue processing the source files - even if we use #error to make // it error out. For this reason, we use the pragma to make sure G++ aborts at the first error @@ -42,32 +39,46 @@ namespace Eigen { +// Use std::array as Eigen array +template <typename T, std::size_t N> using array = std::array<T, N>; + namespace internal { /* std::get is only constexpr in C++14, not yet in C++11 * - libstdc++ from version 4.7 onwards has it nevertheless, * so use that * - libstdc++ older versions: use _M_instance directly - * - libc++ from version 3.4 onwards has it IF compiled with - * -std=c++1y - * - libc++ older versions or -std=c++11: use __elems_ directly + * - libc++ all versions so far: use __elems_ directly * - all other libs: use std::get to be portable, but * this may not be constexpr */ #if defined(__GLIBCXX__) && __GLIBCXX__ < 20120322 #define STD_GET_ARR_HACK a._M_instance[I] -#elif defined(_LIBCPP_VERSION) && (!defined(_LIBCPP_STD_VER) || _LIBCPP_STD_VER <= 11) +#elif defined(_LIBCPP_VERSION) #define STD_GET_ARR_HACK a.__elems_[I] #else #define STD_GET_ARR_HACK std::template get<I, T, N>(a) #endif -template<std::size_t I, class T, std::size_t N> constexpr inline T& std_array_get(std::array<T,N>& a) { return (T&) STD_GET_ARR_HACK; } -template<std::size_t I, class T, std::size_t N> constexpr inline T&& std_array_get(std::array<T,N>&& a) { return (T&&) STD_GET_ARR_HACK; } -template<std::size_t I, class T, std::size_t N> constexpr inline T const& std_array_get(std::array<T,N> const& a) { return (T const&) STD_GET_ARR_HACK; } +template<std::size_t I, class T, std::size_t N> constexpr inline T& array_get(std::array<T,N>& a) { return (T&) STD_GET_ARR_HACK; } +template<std::size_t I, class T, std::size_t N> constexpr inline T&& array_get(std::array<T,N>&& a) { return (T&&) STD_GET_ARR_HACK; } +template<std::size_t I, class T, std::size_t N> constexpr inline T const& array_get(std::array<T,N> const& a) { return (T const&) STD_GET_ARR_HACK; } + +template<std::size_t I, class T> constexpr inline T& array_get(std::vector<T>& a) { return a[I]; } +template<std::size_t I, class T> constexpr inline T&& array_get(std::vector<T>&& a) { return a[I]; } +template<std::size_t I, class T> constexpr inline T const& array_get(std::vector<T> const& a) { return a[I]; } #undef STD_GET_ARR_HACK +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<const std::array<T,N> > { + static const size_t value = N; +}; +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<std::array<T,N> > { + static const size_t value = N; +}; + /* Suppose you have a template of the form * template<typename T> struct X; * And you want to specialize it in such a way: diff --git a/unsupported/Eigen/CXX11/src/Core/util/EmulateCXX11Meta.h b/unsupported/Eigen/CXX11/src/Core/util/EmulateCXX11Meta.h new file mode 100644 index 000000000..494f95690 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Core/util/EmulateCXX11Meta.h @@ -0,0 +1,435 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_EMULATE_CXX11_META_H +#define EIGEN_EMULATE_CXX11_META_H + + + +namespace Eigen { + +// The array class is only available starting with cxx11. Emulate our own here +// if needed +template <typename T, size_t n> class array { + public: + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE T& operator[] (size_t index) { return values[index]; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const T& operator[] (size_t index) const { return values[index]; } + + static const std::size_t size = n; + + T values[n]; + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array() { } + explicit EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v) { + EIGEN_STATIC_ASSERT(n==1, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2) { + EIGEN_STATIC_ASSERT(n==2, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2, const T& v3) { + EIGEN_STATIC_ASSERT(n==3, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2, const T& v3, + const T& v4) { + EIGEN_STATIC_ASSERT(n==4, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + values[3] = v4; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2, const T& v3, const T& v4, + const T& v5) { + EIGEN_STATIC_ASSERT(n==5, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + values[3] = v4; + values[4] = v5; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2, const T& v3, const T& v4, + const T& v5, const T& v6) { + EIGEN_STATIC_ASSERT(n==6, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + values[3] = v4; + values[4] = v5; + values[5] = v6; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array(const T& v1, const T& v2, const T& v3, const T& v4, + const T& v5, const T& v6, const T& v7) { + EIGEN_STATIC_ASSERT(n==7, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + values[3] = v4; + values[4] = v5; + values[5] = v6; + values[6] = v7; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE array( + const T& v1, const T& v2, const T& v3, const T& v4, + const T& v5, const T& v6, const T& v7, const T& v8) { + EIGEN_STATIC_ASSERT(n==8, YOU_MADE_A_PROGRAMMING_MISTAKE) + values[0] = v1; + values[1] = v2; + values[2] = v3; + values[3] = v4; + values[4] = v5; + values[5] = v6; + values[6] = v7; + values[7] = v8; + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + array(std::initializer_list<T> l) { + eigen_assert(l.size() == n); + std::copy(l.begin(), l.end(), values); + } +#endif +}; + + +namespace internal { + +/** \internal + * \file CXX11/Core/util/EmulateCXX11Meta.h + * This file emulates a subset of the functionality provided by CXXMeta.h for + * compilers that don't yet support cxx11 such as nvcc. + */ + +struct empty_list { static const std::size_t count = 0; }; + +template<typename T, typename Tail=empty_list> struct type_list { + typedef T HeadType; + typedef Tail TailType; + static const T head; + static const Tail tail; + static const std::size_t count = 1 + Tail::count; +}; + +struct null_type { }; + +template<typename T1 = null_type, typename T2 = null_type, typename T3 = null_type, + typename T4 = null_type, typename T5 = null_type, typename T6 = null_type, + typename T7 = null_type, typename T8 = null_type> +struct make_type_list { + typedef typename make_type_list<T2, T3, T4, T5, T6, T7, T8>::type tailresult; + + typedef type_list<T1, tailresult> type; +}; + +template<> struct make_type_list<> { + typedef empty_list type; +}; + + +template <std::size_t index, class TList> struct get_type; + +template <class Head, class Tail> +struct get_type<0, type_list<Head, Tail> > +{ + typedef Head type; +}; + +template <std::size_t i, class Head, class Tail> +struct get_type<i, type_list<Head, Tail> > +{ + typedef typename get_type<i-1, Tail>::type type; +}; + + +/* numeric list */ +template <typename T, T n> +struct type2val { + typedef T type; + static const T value = n; +}; + + +template<typename T, size_t n, T V> struct gen_numeric_list_repeated; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 1, V> { + typedef typename make_type_list<type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 2, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 3, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 4, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V>, type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 5, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V>, type2val<T, V>, type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 6, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V>, + type2val<T, V>, type2val<T, V>, type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 7, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V>, + type2val<T, V>, type2val<T, V>, type2val<T, V>, + type2val<T, V> >::type type; +}; + +template<typename T, T V> struct gen_numeric_list_repeated<T, 8, V> { + typedef typename make_type_list<type2val<T, V>, type2val<T, V>, type2val<T, V>, + type2val<T, V>, type2val<T, V>, type2val<T, V>, + type2val<T, V>, type2val<T, V> >::type type; +}; + + +template <std::size_t index, class NList> struct get; + +template <std::size_t i> +struct get<i, empty_list> +{ + get() { eigen_assert(false && "index overflow"); } + typedef void type; + static const char value = '\0'; +}; + +template <std::size_t i, class Head> +struct get<i, type_list<Head, empty_list> > +{ + get() { eigen_assert(false && "index overflow"); } + typedef void type; + static const char value = '\0'; +}; + +template <class Head> +struct get<0, type_list<Head, empty_list> > +{ + typedef typename Head::type type; + static const type value = Head::value; +}; + +template <class Head, class Tail> +struct get<0, type_list<Head, Tail> > +{ + typedef typename Head::type type; + static const type value = Head::value; +}; + +template <std::size_t i, class Head, class Tail> +struct get<i, type_list<Head, Tail> > +{ + typedef typename Tail::HeadType::type type; + static const type value = get<i-1, Tail>::value; +}; + + +template <class NList> struct arg_prod { + static const typename NList::HeadType::type value = get<0, NList>::value * arg_prod<typename NList::TailType>::value; +}; +template <> struct arg_prod<empty_list> { + static const int value = 1; +}; + + +template<int n, typename t> +array<t, n> repeat(t v) { + array<t, n> array; + array.fill(v); + return array; +} + +template<std::size_t I, class Head, class Tail> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Head::type array_get(type_list<Head, Tail>& a) { + return get<I, type_list<Head, Tail> >::value; +} +template<std::size_t I, class Head, class Tail> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Head::type array_get(const type_list<Head, Tail>& a) { + return get<I, type_list<Head, Tail> >::value; +} + +template <class NList> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename NList::HeadType::type array_prod(const NList& l) { + return arg_prod<NList>::value; +}; + +template<std::size_t n, typename t> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE t array_prod(const array<t, n>& a) { + t prod = 1; + for (size_t i = 0; i < n; ++i) { prod *= a[i]; } + return prod; +} +template<typename t> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE t array_prod(const array<t, 0>& /*a*/) { + return 0; +} + +template<typename t> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE t array_prod(const std::vector<t>& a) { + eigen_assert(a.size() > 0); + t prod = 1; + for (size_t i = 0; i < a.size(); ++i) { prod *= a[i]; } + return prod; +} + +template<std::size_t I, class T, std::size_t N> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T& array_get(array<T,N>& a) { + return a[I]; +} +template<std::size_t I, class T, std::size_t N> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const T& array_get(const array<T,N>& a) { + return a[I]; +} + +template<std::size_t I, class T> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T& array_get(std::vector<T>& a) { + return a[I]; +} +template<std::size_t I, class T> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const T& array_get(const std::vector<T>& a) { + return a[I]; +} + +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<array<T,N> > { + static const size_t value = N; +}; +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<array<T,N>& > { + static const size_t value = N; +}; +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<const array<T,N> > { + static const size_t value = N; +}; +template <typename T> struct array_size; +template<class T, std::size_t N> struct array_size<const array<T,N>& > { + static const size_t value = N; +}; + +struct sum_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a + b; } +}; +struct product_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a * b; } +}; + +struct logical_and_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a && b; } +}; +struct logical_or_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a || b; } +}; + +struct equal_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a == b; } +}; +struct not_equal_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a != b; } +}; +struct lesser_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a < b; } +}; +struct lesser_equal_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a <= b; } +}; + +struct greater_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a > b; } +}; +struct greater_equal_op { + template<typename A, typename B> static inline bool run(A a, B b) { return a >= b; } +}; + +struct not_op { + template<typename A> static inline bool run(A a) { return !a; } +}; +struct negation_op { + template<typename A> static inline bool run(A a) { return -a; } +}; +struct greater_equal_zero_op { + template<typename A> static inline bool run(A a) { return a >= 0; } +}; + + +template<typename Reducer, typename Op, typename A, std::size_t N> +struct ArrayApplyAndReduce { + static inline bool run(const array<A, N>& a) { + EIGEN_STATIC_ASSERT(N >= 2, YOU_MADE_A_PROGRAMMING_MISTAKE); + bool result = Reducer::run(Op::run(a[0]), Op::run(a[1])); + for (size_t i = 2; i < N; ++i) { + result = Reducer::run(result, Op::run(a[i])); + } + return result; + } +}; + +template<typename Reducer, typename Op, typename A> +struct ArrayApplyAndReduce<Reducer, Op, A, 1> { + static inline bool run(const array<A, 1>& a) { + return Op::run(a[0]); + } +}; + +template<typename Reducer, typename Op, typename A, std::size_t N> +inline bool array_apply_and_reduce(const array<A, N>& a) { + return ArrayApplyAndReduce<Reducer, Op, A, N>::run(a); +} + +template<typename Reducer, typename Op, typename A, typename B, std::size_t N> +struct ArrayZipAndReduce { + static inline bool run(const array<A, N>& a, const array<B, N>& b) { + EIGEN_STATIC_ASSERT(N >= 2, YOU_MADE_A_PROGRAMMING_MISTAKE); + bool result = Reducer::run(Op::run(a[0], b[0]), Op::run(a[1], b[1])); + for (size_t i = 2; i < N; ++i) { + result = Reducer::run(result, Op::run(a[i], b[i])); + } + return result; + } +}; + +template<typename Reducer, typename Op, typename A, typename B> +struct ArrayZipAndReduce<Reducer, Op, A, B, 1> { + static inline bool run(const array<A, 1>& a, const array<B, 1>& b) { + return Op::run(a[0], b[0]); + } +}; + +template<typename Reducer, typename Op, typename A, typename B, std::size_t N> +inline bool array_zip_and_reduce(const array<A, N>& a, const array<B, N>& b) { + return ArrayZipAndReduce<Reducer, Op, A, B, N>::run(a, b); +} + +} // end namespace internal + +} // end namespace Eigen + + + +#endif // EIGEN_EMULATE_CXX11_META_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/README.md b/unsupported/Eigen/CXX11/src/Tensor/README.md new file mode 100644 index 000000000..6a4d52cc3 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/README.md @@ -0,0 +1,1446 @@ +# Eigen Tensors + +Tensors are multidimensional arrays of elements. Elements are typically scalars, +but more complex types such as strings are also supported. + +[TOC] + +## Tensor Classes + +You can manipulate a tensor with one of the following classes. They all are in +the namespace ```::Eigen.``` + + +### Class Tensor<data_type, rank> + +This is the class to use to create a tensor and allocate memory for it. The +class is templatized with the tensor datatype, such as float or int, and the +tensor rank. The rank is the number of dimensions, for example rank 2 is a +matrix. + +Tensors of this class are resizable. For example, if you assign a tensor of a +different size to a Tensor, that tensor is resized to match its new value. + +#### Constructor Tensor<data_type, rank>(size0, size1, ...) + +Constructor for a Tensor. The constructor must be passed ```rank``` integers +indicating the sizes of the instance along each of the the ```rank``` +dimensions. + + // Create a tensor of rank 3 of sizes 2, 3, 4. This tensor owns + // memory to hold 24 floating point values (24 = 2 x 3 x 4). + Tensor<float, 3> t_3d(2, 3, 4); + + // Resize t_3d by assigning a tensor of different sizes, but same rank. + t_3d = Tensor<float, 3>(3, 4, 3); + +#### Constructor Tensor<data_type, rank>(size_array) + +Constructor where the sizes for the constructor are specified as an array of +values instead of an explicitly list of parameters. The array type to use is +```Eigen::array<Eigen::Index>```. The array can be constructed automatically +from an initializer list. + + // Create a tensor of strings of rank 2 with sizes 5, 7. + Tensor<string, 2> t_2d({5, 7}); + + +### Class TensorFixedSize<data_type, Sizes<size0, size1, ...>> + +Class to use for tensors of fixed size, where the size is known at compile +time. Fixed sized tensors can provide very fast computations because all their +dimensions are known by the compiler. FixedSize tensors are not resizable. + +If the total number of elements in a fixed size tensor is small enough the +tensor data is held onto the stack and does not cause heap allocation and free. + + // Create a 4 x 3 tensor of floats. + TensorFixedSize<float, Sizes<4, 3>> t_4x3; + +### Class TensorMap<Tensor<data_type, rank>> + +This is the class to use to create a tensor on top of memory allocated and +owned by another part of your code. It allows to view any piece of allocated +memory as a Tensor. Instances of this class do not own the memory where the +data are stored. + +A TensorMap is not resizable because it does not own the memory where its data +are stored. + +#### Constructor TensorMap<Tensor<data_type, rank>>(data, size0, size1, ...) + +Constructor for a Tensor. The constructor must be passed a pointer to the +storage for the data, and "rank" size attributes. The storage has to be +large enough to hold all the data. + + // Map a tensor of ints on top of stack-allocated storage. + int storage[128]; // 2 x 4 x 2 x 8 = 128 + TensorMap<int, 4> t_4d(storage, 2, 4, 2, 8); + + // The same storage can be viewed as a different tensor. + // You can also pass the sizes as an array. + TensorMap<int, 2> t_2d(storage, 16, 8); + + // You can also map fixed-size tensors. Here we get a 1d view of + // the 2d fixed-size tensor. + Tensor<float, Sizes<4, 5>> t_4x3; + TensorMap<float, 1> t_12(t_4x3, 12); + + +#### Class TensorRef + +See Assigning to a TensorRef below. + +## Accessing Tensor Elements + +#### <data_type> tensor(index0, index1...) + +Return the element at position ```(index0, index1...)``` in tensor +```tensor```. You must pass as many parameters as the rank of ```tensor```. +The expression can be used as an l-value to set the value of the element at the +specified position. The value returned is of the datatype of the tensor. + + // Set the value of the element at position (0, 1, 0); + Tensor<float, 3> t_3d(2, 3, 4); + t_3d(0, 1, 0) = 12.0f; + + // Initialize all elements to random values. + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 4; ++k) { + t_3d(i, j, k) = ...some random value...; + } + } + } + + // Print elements of a tensor. + for (int i = 0; i < 2; ++i) { + LOG(INFO) << t_3d(i, 0, 0); + } + + +## TensorLayout + +The tensor library supports 2 layouts: ```ColMajor``` (the default) and +```RowMajor```. Only the default column major layout is currently fully +supported, and it is therefore not recommended to attempt to use the row major +layout at the moment. + +The layout of a tensor is optionally specified as part of its type. If not +specified explicitly column major is assumed. + + Tensor<float, 3, ColMajor> col_major; // equivalent to Tensor<float, 3> + TensorMap<Tensor<float, 3, RowMajor> > row_major(data, ...); + +All the arguments to an expression must use the same layout. Attempting to mix +different layouts will result in a compilation error. + +It is possible to change the layout of a tensor or an expression using the +```swap_layout()``` method. Note that this will also reverse the order of the +dimensions. + + Tensor<float, 2, ColMajor> col_major(2, 4); + Tensor<float, 2, RowMajor> row_major(2, 4); + + Tensor<float, 2> col_major_result = col_major; // ok, layouts match + Tensor<float, 2> col_major_result = row_major; // will not compile + + // Simple layout swap + col_major_result = row_major.swap_layout(); + eigen_assert(col_major_result.dimension(0) == 4); + eigen_assert(col_major_result.dimension(1) == 2); + + // Swap the layout and preserve the order of the dimensions + array<int, 2> shuffle(1, 0); + col_major_result = row_major.swap_layout().shuffle(shuffle); + eigen_assert(col_major_result.dimension(0) == 2); + eigen_assert(col_major_result.dimension(1) == 4); + + +## Tensor Operations + +The Eigen Tensor library provides a vast library of operations on Tensors: +numerical operations such as addition and multiplication, geometry operations +such as slicing and shuffling, etc. These operations are available as methods +of the Tensor classes, and in some cases as operator overloads. For example +the following code computes the elementwise addition of two tensors: + + Tensor<float, 3> t1(2, 3, 4); + ...set some values in t1... + Tensor<float, 3> t2(2, 3, 4); + ...set some values in t2... + // Set t3 to the element wise sum of t1 and t2 + Tensor<float, 3> t3 = t1 + t2; + +While the code above looks easy enough, it is important to understand that the +expression ```t1 + t2``` is not actually adding the values of the tensors. The +expression instead constructs a "tensor operator" object of the class +TensorCwiseBinaryOp<scalar_sum>, which has references to the tensors +```t1``` and ```t2```. This is a small C++ object that knows how to add +```t1``` and ```t2```. It is only when the value of the expression is assigned +to the tensor ```t3``` that the addition is actually performed. Technically, +this happens through the overloading of ```operator=()``` in the Tensor class. + +This mechanism for computing tensor expressions allows for lazy evaluation and +optimizations which are what make the tensor library very fast. + +Of course, the tensor operators do nest, and the expression ```t1 + t2 * +0.3f``` is actually represented with the (approximate) tree of operators: + + TensorCwiseBinaryOp<scalar_sum>(t1, TensorCwiseUnaryOp<scalar_mul>(t2, 0.3f)) + + +### Tensor Operations and C++ "auto" + +Because Tensor operations create tensor operators, the C++ ```auto``` keyword +does not have its intuitive meaning. Consider these 2 lines of code: + + Tensor<float, 3> t3 = t1 + t2; + auto t4 = t1 + t2; + +In the first line we allocate the tensor ```t3``` and it will contain the +result of the addition of ```t1``` and ```t2```. In the second line, ```t4``` +is actually the tree of tensor operators that will compute the addition of +```t1``` and ```t2```. In fact, ```t4``` is *not* a tensor and you cannot get +the values of its elements: + + Tensor<float, 3> t3 = t1 + t2; + cout << t3(0, 0, 0); // OK prints the value of t1(0, 0, 0) + t2(0, 0, 0) + + auto t4 = t1 + t2; + cout << t4(0, 0, 0); // Compilation error! + +When you use ```auto``` you do not get a Tensor as a result but instead a +non-evaluated expression. So only use ```auto``` to delay evaluation. + +Unfortunately, there is no single underlying concrete type for holding +non-evaluated expressions, hence you have to use auto in the case when you do +want to hold non-evaluated expressions. + +When you need the results of set of tensor computations you have to assign the +result to a Tensor that will be capable of holding onto them. This can be +either a normal Tensor, a fixed size Tensor, or a TensorMap on an existing +piece of memory. All the following will work: + + auto t4 = t1 + t2; + + Tensor<float, 3> result = t4; // Could also be: result(t4); + cout << result(0, 0, 0); + + TensorMap<float, 4> result(<a float* with enough space>, <size0>, ...) = t4; + cout << result(0, 0, 0); + + TensorFixedSize<float, Sizes<size0, ...>> result = t4; + cout << result(0, 0, 0); + +Until you need the results, you can keep the operation around, and even reuse +it for additional operations. As long as you keep the expression as an +operation, no computation is performed. + + // One way to compute exp((t1 + t2) * 0.2f); + auto t3 = t1 + t2; + auto t4 = t3 * 0.2f; + auto t5 = t4.exp(); + Tensor<float, 3> result = t5; + + // Another way, exactly as efficient as the previous one: + Tensor<float, 3> result = ((t1 + t2) * 0.2f).exp(); + +### Controlling When Expression are Evaluated + +There are several ways to control when expressions are evaluated: +* Assignment to a Tensor, TensorFixedSize, or TensorMap. +* Use of the eval() method. +* Assignment to a TensorRef. + +#### Assigning to a Tensor, TensorFixedSize, or TensorMap. + +The most common way to evaluate an expression is to assign it to a Tensor. In +the example below, the ```auto``` declarations make the intermediate values +"Operations", not Tensors, and do not cause the expressions to be evaluated. +The assignment to the Tensor ```result``` causes the evaluation of all the +operations. + + auto t3 = t1 + t2; // t3 is an Operation. + auto t4 = t3 * 0.2f; // t4 is an Operation. + auto t5 = t4.exp(); // t5 is an Operation. + Tensor<float, 3> result = t5; // The operations are evaluated. + +If you know the ranks and sizes of the Operation value you can assign the +Operation to a TensorFixedSize instead of a Tensor, which is a bit more +efficient. + + // We know that the result is a 4x4x2 tensor! + TensorFixedSize<float, 4, 4, 2> result = t5; + +Simiarly, assigning an expression to a TensorMap causes its evaluation. Like +tensors of type TensorFixedSize, TensorMaps cannot be resized so they have to +have the rank and sizes of the expression that are assigned to them. + +#### Calling eval(). + +When you compute large composite expressions, you sometimes want to tell Eigen +that an intermediate value in the expression tree is worth evaluating ahead of +time. This is done by inserting a call to the ```eval()``` method of the +expression Operation. + + // The previous example could have been written: + Tensor<float, 3> result = ((t1 + t2) * 0.2f).exp(); + + // If you want to compute (t1 + t2) once ahead of time you can write: + Tensor<float, 3> result = ((t1 + t2).eval() * 0.2f).exp(); + +Semantically, calling ```eval()``` is equivalent to materializing the value of +the expression in a temporary Tensor of the right size. The code above in +effect does: + + // .eval() knows the size! + TensorFixedSize<float, 4, 4, 2> tmp = t1 + t2; + Tensor<float, 3> result = (tmp * 0.2f).exp(); + +Note that the return value of ```eval()``` is itself an Operation, so the +following code does not do what you may think: + + // Here t3 is an evaluation Operation. t3 has not been evaluated yet. + auto t3 = (t1 + t2).eval(); + + // You can use t3 in another expression. Still no evaluation. + auto t4 = (t3 * 0.2f).exp(); + + // The value is evaluated when you assign the Operation to a Tensor, using + // an intermediate tensor to represent t3.x + Tensor<float, 3> result = t4; + +While in the examples above calling ```eval()``` does not make a difference in +performance, in other cases it can make a huge difference. In the expression +below the ```broadcast()``` expression causes the ```X.maximum()``` expression +to be evaluated many times: + + Tensor<...> X ...; + Tensor<...> Y = ((X - X.maximum(depth_dim).reshape(dims2d).broadcast(bcast)) + * beta).exp(); + +Inserting a call to ```eval()``` between the ```maximum()``` and +```reshape()``` calls guarantees that maximum() is only computed once and +greatly speeds-up execution: + + Tensor<...> Y = + ((X - X.maximum(depth_dim).eval().reshape(dims2d).broadcast(bcast)) + * beta).exp(); + +In the other example below, the tensor ```Y``` is both used in the expression +and its assignment. This is an aliasing problem and if the evaluation is not +done in the right order Y will be updated incrementally during the evaluation +resulting in bogus results: + + Tensor<...> Y ...; + Y = Y / (Y.sum(depth_dim).reshape(dims2d).broadcast(bcast)); + +Inserting a call to ```eval()``` between the ```sum()``` and ```reshape()``` +expressions ensures that the sum is computed before any updates to ```Y``` are +done. + + Y = Y / (Y.sum(depth_dim).eval().reshape(dims2d).broadcast(bcast)); + +Note that an eval around the full right hand side expression is not needed +because the generated has to compute the i-th value of the right hand side +before assigning it to the left hand side. + +However, if you were assigning the expression value to a shuffle of ```Y``` +then you would need to force an eval for correctness by adding an ```eval()``` +call for the right hand side: + + Y.shuffle(...) = + (Y / (Y.sum(depth_dim).eval().reshape(dims2d).broadcast(bcast))).eval(); + + +#### Assigning to a TensorRef. + +If you need to access only a few elements from the value of an expression you +can avoid materializing the value in a full tensor by using a TensorRef. + +A TensorRef is a small wrapper class for any Eigen Operation. It provides +overloads for the ```()``` operator that let you access individual values in +the expression. TensorRef is convenient, because the Operation themselves do +not provide a way to access individual elements. + + // Create a TensorRef for the expression. The expression is not + // evaluated yet. + TensorRef<Tensor<float, 3> > ref = ((t1 + t2) * 0.2f).exp(); + + // Use "ref" to access individual elements. The expression is evaluated + // on the fly. + float at_0 = ref(0, 0, 0); + cout << ref(0, 1, 0); + +Only use TensorRef when you need a subset of the values of the expression. +TensorRef only computes the values you access. However note that if you are +going to access all the values it will be much faster to materialize the +results in a Tensor first. + +In some cases, if the full Tensor result would be very large, you may save +memory by accessing it as a TensorRef. But not always. So don't count on it. + + +### Controlling How Expressions Are Evaluated + +The tensor library provides several implementations of the various operations +such as contractions and convolutions. The implementations are optimized for +different environments: single threaded on CPU, multi threaded on CPU, or on a +GPU using cuda. Additional implementations may be added later. + +You can choose which implementation to use with the ```device()``` call. If +you do not choose an implementation explicitly the default implementation that +uses a single thread on the CPU is used. + +The default implementation has been optimized for recent Intel CPUs, taking +advantage of SSE, AVX, and FMA instructions. Work is ongoing to tune the +library on ARM CPUs. Note that you need to pass compiler-dependent flags +to enable the use of SSE, AVX, and other instructions. + +For example, the following code adds two tensors using the default +single-threaded CPU implementation: + + Tensor<float, 2> a(30, 40); + Tensor<float, 2> b(30, 40); + Tensor<float, 2> c = a + b; + +To choose a different implementation you have to insert a ```device()``` call +before the assignment of the result. For technical C++ reasons this requires +that the Tensor for the result be declared on its own. This means that you +have to know the size of the result. + + Eigen::Tensor<float, 2> c(30, 40); + c.device(...) = a + b; + +The call to ```device()``` must be the last call on the left of the operator=. + +You must pass to the ```device()``` call an Eigen device object. There are +presently three devices you can use: DefaultDevice, ThreadPoolDevice and +GpuDevice. + + +#### Evaluating With the DefaultDevice + +This is exactly the same as not inserting a ```device()``` call. + + DefaultDevice my_device; + c.device(my_device) = a + b; + +#### Evaluating with a Thread Pool + + // Create the Eigen ThreadPoolDevice. + Eigen::ThreadPoolDevice my_device(4 /* number of threads to use */); + + // Now just use the device when evaluating expressions. + Eigen::Tensor<float, 2> c(30, 50); + c.device(my_device) = a.contract(b, dot_product_dims); + + +#### Evaluating On GPU + +This is presently a bit more complicated than just using a thread pool device. +You need to create a GPU device but you also need to explicitly allocate the +memory for tensors with cuda. + + +## API Reference + +### Datatypes + +In the documentation of the tensor methods and Operation we mention datatypes +that are tensor-type specific: + +#### <Tensor-Type>::Dimensions + +Acts like an array of ints. Has an ```int size``` attribute, and can be +indexed like an array to access individual values. Used to represent the +dimensions of a tensor. See ```dimensions()```. + +#### <Tensor-Type>::Index + +Acts like an ```int```. Used for indexing tensors along their dimensions. See +```operator()```, ```dimension()```, and ```size()```. + +#### <Tensor-Type>::Scalar + +Represents the datatype of individual tensor elements. For example, for a +```Tensor<float>```, ```Scalar``` is the type ```float```. See +```setConstant()```. + +#### <Operation> + +We use this pseudo type to indicate that a tensor Operation is returned by a +method. We indicate in the text the type and dimensions of the tensor that the +Operation returns after evaluation. + +The Operation will have to be evaluated, for example by assigning it to a +tensor, before you can access the values of the resulting tensor. You can also +access the values through a TensorRef. + + +## Built-in Tensor Methods + +These are usual C++ methods that act on tensors immediately. They are not +Operations which provide delayed evaluation of their results. Unless specified +otherwise, all the methods listed below are available on all tensor classes: +Tensor, TensorFixedSize, and TensorMap. + +## Metadata + +### int NumDimensions + +Constant value indicating the number of dimensions of a Tensor. This is also +known as the tensor "rank". + + Eigen::Tensor<float, 2> a(3, 4); + cout << "Dims " << a.NumDimensions; + => Dims 2 + +### Dimensions dimensions() + +Returns an array-like object representing the dimensions of the tensor. +The actual type of the dimensions() result is <Tensor-Type>::Dimensions. + + Eigen::Tensor<float, 2> a(3, 4); + const Eigen::Tensor<float, 2>::Dimensions& d = a.dimensions(); + cout << "Dim size: " << d.size << ", dim 0: " << d[0] + << ", dim 1: " << d[1]; + => Dim size: 2, dim 0: 3, dim 1: 4 + +If you use a C++11 compiler, you can use ```auto``` to simplify the code: + + const auto& d = a.dimensions(); + cout << "Dim size: " << d.size << ", dim 0: " << d[0] + << ", dim 1: " << d[1]; + => Dim size: 2, dim 0: 3, dim 1: 4 + +### Index dimension(Index n) + +Returns the n-th dimension of the tensor. The actual type of the +```dimension()``` result is ```<Tensor-Type>::Index```, but you can +always use it like an int. + + Eigen::Tensor<float, 2> a(3, 4); + int dim1 = a.dimension(1); + cout << "Dim 1: " << dim1; + => Dim 1: 4 + +### Index size() + +Returns the total number of elements in the tensor. This is the product of all +the tensor dimensions. The actual type of the ```size()``` result is +```<Tensor-Type>::Index```, but you can always use it like an int. + + Eigen::Tensor<float, 2> a(3, 4); + cout << "Size: " << a.size(); + => Size: 12 + + +### Getting Dimensions From An Operation + +A few operations provide ```dimensions()``` directly, +e.g. ```TensorReslicingOp```. Most operations defer calculating dimensions +until the operation is being evaluated. If you need access to the dimensions +of a deferred operation, you can wrap it in a TensorRef (see Assigning to a +TensorRef above), which provides ```dimensions()``` and ```dimension()``` as +above. + +TensorRef can also wrap the plain Tensor types, so this is a useful idiom in +templated contexts where the underlying object could be either a raw Tensor +or some deferred operation (e.g. a slice of a Tensor). In this case, the +template code can wrap the object in a TensorRef and reason about its +dimensionality while remaining agnostic to the underlying type. + + +## Constructors and Copies + +TODO. + + Tensor(...) + TensorFixedSize(...) + TensorMap(PointerArgType dataPtr, Index firstDimension, IndexTypes... otherDimensions) + TensorMap(PointerArgType dataPtr, const array<Index, NumIndices>& dimensions) + TensorMap(PointerArgType dataPtr, const Dimensions& dimensions) + Self& operator=(const Self& other) + Self& operator=(const OtherDerived& other) + + +## Contents Initialization + +When a new Tensor or a new TensorFixedSize are created, memory is allocated to +hold all the tensor elements, but the memory is not initialized. Similarly, +when a new TensorMap is created on top of non-initialized memory the memory its +contents are not initialized. + +You can use one of the methods below to initialize the tensor memory. These +have an immediate effect on the tensor and return the tensor itself as a +result. These are not tensor Operations which delay evaluation. + +### <Tensor-Type> setConstant(const Scalar& val) + +Sets all elements of the tensor to the constant value ```val```. ```Scalar``` +is the type of data stored in the tensor. You can pass any value that is +convertible to that type. + +Returns the tensor itself in case you want to chain another call. + + a.setConstant(12.3f); + cout << "Constant: " << endl << a << endl << endl; + => + Constant: + 12.3 12.3 12.3 12.3 + 12.3 12.3 12.3 12.3 + 12.3 12.3 12.3 12.3 + +Note that ```setConstant()``` can be used on any tensor where the element type +has a copy constructor and an ```operator=()```: + + Eigen::Tensor<string, 2> a(2, 3); + a.setConstant("yolo"); + cout << "String tensor: " << endl << a << endl << endl; + => + String tensor: + yolo yolo yolo + yolo yolo yolo + + +### <Tensor-Type> setZero() + +Fills the tensor with zeros. Equivalent to ```setConstant(Scalar(0))```. +Returns the tensor itself in case you want to chain another call. + + a.setZero(); + cout << "Zeros: " << endl << a << endl << endl; + => + Zeros: + 0 0 0 0 + 0 0 0 0 + 0 0 0 0 + + +### <Tensor-Type> setValues({..initializer_list}) + +Fills the tensor with explicit values specified in a std::initializer_list. +The type of the initializer list depends on the type and rank of the tensor. + +If the tensor has rank N, the initializer list must be nested N times. The +most deeply nested lists must contains P scalars of the Tensor type where P is +the size of the last dimension of the Tensor. + +For example, for a ```TensorFixedSize<float, 2, 3>``` the initializer list must +contains 2 lists of 3 floats each. + +```setValues()``` returns the tensor itself in case you want to chain another +call. + + Eigen::Tensor<float, 2> a(2, 3); + a.setValues({{0.0f, 1.0f, 2.0f}, {3.0f, 4.0f, 5.0f}}); + cout << "a" << endl << a << endl << endl; + => + a + 0 1 2 + 3 4 5 + +If a list is too short, the corresponding elements of the tensor will not be +changed. This is valid at each level of nesting. For example the following +code only sets the values of the first row of the tensor. + + Eigen::Tensor<int, 2> a(2, 3); + a.setConstant(1000); + a.setValues({{10, 20, 30}}); + cout << "a" << endl << a << endl << endl; + => + a + 10 20 30 + 1000 1000 1000 + +### <Tensor-Type> setRandom() + +Fills the tensor with random values. Returns the tensor itself in case you +want to chain another call. + + a.setRandom(); + cout << "Random: " << endl << a << endl << endl; + => + Random: + 0.680375 0.59688 -0.329554 0.10794 + -0.211234 0.823295 0.536459 -0.0452059 + 0.566198 -0.604897 -0.444451 0.257742 + +You can customize ```setRandom()``` by providing your own random number +generator as a template argument: + + a.setRandom<MyRandomGenerator>(); + +Here, ```MyRandomGenerator``` must be a struct with the following member +functions, where Scalar and Index are the same as ```<Tensor-Type>::Scalar``` +and ```<Tensor-Type>::Index```. + +See ```struct UniformRandomGenerator``` in TensorFunctors.h for an example. + + // Custom number generator for use with setRandom(). + struct MyRandomGenerator { + // Default and copy constructors. Both are needed + MyRandomGenerator() { } + MyRandomGenerator(const MyRandomGenerator& ) { } + + // Return a random value to be used. "element_location" is the + // location of the entry to set in the tensor, it can typically + // be ignored. + Scalar operator()(Eigen::DenseIndex element_location, + Eigen::DenseIndex /*unused*/ = 0) const { + return <randomly generated value of type T>; + } + + // Same as above but generates several numbers at a time. + typename internal::packet_traits<Scalar>::type packetOp( + Eigen::DenseIndex packet_location, Eigen::DenseIndex /*unused*/ = 0) const { + return <a packet of randomly generated values>; + } + }; + +You can also use one of the 2 random number generators that are part of the +tensor library: +* UniformRandomGenerator +* NormalRandomGenerator + + +## Data Access + +TODO + + const Scalar& operator()(const array<Index, NumIndices>& indices) + const Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) + Scalar& operator()(const array<Index, NumIndices>& indices) + Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) + Scalar& operator[](Index index) + ??? mention coeff() and coeffRef() ??? + +### Scalar* data() +### const Scalar* data() const + +Returns a pointer to the storage for the tensor. The pointer is const if the +tensor was const. This allows direct access to the data. The layout of the +data depends on the tensor layout: RowMajor or ColMajor. + +This access is usually only needed for special cases, for example when mixing +Eigen Tensor code with other libraries. + +Scalar is the type of data stored in the tensor. + + Eigen::Tensor<float, 2> a(3, 4); + float* a_data = a.data(); + a_data[0] = 123.45f; + cout << "a(0, 0): " << a(0, 0); + => a(0, 0): 123.45 + + +## Tensor Operations + +All the methods documented below return non evaluated tensor ```Operations```. +These can be chained: you can apply another Tensor Operation to the value +returned by the method. + +The chain of Operation is evaluated lazily, typically when it is assigned to a +tensor. See "Controlling when Expression are Evaluated" for more details about +their evaluation. + +### <Operation> constant(const Scalar& val) + +Returns a tensor of the same type and dimensions as the original tensor but +where all elements have the value ```val```. + +This is useful, for example, when you want to add or subtract a constant from a +tensor, or multiply every element of a tensor by a scalar. + + Eigen::Tensor<float, 2> a(2, 3); + a.setConstant(1.0f); + Eigen::Tensor<float, 2> b = a + a.constant(2.0f); + Eigen::Tensor<float, 2> c = b * b.constant(0.2f); + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + cout << "c" << endl << c << endl << endl; + => + a + 1 1 1 + 1 1 1 + + b + 3 3 3 + 3 3 3 + + c + 0.6 0.6 0.6 + 0.6 0.6 0.6 + +### <Operation> random() + +Returns a tensor of the same type and dimensions as the current tensor +but where all elements have random values. + +This is for example useful to add random values to an existing tensor. +The generation of random values can be customized in the same manner +as for ```setRandom()```. + + Eigen::Tensor<float, 2> a(2, 3); + a.setConstant(1.0f); + Eigen::Tensor<float, 2> b = a + a.random(); + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + => + a + 1 1 1 + 1 1 1 + + b + 1.68038 1.5662 1.82329 + 0.788766 1.59688 0.395103 + + +## Unary Element Wise Operations + +All these operations take a single input tensor as argument and return a tensor +of the same type and dimensions as the tensor to which they are applied. The +requested operations are applied to each element independently. + +### <Operation> operator-() + +Returns a tensor of the same type and dimensions as the original tensor +containing the opposite values of the original tensor. + + Eigen::Tensor<float, 2> a(2, 3); + a.setConstant(1.0f); + Eigen::Tensor<float, 2> b = -a; + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + => + a + 1 1 1 + 1 1 1 + + b + -1 -1 -1 + -1 -1 -1 + +### <Operation> sqrt() + +Returns a tensor of the same type and dimensions as the original tensor +containing the square roots of the original tensor. + +### <Operation> rsqrt() + +Returns a tensor of the same type and dimensions as the original tensor +containing the inverse square roots of the original tensor. + +### <Operation> square() + +Returns a tensor of the same type and dimensions as the original tensor +containing the squares of the original tensor values. + +### <Operation> inverse() + +Returns a tensor of the same type and dimensions as the original tensor +containing the inverse of the original tensor values. + +### <Operation> exp() + +Returns a tensor of the same type and dimensions as the original tensor +containing the exponential of the original tensor. + +### <Operation> log() + +Returns a tensor of the same type and dimensions as the original tensor +containing the natural logarithms of the original tensor. + +### <Operation> abs() + +Returns a tensor of the same type and dimensions as the original tensor +containing the absolute values of the original tensor. + +### <Operation> pow(Scalar exponent) + +Returns a tensor of the same type and dimensions as the original tensor +containing the coefficients of the original tensor to the power of the +exponent. + +The type of the exponent, Scalar, is always the same as the type of the +tensor coefficients. For example, only integer exponents can be used in +conjuntion with tensors of integer values. + +You can use cast() to lift this restriction. For example this computes +cubic roots of an int Tensor: + + Eigen::Tensor<int, 2> a(2, 3); + a.setValues({{0, 1, 8}, {27, 64, 125}}); + Eigen::Tensor<double, 2> b = a.cast<double>().pow(1.0 / 3.0); + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + => + a + 0 1 8 + 27 64 125 + + b + 0 1 2 + 3 4 5 + +### <Operation> operator * (Scalar scale) +TODO + +### <Operation> cwiseMax(Scalar threshold) +TODO + +### <Operation> cwiseMin(Scalar threshold) +TODO + + ### <Operation> unaryExpr(const CustomUnaryOp& func) +TODO + + +## Binary Element Wise Operations + +These operations take two input tensors as arguments. The 2 input tensors should +be of the same type and dimensions. The result is a tensor of the same +dimensions as the tensors to which they are applied, and unless otherwise +specified it is also of the same type. The requested operations are applied to +each pair of elements independently. + +### <Operation> operator+(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise sums of the inputs. + +### <Operation> operator-(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise differences of the inputs. + +### <Operation> operator*(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise products of the inputs. + +### <Operation> operator/(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise quotients of the inputs. + +This operator is not supported for integer types. + +### <Operation> cwiseMax(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise maximums of the inputs. + +### <Operation> cwiseMin(const OtherDerived& other) + +Returns a tensor of the same type and dimensions as the input tensors +containing the coefficient wise mimimums of the inputs. + +### <Operation> Logical operators + +The following logical operators are supported as well: + +* operator&&(const OtherDerived& other) + +* operator||(const OtherDerived& other) + +* operator<(const OtherDerived& other) + +* operator<=(const OtherDerived& other) + +* operator>(const OtherDerived& other) + +* operator>=(const OtherDerived& other) + +* operator==(const OtherDerived& other) + +* operator!=(const OtherDerived& other) + +They all return a tensor of boolean values. + + +## Selection (select(const ThenDerived& thenTensor, const ElseDerived& elseTensor) + +Selection is a coefficient-wise ternary operator that is the tensor equivalent +to the if-then-else operation. + + Tensor<bool, 3> if = ...; + Tensor<float, 3> then = ...; + Tensor<float, 3> else = ...; + Tensor<float, 3> result = if.select(then, else); + +The 3 arguments must be of the same dimensions, which will also be the dimension +of the result. The 'if' tensor must be of type boolean, the 'then' and the +'else' tensor must be of the same type, which will also be the type of the +result. + +Each coefficient in the result is equal to the corresponding coefficient in the +'then' tensor if the corresponding value in the 'if' tensor is true. If not, the +resulting coefficient will come from the 'else' tensor. + + +## Contractions + +TODO + contract(const OtherDerived& other, const Dimensions& dims) + + + +## Reduction Operations + +A *Reduction* operation returns a tensor with fewer dimensions than the +original tensor. The values in the returned tensor are computed by applying a +*reduction operator* to slices of values from the original tensor. You specify +the dimensions along which the slices are made. + +The Eigen Tensor library provides a set of predefined reduction operators such +as ```maximum()``` and ```sum()``` and lets you define additional operators by +implementing a few methods from a reductor template. + +### Reduction Dimensions + +All reduction operations take a single parameter of type +```<TensorType>::Dimensions``` which can always be specified as an array of +ints. These are called the "reduction dimensions." The values are the indices +of the dimensions of the input tensor over which the reduction is done. The +parameter can have at most as many element as the rank of the input tensor; +each element must be less than the tensor rank, as it indicates one of the +dimensions to reduce. + +Each dimension of the input tensor should occur at most once in the reduction +dimensions as the implementation does not remove duplicates. + +The order of the values in the reduction dimensions does not affect the +results, but the code may execute faster if you list the dimensions in +increasing order. + +Example: Reduction along one dimension. + + // Create a tensor of 3 dimensions: 2, 3, 4 + Eigen::Tensor<int, 2> a(2, 3); + a.setValues({{1, 2, 3}, {6, 5, 4}}); + // Reduce it along the second dimension (1)... + Eigen::array<int, 1> dims({1 /* dimension to reduce */}); + // ...using the "maximum" operator. + // The result is a tensor with one dimension. The size of + // that dimension is the same as the first (non-reduced) dimension of a. + Eigen::Tensor<int, 1> b = a.maximum(dims); + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + => + a + 1 2 3 + 6 5 4 + + b + 3 + 6 + +Example: Reduction along two dimensions. + + Eigen::Tensor<float, 3, Eigen::ColMajor> a(2, 3, 4); + a.setValues({{{0.0f, 1.0f, 2.0f, 3.0f}, + {7.0f, 6.0f, 5.0f, 4.0f}, + {8.0f, 9.0f, 10.0f, 11.0f}}, + {{12.0f, 13.0f, 14.0f, 15.0f}, + {19.0f, 18.0f, 17.0f, 16.0f}, + {20.0f, 21.0f, 22.0f, 23.0f}}}); + // The tensor a has 3 dimensions. We reduce along the + // first 2, resulting in a tensor with a single dimension + // of size 4 (the last dimension of a.) + // Note that we pass the array of reduction dimensions + // directly to the maximum() call. + Eigen::Tensor<float, 1, Eigen::ColMajor> b = + a.maximum(Eigen::array<int, 2>({0, 1})); + cout << "b" << endl << b << endl << endl; + => + b + 20 + 21 + 22 + 23 + +#### Reduction along all dimensions + +As a special case, if you pass no parameter to a reduction operation the +original tensor is reduced along *all* its dimensions. The result is a +one-dimension tensor with a single value. + + Eigen::Tensor<float, 3> a(2, 3, 4); + a.setValues({{{0.0f, 1.0f, 2.0f, 3.0f}, + {7.0f, 6.0f, 5.0f, 4.0f}, + {8.0f, 9.0f, 10.0f, 11.0f}}, + {{12.0f, 13.0f, 14.0f, 15.0f}, + {19.0f, 18.0f, 17.0f, 16.0f}, + {20.0f, 21.0f, 22.0f, 23.0f}}}); + // Reduce along all dimensions using the sum() operator. + Eigen::Tensor<float, 1> b = a.sum(); + cout << "b" << endl << b << endl << endl; + => + b + 276 + + +### <Operation> sum(const Dimensions& new_dims) +### <Operation> sum() + +Reduce a tensor using the sum() operator. The resulting values +are the sum of the reduced values. + +### <Operation> mean(const Dimensions& new_dims) +### <Operation> mean() + +Reduce a tensor using the mean() operator. The resulting values +are the mean of the reduced values. + +### <Operation> maximum(const Dimensions& new_dims) +### <Operation> maximum() + +Reduce a tensor using the maximum() operator. The resulting values are the +largest of the reduced values. + +### <Operation> minimum(const Dimensions& new_dims) +### <Operation> minimum() + +Reduce a tensor using the minimum() operator. The resulting values +are the smallest of the reduced values. + +### <Operation> prod(const Dimensions& new_dims) +### <Operation> prod() + +Reduce a tensor using the prod() operator. The resulting values +are the product of the reduced values. + +### <Operation> reduce(const Dimensions& new_dims, const Reducer& reducer) + +Reduce a tensor using a user-defined reduction operator. See ```SumReducer``` +in TensorFunctors.h for information on how to implement a reduction operator. + + +## Convolutions + +TBD: convolve(const KernelDerived& kernel, const Dimensions& dims) + + +## Geometrical Operations + +These operations return a Tensor with different dimensions than the original +Tensor. They can be used to access slices of tensors, see them with different +dimensions, or pad tensors with additional data. + +### <Operation> reshape(const Dimensions& new_dims) + +Returns a view of the input tensor that has been reshaped to the specified +new dimensions. The argument new_dims is an array of Index values. The +rank of the resulting tensor is equal to the number of elements in new_dims. + +The product of all the sizes in the new dimension array must be equal to +the number of elements in the input tensor. + + // Increase the rank of the input tensor by introducing a new dimension + // of size 1. + Tensor<float, 2> input(7, 11); + array<int, 3> three_dims{{7, 11, 1}}; + Tensor<float, 3> result = input.reshape(three_dims); + + // Decrease the rank of the input tensor by merging 2 dimensions; + array<int, 1> one_dim{{7 * 11}}; + Tensor<float, 1> result = input.reshape(one_dim); + +This operation does not move any data in the input tensor, so the resulting +contents of a reshaped Tensor depend on the data layout of the original Tensor. + +For example this is what happens when you ```reshape()``` a 2D ColMajor tensor +to one dimension: + + Eigen::Tensor<float, 2, Eigen::ColMajor> a(2, 3); + a.setValues({{0.0f, 100.0f, 200.0f}, {300.0f, 400.0f, 500.0f}}); + Eigen::array<Eigen::DenseIndex, 1> one_dim({3 * 2}); + Eigen::Tensor<float, 1, Eigen::ColMajor> b = a.reshape(one_dim); + cout << "b" << endl << b << endl; + => + b + 0 + 300 + 100 + 400 + 200 + 500 + +This is what happens when the 2D Tensor is RowMajor: + + Eigen::Tensor<float, 2, Eigen::RowMajor> a(2, 3); + a.setValues({{0.0f, 100.0f, 200.0f}, {300.0f, 400.0f, 500.0f}}); + Eigen::array<Eigen::DenseIndex, 1> one_dim({3 * 2}); + Eigen::Tensor<float, 1, Eigen::RowMajor> b = a.reshape(one_dim); + cout << "b" << endl << b << endl; + => + b + 0 + 100 + 200 + 300 + 400 + 500 + +The reshape operation is a lvalue. In other words, it can be used on the left +side of the assignment operator. + +The previous example can be rewritten as follow: + + Eigen::Tensor<float, 2, Eigen::ColMajor> a(2, 3); + a.setValues({{0.0f, 100.0f, 200.0f}, {300.0f, 400.0f, 500.0f}}); + Eigen::array<Eigen::DenseIndex, 2> two_dim({2, 3}); + Eigen::Tensor<float, 1, Eigen::ColMajor> b; + b.reshape(two_dim) = a; + cout << "b" << endl << b << endl; + => + b + 0 + 300 + 100 + 400 + 200 + 500 + +Note that "b" itself was not reshaped but that instead the assignment is done to +the reshape view of b. + + +### <Operation> shuffle(const Shuffle& shuffle) + +Returns a copy of the input tensor whose dimensions have been +reordered according to the specified permutation. The argument shuffle +is an array of Index values. Its size is the rank of the input +tensor. It must contain a permutation of 0, 1, ..., rank - 1. The i-th +dimension of the output tensor equals to the size of the shuffle[i]-th +dimension of the input tensor. For example: + + // Shuffle all dimensions to the left by 1. + Tensor<float, 3> input(20, 30, 50); + // ... set some values in input. + Tensor<float, 3> output = input.shuffle({1, 2, 0}) + + eigen_assert(output.dimension(0) == 30); + eigen_assert(output.dimension(1) == 50); + eigen_assert(output.dimension(2) == 20); + +Indices into the output tensor are shuffled accordingly to formulate +indices into the input tensor. For example, one can assert in the above +code snippet that: + + eigen_assert(output(3, 7, 11) == input(11, 3, 7)); + +In general, one can assert that + + eigen_assert(output(..., indices[shuffle[i]], ...) == + input(..., indices[i], ...)) + +The shuffle operation results in a lvalue, which means that it can be assigned +to. In other words, it can be used on the left side of the assignment operator. + +Let's rewrite the previous example to take advantage of this feature: + + // Shuffle all dimensions to the left by 1. + Tensor<float, 3> input(20, 30, 50); + // ... set some values in input. + Tensor<float, 3> output(30, 50, 20); + output.shuffle({2, 0, 1}) = input; + + +### <Operation> stride(const Strides& strides) + +Returns a view of the input tensor that strides (skips stride-1 +elements) along each of the dimensions. The argument strides is an +array of Index values. The dimensions of the resulting tensor are +ceil(input_dimensions[i] / strides[i]). + +For example this is what happens when you ```stride()``` a 2D tensor: + + Eigen::Tensor<int, 2> a(4, 3); + a.setValues({{0, 100, 200}, {300, 400, 500}, {600, 700, 800}, {900, 1000, 1100}}); + Eigen::array<Eigen::DenseIndex, 2> strides({3, 2}); + Eigen::Tensor<int, 2> b = a.stride(strides); + cout << "b" << endl << b << endl; + => + b + 0 200 + 900 1100 + +It is possible to assign a tensor to a stride: + Tensor<float, 3> input(20, 30, 50); + // ... set some values in input. + Tensor<float, 3> output(40, 90, 200); + output.stride({2, 3, 4}) = input; + + +### <Operation> slice(const StartIndices& startIndices, + const Sizes& sizes) + +TBD + + +### <Operation> chip(const Index offset, const Index dim) + +A chip is a special kind of slice. It is the subtensor at the given offset in +the dimension dim. The returned tensor has one fewer dimension than the input +tensor: the dimension dim is removed. + +For example, a matrix chip would be either a row or a column of the input +matrix. + + Eigen::Tensor<int, 2> a(4, 3); + a.setValues({{0, 100, 200}, {300, 400, 500}, + {600, 700, 800}, {900, 1000, 1100}}); + Eigen::Tensor<int, 1> row_3 = a.chip(2, 0); + Eigen::Tensor<int, 1> col_2 = a.chip(1, 1); + cout << "a" << endl << a << endl; + => + a + 0 100 200 + 300 400 500 + 600 700 800 + 900 1000 1100 + cout << "row_3" << endl << row_3 << endl; + => + row_3 + 600 700 800 + cout << "col_2" << endl << col_2 << endl; + => + col_2 + 100 400 700 1000 + +It is possible to assign values to a tensor chip since the chip operation is a +lvalue. For example: + + Eigen::Tensor<int, 1> a(3); + a.setValues({{100, 200, 300}}); + Eigen::Tensor<int, 2> b(2, 3); + b.setZero(); + b.chip(0, 0) = a; + cout << "a" << endl << a << endl; + => + a + 100 + 200 + 300 + cout << "b" << endl << b << endl; + => + b + 100 200 300 + 0 0 0 + + +### <Operation> reverse(const ReverseDimensions& reverse) + +Returns a view of the input tensor that reverses the order of the coefficients +along a subset of the dimensions. The argument reverse is an array of boolean +values that indicates whether or not the order of the coefficients should be +reversed along each of the dimensions. This operation preserves the dimensions +of the input tensor. + +For example this is what happens when you ```reverse()``` the first dimension +of a 2D tensor: + + Eigen::Tensor<int, 2> a(4, 3); + a.setValues({{0, 100, 200}, {300, 400, 500}, + {600, 700, 800}, {900, 1000, 1100}}); + Eigen::array<bool, 2> reverse({true, false}); + Eigen::Tensor<int, 2> b = a.reverse(reverse); + cout << "a" << endl << a << endl << "b" << endl << b << endl; + => + a + 0 100 200 + 300 400 500 + 600 700 800 + 900 1000 1100 + b + 900 1000 1100 + 600 700 800 + 300 400 500 + 0 100 200 + + +TODO +### <Operation> broadcast(const Broadcast& broadcast) + +TODO + +### <Operation> concatenate(const OtherDerived& other, Axis axis) + +TODO + +### <Operation> pad(const PaddingDimensions& padding) + +TODO + +### <Operation> extract_patches(const PatchDims& patch_dims) + +TODO + +### <Operation> extract_image_patches(const Index patch_rows, const Index patch_cols, + const Index row_stride, const Index col_stride, + const PaddingType padding_type) + +TODO + + +## Special Operations + +### <Operation> cast<T>() + +Returns a tensor of type T with the same dimensions as the original tensor. +The returned tensor contains the values of the original tensor converted to +type T. + + Eigen::Tensor<float, 2> a(2, 3); + Eigen::Tensor<int, 2> b = a.cast<int>(); + +This can be useful for example if you need to do element-wise division of +Tensors of integers. This is not currently supported by the Tensor library +but you can easily cast the tensors to floats to do the division: + + Eigen::Tensor<int, 2> a(2, 3); + a.setValues({{0, 1, 2}, {3, 4, 5}}); + Eigen::Tensor<int, 2> b = + (a.cast<float>() / a.constant(2).cast<float>()).cast<int>(); + cout << "a" << endl << a << endl << endl; + cout << "b" << endl << b << endl << endl; + => + a + 0 1 2 + 3 4 5 + + b + 0 0 1 + 1 2 2 + + +### <Operation> eval() + +TODO + + +## Representation of scalar values + +Scalar values are often represented by tensors of size 1 and rank 1. It would be +more logical and user friendly to use tensors of rank 0 instead. For example +Tensor<T, N>::maximum() currently returns a Tensor<T, 1>. Similarly, the inner +product of 2 1d tensors (through contractions) returns a 1d tensor. In the +future these operations might be updated to return 0d tensors instead. + +## Limitations + +* The number of tensor dimensions is currently limited to 250 when using a + compiler that supports cxx11. It is limited to only 5 for older compilers. +* The IndexList class requires a cxx11 compliant compiler. You can use an + array of indices instead if you don't have access to a modern compiler. +* TensorVarDims are only partially supported +* On GPUs only floating point values are properly tested and optimized for. +* Complex and integer values are known to be broken on GPUs. If you try to use + them you'll most likely end up triggering a static assertion failure such as + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + + diff --git a/unsupported/Eigen/CXX11/src/Tensor/Tensor.h b/unsupported/Eigen/CXX11/src/Tensor/Tensor.h index 70ca1433f..037219f23 100644 --- a/unsupported/Eigen/CXX11/src/Tensor/Tensor.h +++ b/unsupported/Eigen/CXX11/src/Tensor/Tensor.h @@ -1,6 +1,7 @@ // This file is part of Eigen, a lightweight C++ template library // for linear algebra. // +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> // Copyright (C) 2013 Christian Seiler <christian@iwakd.de> // // This Source Code Form is subject to the terms of the Mozilla @@ -55,70 +56,46 @@ namespace Eigen { * change dramatically.</dd> * </dl> * - * \ref TopicStorageOrders + * \ref TopicStorageOrders */ -template<typename Scalar_, std::size_t NumIndices_, int Options_ = 0> -class Tensor; -namespace internal { template<typename Scalar_, std::size_t NumIndices_, int Options_> -struct traits<Tensor<Scalar_, NumIndices_, Options_>> +class Tensor : public TensorBase<Tensor<Scalar_, NumIndices_, Options_> > { - typedef Scalar_ Scalar; - typedef Dense StorageKind; - typedef DenseIndex Index; - enum { - Options = Options_ - }; -}; - -template<typename Index, std::size_t NumIndices, std::size_t n, bool RowMajor> -struct tensor_index_linearization_helper -{ - constexpr static inline Index run(std::array<Index, NumIndices> const& indices, std::array<Index, NumIndices> const& dimensions) - { - return std_array_get<RowMajor ? n : (NumIndices - n - 1)>(indices) + - std_array_get<RowMajor ? n : (NumIndices - n - 1)>(dimensions) * - tensor_index_linearization_helper<Index, NumIndices, n - 1, RowMajor>::run(indices, dimensions); - } -}; - -template<typename Index, std::size_t NumIndices, bool RowMajor> -struct tensor_index_linearization_helper<Index, NumIndices, 0, RowMajor> -{ - constexpr static inline Index run(std::array<Index, NumIndices> const& indices, std::array<Index, NumIndices> const&) - { - return std_array_get<RowMajor ? 0 : NumIndices - 1>(indices); - } -}; -} // end namespace internal - -template<typename Scalar_, std::size_t NumIndices_, int Options_> -class Tensor -{ - static_assert(NumIndices_ >= 1, "A tensor must have at least one index."); - public: typedef Tensor<Scalar_, NumIndices_, Options_> Self; + typedef TensorBase<Tensor<Scalar_, NumIndices_, Options_> > Base; + typedef typename Eigen::internal::nested<Self>::type Nested; typedef typename internal::traits<Self>::StorageKind StorageKind; typedef typename internal::traits<Self>::Index Index; - typedef typename internal::traits<Self>::Scalar Scalar; - typedef typename internal::packet_traits<Scalar>::type PacketScalar; + typedef Scalar_ Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; typedef typename NumTraits<Scalar>::Real RealScalar; - typedef Self DenseType; + typedef typename Base::CoeffReturnType CoeffReturnType; + typedef typename Base::PacketReturnType PacketReturnType; + + enum { + IsAligned = bool(EIGEN_ALIGN) & !(Options_&DontAlign), + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = Options_ & RowMajor ? RowMajor : ColMajor, + CoordAccess = true, + }; - constexpr static int Options = Options_; - constexpr static std::size_t NumIndices = NumIndices_; + static const int Options = Options_; + static const std::size_t NumIndices = NumIndices_; + typedef DSizes<Index, NumIndices_> Dimensions; protected: TensorStorage<Scalar, NumIndices, Dynamic, Options> m_storage; public: - EIGEN_STRONG_INLINE Index dimension(std::size_t n) const { return m_storage.dimensions()[n]; } - EIGEN_STRONG_INLINE std::array<Index, NumIndices> dimensions() const { return m_storage.dimensions(); } - EIGEN_STRONG_INLINE Index size() const { return internal::array_prod(m_storage.dimensions()); } - EIGEN_STRONG_INLINE Scalar *data() { return m_storage.data(); } - EIGEN_STRONG_INLINE const Scalar *data() const { return m_storage.data(); } + // Metadata + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index rank() const { return NumIndices; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index dimension(std::size_t n) const { return m_storage.dimensions()[n]; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const DSizes<DenseIndex, NumIndices_>& dimensions() const { return m_storage.dimensions(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index size() const { return m_storage.size(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar *data() { return m_storage.data(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar *data() const { return m_storage.data(); } // This makes EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED // work, because that uses base().coeffRef() - and we don't yet @@ -126,146 +103,254 @@ class Tensor inline Self& base() { return *this; } inline const Self& base() const { return *this; } - void setZero() - { - // FIXME: until we have implemented packet access and the - // expression engine w.r.t. nullary ops, use this - // as a kludge. Only works with POD types, but for - // any standard usage, this shouldn't be a problem - memset((void *)data(), 0, size() * sizeof(Scalar)); - } - - inline Self& operator=(Self const& other) - { - m_storage = other.m_storage; - return *this; - } - +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline const Scalar& coeff(Index firstIndex, Index secondIndex, IndexTypes... otherIndices) const { - static_assert(sizeof...(otherIndices) + 2 == NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); - return coeff(std::array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return coeff(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); } +#endif - inline const Scalar& coeff(const std::array<Index, NumIndices>& indices) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& coeff(const array<Index, NumIndices>& indices) const { eigen_internal_assert(checkIndexRange(indices)); return m_storage.data()[linearizedIndex(indices)]; } - inline const Scalar& coeff(Index index) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& coeff(Index index) const { eigen_internal_assert(index >= 0 && index < size()); return m_storage.data()[index]; } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline Scalar& coeffRef(Index firstIndex, Index secondIndex, IndexTypes... otherIndices) { - static_assert(sizeof...(otherIndices) + 2 == NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); - return coeffRef(std::array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return coeffRef(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); } +#endif - inline Scalar& coeffRef(const std::array<Index, NumIndices>& indices) + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(const array<Index, NumIndices>& indices) { eigen_internal_assert(checkIndexRange(indices)); return m_storage.data()[linearizedIndex(indices)]; } - inline Scalar& coeffRef(Index index) + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) { eigen_internal_assert(index >= 0 && index < size()); return m_storage.data()[index]; } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline const Scalar& operator()(Index firstIndex, Index secondIndex, IndexTypes... otherIndices) const { - static_assert(sizeof...(otherIndices) + 2 == NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); - return this->operator()(std::array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return this->operator()(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + } +#else + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1) const + { + return coeff(array<Index, 2>(i0, i1)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2) const + { + return coeff(array<Index, 3>(i0, i1, i2)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2, Index i3) const + { + return coeff(array<Index, 4>(i0, i1, i2, i3)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2, Index i3, Index i4) const + { + return coeff(array<Index, 5>(i0, i1, i2, i3, i4)); } +#endif - inline const Scalar& operator()(const std::array<Index, NumIndices>& indices) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& operator()(const array<Index, NumIndices>& indices) const { eigen_assert(checkIndexRange(indices)); return coeff(indices); } - inline const Scalar& operator()(Index index) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& operator()(Index index) const { eigen_internal_assert(index >= 0 && index < size()); return coeff(index); } - inline const Scalar& operator[](Index index) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& operator[](Index index) const { - static_assert(NumIndices == 1, "The bracket operator is only for vectors, use the parenthesis operator instead."); + // The bracket operator is only for vectors, use the parenthesis operator instead. + EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE); return coeff(index); } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline Scalar& operator()(Index firstIndex, Index secondIndex, IndexTypes... otherIndices) { - static_assert(sizeof...(otherIndices) + 2 == NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); - return operator()(std::array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return operator()(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}}); + } +#else + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1) + { + return coeffRef(array<Index, 2>(i0, i1)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2) + { + return coeffRef(array<Index, 3>(i0, i1, i2)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3) + { + return coeffRef(array<Index, 4>(i0, i1, i2, i3)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3, Index i4) + { + return coeffRef(array<Index, 5>(i0, i1, i2, i3, i4)); } +#endif - inline Scalar& operator()(const std::array<Index, NumIndices>& indices) + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& operator()(const array<Index, NumIndices>& indices) { eigen_assert(checkIndexRange(indices)); return coeffRef(indices); } - inline Scalar& operator()(Index index) + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& operator()(Index index) { eigen_assert(index >= 0 && index < size()); return coeffRef(index); } - inline Scalar& operator[](Index index) + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& operator[](Index index) { - static_assert(NumIndices == 1, "The bracket operator is only for vectors, use the parenthesis operator instead."); + // The bracket operator is only for vectors, use the parenthesis operator instead + EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE) return coeffRef(index); } - inline Tensor() + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor() : m_storage() { } - inline Tensor(const Self& other) - : m_storage(other.m_storage) - { - } - - inline Tensor(Self&& other) + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor(const Self& other) : m_storage(other.m_storage) { } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline Tensor(Index firstDimension, IndexTypes... otherDimensions) - : m_storage() + : m_storage(internal::array_prod(array<Index, NumIndices>{{firstDimension, otherDimensions...}}), array<Index, NumIndices>{{firstDimension, otherDimensions...}}) + { + // The number of dimensions used to construct a tensor must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherDimensions) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + } +#else + inline explicit Tensor(Index dim1) + : m_storage(dim1, array<Index, 1>(dim1)) + { + EIGEN_STATIC_ASSERT(1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + inline explicit Tensor(Index dim1, Index dim2) + : m_storage(dim1*dim2, array<Index, 2>(dim1, dim2)) { - static_assert(sizeof...(otherDimensions) + 1 == NumIndices, "Number of dimensions used to construct a tensor must be equal to the rank of the tensor."); - resize(std::array<Index, NumIndices>{{firstDimension, otherDimensions...}}); + EIGEN_STATIC_ASSERT(2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) } + inline explicit Tensor(Index dim1, Index dim2, Index dim3) + : m_storage(dim1*dim2*dim3, array<Index, 3>(dim1, dim2, dim3)) + { + EIGEN_STATIC_ASSERT(3 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + inline explicit Tensor(Index dim1, Index dim2, Index dim3, Index dim4) + : m_storage(dim1*dim2*dim3*dim4, array<Index, 4>(dim1, dim2, dim3, dim4)) + { + EIGEN_STATIC_ASSERT(4 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + inline explicit Tensor(Index dim1, Index dim2, Index dim3, Index dim4, Index dim5) + : m_storage(dim1*dim2*dim3*dim4*dim5, array<Index, 4>(dim1, dim2, dim3, dim4, dim5)) + { + EIGEN_STATIC_ASSERT(5 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + } +#endif - inline Tensor(std::array<Index, NumIndices> dimensions) - : m_storage(internal::array_prod(dimensions), dimensions) + inline explicit Tensor(const array<Index, NumIndices>& dimensions) + : m_storage(internal::array_prod(dimensions), dimensions) { EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED } + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor(const TensorBase<OtherDerived, ReadOnlyAccessors>& other) + { + typedef TensorAssignOp<Tensor, const OtherDerived> Assign; + Assign assign(*this, other.derived()); + resize(TensorEvaluator<const Assign, DefaultDevice>(assign, DefaultDevice()).dimensions()); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + } + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor(const TensorBase<OtherDerived, WriteAccessors>& other) + { + typedef TensorAssignOp<Tensor, const OtherDerived> Assign; + Assign assign(*this, other.derived()); + resize(TensorEvaluator<const Assign, DefaultDevice>(assign, DefaultDevice()).dimensions()); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor& operator=(const Tensor& other) + { + typedef TensorAssignOp<Tensor, const Tensor> Assign; + Assign assign(*this, other); + resize(TensorEvaluator<const Assign, DefaultDevice>(assign, DefaultDevice()).dimensions()); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Tensor& operator=(const OtherDerived& other) + { + typedef TensorAssignOp<Tensor, const OtherDerived> Assign; + Assign assign(*this, other); + resize(TensorEvaluator<const Assign, DefaultDevice>(assign, DefaultDevice()).dimensions()); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> void resize(Index firstDimension, IndexTypes... otherDimensions) { - static_assert(sizeof...(otherDimensions) + 1 == NumIndices, "Number of dimensions used to resize a tensor must be equal to the rank of the tensor."); - resize(std::array<Index, NumIndices>{{firstDimension, otherDimensions...}}); + // The number of dimensions used to resize a tensor must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherDimensions) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + resize(array<Index, NumIndices>{{firstDimension, otherDimensions...}}); } +#endif - void resize(const std::array<Index, NumIndices>& dimensions) + EIGEN_DEVICE_FUNC void resize(const array<Index, NumIndices>& dimensions) { std::size_t i; Index size = Index(1); @@ -282,8 +367,17 @@ class Tensor #endif } + EIGEN_DEVICE_FUNC void resize(const DSizes<Index, NumIndices>& dimensions) { + array<Index, NumIndices> dims; + for (std::size_t i = 0; i < NumIndices; ++i) { + dims[i] = dimensions[i]; + } + resize(dims); + } + protected: - bool checkIndexRange(const std::array<Index, NumIndices>& indices) const + + bool checkIndexRange(const array<Index, NumIndices>& indices) const { using internal::array_apply_and_reduce; using internal::array_zip_and_reduce; @@ -298,16 +392,16 @@ class Tensor array_zip_and_reduce<logical_and_op, lesser_op>(indices, m_storage.dimensions()); } - inline Index linearizedIndex(const std::array<Index, NumIndices>& indices) const + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index linearizedIndex(const array<Index, NumIndices>& indices) const { - return internal::tensor_index_linearization_helper<Index, NumIndices, NumIndices - 1, Options&RowMajor>::run(indices, m_storage.dimensions()); + if (Options&RowMajor) { + return m_storage.dimensions().IndexOfRowMajor(indices); + } else { + return m_storage.dimensions().IndexOfColMajor(indices); + } } }; } // end namespace Eigen #endif // EIGEN_CXX11_TENSOR_TENSOR_H - -/* - * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle; - */ diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorAssign.h b/unsupported/Eigen/CXX11/src/Tensor/TensorAssign.h new file mode 100644 index 000000000..a4f73b2a1 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorAssign.h @@ -0,0 +1,164 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_ASSIGN_H +#define EIGEN_CXX11_TENSOR_TENSOR_ASSIGN_H + +namespace Eigen { + +/** \class TensorAssign + * \ingroup CXX11_Tensor_Module + * + * \brief The tensor assignment class. + * + * This class is represents the assignment of the values resulting from the evaluation of + * the rhs expression to the memory locations denoted by the lhs expression. + */ +namespace internal { +template<typename LhsXprType, typename RhsXprType> +struct traits<TensorAssignOp<LhsXprType, RhsXprType> > +{ + typedef typename LhsXprType::Scalar Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename traits<LhsXprType>::StorageKind StorageKind; + typedef typename promote_index_type<typename traits<LhsXprType>::Index, + typename traits<RhsXprType>::Index>::type Index; + typedef typename LhsXprType::Nested LhsNested; + typedef typename RhsXprType::Nested RhsNested; + typedef typename remove_reference<LhsNested>::type _LhsNested; + typedef typename remove_reference<RhsNested>::type _RhsNested; + static const std::size_t NumDimensions = internal::traits<LhsXprType>::NumDimensions; + static const int Layout = internal::traits<LhsXprType>::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename LhsXprType, typename RhsXprType> +struct eval<TensorAssignOp<LhsXprType, RhsXprType>, Eigen::Dense> +{ + typedef const TensorAssignOp<LhsXprType, RhsXprType>& type; +}; + +template<typename LhsXprType, typename RhsXprType> +struct nested<TensorAssignOp<LhsXprType, RhsXprType>, 1, typename eval<TensorAssignOp<LhsXprType, RhsXprType> >::type> +{ + typedef TensorAssignOp<LhsXprType, RhsXprType> type; +}; + +} // end namespace internal + + + +template<typename LhsXprType, typename RhsXprType> +class TensorAssignOp : public TensorBase<TensorAssignOp<LhsXprType, RhsXprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorAssignOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorAssignOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename LhsXprType::CoeffReturnType CoeffReturnType; + typedef typename LhsXprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorAssignOp>::type Nested; + typedef typename Eigen::internal::traits<TensorAssignOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorAssignOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorAssignOp(LhsXprType& lhs, const RhsXprType& rhs) + : m_lhs_xpr(lhs), m_rhs_xpr(rhs) {} + + /** \returns the nested expressions */ + EIGEN_DEVICE_FUNC + typename internal::remove_all<typename LhsXprType::Nested>::type& + lhsExpression() const { return *((typename internal::remove_all<typename LhsXprType::Nested>::type*)&m_lhs_xpr); } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename RhsXprType::Nested>::type& + rhsExpression() const { return m_rhs_xpr; } + + protected: + typename internal::remove_all<typename LhsXprType::Nested>::type& m_lhs_xpr; + const typename internal::remove_all<typename RhsXprType::Nested>::type& m_rhs_xpr; +}; + + +template<typename LeftArgType, typename RightArgType, typename Device> +struct TensorEvaluator<const TensorAssignOp<LeftArgType, RightArgType>, Device> +{ + typedef TensorAssignOp<LeftArgType, RightArgType> XprType; + + enum { + IsAligned = TensorEvaluator<LeftArgType, Device>::IsAligned & TensorEvaluator<RightArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess, + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) : + m_leftImpl(op.lhsExpression(), device), + m_rightImpl(op.rhsExpression(), device) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout)), YOU_MADE_A_PROGRAMMING_MISTAKE); + // The dimensions of the lhs and the rhs tensors should be equal to prevent + // overflows and ensure the result is fully initialized. + eigen_assert(dimensions_match(m_leftImpl.dimensions(), m_leftImpl.dimensions())); + } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename TensorEvaluator<RightArgType, Device>::Dimensions Dimensions; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const + { + // TODO: use left impl instead if right impl dimensions are known at compile time. + return m_rightImpl.dimensions(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + eigen_assert(dimensions_match(m_leftImpl.dimensions(), m_rightImpl.dimensions())); + m_leftImpl.evalSubExprsIfNeeded(NULL); + // If the lhs provides raw access to its storage area (i.e. if m_leftImpl.data() returns a non + // null value), attempt to evaluate the rhs expression in place. Returns true iff in place + // evaluation isn't supported and the caller still needs to manually assign the values generated + // by the rhs to the lhs. + return m_rightImpl.evalSubExprsIfNeeded(m_leftImpl.data()); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_leftImpl.cleanup(); + m_rightImpl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void evalScalar(Index i) { + m_leftImpl.coeffRef(i) = m_rightImpl.coeff(i); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void evalPacket(Index i) { + const int LhsStoreMode = TensorEvaluator<LeftArgType, Device>::IsAligned ? Aligned : Unaligned; + const int RhsLoadMode = TensorEvaluator<RightArgType, Device>::IsAligned ? Aligned : Unaligned; + m_leftImpl.template writePacket<LhsStoreMode>(i, m_rightImpl.template packet<RhsLoadMode>(i)); + } + EIGEN_DEVICE_FUNC CoeffReturnType coeff(Index index) const + { + return m_leftImpl.coeff(index); + } + template<int LoadMode> + EIGEN_DEVICE_FUNC PacketReturnType packet(Index index) const + { + return m_leftImpl.template packet<LoadMode>(index); + } + + private: + TensorEvaluator<LeftArgType, Device> m_leftImpl; + TensorEvaluator<RightArgType, Device> m_rightImpl; +}; + +} + + +#endif // EIGEN_CXX11_TENSOR_TENSOR_ASSIGN_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorBase.h b/unsupported/Eigen/CXX11/src/Tensor/TensorBase.h new file mode 100644 index 000000000..e08ac6aa1 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorBase.h @@ -0,0 +1,573 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_BASE_H +#define EIGEN_CXX11_TENSOR_TENSOR_BASE_H + +namespace Eigen { + +/** \class TensorBase + * \ingroup CXX11_Tensor_Module + * + * \brief The tensor base class. + * + * This class is the common parent of the Tensor and TensorMap class, thus + * making it possible to use either class interchangably in expressions. + */ + +template<typename Derived> +class TensorBase<Derived, ReadOnlyAccessors> +{ + public: + typedef internal::traits<Derived> DerivedTraits; + typedef typename DerivedTraits::Scalar Scalar; + typedef typename DerivedTraits::Index Index; + typedef typename internal::remove_const<Scalar>::type CoeffReturnType; + typedef typename internal::packet_traits<CoeffReturnType>::type PacketReturnType; + static const int NumDimensions = DerivedTraits::NumDimensions; + + // Generic nullary operation support. + template <typename CustomNullaryOp> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseNullaryOp<CustomNullaryOp, const Derived> + nullaryExpr(const CustomNullaryOp& func) const { + return TensorCwiseNullaryOp<CustomNullaryOp, const Derived>(derived(), func); + } + + // Coefficient-wise nullary operators + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseNullaryOp<internal::scalar_constant_op<Scalar>, const Derived> + constant(const Scalar& value) const { + return nullaryExpr(internal::scalar_constant_op<Scalar>(value)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseNullaryOp<internal::UniformRandomGenerator<Scalar>, const Derived> + random() const { + return nullaryExpr(internal::UniformRandomGenerator<Scalar>()); + } + template <typename RandomGenerator> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseNullaryOp<RandomGenerator, const Derived> + random() const { + return nullaryExpr(RandomGenerator()); + } + + // Generic unary operation support. + template <typename CustomUnaryOp> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<CustomUnaryOp, const Derived> + unaryExpr(const CustomUnaryOp& func) const { + return TensorCwiseUnaryOp<CustomUnaryOp, const Derived>(derived(), func); + } + + // Coefficient-wise unary operators + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_opposite_op<Scalar>, const Derived> + operator-() const { + return unaryExpr(internal::scalar_opposite_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_sqrt_op<Scalar>, const Derived> + sqrt() const { + return unaryExpr(internal::scalar_sqrt_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_square_op<Scalar>, const Derived> + square() const { + return unaryExpr(internal::scalar_square_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_cube_op<Scalar>, const Derived> + cube() const { + return unaryExpr(internal::scalar_cube_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_inverse_op<Scalar>, const Derived> + inverse() const { + return unaryExpr(internal::scalar_inverse_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_exp_op<Scalar>, const Derived> + exp() const { + return unaryExpr(internal::scalar_exp_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_log_op<Scalar>, const Derived> + log() const { + return unaryExpr(internal::scalar_log_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_abs_op<Scalar>, const Derived> + abs() const { + return unaryExpr(internal::scalar_abs_op<Scalar>()); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_pow_op<Scalar>, const Derived> + pow(Scalar exponent) const { + return unaryExpr(internal::scalar_pow_op<Scalar>(exponent)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_add_op<Scalar>, const Derived> + operator+ (Scalar rhs) const { + return unaryExpr(internal::scalar_add_op<Scalar>(rhs)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_sub_op<Scalar>, const Derived> + operator- (Scalar rhs) const { + EIGEN_STATIC_ASSERT((std::numeric_limits<Scalar>::is_signed || internal::is_same<Scalar, const std::complex<float> >::value), YOU_MADE_A_PROGRAMMING_MISTAKE); + return unaryExpr(internal::scalar_sub_op<Scalar>(rhs)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_multiple_op<Scalar>, const Derived> + operator* (Scalar rhs) const { + return unaryExpr(internal::scalar_multiple_op<Scalar>(rhs)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_quotient1_op<Scalar>, const Derived> + operator/ (Scalar rhs) const { + // EIGEN_STATIC_ASSERT(!std::numeric_limits<Scalar>::is_integer, YOU_MADE_A_PROGRAMMING_MISTAKE); + return unaryExpr(internal::scalar_quotient1_op<Scalar>(rhs)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseBinaryOp<internal::scalar_max_op<Scalar>, const Derived, const TensorCwiseNullaryOp<internal::scalar_constant_op<Scalar>, const Derived> > + cwiseMax(Scalar threshold) const { + return cwiseMax(constant(threshold)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseBinaryOp<internal::scalar_min_op<Scalar>, const Derived, const TensorCwiseNullaryOp<internal::scalar_constant_op<Scalar>, const Derived> > + cwiseMin(Scalar threshold) const { + return cwiseMin(constant(threshold)); + } + + template <typename NewType> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseUnaryOp<internal::scalar_cast_op<Scalar, NewType>, const Derived> + cast() const { + return unaryExpr(internal::scalar_cast_op<Scalar, NewType>()); + } + + // Generic binary operation support. + template <typename CustomBinaryOp, typename OtherDerived> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const TensorCwiseBinaryOp<CustomBinaryOp, const Derived, const OtherDerived> + binaryExpr(const OtherDerived& other, const CustomBinaryOp& func) const { + return TensorCwiseBinaryOp<CustomBinaryOp, const Derived, const OtherDerived>(derived(), other, func); + } + + // Coefficient-wise binary operators. + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_sum_op<Scalar>, const Derived, const OtherDerived> + operator+(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_sum_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_difference_op<Scalar>, const Derived, const OtherDerived> + operator-(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_difference_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_product_op<Scalar>, const Derived, const OtherDerived> + operator*(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_product_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_quotient_op<Scalar>, const Derived, const OtherDerived> + operator/(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_quotient_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_max_op<Scalar>, const Derived, const OtherDerived> + cwiseMax(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_max_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_min_op<Scalar>, const Derived, const OtherDerived> + cwiseMin(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_min_op<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_boolean_and_op, const Derived, const OtherDerived> + operator&&(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_boolean_and_op()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<internal::scalar_boolean_or_op, const Derived, const OtherDerived> + operator||(const OtherDerived& other) const { + return binaryExpr(other.derived(), internal::scalar_boolean_or_op()); + } + + // Comparisons and tests. + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::less<Scalar>, const Derived, const OtherDerived> + operator<(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::less<Scalar>()); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::less_equal<Scalar>, const Derived, const OtherDerived> + operator<=(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::less_equal<Scalar>()); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::greater<Scalar>, const Derived, const OtherDerived> + operator>(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::greater<Scalar>()); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::greater_equal<Scalar>, const Derived, const OtherDerived> + operator>=(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::greater_equal<Scalar>()); + } + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::equal_to<Scalar>, const Derived, const OtherDerived> + operator==(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::equal_to<Scalar>()); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorCwiseBinaryOp<std::not_equal_to<Scalar>, const Derived, const OtherDerived> + operator!=(const OtherDerived& other) const { + return binaryExpr(other.derived(), std::not_equal_to<Scalar>()); + } + + // Coefficient-wise ternary operators. + template<typename ThenDerived, typename ElseDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorSelectOp<const Derived, const ThenDerived, const ElseDerived> + select(const ThenDerived& thenTensor, const ElseDerived& elseTensor) const { + return TensorSelectOp<const Derived, const ThenDerived, const ElseDerived>(derived(), thenTensor.derived(), elseTensor.derived()); + } + + // Contractions. + typedef Eigen::IndexPair<Index> DimensionPair; + + template<typename OtherDerived, typename Dimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorContractionOp<const Dimensions, const Derived, const OtherDerived> + contract(const OtherDerived& other, const Dimensions& dims) const { + return TensorContractionOp<const Dimensions, const Derived, const OtherDerived>(derived(), other.derived(), dims); + } + + // Convolutions. + template<typename KernelDerived, typename Dimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorConvolutionOp<const Dimensions, const Derived, const KernelDerived> + convolve(const KernelDerived& kernel, const Dimensions& dims) const { + return TensorConvolutionOp<const Dimensions, const Derived, const KernelDerived>(derived(), kernel.derived(), dims); + } + + // Reductions. + template <typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<internal::SumReducer<CoeffReturnType>, const Dims, const Derived> + sum(const Dims& dims) const { + return TensorReductionOp<internal::SumReducer<CoeffReturnType>, const Dims, const Derived>(derived(), dims, internal::SumReducer<CoeffReturnType>()); + } + + const TensorReductionOp<internal::SumReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived> + sum() const { + array<Index, NumDimensions> in_dims; + for (int i = 0; i < NumDimensions; ++i) in_dims[i] = i; + return TensorReductionOp<internal::SumReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived>(derived(), in_dims, internal::SumReducer<CoeffReturnType>()); + } + + template <typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<internal::MeanReducer<CoeffReturnType>, const Dims, const Derived> + mean(const Dims& dims) const { + return TensorReductionOp<internal::MeanReducer<CoeffReturnType>, const Dims, const Derived>(derived(), dims, internal::MeanReducer<CoeffReturnType>()); + } + + const TensorReductionOp<internal::MeanReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived> + mean() const { + array<Index, NumDimensions> in_dims; + for (int i = 0; i < NumDimensions; ++i) in_dims[i] = i; + return TensorReductionOp<internal::MeanReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived>(derived(), in_dims, internal::MeanReducer<CoeffReturnType>()); + } + + template <typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<internal::ProdReducer<CoeffReturnType>, const Dims, const Derived> + prod(const Dims& dims) const { + return TensorReductionOp<internal::ProdReducer<CoeffReturnType>, const Dims, const Derived>(derived(), dims, internal::ProdReducer<CoeffReturnType>()); + } + + const TensorReductionOp<internal::ProdReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived> + prod() const { + array<Index, NumDimensions> in_dims; + for (int i = 0; i < NumDimensions; ++i) in_dims[i] = i; + return TensorReductionOp<internal::ProdReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived>(derived(), in_dims, internal::ProdReducer<CoeffReturnType>()); + } + + template <typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<internal::MaxReducer<CoeffReturnType>, const Dims, const Derived> + maximum(const Dims& dims) const { + return TensorReductionOp<internal::MaxReducer<CoeffReturnType>, const Dims, const Derived>(derived(), dims, internal::MaxReducer<CoeffReturnType>()); + } + + const TensorReductionOp<internal::MaxReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived> + maximum() const { + array<Index, NumDimensions> in_dims; + for (int i = 0; i < NumDimensions; ++i) in_dims[i] = i; + return TensorReductionOp<internal::MaxReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived>(derived(), in_dims, internal::MaxReducer<CoeffReturnType>()); + } + + template <typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<internal::MinReducer<CoeffReturnType>, const Dims, const Derived> + minimum(const Dims& dims) const { + return TensorReductionOp<internal::MinReducer<CoeffReturnType>, const Dims, const Derived>(derived(), dims, internal::MinReducer<CoeffReturnType>()); + } + + const TensorReductionOp<internal::MinReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived> + minimum() const { + array<Index, NumDimensions> in_dims; + for (int i = 0; i < NumDimensions; ++i) in_dims[i] = i; + return TensorReductionOp<internal::MinReducer<CoeffReturnType>, const array<Index, NumDimensions>, const Derived>(derived(), in_dims, internal::MinReducer<CoeffReturnType>()); + } + + template <typename Reducer, typename Dims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReductionOp<Reducer, const Dims, const Derived> + reduce(const Dims& dims, const Reducer& reducer) const { + return TensorReductionOp<Reducer, const Dims, const Derived>(derived(), dims, reducer); + } + + template <typename Broadcast> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorBroadcastingOp<const Broadcast, const Derived> + broadcast(const Broadcast& broadcast) const { + return TensorBroadcastingOp<const Broadcast, const Derived>(derived(), broadcast); + } + + template <typename Axis, typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorConcatenationOp<Axis, const Derived, const OtherDerived> + concatenate(const OtherDerived& other, Axis axis) const { + return TensorConcatenationOp<Axis, const Derived, const OtherDerived>(derived(), other.derived(), axis); + } + + template <typename PatchDims> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorPatchOp<const PatchDims, const Derived> + extract_patches(const PatchDims& patch_dims) const { + return TensorPatchOp<const PatchDims, const Derived>(derived(), patch_dims); + } + + template <Index Rows, Index Cols> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorImagePatchOp<Rows, Cols, const Derived> + extract_image_patches() const { + return TensorImagePatchOp<Rows, Cols, const Derived>(derived(), Rows, Cols, 1, 1, PADDING_SAME); + } + + template <Index Rows, Index Cols> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorImagePatchOp<Rows, Cols, const Derived> + extract_image_patches(const PaddingType padding_type) const { + return TensorImagePatchOp<Rows, Cols, const Derived>(derived(), Rows, Cols, 1, 1, padding_type); + } + + template <Index Rows, Index Cols> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorImagePatchOp<Rows, Cols, const Derived> + extract_image_patches(const Index stride, const PaddingType padding_type) const { + return TensorImagePatchOp<Rows, Cols, const Derived>(derived(), Rows, Cols, stride, stride, padding_type); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorImagePatchOp<Dynamic, Dynamic, const Derived> + extract_image_patches(const Index patch_rows, const Index patch_cols, + const Index row_stride = 1, const Index col_stride = 1) const { + return TensorImagePatchOp<Dynamic, Dynamic, const Derived>(derived(), patch_rows, patch_cols, row_stride, col_stride, + PADDING_SAME); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorImagePatchOp<Dynamic, Dynamic, const Derived> + extract_image_patches(const Index patch_rows, const Index patch_cols, + const Index row_stride, const Index col_stride, + const PaddingType padding_type) const { + return TensorImagePatchOp<Dynamic, Dynamic, const Derived>(derived(), patch_rows, patch_cols, row_stride, col_stride, + padding_type); + } + + // Morphing operators. + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorLayoutSwapOp<const Derived> + swap_layout() const { + return TensorLayoutSwapOp<const Derived>(derived()); + } + template <typename NewDimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReshapingOp<const NewDimensions, const Derived> + reshape(const NewDimensions& newDimensions) const { + return TensorReshapingOp<const NewDimensions, const Derived>(derived(), newDimensions); + } + template <typename StartIndices, typename Sizes> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorSlicingOp<const StartIndices, const Sizes, const Derived> + slice(const StartIndices& startIndices, const Sizes& sizes) const { + return TensorSlicingOp<const StartIndices, const Sizes, const Derived>(derived(), startIndices, sizes); + } + template <Index DimId> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorChippingOp<DimId, const Derived> + chip(const Index offset) const { + return TensorChippingOp<DimId, const Derived>(derived(), offset, DimId); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorChippingOp<Dynamic, const Derived> + chip(const Index offset, const Index dim) const { + return TensorChippingOp<Dynamic, const Derived>(derived(), offset, dim); + } + template <typename ReverseDimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorReverseOp<const ReverseDimensions, const Derived> + reverse(const ReverseDimensions& rev) const { + return TensorReverseOp<const ReverseDimensions, const Derived>(derived(), rev); + } + template <typename PaddingDimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorPaddingOp<const PaddingDimensions, const Derived> + pad(const PaddingDimensions& padding) const { + return TensorPaddingOp<const PaddingDimensions, const Derived>(derived(), padding); + } + template <typename Shuffle> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorShufflingOp<const Shuffle, const Derived> + shuffle(const Shuffle& shuffle) const { + return TensorShufflingOp<const Shuffle, const Derived>(derived(), shuffle); + } + template <typename Strides> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorStridingOp<const Strides, const Derived> + stride(const Strides& strides) const { + return TensorStridingOp<const Strides, const Derived>(derived(), strides); + } + + // Force the evaluation of the expression. + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const TensorForcedEvalOp<const Derived> eval() const { + return TensorForcedEvalOp<const Derived>(derived()); + } + + protected: + template <typename Scalar, std::size_t NumIndices, int Options> friend class Tensor; + template <typename Scalar, int Options> friend class TensorVarDim; + template <typename OtherDerived, int AccessLevel> friend class TensorBase; + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Derived& derived() const { return *static_cast<const Derived*>(this); } +}; + +template<typename Derived> +class TensorBase<Derived, WriteAccessors> : public TensorBase<Derived, ReadOnlyAccessors> { + public: + typedef internal::traits<Derived> DerivedTraits; + typedef typename DerivedTraits::Scalar Scalar; + typedef typename DerivedTraits::Index Index; + typedef Scalar CoeffReturnType; + typedef typename internal::packet_traits<Scalar>::type PacketReturnType; + static const int NumDimensions = DerivedTraits::NumDimensions; + + template <typename Scalar, std::size_t NumIndices, int Options> friend class Tensor; + template <typename Scalar, int Options> friend class TensorVarDim; + template <typename OtherDerived, int AccessLevel> friend class TensorBase; + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& setZero() { + return setConstant(Scalar(0)); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& setConstant(const Scalar& val) { + return derived() = this->constant(val); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& setRandom() { + return derived() = this->random(); + } + template <typename RandomGenerator> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& setRandom() { + return derived() = this->template random<RandomGenerator>(); + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& setValues( + const typename internal::Initializer<Derived, NumDimensions>::InitList& vals) { + TensorEvaluator<Derived, DefaultDevice> eval(derived(), DefaultDevice()); + internal::initialize_tensor<Derived, NumDimensions>(eval, vals); + return derived(); + } +#endif // EIGEN_HAS_VARIADIC_TEMPLATES + + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Derived& operator+=(const OtherDerived& other) { + return derived() = derived() + other.derived(); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Derived& operator-=(const OtherDerived& other) { + return derived() = derived() - other.derived(); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Derived& operator*=(const OtherDerived& other) { + return derived() = derived() * other.derived(); + } + template<typename OtherDerived> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Derived& operator/=(const OtherDerived& other) { + return derived() = derived() / other.derived(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorLayoutSwapOp<Derived> + swap_layout() const { + return TensorLayoutSwapOp<Derived>(derived()); + } + template <typename NewDimensions> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorReshapingOp<const NewDimensions, Derived> + reshape(const NewDimensions& newDimensions) const { + return TensorReshapingOp<const NewDimensions, Derived>(derived(), newDimensions); + } + template <typename StartIndices, typename Sizes> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorSlicingOp<const StartIndices, const Sizes, Derived> + slice(const StartIndices& startIndices, const Sizes& sizes) const { + return TensorSlicingOp<const StartIndices, const Sizes, Derived>(derived(), startIndices, sizes); + } + template <DenseIndex DimId> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorChippingOp<DimId, Derived> + chip(const Index offset) const { + return TensorChippingOp<DimId, Derived>(derived(), offset, DimId); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorChippingOp<Dynamic, Derived> + chip(const Index offset, const Index dim) const { + return TensorChippingOp<Dynamic, Derived>(derived(), offset, dim); + } + template <typename Shuffle> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorShufflingOp<const Shuffle, Derived> + shuffle(const Shuffle& shuffle) const { + return TensorShufflingOp<const Shuffle, Derived>(derived(), shuffle); + } + template <typename Strides> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorStridingOp<const Strides, Derived> + stride(const Strides& strides) const { + return TensorStridingOp<const Strides, Derived>(derived(), strides); + } + + // Select the device on which to evaluate the expression. + template <typename DeviceType> + TensorDevice<Derived, DeviceType> device(const DeviceType& device) { + return TensorDevice<Derived, DeviceType>(device, derived()); + } + + protected: + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Derived& derived() { return *static_cast<Derived*>(this); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Derived& derived() const { return *static_cast<const Derived*>(this); } +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_BASE_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorBroadcasting.h b/unsupported/Eigen/CXX11/src/Tensor/TensorBroadcasting.h new file mode 100644 index 000000000..5790e19d6 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorBroadcasting.h @@ -0,0 +1,341 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_BROADCASTING_H +#define EIGEN_CXX11_TENSOR_TENSOR_BROADCASTING_H + +namespace Eigen { + +/** \class TensorBroadcasting + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor broadcasting class. + * + * + */ +namespace internal { +template<typename Broadcast, typename XprType> +struct traits<TensorBroadcastingOp<Broadcast, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename Broadcast, typename XprType> +struct eval<TensorBroadcastingOp<Broadcast, XprType>, Eigen::Dense> +{ + typedef const TensorBroadcastingOp<Broadcast, XprType>& type; +}; + +template<typename Broadcast, typename XprType> +struct nested<TensorBroadcastingOp<Broadcast, XprType>, 1, typename eval<TensorBroadcastingOp<Broadcast, XprType> >::type> +{ + typedef TensorBroadcastingOp<Broadcast, XprType> type; +}; + +} // end namespace internal + + + +template<typename Broadcast, typename XprType> +class TensorBroadcastingOp : public TensorBase<TensorBroadcastingOp<Broadcast, XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorBroadcastingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorBroadcastingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorBroadcastingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorBroadcastingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorBroadcastingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorBroadcastingOp(const XprType& expr, const Broadcast& broadcast) + : m_xpr(expr), m_broadcast(broadcast) {} + + EIGEN_DEVICE_FUNC + const Broadcast& broadcast() const { return m_broadcast; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const Broadcast m_broadcast; +}; + + +// Eval as rvalue +template<typename Broadcast, typename ArgType, typename Device> +struct TensorEvaluator<const TensorBroadcastingOp<Broadcast, ArgType>, Device> +{ + typedef TensorBroadcastingOp<Broadcast, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + typedef typename TensorEvaluator<ArgType, Device>::Dimensions InputDimensions; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + const Broadcast& broadcast = op.broadcast(); + for (int i = 0; i < NumDims; ++i) { + eigen_assert(input_dims[i] > 0); + m_dimensions[i] = input_dims[i] * broadcast[i]; + } + + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_inputStrides[0] = 1; + m_outputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_inputStrides[i] = m_inputStrides[i-1] * input_dims[i-1]; + m_outputStrides[i] = m_outputStrides[i-1] * m_dimensions[i-1]; + } + } else { + m_inputStrides[NumDims-1] = 1; + m_outputStrides[NumDims-1] = 1; + for (int i = NumDims-2; i >= 0; --i) { + m_inputStrides[i] = m_inputStrides[i+1] * input_dims[i+1]; + m_outputStrides[i] = m_outputStrides[i+1] * m_dimensions[i+1]; + } + } + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE CoeffReturnType coeff(Index index) const + { + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return coeffColMajor(index); + } else { + return coeffRowMajor(index); + } + } + + // TODO: attempt to speed this up. The integer divisions and modulo are slow + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeffColMajor(Index index) const + { + Index inputIndex = 0; + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStrides[i]; + if (internal::index_statically_eq<Broadcast>()(i, 1)) { + eigen_assert(idx < m_impl.dimensions()[i]); + inputIndex += idx * m_inputStrides[i]; + } else { + if (internal::index_statically_eq<InputDimensions>()(i, 1)) { + eigen_assert(idx % m_impl.dimensions()[i] == 0); + } else { + inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i]; + } + } + index -= idx * m_outputStrides[i]; + } + if (internal::index_statically_eq<Broadcast>()(0, 1)) { + eigen_assert(index < m_impl.dimensions()[0]); + inputIndex += index; + } else { + if (internal::index_statically_eq<InputDimensions>()(0, 1)) { + eigen_assert(index % m_impl.dimensions()[0] == 0); + } else { + inputIndex += (index % m_impl.dimensions()[0]); + } + } + return m_impl.coeff(inputIndex); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeffRowMajor(Index index) const + { + Index inputIndex = 0; + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_outputStrides[i]; + if (internal::index_statically_eq<Broadcast>()(i, 1)) { + eigen_assert(idx < m_impl.dimensions()[i]); + inputIndex += idx * m_inputStrides[i]; + } else { + if (internal::index_statically_eq<InputDimensions>()(i, 1)) { + eigen_assert(idx % m_impl.dimensions()[i] == 0); + } else { + inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i]; + } + } + index -= idx * m_outputStrides[i]; + } + if (internal::index_statically_eq<Broadcast>()(NumDims-1, 1)) { + eigen_assert(index < m_impl.dimensions()[NumDims-1]); + inputIndex += index; + } else { + if (internal::index_statically_eq<InputDimensions>()(NumDims-1, 1)) { + eigen_assert(index % m_impl.dimensions()[NumDims-1] == 0); + } else { + inputIndex += (index % m_impl.dimensions()[NumDims-1]); + } + } + return m_impl.coeff(inputIndex); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE PacketReturnType packet(Index index) const + { + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return packetColMajor<LoadMode>(index); + } else { + return packetRowMajor<LoadMode>(index); + } + } + + // Ignore the LoadMode and always use unaligned loads since we can't guarantee + // the alignment at compile time. + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetColMajor(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + const Index originalIndex = index; + + Index inputIndex = 0; + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStrides[i]; + if (internal::index_statically_eq<Broadcast>()(i, 1)) { + eigen_assert(idx < m_impl.dimensions()[i]); + inputIndex += idx * m_inputStrides[i]; + } else { + if (internal::index_statically_eq<InputDimensions>()(i, 1)) { + eigen_assert(idx % m_impl.dimensions()[i] == 0); + } else { + inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i]; + } + } + index -= idx * m_outputStrides[i]; + } + Index innermostLoc; + if (internal::index_statically_eq<Broadcast>()(0, 1)) { + eigen_assert(index < m_impl.dimensions()[0]); + innermostLoc = index; + } else { + if (internal::index_statically_eq<InputDimensions>()(0, 1)) { + eigen_assert(innermostLoc % m_impl.dimensions()[0] == 0); + innermostLoc = 0; + } else { + innermostLoc = index % m_impl.dimensions()[0]; + } + } + inputIndex += innermostLoc; + + // Todo: this could be extended to the second dimension if we're not + // broadcasting alongside the first dimension, and so on. + if (innermostLoc + packetSize <= m_impl.dimensions()[0]) { + return m_impl.template packet<Unaligned>(inputIndex); + } else { + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + values[0] = m_impl.coeff(inputIndex); + for (int i = 1; i < packetSize; ++i) { + values[i] = coeffColMajor(originalIndex+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetRowMajor(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + const Index originalIndex = index; + + Index inputIndex = 0; + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_outputStrides[i]; + if (internal::index_statically_eq<Broadcast>()(i, 1)) { + eigen_assert(idx < m_impl.dimensions()[i]); + inputIndex += idx * m_inputStrides[i]; + } else { + if (internal::index_statically_eq<InputDimensions>()(i, 1)) { + eigen_assert(idx % m_impl.dimensions()[i] == 0); + } else { + inputIndex += (idx % m_impl.dimensions()[i]) * m_inputStrides[i]; + } + } + index -= idx * m_outputStrides[i]; + } + Index innermostLoc; + if (internal::index_statically_eq<Broadcast>()(NumDims-1, 1)) { + eigen_assert(index < m_impl.dimensions()[NumDims-1]); + innermostLoc = index; + } else { + if (internal::index_statically_eq<InputDimensions>()(NumDims-1, 1)) { + eigen_assert(innermostLoc % m_impl.dimensions()[NumDims-1] == 0); + innermostLoc = 0; + } else { + innermostLoc = index % m_impl.dimensions()[NumDims-1]; + } + } + inputIndex += innermostLoc; + + // Todo: this could be extended to the second dimension if we're not + // broadcasting alongside the first dimension, and so on. + if (innermostLoc + packetSize <= m_impl.dimensions()[NumDims-1]) { + return m_impl.template packet<Unaligned>(inputIndex); + } else { + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + values[0] = m_impl.coeff(inputIndex); + for (int i = 1; i < packetSize; ++i) { + values[i] = coeffRowMajor(originalIndex+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + Dimensions m_dimensions; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims> m_inputStrides; + TensorEvaluator<ArgType, Device> m_impl; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_BROADCASTING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorChipping.h b/unsupported/Eigen/CXX11/src/Tensor/TensorChipping.h new file mode 100644 index 000000000..dc9586cbc --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorChipping.h @@ -0,0 +1,363 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H +#define EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H + +namespace Eigen { + +/** \class TensorKChippingReshaping + * \ingroup CXX11_Tensor_Module + * + * \brief A chip is a thin slice, corresponding to a column or a row in a 2-d tensor. + * + * + */ + +namespace internal { +template<DenseIndex DimId, typename XprType> +struct traits<TensorChippingOp<DimId, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions - 1; + static const int Layout = XprTraits::Layout; +}; + +template<DenseIndex DimId, typename XprType> +struct eval<TensorChippingOp<DimId, XprType>, Eigen::Dense> +{ + typedef const TensorChippingOp<DimId, XprType>& type; +}; + +template<DenseIndex DimId, typename XprType> +struct nested<TensorChippingOp<DimId, XprType>, 1, typename eval<TensorChippingOp<DimId, XprType> >::type> +{ + typedef TensorChippingOp<DimId, XprType> type; +}; + +template <DenseIndex DimId> +struct DimensionId +{ + DimensionId(DenseIndex dim) { + eigen_assert(dim == DimId); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { + return DimId; + } +}; +template <> +struct DimensionId<Dynamic> +{ + DimensionId(DenseIndex dim) : actual_dim(dim) { + eigen_assert(dim >= 0); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex actualDim() const { + return actual_dim; + } + private: + const DenseIndex actual_dim; +}; + + +} // end namespace internal + + + +template<DenseIndex DimId, typename XprType> +class TensorChippingOp : public TensorBase<TensorChippingOp<DimId, XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorChippingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorChippingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorChippingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorChippingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorChippingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorChippingOp(const XprType& expr, const Index offset, const Index dim) + : m_xpr(expr), m_offset(offset), m_dim(dim) { + } + + EIGEN_DEVICE_FUNC + const Index offset() const { return m_offset; } + EIGEN_DEVICE_FUNC + const Index dim() const { return m_dim.actualDim(); } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorChippingOp& operator = (const TensorChippingOp& other) + { + typedef TensorAssignOp<TensorChippingOp, const TensorChippingOp> Assign; + Assign assign(*this, other); + static const bool Vectorize = TensorEvaluator<const Assign, DefaultDevice>::PacketAccess; + internal::TensorExecutor<const Assign, DefaultDevice, Vectorize>::run(assign, DefaultDevice()); + return *this; + } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorChippingOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorChippingOp, const OtherDerived> Assign; + Assign assign(*this, other); + static const bool Vectorize = TensorEvaluator<const Assign, DefaultDevice>::PacketAccess; + internal::TensorExecutor<const Assign, DefaultDevice, Vectorize>::run(assign, DefaultDevice()); + return *this; + } + + protected: + typename XprType::Nested m_xpr; + const Index m_offset; + const internal::DimensionId<DimId> m_dim; +}; + + +// Eval as rvalue +template<DenseIndex DimId, typename ArgType, typename Device> +struct TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> +{ + typedef TensorChippingOp<DimId, ArgType> XprType; + static const int NumInputDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + static const int NumDims = NumInputDims-1; + typedef typename XprType::Index Index; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + // Alignment can't be guaranteed at compile time since it depends on the + // slice offsets. + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_dim(op.dim()), m_device(device) + { + // We could also support the case where NumInputDims==1 if needed. + EIGEN_STATIC_ASSERT(NumInputDims >= 2, YOU_MADE_A_PROGRAMMING_MISTAKE); + eigen_assert(NumInputDims > m_dim.actualDim()); + + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + int j = 0; + for (int i = 0; i < NumInputDims; ++i) { + if (i != m_dim.actualDim()) { + m_dimensions[j] = input_dims[i]; + ++j; + } + } + + m_stride = 1; + m_inputStride = 1; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = 0; i < m_dim.actualDim(); ++i) { + m_stride *= input_dims[i]; + m_inputStride *= input_dims[i]; + } + } else { + for (int i = NumInputDims-1; i > m_dim.actualDim(); --i) { + m_stride *= input_dims[i]; + m_inputStride *= input_dims[i]; + } + } + m_inputStride *= input_dims[m_dim.actualDim()]; + m_inputOffset = m_stride * op.offset(); + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(srcCoeff(index)); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == 0) || + (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == NumInputDims-1)) { + // m_stride is equal to 1, so let's avoid the integer division. + eigen_assert(m_stride == 1); + Index inputIndex = index * m_inputStride + m_inputOffset; + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = m_impl.coeff(inputIndex); + inputIndex += m_inputStride; + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } else if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == NumInputDims - 1) || + (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == 0)) { + // m_stride is aways greater than index, so let's avoid the integer division. + eigen_assert(m_stride > index); + return m_impl.template packet<LoadMode>(index + m_inputOffset); + } else { + const Index idx = index / m_stride; + const Index rem = index - idx * m_stride; + if (rem + packetSize <= m_stride) { + Index inputIndex = idx * m_inputStride + m_inputOffset + rem; + return m_impl.template packet<LoadMode>(inputIndex); + } else { + // Cross the stride boundary. Fallback to slow path. + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index); + ++index; + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar* data() const { + Scalar* result = m_impl.data(); + if (m_dim.actualDim() == NumDims && result) { + return result + m_inputOffset; + } else { + return NULL; + } + } + + protected: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const + { + Index inputIndex; + if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == 0) || + (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == NumInputDims-1)) { + // m_stride is equal to 1, so let's avoid the integer division. + eigen_assert(m_stride == 1); + inputIndex = index * m_inputStride + m_inputOffset; + } else if ((static_cast<int>(Layout) == static_cast<int>(ColMajor) && m_dim.actualDim() == NumInputDims-1) || + (static_cast<int>(Layout) == static_cast<int>(RowMajor) && m_dim.actualDim() == 0)) { + // m_stride is aways greater than index, so let's avoid the integer division. + eigen_assert(m_stride > index); + inputIndex = index + m_inputOffset; + } else { + const Index idx = index / m_stride; + inputIndex = idx * m_inputStride + m_inputOffset; + index -= idx * m_stride; + inputIndex += index; + } + return inputIndex; + } + + Dimensions m_dimensions; + Index m_stride; + Index m_inputOffset; + Index m_inputStride; + TensorEvaluator<ArgType, Device> m_impl; + const internal::DimensionId<DimId> m_dim; + const Device& m_device; +}; + + +// Eval as lvalue +template<DenseIndex DimId, typename ArgType, typename Device> +struct TensorEvaluator<TensorChippingOp<DimId, ArgType>, Device> + : public TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> +{ + typedef TensorEvaluator<const TensorChippingOp<DimId, ArgType>, Device> Base; + typedef TensorChippingOp<DimId, ArgType> XprType; + static const int NumInputDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + static const int NumDims = NumInputDims-1; + typedef typename XprType::Index Index; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) + { } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) + { + return this->m_impl.coeffRef(this->srcCoeff(index)); + } + + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + static const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + + if ((static_cast<int>(this->Layout) == static_cast<int>(ColMajor) && this->m_dim.actualDim() == 0) || + (static_cast<int>(this->Layout) == static_cast<int>(RowMajor) && this->m_dim.actualDim() == NumInputDims-1)) { + // m_stride is equal to 1, so let's avoid the integer division. + eigen_assert(this->m_stride == 1); + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + internal::pstore<CoeffReturnType, PacketReturnType>(values, x); + Index inputIndex = index * this->m_inputStride + this->m_inputOffset; + for (int i = 0; i < packetSize; ++i) { + this->m_impl.coeffRef(inputIndex) = values[i]; + inputIndex += this->m_inputStride; + } + } else if ((static_cast<int>(this->Layout) == static_cast<int>(ColMajor) && this->m_dim.actualDim() == NumInputDims-1) || + (static_cast<int>(this->Layout) == static_cast<int>(RowMajor) && this->m_dim.actualDim() == 0)) { + // m_stride is aways greater than index, so let's avoid the integer division. + eigen_assert(this->m_stride > index); + this->m_impl.template writePacket<StoreMode>(index + this->m_inputOffset, x); + } else { + const Index idx = index / this->m_stride; + const Index rem = index - idx * this->m_stride; + if (rem + packetSize <= this->m_stride) { + const Index inputIndex = idx * this->m_inputStride + this->m_inputOffset + rem; + this->m_impl.template writePacket<StoreMode>(inputIndex, x); + } else { + // Cross stride boundary. Fallback to slow path. + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + internal::pstore<CoeffReturnType, PacketReturnType>(values, x); + for (int i = 0; i < packetSize; ++i) { + this->coeffRef(index) = values[i]; + ++index; + } + } + } + } +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_CHIPPING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorConcatenation.h b/unsupported/Eigen/CXX11/src/Tensor/TensorConcatenation.h new file mode 100644 index 000000000..a1dec76d1 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorConcatenation.h @@ -0,0 +1,258 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H +#define EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H + +namespace Eigen { + +/** \class TensorConcatenationOp + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor concatenation class. + * + * + */ +namespace internal { +template<typename Axis, typename LhsXprType, typename RhsXprType> +struct traits<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs are different. + typedef typename promote_storage_type<typename LhsXprType::Scalar, + typename RhsXprType::Scalar>::ret Scalar; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename promote_storage_type<typename traits<LhsXprType>::StorageKind, + typename traits<RhsXprType>::StorageKind>::ret StorageKind; + typedef typename promote_index_type<typename traits<LhsXprType>::Index, + typename traits<RhsXprType>::Index>::type Index; + typedef typename LhsXprType::Nested LhsNested; + typedef typename RhsXprType::Nested RhsNested; + typedef typename remove_reference<LhsNested>::type _LhsNested; + typedef typename remove_reference<RhsNested>::type _RhsNested; + static const int NumDimensions = traits<LhsXprType>::NumDimensions; + static const int Layout = traits<LhsXprType>::Layout; + enum { Flags = 0 }; +}; + +template<typename Axis, typename LhsXprType, typename RhsXprType> +struct eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, Eigen::Dense> +{ + typedef const TensorConcatenationOp<Axis, LhsXprType, RhsXprType>& type; +}; + +template<typename Axis, typename LhsXprType, typename RhsXprType> +struct nested<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, 1, typename eval<TensorConcatenationOp<Axis, LhsXprType, RhsXprType> >::type> +{ + typedef TensorConcatenationOp<Axis, LhsXprType, RhsXprType> type; +}; + +} // end namespace internal + + +template<typename Axis, typename LhsXprType, typename RhsXprType> +class TensorConcatenationOp : public TensorBase<TensorConcatenationOp<Axis, LhsXprType, RhsXprType>, WriteAccessors> +{ + public: + typedef typename internal::traits<TensorConcatenationOp>::Scalar Scalar; + typedef typename internal::traits<TensorConcatenationOp>::Packet Packet; + typedef typename internal::traits<TensorConcatenationOp>::StorageKind StorageKind; + typedef typename internal::traits<TensorConcatenationOp>::Index Index; + typedef typename internal::nested<TensorConcatenationOp>::type Nested; + typedef typename internal::promote_storage_type<typename LhsXprType::CoeffReturnType, + typename RhsXprType::CoeffReturnType>::ret CoeffReturnType; + typedef typename internal::promote_storage_type<typename LhsXprType::PacketReturnType, + typename RhsXprType::PacketReturnType>::ret PacketReturnType; + typedef typename NumTraits<Scalar>::Real RealScalar; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorConcatenationOp(const LhsXprType& lhs, const RhsXprType& rhs, Axis axis) + : m_lhs_xpr(lhs), m_rhs_xpr(rhs), m_axis(axis) {} + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename LhsXprType::Nested>::type& + lhsExpression() const { return m_lhs_xpr; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename RhsXprType::Nested>::type& + rhsExpression() const { return m_rhs_xpr; } + + EIGEN_DEVICE_FUNC Axis axis() const { return m_axis; } + + protected: + typename LhsXprType::Nested m_lhs_xpr; + typename RhsXprType::Nested m_rhs_xpr; + const Axis m_axis; +}; + + +// Eval as rvalue +template<typename Axis, typename LeftArgType, typename RightArgType, typename Device> +struct TensorEvaluator<const TensorConcatenationOp<Axis, LeftArgType, RightArgType>, Device> +{ + typedef TensorConcatenationOp<Axis, LeftArgType, RightArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<LeftArgType, Device>::Dimensions>::value; + static const int RightNumDims = internal::array_size<typename TensorEvaluator<RightArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess, + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_leftImpl(op.lhsExpression(), device), m_rightImpl(op.rhsExpression(), device), m_axis(op.axis()) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout) || NumDims == 1), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT(NumDims == RightNumDims, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(0 <= m_axis && m_axis < NumDims); + const Dimensions& lhs_dims = m_leftImpl.dimensions(); + const Dimensions& rhs_dims = m_rightImpl.dimensions(); + int i = 0; + for (; i < m_axis; ++i) { + eigen_assert(lhs_dims[i] > 0); + eigen_assert(lhs_dims[i] == rhs_dims[i]); + m_dimensions[i] = lhs_dims[i]; + } + eigen_assert(lhs_dims[i] > 0); // Now i == m_axis. + eigen_assert(rhs_dims[i] > 0); + m_dimensions[i] = lhs_dims[i] + rhs_dims[i]; + for (++i; i < NumDims; ++i) { + eigen_assert(lhs_dims[i] > 0); + eigen_assert(lhs_dims[i] == rhs_dims[i]); + m_dimensions[i] = lhs_dims[i]; + } + + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_leftStrides[0] = 1; + m_rightStrides[0] = 1; + m_outputStrides[0] = 1; + + for (int i = 1; i < NumDims; ++i) { + m_leftStrides[i] = m_leftStrides[i-1] * lhs_dims[i-1]; + m_rightStrides[i] = m_rightStrides[i-1] * rhs_dims[i-1]; + m_outputStrides[i] = m_outputStrides[i-1] * m_dimensions[i-1]; + } + } else { + m_leftStrides[NumDims - 1] = 1; + m_rightStrides[NumDims - 1] = 1; + m_outputStrides[NumDims - 1] = 1; + + for (int i = NumDims - 2; i >= 0; --i) { + m_leftStrides[i] = m_leftStrides[i+1] * lhs_dims[i+1]; + m_rightStrides[i] = m_rightStrides[i+1] * rhs_dims[i+1]; + m_outputStrides[i] = m_outputStrides[i+1] * m_dimensions[i+1]; + } + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + // TODO(phli): Add short-circuit memcpy evaluation if underlying data are linear? + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) + { + m_leftImpl.evalSubExprsIfNeeded(NULL); + m_rightImpl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() + { + m_leftImpl.cleanup(); + m_rightImpl.cleanup(); + } + + // TODO(phli): attempt to speed this up. The integer divisions and modulo are slow. + // See CL/76180724 comments for more ideas. + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + // Collect dimension-wise indices (subs). + array<Index, NumDims> subs; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + subs[i] = index / m_outputStrides[i]; + index -= subs[i] * m_outputStrides[i]; + } + subs[0] = index; + } else { + for (int i = 0; i < NumDims - 1; ++i) { + subs[i] = index / m_outputStrides[i]; + index -= subs[i] * m_outputStrides[i]; + } + subs[NumDims - 1] = index; + } + + const Dimensions& left_dims = m_leftImpl.dimensions(); + if (subs[m_axis] < left_dims[m_axis]) { + Index left_index; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + left_index = subs[0]; + for (int i = 1; i < NumDims; ++i) { + left_index += (subs[i] % left_dims[i]) * m_leftStrides[i]; + } + } else { + left_index = subs[NumDims - 1]; + for (int i = NumDims - 2; i >= 0; --i) { + left_index += (subs[i] % left_dims[i]) * m_leftStrides[i]; + } + } + return m_leftImpl.coeff(left_index); + } else { + subs[m_axis] -= left_dims[m_axis]; + const Dimensions& right_dims = m_rightImpl.dimensions(); + Index right_index; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + right_index = subs[0]; + for (int i = 1; i < NumDims; ++i) { + right_index += (subs[i] % right_dims[i]) * m_rightStrides[i]; + } + } else { + right_index = subs[NumDims - 1]; + for (int i = NumDims - 2; i >= 0; --i) { + right_index += (subs[i] % right_dims[i]) * m_rightStrides[i]; + } + } + return m_rightImpl.coeff(right_index); + } + } + + // TODO(phli): Add a real vectorization. + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + static const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index + packetSize - 1 < dimensions().TotalSize()); + + EIGEN_ALIGN_DEFAULT CoeffReturnType values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + Dimensions m_dimensions; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims> m_leftStrides; + array<Index, NumDims> m_rightStrides; + TensorEvaluator<LeftArgType, Device> m_leftImpl; + TensorEvaluator<RightArgType, Device> m_rightImpl; + const Axis m_axis; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_CONCATENATION_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorContraction.h b/unsupported/Eigen/CXX11/src/Tensor/TensorContraction.h new file mode 100644 index 000000000..f7254a24d --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorContraction.h @@ -0,0 +1,992 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_H +#define EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_H + +namespace Eigen { + +/** \class TensorContraction + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor contraction class. + * + * + */ +namespace internal { + +enum { + Rhs = 0, + Lhs = 1, +}; + +/* + * Implementation of the Eigen blas_data_mapper class for tensors. + */ +template<typename Scalar, typename Index, int side, + typename Tensor, + typename nocontract_t, typename contract_t, + size_t packet_size, bool inner_dim_contiguous> +class BaseTensorContractionMapper { + public: + EIGEN_DEVICE_FUNC + BaseTensorContractionMapper(const Tensor& tensor, + const nocontract_t& nocontract_strides, + const nocontract_t& ij_strides, + const contract_t& contract_strides, + const contract_t& k_strides) : + m_tensor(tensor), + m_nocontract_strides(nocontract_strides), + m_ij_strides(ij_strides), + m_contract_strides(contract_strides), + m_k_strides(k_strides) { } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE void prefetch(Index /*i*/) { } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar operator()(Index row) const { + // column major assumption + return operator()(row, 0); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar operator()(Index row, Index col) const { + return m_tensor.coeff(computeIndex(row, col)); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index computeIndex(Index row, Index col) const { + const bool left = (side == Lhs); + Index nocontract_val = left ? row : col; + Index linidx = 0; + for (int i = array_size<nocontract_t>::value - 1; i > 0; i--) { + const Index idx = nocontract_val / m_ij_strides[i]; + linidx += idx * m_nocontract_strides[i]; + nocontract_val -= idx * m_ij_strides[i]; + } + if (array_size<typename Tensor::Dimensions>::value > array_size<contract_t>::value) { + if (side == Lhs && inner_dim_contiguous) { + eigen_assert(m_nocontract_strides[0] == 1); + linidx += nocontract_val; + } else { + linidx += nocontract_val * m_nocontract_strides[0]; + } + } + + Index contract_val = left ? col : row; + for (int i = array_size<contract_t>::value - 1; i > 0; i--) { + const Index idx = contract_val / m_k_strides[i]; + linidx += idx * m_contract_strides[i]; + contract_val -= idx * m_k_strides[i]; + } + EIGEN_STATIC_ASSERT(array_size<contract_t>::value > 0, YOU_MADE_A_PROGRAMMING_MISTAKE); + if (side == Rhs && inner_dim_contiguous) { + eigen_assert(m_contract_strides[0] == 1); + linidx += contract_val; + } else { + linidx += contract_val * m_contract_strides[0]; + } + + return linidx; + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE IndexPair<Index> computeIndexPair(Index row, Index col, const Index distance) const { + const bool left = (side == Lhs); + Index nocontract_val[2] = {left ? row : col, left ? row + distance : col}; + Index linidx[2] = {0, 0}; + for (int i = array_size<nocontract_t>::value - 1; i > 0; i--) { + const Index idx0 = nocontract_val[0] / m_ij_strides[i]; + const Index idx1 = nocontract_val[1] / m_ij_strides[i]; + linidx[0] += idx0 * m_nocontract_strides[i]; + linidx[1] += idx1 * m_nocontract_strides[i]; + nocontract_val[0] -= idx0 * m_ij_strides[i]; + nocontract_val[1] -= idx1 * m_ij_strides[i]; + } + if (array_size<typename Tensor::Dimensions>::value > array_size<contract_t>::value) { + if (side == Lhs && inner_dim_contiguous) { + eigen_assert(m_nocontract_strides[0] == 1); + linidx[0] += nocontract_val[0]; + linidx[1] += nocontract_val[1]; + } else { + linidx[0] += nocontract_val[0] * m_nocontract_strides[0]; + linidx[1] += nocontract_val[1] * m_nocontract_strides[0]; + } + } + + Index contract_val[2] = {left ? col : row, left ? col : row + distance}; + for (int i = array_size<contract_t>::value - 1; i > 0; i--) { + const Index idx0 = contract_val[0] / m_k_strides[i]; + const Index idx1 = contract_val[1] / m_k_strides[i]; + linidx[0] += idx0 * m_contract_strides[i]; + linidx[1] += idx1 * m_contract_strides[i]; + contract_val[0] -= idx0 * m_k_strides[i]; + contract_val[1] -= idx1 * m_k_strides[i]; + } + EIGEN_STATIC_ASSERT(array_size<contract_t>::value > 0, YOU_MADE_A_PROGRAMMING_MISTAKE); + if (side == Rhs && inner_dim_contiguous) { + eigen_assert(m_contract_strides[0] == 1); + linidx[0] += contract_val[0]; + linidx[1] += contract_val[1]; + } else { + linidx[0] += contract_val[0] * m_contract_strides[0]; + linidx[1] += contract_val[1] * m_contract_strides[0]; + } + return IndexPair<Index>(linidx[0], linidx[1]); + } + + Index firstAligned(Index size) const { + return size; + } + Index stride() const { + return 1; + } + + protected: + const Tensor m_tensor; + const nocontract_t m_nocontract_strides; + const nocontract_t m_ij_strides; + const contract_t m_contract_strides; + const contract_t m_k_strides; +}; + + + +template<typename Scalar, typename Index, int side, + typename Tensor, + typename nocontract_t, typename contract_t, + size_t packet_size, + bool inner_dim_contiguous, bool inner_dim_reordered, int Alignment> +class TensorContractionInputMapper; + +template<typename Scalar, typename Index, int side, + typename Tensor, + typename nocontract_t, typename contract_t, + size_t packet_size, + bool inner_dim_contiguous, bool inner_dim_reordered, int Alignment> +class TensorContractionSubMapper { + public: + typedef typename packet_traits<Scalar>::type Packet; + typedef typename packet_traits<Scalar>::half HalfPacket; + + typedef TensorContractionInputMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, packet_size, inner_dim_contiguous, inner_dim_reordered, Alignment> ParentMapper; + typedef TensorContractionSubMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, packet_size, inner_dim_contiguous, inner_dim_reordered, Alignment> Self; + typedef Self LinearMapper; + + EIGEN_DEVICE_FUNC TensorContractionSubMapper(const ParentMapper& base_mapper, Index vert_offset, Index horiz_offset) + : m_base_mapper(base_mapper), m_vert_offset(vert_offset), m_horiz_offset(horiz_offset) { } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE Scalar operator()(Index i) const { + return m_base_mapper(i + m_vert_offset, m_horiz_offset); + } + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE Scalar operator()(Index i, Index j) const { + return m_base_mapper(i + m_vert_offset, j + m_horiz_offset); + } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE Packet loadPacket(Index i) const { + return m_base_mapper.loadPacket(i + m_vert_offset, m_horiz_offset); + } + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE Packet loadPacket(Index i, Index j) const { + return m_base_mapper.loadPacket(i + m_vert_offset, j + m_horiz_offset); + } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE HalfPacket loadHalfPacket(Index i) const { + return m_base_mapper.loadHalfPacket(i + m_vert_offset, m_horiz_offset); + } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE void storePacket(Index i, Packet p) const { + m_base_mapper.storePacket(i + m_vert_offset, m_horiz_offset, p); + } + + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE LinearMapper getLinearMapper(Index i, Index j) const { + return LinearMapper(m_base_mapper, i + m_vert_offset, j + m_horiz_offset); + } + + template <typename PacketT, int AlignmentType> + EIGEN_ALWAYS_INLINE PacketT load(Index i) const { + EIGEN_STATIC_ASSERT((internal::is_same<PacketT, Packet>::value), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((AlignmentType == Aligned || Alignment == Unaligned), YOU_MADE_A_PROGRAMMING_MISTAKE); + return loadPacket(i); + } + + template <typename Packet> + bool aligned(Index /*i*/) const { + return false; + } + + private: + const ParentMapper& m_base_mapper; + const Index m_vert_offset; + const Index m_horiz_offset; +}; + + +template<typename Scalar, typename Index, int side, + typename Tensor, + typename nocontract_t, typename contract_t, + size_t packet_size = (Tensor::PacketAccess ? packet_traits<Scalar>::size : 1), + bool inner_dim_contiguous = false, bool inner_dim_reordered = (side != Lhs), int Alignment=Unaligned> +class TensorContractionInputMapper + : public BaseTensorContractionMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, packet_size, inner_dim_contiguous> { + + public: + typedef BaseTensorContractionMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, packet_size, inner_dim_contiguous> Base; + typedef TensorContractionSubMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, packet_size, inner_dim_contiguous, inner_dim_reordered, Alignment> SubMapper; + typedef SubMapper VectorMapper; + + TensorContractionInputMapper(const Tensor& tensor, + const nocontract_t& nocontract_strides, + const nocontract_t& ij_strides, + const contract_t& contract_strides, + const contract_t& k_strides) + : Base(tensor, nocontract_strides, ij_strides, contract_strides, k_strides) { } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE SubMapper getSubMapper(Index i, Index j) const { + return SubMapper(*this, i, j); + } + + EIGEN_ALWAYS_INLINE VectorMapper getVectorMapper(Index i, Index j) const { + return VectorMapper(*this, i, j); + } + + typedef typename packet_traits<Scalar>::type Packet; + typedef typename packet_traits<Scalar>::half HalfPacket; + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Packet loadPacket(Index i, Index j) const { + // whole method makes column major assumption + + // don't need to add offsets for now (because operator handles that) + // current code assumes packet size must be a multiple of 2 + EIGEN_STATIC_ASSERT(packet_size % 2 == 0, YOU_MADE_A_PROGRAMMING_MISTAKE); + + if (Tensor::PacketAccess && inner_dim_contiguous && !inner_dim_reordered) { + const Index index = this->computeIndex(i, j); + eigen_assert(this->computeIndex(i+packet_size-1, j) == index + packet_size-1); + return this->m_tensor.template packet<Alignment>(index); + } + + const IndexPair<Index> indexPair = this->computeIndexPair(i, j, packet_size - 1); + const Index first = indexPair.first; + const Index last = indexPair.second; + + // We can always do optimized packet reads from left hand side right now, because + // the vertical matrix dimension on the left hand side is never contracting. + // On the right hand side we need to check if the contracting dimensions may have + // been shuffled first. + if (Tensor::PacketAccess && + (side == Lhs || internal::array_size<contract_t>::value <= 1 || !inner_dim_reordered) && + (last - first) == (packet_size - 1)) { + + return this->m_tensor.template packet<Alignment>(first); + } + + EIGEN_ALIGN_DEFAULT Scalar data[packet_size]; + + data[0] = this->m_tensor.coeff(first); + for (Index k = 1; k < packet_size - 1; k += 2) { + const IndexPair<Index> internal_pair = this->computeIndexPair(i + k, j, 1); + data[k] = this->m_tensor.coeff(internal_pair.first); + data[k + 1] = this->m_tensor.coeff(internal_pair.second); + } + data[packet_size - 1] = this->m_tensor.coeff(last); + + return pload<Packet>(data); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE HalfPacket loadHalfPacket(Index i, Index j) const { + // whole method makes column major assumption + + // don't need to add offsets for now (because operator handles that) + const Index half_packet_size = unpacket_traits<HalfPacket>::size; + if (half_packet_size == packet_size) { + return loadPacket(i, j); + } + EIGEN_ALIGN_DEFAULT Scalar data[half_packet_size]; + for (Index k = 0; k < half_packet_size; k++) { + data[k] = operator()(i + k, j); + } + return pload<HalfPacket>(data); + } +}; + + + + +template<typename Scalar, typename Index, int side, + typename Tensor, + typename nocontract_t, typename contract_t, + bool inner_dim_contiguous, bool inner_dim_reordered, int Alignment> +class TensorContractionInputMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, 1, inner_dim_contiguous, inner_dim_reordered, Alignment> + : public BaseTensorContractionMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, 1, inner_dim_contiguous> { + + public: + typedef BaseTensorContractionMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, 1, inner_dim_contiguous> Base; + typedef TensorContractionSubMapper<Scalar, Index, side, Tensor, nocontract_t, contract_t, 1, inner_dim_contiguous, inner_dim_reordered, Alignment> SubMapper; + typedef SubMapper VectorMapper; + + TensorContractionInputMapper(const Tensor& tensor, + const nocontract_t& nocontract_strides, + const nocontract_t& ij_strides, + const contract_t& contract_strides, + const contract_t& k_strides) + : Base(tensor, nocontract_strides, ij_strides, contract_strides, k_strides) { } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE SubMapper getSubMapper(Index i, Index j) const { + return SubMapper(*this, i, j); + } + + EIGEN_ALWAYS_INLINE VectorMapper getVectorMapper(Index i, Index j) const { + return VectorMapper(*this, i, j); + } + + typedef typename packet_traits<Scalar>::type Packet; + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Packet loadPacket(Index i, Index j) const { + EIGEN_ALIGN_DEFAULT Scalar data[1]; + data[0] = this->m_tensor.coeff(this->computeIndex(i, j)); + return pload<typename packet_traits<Scalar>::type>(data); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Packet loadHalfPacket(Index i, Index j) const { + return loadPacket(i, j); + } +}; + + +template <size_t n> struct max_n_1 { + static const size_t size = n; +}; +template <> struct max_n_1<0> { + static const size_t size = 1; +}; + + +template<typename Dimensions, typename LhsXprType, typename RhsXprType> +struct traits<TensorContractionOp<Dimensions, LhsXprType, RhsXprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs are different. + typedef typename internal::promote_storage_type<typename LhsXprType::Scalar, + typename RhsXprType::Scalar>::ret Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename promote_storage_type<typename traits<LhsXprType>::StorageKind, + typename traits<RhsXprType>::StorageKind>::ret StorageKind; + typedef typename promote_index_type<typename traits<LhsXprType>::Index, + typename traits<RhsXprType>::Index>::type Index; + typedef typename LhsXprType::Nested LhsNested; + typedef typename RhsXprType::Nested RhsNested; + typedef typename remove_reference<LhsNested>::type _LhsNested; + typedef typename remove_reference<RhsNested>::type _RhsNested; + + // From NumDims below. + static const int NumDimensions = max_n_1<traits<RhsXprType>::NumDimensions + traits<RhsXprType>::NumDimensions - 2 * array_size<Dimensions>::value>::size; + static const int Layout = traits<LhsXprType>::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename Dimensions, typename LhsXprType, typename RhsXprType> +struct eval<TensorContractionOp<Dimensions, LhsXprType, RhsXprType>, Eigen::Dense> +{ + typedef const TensorContractionOp<Dimensions, LhsXprType, RhsXprType>& type; +}; + +template<typename Dimensions, typename LhsXprType, typename RhsXprType> +struct nested<TensorContractionOp<Dimensions, LhsXprType, RhsXprType>, 1, typename eval<TensorContractionOp<Dimensions, LhsXprType, RhsXprType> >::type> +{ + typedef TensorContractionOp<Dimensions, LhsXprType, RhsXprType> type; +}; + +template<typename Indices_, typename LeftArgType_, typename RightArgType_, typename Device_> +struct traits<TensorEvaluator<const TensorContractionOp<Indices_, LeftArgType_, RightArgType_>, Device_> > { + typedef Indices_ Indices; + typedef LeftArgType_ LeftArgType; + typedef RightArgType_ RightArgType; + typedef Device_ Device; + + // From NumDims below. + static const int NumDimensions = max_n_1<traits<LeftArgType_>::NumDimensions + traits<RightArgType_>::NumDimensions - 2 * array_size<Indices_>::value>::size; +}; + +} // end namespace internal + +template<typename Indices, typename LhsXprType, typename RhsXprType> +class TensorContractionOp : public TensorBase<TensorContractionOp<Indices, LhsXprType, RhsXprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorContractionOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorContractionOp>::Packet Packet; + typedef typename internal::promote_storage_type<typename LhsXprType::CoeffReturnType, + typename RhsXprType::CoeffReturnType>::ret CoeffReturnType; + typedef typename internal::promote_storage_type<typename LhsXprType::PacketReturnType, + typename RhsXprType::PacketReturnType>::ret PacketReturnType; + typedef typename Eigen::internal::nested<TensorContractionOp>::type Nested; + typedef typename Eigen::internal::traits<TensorContractionOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorContractionOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorContractionOp( + const LhsXprType& lhs, const RhsXprType& rhs, const Indices& dims) + : m_lhs_xpr(lhs), m_rhs_xpr(rhs), m_indices(dims) {} + + EIGEN_DEVICE_FUNC + const Indices& indices() const { return m_indices; } + + /** \returns the nested expressions */ + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename LhsXprType::Nested>::type& + lhsExpression() const { return m_lhs_xpr; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename RhsXprType::Nested>::type& + rhsExpression() const { return m_rhs_xpr; } + + protected: + typename LhsXprType::Nested m_lhs_xpr; + typename RhsXprType::Nested m_rhs_xpr; + const Indices m_indices; +}; + + +template<bool cond> struct Cond {}; + +template<typename T1, typename T2> EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE +const T1& choose(Cond<true>, const T1& first, const T2&) { + return first; +} + +template<typename T1, typename T2> EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE +const T2& choose(Cond<false>, const T1&, const T2& second) { + return second; +} + + +template<typename Derived> +struct TensorContractionEvaluatorBase +{ + typedef typename internal::traits<Derived>::Indices Indices; + typedef typename internal::traits<Derived>::LeftArgType LeftArgType; + typedef typename internal::traits<Derived>::RightArgType RightArgType; + typedef typename internal::traits<Derived>::Device Device; + + typedef TensorContractionOp<Indices, LeftArgType, RightArgType> XprType; + typedef typename internal::remove_const<typename XprType::Scalar>::type Scalar; + typedef typename XprType::Packet Packet; + typedef typename XprType::Index Index; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + enum { + IsAligned = true, + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + // Most of the code is assuming that both input tensors are ColMajor. If the + // inputs are RowMajor, we will "cheat" by swapping the LHS and RHS: + // If we want to compute A * B = C, where A is LHS and B is RHS, the code + // will pretend B is LHS and A is RHS. + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), LeftArgType, RightArgType>::type EvalLeftArgType; + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), RightArgType, LeftArgType>::type EvalRightArgType; + + static const int LDims = + internal::array_size<typename TensorEvaluator<EvalLeftArgType, Device>::Dimensions>::value; + static const int RDims = + internal::array_size<typename TensorEvaluator<EvalRightArgType, Device>::Dimensions>::value; + static const int ContractDims = internal::array_size<Indices>::value; + static const int NumDims = internal::max_n_1<LDims + RDims - 2 * ContractDims>::size; + + typedef array<Index, LDims> left_dim_mapper_t; + typedef array<Index, RDims> right_dim_mapper_t; + typedef array<Index, ContractDims> contract_t; + typedef array<Index, internal::max_n_1<LDims - ContractDims>::size> left_nocontract_t; + typedef array<Index, internal::max_n_1<RDims - ContractDims>::size> right_nocontract_t; + + typedef DSizes<Index, NumDims> Dimensions; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorContractionEvaluatorBase(const XprType& op, const Device& device) + : m_leftImpl(choose(Cond<static_cast<int>(Layout) == static_cast<int>(ColMajor)>(), + op.lhsExpression(), op.rhsExpression()), device), + m_rightImpl(choose(Cond<static_cast<int>(Layout) == static_cast<int>(ColMajor)>(), + op.rhsExpression(), op.lhsExpression()), device), + m_device(device), + m_result(NULL) { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == + static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout)), + YOU_MADE_A_PROGRAMMING_MISTAKE); + + eigen_assert((internal::array_size<contract_t>::value > 0) && "Must contract on some indices"); + + + DSizes<Index, LDims> eval_left_dims; + DSizes<Index, RDims> eval_right_dims; + array<IndexPair<Index>, ContractDims> eval_op_indices; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + // For ColMajor, we keep using the existing dimensions + for (int i = 0; i < LDims; i++) { + eval_left_dims[i] = m_leftImpl.dimensions()[i]; + } + for (int i = 0; i < RDims; i++) { + eval_right_dims[i] = m_rightImpl.dimensions()[i]; + } + // We keep the pairs of contracting indices. + for (int i = 0; i < ContractDims; i++) { + eval_op_indices[i].first = op.indices()[i].first; + eval_op_indices[i].second = op.indices()[i].second; + } + } else { + // For RowMajor, we need to reverse the existing dimensions + for (int i = 0; i < LDims; i++) { + eval_left_dims[i] = m_leftImpl.dimensions()[LDims - i - 1]; + } + for (int i = 0; i < RDims; i++) { + eval_right_dims[i] = m_rightImpl.dimensions()[RDims - i - 1]; + } + // We need to flip all the pairs of contracting indices as well as + // reversing the dimensions. + for (int i = 0; i < ContractDims; i++) { + eval_op_indices[i].first = LDims - 1 - op.indices()[i].second; + eval_op_indices[i].second = RDims - 1 - op.indices()[i].first; + } + } + + array<Index, LDims> lhs_strides; + lhs_strides[0] = 1; + for (int i = 0; i < LDims-1; ++i) { + lhs_strides[i+1] = lhs_strides[i] * eval_left_dims[i]; + } + + array<Index, RDims> rhs_strides; + rhs_strides[0] = 1; + for (int i = 0; i < RDims-1; ++i) { + rhs_strides[i+1] = rhs_strides[i] * eval_right_dims[i]; + } + + m_i_strides[0] = 1; + m_j_strides[0] = 1; + m_k_strides[0] = 1; + + m_i_size = 1; + m_j_size = 1; + m_k_size = 1; + + // To compute the dimension, we simply concatenate the non-contracting + // dimensions of the left and then the right tensor. Additionally, we also + // compute the strides corresponding to the left non-contracting + // dimensions and right non-contracting dimensions. + m_lhs_inner_dim_contiguous = true; + int dim_idx = 0; + int nocontract_idx = 0; + + for (int i = 0; i < LDims; i++) { + // find if we are contracting on index i of left tensor + bool contracting = false; + for (int j = 0; j < ContractDims; j++) { + if (eval_op_indices[j].first == i) { + contracting = true; + break; + } + } + if (!contracting) { + // add dimension size to output dimensions + m_dimensions[dim_idx] = eval_left_dims[i]; + m_left_nocontract_strides[nocontract_idx] = lhs_strides[i]; + if (dim_idx != i) { + m_lhs_inner_dim_contiguous = false; + } + if (nocontract_idx+1 < internal::array_size<left_nocontract_t>::value) { + m_i_strides[nocontract_idx+1] = + m_i_strides[nocontract_idx] * eval_left_dims[i]; + } else { + m_i_size = m_i_strides[nocontract_idx] * eval_left_dims[i]; + } + dim_idx++; + nocontract_idx++; + } + } + + nocontract_idx = 0; + for (int i = 0; i < RDims; i++) { + bool contracting = false; + // find if we are contracting on index i of right tensor + for (int j = 0; j < ContractDims; j++) { + if (eval_op_indices[j].second == i) { + contracting = true; + break; + } + } + if (!contracting) { + m_dimensions[dim_idx] = eval_right_dims[i]; + if (nocontract_idx+1 < internal::array_size<right_nocontract_t>::value) { + m_j_strides[nocontract_idx+1] = + m_j_strides[nocontract_idx] * eval_right_dims[i]; + } else { + m_j_size = m_j_strides[nocontract_idx] * eval_right_dims[i]; + } + m_right_nocontract_strides[nocontract_idx] = rhs_strides[i]; + dim_idx++; + nocontract_idx++; + } + } + + // Now compute the strides corresponding to the contracting dimensions. We + // assumed above that non-contracting axes are represented in the same order + // in the matrix as they are in the tensor. This is not the case for + // contracting axes. As the contracting axes must be of the same size in + // each tensor, we'll only look at the first tensor here. + m_rhs_inner_dim_contiguous = true; + m_rhs_inner_dim_reordered = false; + for (int i = 0; i < ContractDims; i++) { + Index left = eval_op_indices[i].first; + Index right = eval_op_indices[i].second; + + Index size = eval_left_dims[left]; + eigen_assert(size == eval_right_dims[right] && + "Contraction axes must be same size"); + + if (i+1 < internal::array_size<contract_t>::value) { + m_k_strides[i+1] = m_k_strides[i] * size; + } else { + m_k_size = m_k_strides[i] * size; + } + m_left_contracting_strides[i] = lhs_strides[left]; + m_right_contracting_strides[i] = rhs_strides[right]; + + if (i > 0 && right < eval_op_indices[i-1].second) { + m_rhs_inner_dim_reordered = true; + } + if (right != i) { + m_rhs_inner_dim_contiguous = false; + } + } + + // Scalar case. We represent the result as a 1d tensor of size 1. + if (LDims + RDims == 2 * ContractDims) { + m_dimensions[0] = 1; + } + + // If the layout is RowMajor, we need to reverse the m_dimensions + if (static_cast<int>(Layout) == static_cast<int>(RowMajor)) { + for (int i = 0, j = NumDims - 1; i < j; i++, j--) { + std::swap(m_dimensions[i], m_dimensions[j]); + } + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* data) { + m_leftImpl.evalSubExprsIfNeeded(NULL); + m_rightImpl.evalSubExprsIfNeeded(NULL); + if (data) { + evalTo(data); + return false; + } else { + m_result = static_cast<Scalar *>(m_device.allocate(dimensions().TotalSize() * sizeof(Scalar))); + evalTo(m_result); + return true; + } + } + + EIGEN_DEVICE_FUNC void evalTo(Scalar* buffer) const { + if (this->m_lhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_reordered) { + static_cast<const Derived*>(this)->template evalProduct<true, true, true, Unaligned>(buffer); + } + else { + static_cast<const Derived*>(this)->template evalProduct<true, true, false, Unaligned>(buffer); + } + } + else { + if (this->m_rhs_inner_dim_reordered) { + static_cast<const Derived*>(this)->template evalProduct<true, false, true, Unaligned>(buffer); + } + else { + static_cast<const Derived*>(this)->template evalProduct<true, false, false, Unaligned>(buffer); + } + } + } + else { + if (this->m_rhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_reordered) { + static_cast<const Derived*>(this)->template evalProduct<false, true, true, Unaligned>(buffer); + } + else { + static_cast<const Derived*>(this)->template evalProduct<false, true, false, Unaligned>(buffer); + } + } + else { + if (this->m_rhs_inner_dim_reordered) { + static_cast<const Derived*>(this)->template evalProduct<false, false, true, Unaligned>(buffer); + } + else { + static_cast<const Derived*>(this)->template evalProduct<false, false, false, Unaligned>(buffer); + } + } + } + } + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + void evalGemv(Scalar* buffer) const { + const Index rows = m_i_size; + const Index cols = m_k_size; + + typedef typename internal::remove_const<typename EvalLeftArgType::Scalar>::type LhsScalar; + typedef typename internal::remove_const<typename EvalRightArgType::Scalar>::type RhsScalar; + typedef TensorEvaluator<EvalLeftArgType, Device> LeftEvaluator; + typedef TensorEvaluator<EvalRightArgType, Device> RightEvaluator; + const int lhs_packet_size = internal::packet_traits<LhsScalar>::size; + const int rhs_packet_size = internal::packet_traits<RhsScalar>::size; + typedef internal::TensorContractionInputMapper<LhsScalar, Index, internal::Lhs, + LeftEvaluator, left_nocontract_t, + contract_t, lhs_packet_size, + lhs_inner_dim_contiguous, + false, Unaligned> LhsMapper; + + typedef internal::TensorContractionInputMapper<RhsScalar, Index, internal::Rhs, + RightEvaluator, right_nocontract_t, + contract_t, rhs_packet_size, + rhs_inner_dim_contiguous, + rhs_inner_dim_reordered, Unaligned> RhsMapper; + + LhsMapper lhs(m_leftImpl, m_left_nocontract_strides, m_i_strides, + m_left_contracting_strides, m_k_strides); + RhsMapper rhs(m_rightImpl, m_right_nocontract_strides, m_j_strides, + m_right_contracting_strides, m_k_strides); + + const Scalar alpha(1); + const Index resIncr(1); + + // zero out the result buffer (which must be of size at least rows * sizeof(Scalar) + m_device.memset(buffer, 0, rows * sizeof(Scalar)); + + internal::general_matrix_vector_product<Index,LhsScalar,LhsMapper,ColMajor,false,RhsScalar,RhsMapper,false>::run( + rows, cols, lhs, rhs, + buffer, resIncr, alpha); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_leftImpl.cleanup(); + m_rightImpl.cleanup(); + + if (m_result != NULL) { + m_device.deallocate(m_result); + m_result = NULL; + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const { + return m_result[index]; + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC PacketReturnType packet(Index index) const { + return internal::ploadt<Packet, LoadMode>(m_result + index); + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + // Prevent assignment + TensorContractionEvaluatorBase& operator = (const TensorContractionEvaluatorBase&); + Dimensions m_dimensions; + + contract_t m_k_strides; + contract_t m_left_contracting_strides; + contract_t m_right_contracting_strides; + + bool m_lhs_inner_dim_contiguous; + bool m_rhs_inner_dim_contiguous; + bool m_rhs_inner_dim_reordered; + + left_nocontract_t m_i_strides; + right_nocontract_t m_j_strides; + left_nocontract_t m_left_nocontract_strides; + right_nocontract_t m_right_nocontract_strides; + + Index m_i_size; + Index m_j_size; + Index m_k_size; + + TensorEvaluator<EvalLeftArgType, Device> m_leftImpl; + TensorEvaluator<EvalRightArgType, Device> m_rightImpl; + const Device& m_device; + Scalar* m_result; +}; + + +// evaluator for default device +template<typename Indices, typename LeftArgType, typename RightArgType, typename Device> +struct TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, Device> : + public TensorContractionEvaluatorBase< + TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, Device> > { + typedef TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, Device> Self; + typedef TensorContractionEvaluatorBase<Self> Base; + + typedef TensorContractionOp<Indices, LeftArgType, RightArgType> XprType; + typedef typename internal::remove_const<typename XprType::Scalar>::type Scalar; + typedef typename XprType::Packet Packet; + typedef typename XprType::Index Index; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + enum { + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + }; + + // Most of the code is assuming that both input tensors are ColMajor. If the + // inputs are RowMajor, we will "cheat" by swapping the LHS and RHS: + // If we want to compute A * B = C, where A is LHS and B is RHS, the code + // will pretend B is LHS and A is RHS. + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), LeftArgType, RightArgType>::type EvalLeftArgType; + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), RightArgType, LeftArgType>::type EvalRightArgType; + + static const int LDims = + internal::array_size<typename TensorEvaluator<EvalLeftArgType, Device>::Dimensions>::value; + static const int RDims = + internal::array_size<typename TensorEvaluator<EvalRightArgType, Device>::Dimensions>::value; + static const int ContractDims = internal::array_size<Indices>::value; + + typedef array<Index, LDims> left_dim_mapper_t; + typedef array<Index, RDims> right_dim_mapper_t; + + typedef array<Index, ContractDims> contract_t; + typedef array<Index, internal::max_n_1<LDims - ContractDims>::size> left_nocontract_t; + typedef array<Index, internal::max_n_1<RDims - ContractDims>::size> right_nocontract_t; + + static const int NumDims = internal::max_n_1<LDims + RDims - 2 * ContractDims>::size; + + // Could we use NumDimensions here? + typedef DSizes<Index, NumDims> Dimensions; + + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) : + Base(op, device) { } + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + void evalProduct(Scalar* buffer) const { + if (this->m_j_size == 1) { + this->template evalGemv<lhs_inner_dim_contiguous, rhs_inner_dim_contiguous, rhs_inner_dim_reordered, Alignment>(buffer); + return; + } + + evalGemm<lhs_inner_dim_contiguous, rhs_inner_dim_contiguous, rhs_inner_dim_reordered, Alignment>(buffer); + } + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + EIGEN_DEVICE_FUNC void evalGemm(Scalar* buffer) const { + // columns in left side, rows in right side + const Index k = this->m_k_size; + + // rows in left side + const Index m = this->m_i_size; + + // columns in right side + const Index n = this->m_j_size; + + // zero out the result buffer (which must be of size at least m * n * sizeof(Scalar) + this->m_device.memset(buffer, 0, m * n * sizeof(Scalar)); + + // define mr, nr, and all of my data mapper types + typedef typename internal::remove_const<typename EvalLeftArgType::Scalar>::type LhsScalar; + typedef typename internal::remove_const<typename EvalRightArgType::Scalar>::type RhsScalar; + typedef typename internal::gebp_traits<LhsScalar, RhsScalar> Traits; + + const Index nr = Traits::nr; + const Index mr = Traits::mr; + + typedef TensorEvaluator<EvalLeftArgType, Device> LeftEvaluator; + typedef TensorEvaluator<EvalRightArgType, Device> RightEvaluator; + + const int lhs_packet_size = internal::packet_traits<LhsScalar>::size; + const int rhs_packet_size = internal::packet_traits<RhsScalar>::size; + + typedef internal::TensorContractionInputMapper<LhsScalar, Index, internal::Lhs, + LeftEvaluator, left_nocontract_t, + contract_t, lhs_packet_size, + lhs_inner_dim_contiguous, + false, Unaligned> LhsMapper; + + typedef internal::TensorContractionInputMapper<RhsScalar, Index, internal::Rhs, + RightEvaluator, right_nocontract_t, + contract_t, rhs_packet_size, + rhs_inner_dim_contiguous, + rhs_inner_dim_reordered, Unaligned> RhsMapper; + + typedef internal::blas_data_mapper<Scalar, Index, ColMajor> OutputMapper; + + // Declare GEBP packing and kernel structs + internal::gemm_pack_lhs<LhsScalar, Index, typename LhsMapper::SubMapper, mr, Traits::LhsProgress, ColMajor> pack_lhs; + internal::gemm_pack_rhs<RhsScalar, Index, typename RhsMapper::SubMapper, nr, ColMajor> pack_rhs; + + internal::gebp_kernel<LhsScalar, RhsScalar, Index, OutputMapper, mr, nr, false, false> gebp; + + // initialize data mappers + LhsMapper lhs(this->m_leftImpl, this->m_left_nocontract_strides, this->m_i_strides, + this->m_left_contracting_strides, this->m_k_strides); + + RhsMapper rhs(this->m_rightImpl, this->m_right_nocontract_strides, this->m_j_strides, + this->m_right_contracting_strides, this->m_k_strides); + + OutputMapper output(buffer, m); + + typedef typename internal::gemm_blocking_space<ColMajor, LhsScalar, RhsScalar, Dynamic, Dynamic, Dynamic> BlockingType; + + // Sizes of the blocks to load in cache. See the Goto paper for details. + BlockingType blocking(m, n, k, 1, true); + const Index kc = blocking.kc(); + const Index mc = (std::min)(m, blocking.mc()); + const Index nc = (std::min)(n, blocking.nc()); + const Index sizeA = mc * kc; + const Index sizeB = kc * nc; + + LhsScalar* blockA = static_cast<LhsScalar *>(this->m_device.allocate(sizeA * sizeof(LhsScalar))); + RhsScalar* blockB = static_cast<RhsScalar *>(this->m_device.allocate(sizeB * sizeof(RhsScalar))); + + for(Index i2=0; i2<m; i2+=mc) + { + const Index actual_mc = (std::min)(i2+mc,m)-i2; + for (Index k2 = 0; k2 < k; k2 += kc) { + // make sure we don't overshoot right edge of left matrix, then pack vertical panel + const Index actual_kc = (std::min)(k2 + kc, k) - k2; + pack_lhs(blockA, lhs.getSubMapper(i2, k2), actual_kc, actual_mc, 0, 0); + + // series of horizontal blocks + for (Index j2 = 0; j2 < n; j2 += nc) { + // make sure we don't overshoot right edge of right matrix, then pack block + const Index actual_nc = (std::min)(j2 + nc, n) - j2; + pack_rhs(blockB, rhs.getSubMapper(k2, j2), actual_kc, actual_nc, 0, 0); + + // call gebp (matrix kernel) + // The parameters here are copied from Eigen's GEMM implementation + gebp(output.getSubMapper(i2, j2), blockA, blockB, actual_mc, actual_kc, actual_nc, 1.0, -1, -1, 0, 0); + } + } + } + + this->m_device.deallocate(blockA); + this->m_device.deallocate(blockB); + } +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorContractionCuda.h b/unsupported/Eigen/CXX11/src/Tensor/TensorContractionCuda.h new file mode 100644 index 000000000..588770bb4 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorContractionCuda.h @@ -0,0 +1,1384 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014-2015 Benoit Steiner <benoit.steiner.goog@gmail.com> +// Copyright (C) 2015 Navdeep Jaitly <ndjaitly@google.com> +// Copyright (C) 2014 Eric Martin <eric@ericmart.in> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_CUDA_H +#define EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_CUDA_H + +#if defined(EIGEN_USE_GPU) && defined(__CUDACC__) + +namespace Eigen { + +template<typename Scalar, typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper, bool needs_edge_check> +__device__ EIGEN_STRONG_INLINE void +EigenContractionKernelInternal(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, volatile Scalar* lhs_shmem, volatile Scalar* rhs_shmem, + const Index m_size, const Index n_size, const Index k_size) { + + const Index m_block_idx = blockIdx.x; + const Index n_block_idx = blockIdx.y; + + const Index base_m = 64 * m_block_idx; + const Index base_n = 64 * n_block_idx; + + // declare and initialize 64 registers for output 8x8 block + + // prefetch registers + Scalar lhs_pf0; + Scalar lhs_pf1; + Scalar lhs_pf2; + Scalar lhs_pf3; + Scalar lhs_pf4; + Scalar lhs_pf5; + Scalar lhs_pf6; + Scalar lhs_pf7; + + Scalar rhs_pf0; + Scalar rhs_pf1; + Scalar rhs_pf2; + Scalar rhs_pf3; + Scalar rhs_pf4; + Scalar rhs_pf5; + Scalar rhs_pf6; + Scalar rhs_pf7; + + // shared memory is formatted + // (contract idx in block, nocontract idx in block, block idx) + // where block idx is column major. This transposition limits the number of + // bank conflicts when reading the LHS. The core idea is that since the contracting + // index is shared by both sides, then the contracting index should be in threadIdx.x. + + // On the LHS, we pad each row inside of each block with an extra element. This makes + // each block 8 rows of 9 elements, which is 72 elements. This gives no bank conflicts + // on writes and very few 2-way conflicts on reads. There is an 8x8 grid of these blocks. + + // On the RHS we just add 8 padding elements to the end of each block. This gives no bank + // conflicts on writes and also none on reads. + + // storage indices + const Index lhs_store_idx_base = threadIdx.y * 72 + threadIdx.x * 9 + threadIdx.z; + const Index rhs_store_idx_base = threadIdx.y * 72 + threadIdx.z * 8 + threadIdx.x; + + const Index lhs_store_idx_0 = lhs_store_idx_base + 576 * 0; + const Index lhs_store_idx_1 = lhs_store_idx_base + 576 * 1; + const Index lhs_store_idx_2 = lhs_store_idx_base + 576 * 2; + const Index lhs_store_idx_3 = lhs_store_idx_base + 576 * 3; + const Index lhs_store_idx_4 = lhs_store_idx_base + 576 * 4; + const Index lhs_store_idx_5 = lhs_store_idx_base + 576 * 5; + const Index lhs_store_idx_6 = lhs_store_idx_base + 576 * 6; + const Index lhs_store_idx_7 = lhs_store_idx_base + 576 * 7; + + const Index rhs_store_idx_0 = rhs_store_idx_base + 576 * 0; + const Index rhs_store_idx_1 = rhs_store_idx_base + 576 * 1; + const Index rhs_store_idx_2 = rhs_store_idx_base + 576 * 2; + const Index rhs_store_idx_3 = rhs_store_idx_base + 576 * 3; + const Index rhs_store_idx_4 = rhs_store_idx_base + 576 * 4; + const Index rhs_store_idx_5 = rhs_store_idx_base + 576 * 5; + const Index rhs_store_idx_6 = rhs_store_idx_base + 576 * 6; + const Index rhs_store_idx_7 = rhs_store_idx_base + 576 * 7; + + // in the loading code, the following variables are important: + // threadIdx.x: the vertical position in an 8x8 block + // threadIdx.y: the vertical index of the 8x8 block in the grid + // threadIdx.z: the horizontal position in an 8x8 block + // k: the horizontal index of the 8x8 block in the grid + // + // The k parameter is implicit (it was the loop counter for a loop that went + // from 0 to <8, but now that loop is unrolled in the below code. + + const Index load_idx_vert = threadIdx.x + 8 * threadIdx.y; + const Index lhs_vert = base_m + load_idx_vert; + +#define prefetchIntoRegisters(base_k) \ + { \ + lhs_pf0 = Scalar(0); \ + lhs_pf1 = Scalar(0); \ + lhs_pf2 = Scalar(0); \ + lhs_pf3 = Scalar(0); \ + lhs_pf4 = Scalar(0); \ + lhs_pf5 = Scalar(0); \ + lhs_pf6 = Scalar(0); \ + lhs_pf7 = Scalar(0); \ + \ + rhs_pf0 = Scalar(0); \ + rhs_pf1 = Scalar(0); \ + rhs_pf2 = Scalar(0); \ + rhs_pf3 = Scalar(0); \ + rhs_pf4 = Scalar(0); \ + rhs_pf5 = Scalar(0); \ + rhs_pf6 = Scalar(0); \ + rhs_pf7 = Scalar(0); \ + \ + if (!needs_edge_check || lhs_vert < m_size) { \ + const Index lhs_horiz_0 = base_k + threadIdx.z + 0 * 8; \ + const Index lhs_horiz_1 = base_k + threadIdx.z + 1 * 8; \ + const Index lhs_horiz_2 = base_k + threadIdx.z + 2 * 8; \ + const Index lhs_horiz_3 = base_k + threadIdx.z + 3 * 8; \ + const Index lhs_horiz_4 = base_k + threadIdx.z + 4 * 8; \ + const Index lhs_horiz_5 = base_k + threadIdx.z + 5 * 8; \ + const Index lhs_horiz_6 = base_k + threadIdx.z + 6 * 8; \ + const Index lhs_horiz_7 = base_k + threadIdx.z + 7 * 8; \ + \ + if (!needs_edge_check || lhs_horiz_7 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + lhs_pf3 = lhs(lhs_vert, lhs_horiz_3); \ + lhs_pf4 = lhs(lhs_vert, lhs_horiz_4); \ + lhs_pf5 = lhs(lhs_vert, lhs_horiz_5); \ + lhs_pf6 = lhs(lhs_vert, lhs_horiz_6); \ + lhs_pf7 = lhs(lhs_vert, lhs_horiz_7); \ + } else if (lhs_horiz_6 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + lhs_pf3 = lhs(lhs_vert, lhs_horiz_3); \ + lhs_pf4 = lhs(lhs_vert, lhs_horiz_4); \ + lhs_pf5 = lhs(lhs_vert, lhs_horiz_5); \ + lhs_pf6 = lhs(lhs_vert, lhs_horiz_6); \ + } else if (lhs_horiz_5 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + lhs_pf3 = lhs(lhs_vert, lhs_horiz_3); \ + lhs_pf4 = lhs(lhs_vert, lhs_horiz_4); \ + lhs_pf5 = lhs(lhs_vert, lhs_horiz_5); \ + } else if (lhs_horiz_4 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + lhs_pf3 = lhs(lhs_vert, lhs_horiz_3); \ + lhs_pf4 = lhs(lhs_vert, lhs_horiz_4); \ + } else if (lhs_horiz_3 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + lhs_pf3 = lhs(lhs_vert, lhs_horiz_3); \ + } else if (lhs_horiz_2 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + lhs_pf2 = lhs(lhs_vert, lhs_horiz_2); \ + } else if (lhs_horiz_1 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + lhs_pf1 = lhs(lhs_vert, lhs_horiz_1); \ + } else if (lhs_horiz_0 < k_size) { \ + lhs_pf0 = lhs(lhs_vert, lhs_horiz_0); \ + } \ + } \ + \ + const Index rhs_vert = base_k + load_idx_vert; \ + if (!needs_edge_check || rhs_vert < k_size) { \ + const Index rhs_horiz_0 = base_n + threadIdx.z + 0 * 8; \ + const Index rhs_horiz_1 = base_n + threadIdx.z + 1 * 8; \ + const Index rhs_horiz_2 = base_n + threadIdx.z + 2 * 8; \ + const Index rhs_horiz_3 = base_n + threadIdx.z + 3 * 8; \ + const Index rhs_horiz_4 = base_n + threadIdx.z + 4 * 8; \ + const Index rhs_horiz_5 = base_n + threadIdx.z + 5 * 8; \ + const Index rhs_horiz_6 = base_n + threadIdx.z + 6 * 8; \ + const Index rhs_horiz_7 = base_n + threadIdx.z + 7 * 8; \ + \ + if (rhs_horiz_7 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + rhs_pf3 = rhs(rhs_vert, rhs_horiz_3); \ + rhs_pf4 = rhs(rhs_vert, rhs_horiz_4); \ + rhs_pf5 = rhs(rhs_vert, rhs_horiz_5); \ + rhs_pf6 = rhs(rhs_vert, rhs_horiz_6); \ + rhs_pf7 = rhs(rhs_vert, rhs_horiz_7); \ + } else if (rhs_horiz_6 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + rhs_pf3 = rhs(rhs_vert, rhs_horiz_3); \ + rhs_pf4 = rhs(rhs_vert, rhs_horiz_4); \ + rhs_pf5 = rhs(rhs_vert, rhs_horiz_5); \ + rhs_pf6 = rhs(rhs_vert, rhs_horiz_6); \ + } else if (rhs_horiz_5 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + rhs_pf3 = rhs(rhs_vert, rhs_horiz_3); \ + rhs_pf4 = rhs(rhs_vert, rhs_horiz_4); \ + rhs_pf5 = rhs(rhs_vert, rhs_horiz_5); \ + } else if (rhs_horiz_4 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + rhs_pf3 = rhs(rhs_vert, rhs_horiz_3); \ + rhs_pf4 = rhs(rhs_vert, rhs_horiz_4); \ + } else if (rhs_horiz_3 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + rhs_pf3 = rhs(rhs_vert, rhs_horiz_3); \ + } else if (rhs_horiz_2 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + rhs_pf2 = rhs(rhs_vert, rhs_horiz_2); \ + } else if (rhs_horiz_1 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + rhs_pf1 = rhs(rhs_vert, rhs_horiz_1); \ + } else if (rhs_horiz_0 < n_size) { \ + rhs_pf0 = rhs(rhs_vert, rhs_horiz_0); \ + } \ + } \ + } \ + +#define writeRegToShmem(_) \ + lhs_shmem[lhs_store_idx_0] = lhs_pf0; \ + rhs_shmem[rhs_store_idx_0] = rhs_pf0; \ + \ + lhs_shmem[lhs_store_idx_1] = lhs_pf1; \ + rhs_shmem[rhs_store_idx_1] = rhs_pf1; \ + \ + lhs_shmem[lhs_store_idx_2] = lhs_pf2; \ + rhs_shmem[rhs_store_idx_2] = rhs_pf2; \ + \ + lhs_shmem[lhs_store_idx_3] = lhs_pf3; \ + rhs_shmem[rhs_store_idx_3] = rhs_pf3; \ + \ + lhs_shmem[lhs_store_idx_4] = lhs_pf4; \ + rhs_shmem[rhs_store_idx_4] = rhs_pf4; \ + \ + lhs_shmem[lhs_store_idx_5] = lhs_pf5; \ + rhs_shmem[rhs_store_idx_5] = rhs_pf5; \ + \ + lhs_shmem[lhs_store_idx_6] = lhs_pf6; \ + rhs_shmem[rhs_store_idx_6] = rhs_pf6; \ + \ + lhs_shmem[lhs_store_idx_7] = lhs_pf7; \ + rhs_shmem[rhs_store_idx_7] = rhs_pf7; \ + + // declare and initialize result array +#define res(i, j) _res_##i##j +#define initResultRow(i) \ + Scalar res(i, 0) = Scalar(0); \ + Scalar res(i, 1) = Scalar(0); \ + Scalar res(i, 2) = Scalar(0); \ + Scalar res(i, 3) = Scalar(0); \ + Scalar res(i, 4) = Scalar(0); \ + Scalar res(i, 5) = Scalar(0); \ + Scalar res(i, 6) = Scalar(0); \ + Scalar res(i, 7) = Scalar(0); \ + + initResultRow(0); + initResultRow(1); + initResultRow(2); + initResultRow(3); + initResultRow(4); + initResultRow(5); + initResultRow(6); + initResultRow(7); +#undef initResultRow + + for (Index base_k = 0; base_k < k_size; base_k += 64) { + // wait for previous iteration to finish with shmem. Despite common sense, + // the code is a bit faster with this here then at bottom of loop + __syncthreads(); + + prefetchIntoRegisters(base_k); + writeRegToShmem(); + + #undef prefetchIntoRegisters + #undef writeRegToShmem + + // wait for shared mem packing to be done before starting computation + __syncthreads(); + + // compute 8x8 matrix product by outer product. This involves packing one column + // of LHS and one row of RHS into registers (takes 16 registers). + +#define lcol(i) _lcol##i + Scalar lcol(0); + Scalar lcol(1); + Scalar lcol(2); + Scalar lcol(3); + Scalar lcol(4); + Scalar lcol(5); + Scalar lcol(6); + Scalar lcol(7); + +#define rrow(j) _rrow##j + Scalar rrow(0); + Scalar rrow(1); + Scalar rrow(2); + Scalar rrow(3); + Scalar rrow(4); + Scalar rrow(5); + Scalar rrow(6); + Scalar rrow(7); + + // Now x corresponds to k, y to m, and z to n + const volatile Scalar* lhs_block = &lhs_shmem[threadIdx.x + 9 * threadIdx.y]; + const volatile Scalar* rhs_block = &rhs_shmem[threadIdx.x + 8 * threadIdx.z]; + +#define lhs_element(i, j) lhs_block[72 * ((i) + 8 * (j))] +#define rhs_element(i, j) rhs_block[72 * ((i) + 8 * (j))] + +#define loadData(i, j) \ + lcol(0) = lhs_element(0, j); \ + rrow(0) = rhs_element(i, 0); \ + lcol(1) = lhs_element(1, j); \ + rrow(1) = rhs_element(i, 1); \ + lcol(2) = lhs_element(2, j); \ + rrow(2) = rhs_element(i, 2); \ + lcol(3) = lhs_element(3, j); \ + rrow(3) = rhs_element(i, 3); \ + lcol(4) = lhs_element(4, j); \ + rrow(4) = rhs_element(i, 4); \ + lcol(5) = lhs_element(5, j); \ + rrow(5) = rhs_element(i, 5); \ + lcol(6) = lhs_element(6, j); \ + rrow(6) = rhs_element(i, 6); \ + lcol(7) = lhs_element(7, j); \ + rrow(7) = rhs_element(i, 7); \ + +#define computeCol(j) \ + res(0, j) += lcol(0) * rrow(j); \ + res(1, j) += lcol(1) * rrow(j); \ + res(2, j) += lcol(2) * rrow(j); \ + res(3, j) += lcol(3) * rrow(j); \ + res(4, j) += lcol(4) * rrow(j); \ + res(5, j) += lcol(5) * rrow(j); \ + res(6, j) += lcol(6) * rrow(j); \ + res(7, j) += lcol(7) * rrow(j); \ + +#define computePass(i) \ + loadData(i, i); \ + \ + computeCol(0); \ + computeCol(1); \ + computeCol(2); \ + computeCol(3); \ + computeCol(4); \ + computeCol(5); \ + computeCol(6); \ + computeCol(7); \ + + computePass(0); + computePass(1); + computePass(2); + computePass(3); + computePass(4); + computePass(5); + computePass(6); + computePass(7); + +#undef lcol +#undef rrow +#undef lhs_element +#undef rhs_element +#undef loadData +#undef computeCol +#undef computePass + } // end loop over k + + // we've now iterated over all of the large (ie width 64) k blocks and + // accumulated results in registers. At this point thread (x, y, z) contains + // the sum across all big k blocks of the product of little k block of index (x, y) + // with block of index (y, z). To compute the final output, we need to reduce + // the 8 threads over y by summation. +#define shuffleInc(i, j, mask) res(i, j) += __shfl_xor(res(i, j), mask) + +#define reduceRow(i, mask) \ + shuffleInc(i, 0, mask); \ + shuffleInc(i, 1, mask); \ + shuffleInc(i, 2, mask); \ + shuffleInc(i, 3, mask); \ + shuffleInc(i, 4, mask); \ + shuffleInc(i, 5, mask); \ + shuffleInc(i, 6, mask); \ + shuffleInc(i, 7, mask); \ + +#define reduceMatrix(mask) \ + reduceRow(0, mask); \ + reduceRow(1, mask); \ + reduceRow(2, mask); \ + reduceRow(3, mask); \ + reduceRow(4, mask); \ + reduceRow(5, mask); \ + reduceRow(6, mask); \ + reduceRow(7, mask); \ + + // actually perform the reduction, now each thread of index (_, y, z) + // contains the correct values in its registers that belong in the output + // block + reduceMatrix(1); + reduceMatrix(2); + reduceMatrix(4); + +#undef shuffleInc +#undef reduceRow +#undef reduceMatrix + + // now we need to copy the 64 values into main memory. We can't split work + // among threads because all variables are in registers. There's 2 ways + // to do this: + // (1) have 1 thread do 64 writes from registers into global memory + // (2) have 1 thread do 64 writes into shared memory, and then 8 threads + // each do 8 writes into global memory. We can just overwrite the shared + // memory from the problem we just solved. + // (2) is slightly faster than (1) due to less branching and more ILP + + // TODO: won't yield much gain, but could just use currently unused shared mem + // and then we won't have to sync + // wait for shared mem to be out of use + __syncthreads(); + +#define writeResultShmem(i, j) \ + lhs_shmem[i + 8 * threadIdx.y + 64 * threadIdx.z + 512 * j] = res(i, j); \ + +#define writeRow(i) \ + writeResultShmem(i, 0); \ + writeResultShmem(i, 1); \ + writeResultShmem(i, 2); \ + writeResultShmem(i, 3); \ + writeResultShmem(i, 4); \ + writeResultShmem(i, 5); \ + writeResultShmem(i, 6); \ + writeResultShmem(i, 7); \ + + if (threadIdx.x == 0) { + writeRow(0); + writeRow(1); + writeRow(2); + writeRow(3); + writeRow(4); + writeRow(5); + writeRow(6); + writeRow(7); + } +#undef writeResultShmem +#undef writeRow + + const int max_i_write = (min)((int)((m_size - base_m - threadIdx.y + 7) / 8), 8); + const int max_j_write = (min)((int)((n_size - base_n - threadIdx.z + 7) / 8), 8); + + if (threadIdx.x < max_i_write) { + if (max_j_write == 8) { + // TODO: can i trade bank conflicts for coalesced writes? + Scalar val0 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 0]; + Scalar val1 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 1]; + Scalar val2 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 2]; + Scalar val3 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 3]; + Scalar val4 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 4]; + Scalar val5 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 5]; + Scalar val6 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 6]; + Scalar val7 = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * 7]; + + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 0) = val0; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 1) = val1; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 2) = val2; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 3) = val3; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 4) = val4; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 5) = val5; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 6) = val6; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * 7) = val7; + } else { +#pragma unroll 7 + for (int j = 0; j < max_j_write; j++) { + Scalar val = lhs_shmem[threadIdx.x + 8 * threadIdx.y + 64 * threadIdx.z + 512 * j]; + output(base_m + threadIdx.y + 8 * threadIdx.x, base_n + threadIdx.z + 8 * j) = val; + } + } + } +#undef res +} + + +template<typename Scalar, typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper> +__global__ void +__launch_bounds__(512) +EigenContractionKernel(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, + const Index m_size, const Index n_size, const Index k_size) { + __shared__ volatile Scalar lhs_shmem[72 * 64]; + __shared__ volatile Scalar rhs_shmem[72 * 64]; + + const Index m_block_idx = blockIdx.x; + const Index n_block_idx = blockIdx.y; + + const Index base_m = 64 * m_block_idx; + const Index base_n = 64 * n_block_idx; + + if (base_m + 63 < m_size && base_n + 63 < n_size) { + EigenContractionKernelInternal<Scalar, Index, LhsMapper, RhsMapper, OutputMapper, false>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size); + } else { + EigenContractionKernelInternal<Scalar, Index, LhsMapper, RhsMapper, OutputMapper, true>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size); + } +} + + +template<typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper, bool CHECK_LHS_BOUNDARY, + bool CHECK_RHS_BOUNDARY> +__device__ EIGEN_STRONG_INLINE void +EigenFloatContractionKernelInternal16x16(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, float2 lhs_shmem2[][16], + float2 rhs_shmem2[][8], const Index m_size, + const Index n_size, const Index k_size, + const Index base_m, const Index base_n) { + typedef float Scalar; + + // prefetch registers + float4 lhs_pf0, rhs_pf0; + + float4 results[4]; + for (int i=0; i < 4; i++) { + results[i].x = results[i].y = results[i].z = results[i].w = 0; + } + + +#define prefetch_lhs(reg, row, col) \ + if (!CHECK_LHS_BOUNDARY) { \ + if (col < k_size) { \ + reg =lhs.loadPacket(row, col); \ + } \ + } else { \ + if (col < k_size) { \ + if (row + 3 < m_size) { \ + reg =lhs.loadPacket(row, col); \ + } else if (row + 2 < m_size) { \ + reg.x =lhs(row + 0, col); \ + reg.y =lhs(row + 1, col); \ + reg.z =lhs(row + 2, col); \ + } else if (row + 1 < m_size) { \ + reg.x =lhs(row + 0, col); \ + reg.y =lhs(row + 1, col); \ + } else if (row < m_size) { \ + reg.x =lhs(row + 0, col); \ + } \ + } \ + } \ + + + Index lhs_vert = base_m+threadIdx.x*4; + + for (Index k = 0; k < k_size; k += 16) { + lhs_pf0 = internal::pset1<float4>(0); + rhs_pf0 = internal::pset1<float4>(0); + + Index lhs_horiz = threadIdx.y+k; + prefetch_lhs(lhs_pf0, lhs_vert, lhs_horiz) + + Index rhs_vert = k+(threadIdx.x%4)*4; + Index rhs_horiz0 = (threadIdx.x>>2)+threadIdx.y*4+base_n; + + if (!CHECK_RHS_BOUNDARY) { + if ((rhs_vert + 3) < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0 = rhs.loadPacket(rhs_vert, rhs_horiz0); + } else if (rhs_vert + 2 < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf0.z = rhs(rhs_vert + 2, rhs_horiz0); + } else if (rhs_vert + 1 < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + } else if (rhs_vert < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + } + } else { + if (rhs_horiz0 < n_size) { + if ((rhs_vert + 3) < k_size) { + rhs_pf0 = rhs.loadPacket(rhs_vert, rhs_horiz0); + } else if ((rhs_vert + 2) < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf0.z = rhs(rhs_vert + 2, rhs_horiz0); + } else if ((rhs_vert + 1) < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + } else if (rhs_vert < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + } + } + } + float x1, x2 ; + // the following can be a bitwise operation..... some day. + if((threadIdx.x%8) < 4) { + x1 = rhs_pf0.y; + x2 = rhs_pf0.w; + } else { + x1 = rhs_pf0.x; + x2 = rhs_pf0.z; + } + x1 = __shfl_xor(x1, 4); + x2 = __shfl_xor(x2, 4); + if((threadIdx.x%8) < 4) { + rhs_pf0.y = x1; + rhs_pf0.w = x2; + } else { + rhs_pf0.x = x1; + rhs_pf0.z = x2; + } + + // We have 64 features. + // Row 0 -> times (0, 4, 8, 12, 1, 5, 9, 13) for features 0, 1. + // Row 1 -> times (0, 4, 8, 12, 1, 5, 9, 13) for features 2, 3. + // ... + // Row 31 -> times (0, 4, 8, 12, 1, 5, 9, 13) for features 62, 63 + // Row 32 -> times (2, 6, 10, 14, 3, 7, 11, 15) for features 0, 1 + // ... + rhs_shmem2[(threadIdx.x>>3)+ threadIdx.y*2][threadIdx.x%8] = make_float2(rhs_pf0.x, rhs_pf0.y); + rhs_shmem2[(threadIdx.x>>3)+ threadIdx.y*2+32][threadIdx.x%8] = make_float2(rhs_pf0.z, rhs_pf0.w); + + // Row 0 (time 0) -> features (0, 1), (4, 5), .. (28, 29), (32, 33), .. (60, 61) + // Row 1 (time 1) -> features (0, 1), (4, 5), .. (28, 29), (32, 33), .. (60, 61) + // ... + // Row 15 (time 15) -> features (0, 1), (4, 5), .. (28, 29), (32, 33), .. (60, 61) + // Row 16 (time 0) -> features (2, 3), (6, 7), .. (30, 31), (34, 35), .. (62, 63) + // ... + + lhs_shmem2[threadIdx.y][threadIdx.x] = make_float2(lhs_pf0.x, lhs_pf0.y); + lhs_shmem2[threadIdx.y+16][threadIdx.x] = make_float2(lhs_pf0.z, lhs_pf0.w); + + +#define add_vals(fl1, fl2, fr1, fr2)\ + results[0].x += fl1.x * fr1.x;\ + results[0].y += fl1.y * fr1.x;\ + results[0].z += fl2.x * fr1.x;\ + results[0].w += fl2.y * fr1.x;\ +\ + results[1].x += fl1.x * fr1.y;\ + results[1].y += fl1.y * fr1.y;\ + results[1].z += fl2.x * fr1.y;\ + results[1].w += fl2.y * fr1.y;\ +\ + results[2].x += fl1.x * fr2.x;\ + results[2].y += fl1.y * fr2.x;\ + results[2].z += fl2.x * fr2.x;\ + results[2].w += fl2.y * fr2.x;\ +\ + results[3].x += fl1.x * fr2.y;\ + results[3].y += fl1.y * fr2.y;\ + results[3].z += fl2.x * fr2.y;\ + results[3].w += fl2.y * fr2.y;\ + + __syncthreads(); + + // Do the multiplies. + #pragma unroll + for (int koff = 0; koff < 16; koff ++) { + // 32 x threads. + float2 fl1 = lhs_shmem2[koff][threadIdx.x]; + float2 fl2 = lhs_shmem2[koff + 16][threadIdx.x]; + + int start_feature = threadIdx.y * 4; + float2 fr1 = rhs_shmem2[(start_feature>>1) + 32*((koff%4)/2)][koff/4 + (koff%2)*4]; + float2 fr2 = rhs_shmem2[(start_feature>>1) + 1 + 32*((koff%4)/2)][koff/4 + (koff%2)*4]; + + add_vals(fl1, fl2, fr1, fr2) + } + __syncthreads(); + } + +#undef prefetch_lhs +#undef add_vals + + Index horiz_base = threadIdx.y*4+base_n; + if (!CHECK_LHS_BOUNDARY && !CHECK_RHS_BOUNDARY) { + for (int i = 0; i < 4; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } else if (!CHECK_RHS_BOUNDARY) { + // CHECK LHS + if (lhs_vert + 3 < m_size) { + for (int i = 0; i < 4; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } else if (lhs_vert + 2 < m_size) { + for (int i = 0; i < 4; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + } + } else if (lhs_vert + 1 < m_size) { + for (int i = 0; i < 4; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + } + } else if (lhs_vert < m_size) { + for (int i = 0; i < 4; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + } + } + } else if (!CHECK_LHS_BOUNDARY) { + // CHECK RHS + /* + int ncols_rem = fminf(n_size- horiz_base, 4); + for (int i = 0; i < ncols_rem; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + }*/ + for (int i = 0; i < 4; i++) { + if (horiz_base+i < n_size) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } + } else { + // CHECK both boundaries. + for (int i = 0; i < 4; i++) { + if (horiz_base+i < n_size) { + if (lhs_vert < m_size) + output(lhs_vert, horiz_base + i) = results[i].x; + if (lhs_vert + 1 < m_size) + output(lhs_vert + 1, horiz_base + i) = results[i].y; + if (lhs_vert + 2 < m_size) + output(lhs_vert + 2, horiz_base + i) = results[i].z; + if (lhs_vert + 3 < m_size) + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } + } +} + + +template<typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper, bool CHECK_LHS_BOUNDARY, + bool CHECK_RHS_BOUNDARY> +__device__ EIGEN_STRONG_INLINE void +EigenFloatContractionKernelInternal(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, float2 lhs_shmem2[][32], + float2 rhs_shmem2[][8], const Index m_size, + const Index n_size, const Index k_size, + const Index base_m, const Index base_n) { + typedef float Scalar; + + // prefetch registers + float4 lhs_pf0, lhs_pf1, lhs_pf2, lhs_pf3; + float4 rhs_pf0, rhs_pf1; + + float4 results[8]; + for (int i=0; i < 8; i++) { + results[i].x = results[i].y = results[i].z = results[i].w = 0; + } + + + Index lhs_vert = base_m+threadIdx.x*4+(threadIdx.y%4)*32; + for (Index k = 0; k < k_size; k += 32) { + lhs_pf0 = internal::pset1<float4>(0); + lhs_pf1 = internal::pset1<float4>(0); + lhs_pf2 = internal::pset1<float4>(0); + lhs_pf3 = internal::pset1<float4>(0); + + rhs_pf0 = internal::pset1<float4>(0); + rhs_pf1 = internal::pset1<float4>(0); + + if (!CHECK_LHS_BOUNDARY) { + if ((threadIdx.y/4+k+24) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + lhs_pf2 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+16)); + lhs_pf3 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+24)); + } else if ((threadIdx.y/4+k+16) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + lhs_pf2 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+16)); + } else if ((threadIdx.y/4+k+8) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + } else if ((threadIdx.y/4+k) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + } + } else { + // just CHECK_LHS_BOUNDARY + if (lhs_vert + 3 < m_size) { + if ((threadIdx.y/4+k+24) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + lhs_pf2 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+16)); + lhs_pf3 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+24)); + } else if ((threadIdx.y/4+k+16) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + lhs_pf2 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+16)); + } else if ((threadIdx.y/4+k+8) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + lhs_pf1 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k+8)); + } else if ((threadIdx.y/4+k) < k_size) { + lhs_pf0 =lhs.loadPacket(lhs_vert, (threadIdx.y/4+k)); + } + } else if (lhs_vert + 2 < m_size) { + if ((threadIdx.y/4+k+24) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf0.z =lhs(lhs_vert + 2, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + lhs_pf1.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + lhs_pf2.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+16)); + lhs_pf2.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+16)); + lhs_pf3.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+24)); + lhs_pf3.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+24)); + lhs_pf3.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+24)); + } else if ((threadIdx.y/4+k+16) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf0.z =lhs(lhs_vert + 2, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + lhs_pf1.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + lhs_pf2.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+16)); + lhs_pf2.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+16)); + } else if ((threadIdx.y/4+k+8) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf0.z =lhs(lhs_vert + 2, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + lhs_pf1.z =lhs(lhs_vert + 2, (threadIdx.y/4+k+8)); + } else if ((threadIdx.y/4+k) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf0.z =lhs(lhs_vert + 2, (threadIdx.y/4+k)); + } + } else if (lhs_vert + 1 < m_size) { + if ((threadIdx.y/4+k+24) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + lhs_pf2.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+16)); + lhs_pf3.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+24)); + lhs_pf3.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+24)); + } else if ((threadIdx.y/4+k+16) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + lhs_pf2.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+16)); + } else if ((threadIdx.y/4+k+8) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf1.y =lhs(lhs_vert + 1, (threadIdx.y/4+k+8)); + } else if ((threadIdx.y/4+k) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf0.y =lhs(lhs_vert + 1, (threadIdx.y/4+k)); + } + } else if (lhs_vert < m_size) { + if ((threadIdx.y/4+k+24) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + lhs_pf3.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+24)); + } else if ((threadIdx.y/4+k+16) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + lhs_pf2.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+16)); + } else if ((threadIdx.y/4+k+8) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + lhs_pf1.x =lhs(lhs_vert + 0, (threadIdx.y/4+k+8)); + } else if ((threadIdx.y/4+k) < k_size) { + lhs_pf0.x =lhs(lhs_vert + 0, (threadIdx.y/4+k)); + } + } + } + __syncthreads(); + Index rhs_vert = k+threadIdx.x*4; + Index rhs_horiz0 = threadIdx.y*2+base_n; + Index rhs_horiz1 = threadIdx.y*2+1+base_n; + if (!CHECK_RHS_BOUNDARY) { + if ((rhs_vert + 3) < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0 = rhs.loadPacket(rhs_vert, rhs_horiz0); + rhs_pf1 = rhs.loadPacket(rhs_vert, rhs_horiz1); + } else if (rhs_vert + 2 < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf0.z = rhs(rhs_vert + 2, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + rhs_pf1.y = rhs(rhs_vert + 1, rhs_horiz1); + rhs_pf1.z = rhs(rhs_vert + 2, rhs_horiz1); + } else if (rhs_vert + 1 < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + rhs_pf1.y = rhs(rhs_vert + 1, rhs_horiz1); + } else if (rhs_vert < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + } + } else { + if (rhs_horiz1 < n_size) { + if ((rhs_vert + 3) < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0 = rhs.loadPacket(rhs_vert, rhs_horiz0); + rhs_pf1 = rhs.loadPacket(rhs_vert, rhs_horiz1); + } else if (rhs_vert + 2 < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf0.z = rhs(rhs_vert + 2, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + rhs_pf1.y = rhs(rhs_vert + 1, rhs_horiz1); + rhs_pf1.z = rhs(rhs_vert + 2, rhs_horiz1); + } else if (k+threadIdx.x*4 + 1 < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + rhs_pf1.y = rhs(rhs_vert + 1, rhs_horiz1); + } else if (k+threadIdx.x*4 < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf1.x = rhs(rhs_vert, rhs_horiz1); + } + } else if (rhs_horiz0 < n_size) { + if ((rhs_vert + 3) < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0 = rhs.loadPacket(rhs_vert, rhs_horiz0); + } else if ((rhs_vert + 2) < k_size) { + // just CHECK_RHS_BOUNDARY + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + rhs_pf0.z = rhs(rhs_vert + 2, rhs_horiz0); + } else if ((rhs_vert + 1) < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + rhs_pf0.y = rhs(rhs_vert + 1, rhs_horiz0); + } else if (rhs_vert < k_size) { + rhs_pf0.x = rhs(rhs_vert, rhs_horiz0); + } + } + } + __syncthreads(); + // Loaded. Do computation + // Row 0 -> times (0, 4, 8, .. 28) for features 0, 1. + // Row 1 -> times (0, 4, 8, .. 28) for features 2, 3. + // .. + // Row 31 -> times (0, 4, 8, .. 28) for features 62, 63 + rhs_shmem2[threadIdx.y][threadIdx.x] = make_float2(rhs_pf0.x, rhs_pf1.x); + // Row 32 -> times (1, 5, 9, .. 29) for features 0, 1. + // Row 33 -> times (1, 5, 9, .. 29) for features 2, 3. + // .. + rhs_shmem2[threadIdx.y+32][threadIdx.x] = make_float2(rhs_pf0.y, rhs_pf1.y); + // Row 64 -> times (2, 6, 10, .. 30) for features 0, 1. + // Row 65 -> times (2, 6, 10, .. 30) for features 2, 3. + rhs_shmem2[threadIdx.y+64][threadIdx.x] = make_float2(rhs_pf0.z, rhs_pf1.z); + // Row 96 -> times (3, 7, 11, .. 31) for features 0, 1. + // Row 97 -> times (3, 7, 11, .. 31) for features 2, 3. + rhs_shmem2[threadIdx.y+96][threadIdx.x] = make_float2(rhs_pf0.w, rhs_pf1.w); + + // LHS. + // Row 0 (time 0) -> features (0, 1), (4, 5), .. (28, 29), (32, 33), .. (60, 61) .. (124, 125) + // Row 1 (time 1) -> features (0, 1), (4, 5), .. (28, 29), (32, 33), .. (60, 61) .. (124, 125) + // ... + // Row 8 (time 0) -> features (2, 3), (6, 7), .. (30, 31), (34, 35), .. (62, 63) .. (126, 127) + // Row 15 (time 7) -> features (2, 3), (6, 7), .. (30, 31), (34, 35), .. (62, 63) .. (126, 127) + + +#define add_vals(a_feat1, a_feat2, f1, f2, f3, f4)\ + results[0].x += a_feat1.x * f1.x;\ + results[1].x += a_feat1.x * f1.y;\ + results[2].x += a_feat1.x * f2.x;\ + results[3].x += a_feat1.x * f2.y;\ + results[4].x += a_feat1.x * f3.x;\ + results[5].x += a_feat1.x * f3.y;\ + results[6].x += a_feat1.x * f4.x;\ + results[7].x += a_feat1.x * f4.y;\ +\ + results[0].y += a_feat1.y * f1.x;\ + results[1].y += a_feat1.y * f1.y;\ + results[2].y += a_feat1.y * f2.x;\ + results[3].y += a_feat1.y * f2.y;\ + results[4].y += a_feat1.y * f3.x;\ + results[5].y += a_feat1.y * f3.y;\ + results[6].y += a_feat1.y * f4.x;\ + results[7].y += a_feat1.y * f4.y;\ +\ + results[0].z += a_feat2.x * f1.x;\ + results[1].z += a_feat2.x * f1.y;\ + results[2].z += a_feat2.x * f2.x;\ + results[3].z += a_feat2.x * f2.y;\ + results[4].z += a_feat2.x * f3.x;\ + results[5].z += a_feat2.x * f3.y;\ + results[6].z += a_feat2.x * f4.x;\ + results[7].z += a_feat2.x * f4.y;\ +\ + results[0].w += a_feat2.y * f1.x;\ + results[1].w += a_feat2.y * f1.y;\ + results[2].w += a_feat2.y * f2.x;\ + results[3].w += a_feat2.y * f2.y;\ + results[4].w += a_feat2.y * f3.x;\ + results[5].w += a_feat2.y * f3.y;\ + results[6].w += a_feat2.y * f4.x;\ + results[7].w += a_feat2.y * f4.y;\ + + lhs_shmem2[threadIdx.y/4][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf0.x, lhs_pf0.y); + lhs_shmem2[threadIdx.y/4+8][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf1.x, lhs_pf1.y); + lhs_shmem2[threadIdx.y/4+16][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf2.x, lhs_pf2.y); + lhs_shmem2[threadIdx.y/4+24][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf3.x, lhs_pf3.y); + + lhs_shmem2[threadIdx.y/4 + 32][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf0.z, lhs_pf0.w); + lhs_shmem2[threadIdx.y/4 + 40][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf1.z, lhs_pf1.w); + lhs_shmem2[threadIdx.y/4 + 48][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf2.z, lhs_pf2.w); + lhs_shmem2[threadIdx.y/4 + 56][threadIdx.x+(threadIdx.y%4)*8] = make_float2(lhs_pf3.z, lhs_pf3.w); + + __syncthreads(); + + // Do the multiplies. + #pragma unroll + for (int koff = 0; koff < 32; koff ++) { + float2 a3 = lhs_shmem2[koff][threadIdx.x + (threadIdx.y % 4) * 8]; + float2 a4 = lhs_shmem2[koff + 32][threadIdx.x + (threadIdx.y % 4) * 8]; + + // first feature is at (threadIdx.y/4) * 8 last is at start + 8. + int start_feature = (threadIdx.y / 4) * 8; + + float2 br1 = rhs_shmem2[start_feature/2 + (koff % 4) * 32][koff/4]; + float2 br2 = rhs_shmem2[start_feature/2 + 1 + (koff % 4) * 32][koff/4]; + float2 br3 = rhs_shmem2[start_feature/2 + 2 + (koff % 4) * 32][koff/4]; + float2 br4 = rhs_shmem2[start_feature/2 + 3 + (koff % 4) * 32][koff/4]; + + add_vals(a3, a4, br1, br2, br3, br4) + } + __syncthreads(); + } // end loop over k + + + __syncthreads(); + Index horiz_base = (threadIdx.y/4)*8+base_n; + if (!CHECK_LHS_BOUNDARY && !CHECK_RHS_BOUNDARY) { + for (int i = 0; i < 8; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } else if (!CHECK_RHS_BOUNDARY) { + if (lhs_vert + 3 < m_size) { + for (int i = 0; i < 8; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } else if (lhs_vert + 2 < m_size) { + for (int i = 0; i < 8; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + } + } else if (lhs_vert + 1 < m_size) { + for (int i = 0; i < 8; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + } + } else if (lhs_vert < m_size) { + for (int i = 0; i < 8; i++) { + output(lhs_vert, horiz_base + i) = results[i].x; + } + } + } else if (!CHECK_LHS_BOUNDARY) { + // CHECK BOUNDARY_B + for (int i = 0; i < 8; i++) { + if (horiz_base + i < n_size) { + output(lhs_vert, horiz_base + i) = results[i].x; + output(lhs_vert + 1, horiz_base + i) = results[i].y; + output(lhs_vert + 2, horiz_base + i) = results[i].z; + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } + } else { + // CHECK both boundaries. + for (int i = 0; i < 8; i++) { + if (horiz_base + i < n_size) { + if (lhs_vert < m_size) + output(lhs_vert, horiz_base + i) = results[i].x; + if (lhs_vert + 1 < m_size) + output(lhs_vert + 1, horiz_base + i) = results[i].y; + if (lhs_vert + 2 < m_size) + output(lhs_vert + 2, horiz_base + i) = results[i].z; + if (lhs_vert + 3 < m_size) + output(lhs_vert + 3, horiz_base + i) = results[i].w; + } + } + } +} + + +template<typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper> +__global__ void +__launch_bounds__(256) +EigenFloatContractionKernel(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, + const Index m_size, const Index n_size, const Index k_size) { + __shared__ float2 lhs_shmem[64*32]; + __shared__ float2 rhs_shmem[128*8]; + + typedef float2 LHS_MEM[64][32]; + typedef float2 RHS_MEM[128][8]; + + typedef float2 LHS_MEM16x16[32][16]; + typedef float2 RHS_MEM16x16[64][8]; + + const Index m_block_idx = blockIdx.x; + const Index n_block_idx = blockIdx.y; + + const Index base_m = 128 * m_block_idx; + const Index base_n = 64 * n_block_idx; + + bool check_rhs = (base_n + 63) >= n_size; + bool check_lhs128 = (base_m + 127) >= m_size; + bool check_lhs64 = (base_m + 63) >= m_size; + + if (!check_rhs) { + if (!check_lhs128) { + // >= 128 rows left + EigenFloatContractionKernelInternal<Index, LhsMapper, RhsMapper, OutputMapper, false, false>( + lhs, rhs, output, *((LHS_MEM *) lhs_shmem), *((RHS_MEM *) rhs_shmem), m_size, n_size, k_size, base_m, base_n); + } else { + EigenFloatContractionKernelInternal<Index, LhsMapper, RhsMapper, OutputMapper, true, false>( + lhs, rhs, output, *((LHS_MEM *) lhs_shmem), *((RHS_MEM *) rhs_shmem), m_size, n_size, k_size, base_m, base_n); + } + } else { + if (!check_lhs128) { + // >= 128 rows left + EigenFloatContractionKernelInternal<Index, LhsMapper, RhsMapper, OutputMapper, false, true>( + lhs, rhs, output, *((LHS_MEM *) lhs_shmem), *((RHS_MEM *) rhs_shmem), m_size, n_size, k_size, base_m, base_n); + } else { + EigenFloatContractionKernelInternal<Index, LhsMapper, RhsMapper, OutputMapper, true, true>( + lhs, rhs, output, *((LHS_MEM *) lhs_shmem), *((RHS_MEM *) rhs_shmem), m_size, n_size, k_size, base_m, base_n); + } + } +} + +template<typename Index, typename LhsMapper, + typename RhsMapper, typename OutputMapper> +__global__ void +__launch_bounds__(256) +EigenFloatContractionKernel16x16(const LhsMapper lhs, const RhsMapper rhs, + const OutputMapper output, + const Index m_size, const Index n_size, const Index k_size) { + __shared__ float2 lhs_shmem[32][16]; + __shared__ float2 rhs_shmem[64][8]; + + const Index m_block_idx = blockIdx.x; + const Index n_block_idx = blockIdx.y; + + const Index base_m = 64 * m_block_idx; + const Index base_n = 64 * n_block_idx; + + if (base_m + 63 < m_size) { + if (base_n + 63 < n_size) { + EigenFloatContractionKernelInternal16x16<Index, LhsMapper, RhsMapper, OutputMapper, false, false>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size, base_m, base_n); + } else { + EigenFloatContractionKernelInternal16x16<Index, LhsMapper, RhsMapper, OutputMapper, false, true>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size, base_m, base_n); + } + } else { + if (base_n + 63 < n_size) { + EigenFloatContractionKernelInternal16x16<Index, LhsMapper, RhsMapper, OutputMapper, true, false>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size, base_m, base_n); + } else { + EigenFloatContractionKernelInternal16x16<Index, LhsMapper, RhsMapper, OutputMapper, true, true>(lhs, rhs, output, lhs_shmem, rhs_shmem, m_size, n_size, k_size, base_m, base_n); + } + } +} + + +template<typename Indices, typename LeftArgType, typename RightArgType> +struct TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, GpuDevice> : + public TensorContractionEvaluatorBase<TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, GpuDevice> > { + + typedef GpuDevice Device; + + typedef TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, Device> Self; + typedef TensorContractionEvaluatorBase<Self> Base; + + typedef TensorContractionOp<Indices, LeftArgType, RightArgType> XprType; + typedef typename internal::remove_const<typename XprType::Scalar>::type Scalar; + typedef typename XprType::Packet Packet; + typedef typename XprType::Index Index; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + enum { + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + }; + + // Most of the code is assuming that both input tensors are ColMajor. If the + // inputs are RowMajor, we will "cheat" by swapping the LHS and RHS: + // If we want to compute A * B = C, where A is LHS and B is RHS, the code + // will pretend B is LHS and A is RHS. + typedef typename internal::conditional< + Layout == ColMajor, LeftArgType, RightArgType>::type EvalLeftArgType; + typedef typename internal::conditional< + Layout == ColMajor, RightArgType, LeftArgType>::type EvalRightArgType; + + static const int LDims = + internal::array_size<typename TensorEvaluator<EvalLeftArgType, Device>::Dimensions>::value; + static const int RDims = + internal::array_size<typename TensorEvaluator<EvalRightArgType, Device>::Dimensions>::value; + static const int ContractDims = internal::array_size<Indices>::value; + + typedef array<Index, LDims> left_dim_mapper_t; + typedef array<Index, RDims> right_dim_mapper_t; + + typedef array<Index, ContractDims> contract_t; + typedef array<Index, internal::max_n_1<LDims - ContractDims>::size> left_nocontract_t; + typedef array<Index, internal::max_n_1<RDims - ContractDims>::size> right_nocontract_t; + + static const int NumDims = internal::max_n_1<LDims + RDims - 2 * ContractDims>::size; + + typedef DSizes<Index, NumDims> Dimensions; + + // typedefs needed in evalTo + typedef typename internal::remove_const<typename EvalLeftArgType::Scalar>::type LhsScalar; + typedef typename internal::remove_const<typename EvalRightArgType::Scalar>::type RhsScalar; + + typedef TensorEvaluator<EvalLeftArgType, Device> LeftEvaluator; + typedef TensorEvaluator<EvalRightArgType, Device> RightEvaluator; + + typedef typename LeftEvaluator::Dimensions LeftDimensions; + typedef typename RightEvaluator::Dimensions RightDimensions; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) : + Base(op, device) {} + + // We need to redefine this method to make nvcc happy + EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* data) { + this->m_leftImpl.evalSubExprsIfNeeded(NULL); + this->m_rightImpl.evalSubExprsIfNeeded(NULL); + if (data) { + evalTo(data); + return false; + } else { + this->m_result = static_cast<Scalar *>(this->m_device.allocate(this->dimensions().TotalSize() * sizeof(Scalar))); + evalTo(this->m_result); + return true; + } + } + + void evalTo(Scalar* buffer) const { + if (this->m_lhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_reordered) { + evalTyped<true, true, true, Unaligned>(buffer); + } + else { + evalTyped<true, true, false, Unaligned>(buffer); + } + } + else { + if (this->m_rhs_inner_dim_reordered) { + evalTyped<true, false, true, Unaligned>(buffer); + } + else { + evalTyped<true, false, false, Unaligned>(buffer); + } + } + } + else { + if (this->m_rhs_inner_dim_contiguous) { + if (this->m_rhs_inner_dim_reordered) { + evalTyped<false, true, true, Unaligned>(buffer); + } + else { + evalTyped<false, true, false, Unaligned>(buffer); + } + } + else { + if (this->m_rhs_inner_dim_reordered) { + evalTyped<false, false, true, Unaligned>(buffer); + } + else { + evalTyped<false, false, false, Unaligned>(buffer); + } + } + } + } + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + void evalTyped(Scalar* buffer) const { + // columns in left side, rows in right side + const Index k = this->m_k_size; + + // rows in left side + const Index m = this->m_i_size; + + // columns in right side + const Index n = this->m_j_size; + + // zero out the result buffer (which must be of size at least m * n * sizeof(Scalar) + this->m_device.memset(buffer, 0, m * n * sizeof(Scalar)); + + typedef internal::TensorContractionInputMapper<LhsScalar, Index, internal::Lhs, + LeftEvaluator, left_nocontract_t, + contract_t, 4, + lhs_inner_dim_contiguous, + false, Unaligned> LhsMapper; + + typedef internal::TensorContractionInputMapper<RhsScalar, Index, internal::Rhs, + RightEvaluator, right_nocontract_t, + contract_t, 4, + rhs_inner_dim_contiguous, + rhs_inner_dim_reordered, Unaligned> RhsMapper; + + typedef internal::blas_data_mapper<Scalar, Index, ColMajor> OutputMapper; + + + // initialize data mappers + LhsMapper lhs(this->m_leftImpl, this->m_left_nocontract_strides, this->m_i_strides, + this->m_left_contracting_strides, this->m_k_strides); + + RhsMapper rhs(this->m_rightImpl, this->m_right_nocontract_strides, this->m_j_strides, + this->m_right_contracting_strides, this->m_k_strides); + + OutputMapper output(buffer, m); + + setCudaSharedMemConfig(cudaSharedMemBankSizeEightByte); + if (internal::is_same<LhsScalar, float>::value && + internal::is_same<RhsScalar, float>::value) { + if (m < 768 || n < 768) { + const Index m_blocks = (m + 63) / 64; + const Index n_blocks = (n + 63) / 64; + const dim3 num_blocks(m_blocks, n_blocks, 1); + const dim3 block_size(16, 16, 1); + LAUNCH_CUDA_KERNEL((EigenFloatContractionKernel16x16<Index, LhsMapper, RhsMapper, OutputMapper>), num_blocks, block_size, 0, this->m_device, lhs, rhs, output, m, n, k); + } else { + const Index m_blocks = (m + 127) / 128; + const Index n_blocks = (n + 63) / 64; + const dim3 num_blocks(m_blocks, n_blocks, 1); + const dim3 block_size(8, 32, 1); + LAUNCH_CUDA_KERNEL((EigenFloatContractionKernel<Index, LhsMapper, RhsMapper, OutputMapper>), num_blocks, block_size, 0, this->m_device, lhs, rhs, output, m, n, k); + } + } else { + const Index m_blocks = (m + 63) / 64; + const Index n_blocks = (n + 63) / 64; + const dim3 num_blocks(m_blocks, n_blocks, 1); + const dim3 block_size(8, 8, 8); + LAUNCH_CUDA_KERNEL((EigenContractionKernel<Scalar, Index, LhsMapper, RhsMapper, OutputMapper>), num_blocks, block_size, 0, this->m_device, lhs, rhs, output, m, n, k); + } + } +}; + +} // end namespace Eigen + +#endif // EIGEN_USE_GPU and __CUDACC__ +#endif // EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_CUDA_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorContractionThreadPool.h b/unsupported/Eigen/CXX11/src/Tensor/TensorContractionThreadPool.h new file mode 100644 index 000000000..8b87f1045 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorContractionThreadPool.h @@ -0,0 +1,382 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_THREAD_POOL_H +#define EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_THREAD_POOL_H + +// evaluator for thread pool device +#ifdef EIGEN_USE_THREADS + +namespace Eigen { +namespace internal { + +template<typename LhsScalar, typename LhsMapper, typename Index> +struct packLhsArg { + LhsScalar* blockA; + const LhsMapper& lhs; + const Index m_start; + const Index k_start; + const Index mc; + const Index kc; +}; + +template<typename LhsScalar, typename RhsScalar, typename RhsMapper, typename OutputMapper, typename Index> +struct packRhsAndKernelArg { + const std::vector<LhsScalar*>* blockAs; + RhsScalar* blockB; + const RhsMapper& rhs; + OutputMapper& output; + const Index m; + const Index k; + const Index n; + const Index mc; + const Index kc; + const Index nc; + const Index num_threads; + const Index num_blockAs; + const Index max_m; + const Index k_block_idx; + const Index m_block_idx; + const Index n_block_idx; + const Index m_blocks; + const Index n_blocks; + std::vector<Promise>* kernel_promises; + const std::vector<Future>* lhs_futures; + const bool need_to_pack; +}; + +} // end namespace internal + + +template<typename Indices, typename LeftArgType, typename RightArgType> +struct TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, ThreadPoolDevice> : + public TensorContractionEvaluatorBase<TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, ThreadPoolDevice> > { + + typedef ThreadPoolDevice Device; + + typedef TensorEvaluator<const TensorContractionOp<Indices, LeftArgType, RightArgType>, Device> Self; + typedef TensorContractionEvaluatorBase<Self> Base; + + typedef TensorContractionOp<Indices, LeftArgType, RightArgType> XprType; + typedef typename internal::remove_const<typename XprType::Scalar>::type Scalar; + typedef typename XprType::Packet Packet; + typedef typename XprType::Index Index; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + enum { + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + }; + + // Most of the code is assuming that both input tensors are ColMajor. If the + // inputs are RowMajor, we will "cheat" by swapping the LHS and RHS: + // If we want to compute A * B = C, where A is LHS and B is RHS, the code + // will pretend B is LHS and A is RHS. + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), LeftArgType, RightArgType>::type EvalLeftArgType; + typedef typename internal::conditional< + static_cast<int>(Layout) == static_cast<int>(ColMajor), RightArgType, LeftArgType>::type EvalRightArgType; + + static const int LDims = + internal::array_size<typename TensorEvaluator<EvalLeftArgType, Device>::Dimensions>::value; + static const int RDims = + internal::array_size<typename TensorEvaluator<EvalRightArgType, Device>::Dimensions>::value; + static const int ContractDims = internal::array_size<Indices>::value; + + typedef array<Index, LDims> left_dim_mapper_t; + typedef array<Index, RDims> right_dim_mapper_t; + + typedef array<Index, ContractDims> contract_t; + typedef array<Index, internal::max_n_1<LDims - ContractDims>::size> left_nocontract_t; + typedef array<Index, internal::max_n_1<RDims - ContractDims>::size> right_nocontract_t; + + static const int NumDims = internal::max_n_1<LDims + RDims - 2 * ContractDims>::size; + + typedef DSizes<Index, NumDims> Dimensions; + + // typedefs needed in evalTo + typedef typename internal::remove_const<typename EvalLeftArgType::Scalar>::type LhsScalar; + typedef typename internal::remove_const<typename EvalRightArgType::Scalar>::type RhsScalar; + typedef typename internal::gebp_traits<LhsScalar, RhsScalar> Traits; + + typedef TensorEvaluator<EvalLeftArgType, Device> LeftEvaluator; + typedef TensorEvaluator<EvalRightArgType, Device> RightEvaluator; + + TensorEvaluator(const XprType& op, const Device& device) : + Base(op, device) {} + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + void evalProduct(Scalar* buffer) const { + if (this->m_j_size == 1) { + this->template evalGemv<lhs_inner_dim_contiguous, rhs_inner_dim_contiguous, rhs_inner_dim_reordered, Alignment>(buffer); + return; + } + + evalGemm<lhs_inner_dim_contiguous, rhs_inner_dim_contiguous, rhs_inner_dim_reordered, Alignment>(buffer); + } + + template <bool lhs_inner_dim_contiguous, bool rhs_inner_dim_contiguous, bool rhs_inner_dim_reordered, int Alignment> + void evalGemm(Scalar* buffer) const { + // columns in left side, rows in right side + const Index k = this->m_k_size; + + // rows in left side + const Index m = this->m_i_size; + + // columns in right side + const Index n = this->m_j_size; + + // zero out the result buffer (which must be of size at least m * n * sizeof(Scalar) + this->m_device.memset(buffer, 0, m * n * sizeof(Scalar)); + + + const int lhs_packet_size = internal::packet_traits<LhsScalar>::size; + const int rhs_packet_size = internal::packet_traits<RhsScalar>::size; + + typedef internal::TensorContractionInputMapper<LhsScalar, Index, internal::Lhs, + LeftEvaluator, left_nocontract_t, + contract_t, lhs_packet_size, + lhs_inner_dim_contiguous, + false, Unaligned> LhsMapper; + + typedef internal::TensorContractionInputMapper<RhsScalar, Index, internal::Rhs, + RightEvaluator, right_nocontract_t, + contract_t, rhs_packet_size, + rhs_inner_dim_contiguous, + rhs_inner_dim_reordered, Unaligned> RhsMapper; + + typedef internal::blas_data_mapper<Scalar, Index, ColMajor> OutputMapper; + + // TODO: packing could be faster sometimes if we supported row major tensor mappers + typedef internal::gemm_pack_lhs<LhsScalar, Index, typename LhsMapper::SubMapper, Traits::mr, + Traits::LhsProgress, ColMajor> LhsPacker; + typedef internal::gemm_pack_rhs<RhsScalar, Index, typename RhsMapper::SubMapper, Traits::nr, ColMajor> RhsPacker; + + // TODO: replace false, false with conjugate values? + typedef internal::gebp_kernel<LhsScalar, RhsScalar, Index, OutputMapper, + Traits::mr, Traits::nr, false, false> GebpKernel; + + typedef internal::packLhsArg<LhsScalar, LhsMapper, Index> packLArg; + typedef internal::packRhsAndKernelArg<LhsScalar, RhsScalar, RhsMapper, OutputMapper, Index> packRKArg; + + // initialize data mappers + LhsMapper lhs(this->m_leftImpl, this->m_left_nocontract_strides, this->m_i_strides, + this->m_left_contracting_strides, this->m_k_strides); + + RhsMapper rhs(this->m_rightImpl, this->m_right_nocontract_strides, this->m_j_strides, + this->m_right_contracting_strides, this->m_k_strides); + + OutputMapper output(buffer, m); + + LhsPacker pack_lhs; + + // compute block sizes (which depend on number of threads) + const Index num_threads = this->m_device.numThreads(); + Index mc = m; + Index nc = n; + Index kc = k; + internal::computeProductBlockingSizes<LhsScalar,RhsScalar,1>(kc, mc, nc, num_threads); + eigen_assert(mc <= m); + eigen_assert(nc <= n); + eigen_assert(kc <= k); + +#define CEIL_DIV(a, b) (((a) + (b) - 1) / (b)) + const Index k_blocks = CEIL_DIV(k, kc); + const Index n_blocks = CEIL_DIV(n, nc); + const Index m_blocks = CEIL_DIV(m, mc); + const int sizeA = mc * kc; + const int sizeB = kc * nc; + + /* cout << "m: " << m << " n: " << n << " k: " << k << endl; + cout << "mc: " << mc << " nc: " << nc << " kc: " << kc << endl; + cout << "m_blocks: " << m_blocks << " n_blocks: " << n_blocks << " k_blocks: " << k_blocks << endl; + cout << "num threads: " << num_threads << endl; + */ + + // note: m_device.allocate should return 16 byte aligned pointers, but if blockA and blockB + // aren't 16 byte aligned segfaults will happen due to SIMD instructions + // note: You can get away with allocating just a single blockA and offsets and meet the + // the alignment requirements with the assumption that + // (Traits::mr * sizeof(ResScalar)) % 16 == 0 + const Index numBlockAs = (std::min)(num_threads, m_blocks); + std::vector<LhsScalar *> blockAs; + blockAs.reserve(num_threads); + for (int i = 0; i < num_threads; i++) { + blockAs.push_back(static_cast<LhsScalar *>(this->m_device.allocate(sizeA * sizeof(LhsScalar)))); + } + + // To circumvent alignment issues, I'm just going to separately allocate the memory for each thread + // TODO: is this too much memory to allocate? This simplifies coding a lot, but is wasteful. + // Other options: (1) reuse memory when a thread finishes. con: tricky + // (2) allocate block B memory in each thread. con: overhead + std::vector<RhsScalar *> blockBs; + blockBs.reserve(n_blocks); + for (int i = 0; i < n_blocks; i++) { + blockBs.push_back(static_cast<RhsScalar *>(this->m_device.allocate(sizeB * sizeof(RhsScalar)))); + } + + // lhs_futures starts with all null futures + std::vector<Future> lhs_futures(num_threads); + + // this should really be numBlockAs * n_blocks; + const Index num_kernel_promises = num_threads * n_blocks; + std::vector<Promise> kernel_promises(num_kernel_promises); + std::vector<Future> kernel_futures(num_kernel_promises); + for (int i = 0; i < kernel_promises.size(); ++i) { + kernel_promises[i].set_value(); + kernel_futures[i] = kernel_promises[i].get_future(); + } + + for (Index k_block_idx = 0; k_block_idx < k_blocks; k_block_idx++) { + const Index k_start = k_block_idx * kc; + // make sure we don't overshoot right edge of left matrix + const Index actual_kc = (std::min)(k_start + kc, k) - k_start; + + for (Index m_block_idx = 0; m_block_idx < m_blocks; m_block_idx += numBlockAs) { + const int num_blocks = (std::min)(m_blocks-m_block_idx, numBlockAs); + + for (Index mt_block_idx = m_block_idx; mt_block_idx < m_block_idx+num_blocks; mt_block_idx++) { + const Index m_start = mt_block_idx * mc; + const Index actual_mc = (std::min)(m_start + mc, m) - m_start; + eigen_assert(actual_mc > 0); + + int blockAId = (k_block_idx * m_blocks + mt_block_idx) % num_threads; + for (int i = 0; i < n_blocks; ++i) { + int future_id = (blockAId * n_blocks + i); + wait_until_ready(&kernel_futures[future_id]); + kernel_promises[future_id] = Promise(); + kernel_futures[future_id] = kernel_promises[future_id].get_future(); + } + const packLArg arg = { + blockAs[blockAId], // blockA + lhs, // lhs + m_start, // m + k_start, // k + actual_mc, // mc + actual_kc, // kc + }; + + lhs_futures[blockAId] = + this->m_device.enqueue(&Self::packLhs<packLArg, LhsPacker>, arg); + } + + // now start kernels. + const Index m_base_start = m_block_idx * mc; + const bool need_to_pack = m_block_idx == 0; + + for (Index n_block_idx = 0; n_block_idx < n_blocks; n_block_idx++) { + const Index n_start = n_block_idx * nc; + const Index actual_nc = (std::min)(n_start + nc, n) - n_start; + + // first make sure the previous kernels are all done before overwriting rhs. Also wait if + // we're going to start new k. In both cases need_to_pack is true. + if (need_to_pack) { + for (int i = num_blocks; i < num_threads; ++i) { + int blockAId = (k_block_idx * m_blocks + i + m_block_idx) % num_threads; + int future_id = (blockAId * n_blocks + n_block_idx); + wait_until_ready(&kernel_futures[future_id]); + } + } + + packRKArg arg = { + &blockAs, // blockA + blockBs[n_block_idx], // blockB + rhs, // rhs + output, // output + m_base_start, // m + k_start, // k + n_start, // n + mc, // mc + actual_kc, // kc + actual_nc, // nc + num_threads, + numBlockAs, + m, + k_block_idx, + m_block_idx, + n_block_idx, // n_block_idx + m_blocks, // m_blocks + n_blocks, // n_blocks + &kernel_promises, // kernel_promises + &lhs_futures, // lhs_futures + need_to_pack, // need_to_pack + }; + + this->m_device.enqueueNoFuture(&Self::packRhsAndKernel<packRKArg, RhsPacker, GebpKernel>, arg); + } + } + } + + // Make sure all the kernels are done. + for (int i = 0; i < kernel_futures.size(); ++i) { + wait_until_ready(&kernel_futures[i]); + } + + // deallocate all of the memory for both A and B's + for (int i = 0; i < blockAs.size(); i++) { + this->m_device.deallocate(blockAs[i]); + } + for (int i = 0; i < blockBs.size(); i++) { + this->m_device.deallocate(blockBs[i]); + } + +#undef CEIL_DIV + } + + /* + * Packs a LHS block of size (mt, kc) starting at lhs(m, k). Before packing + * the LHS block, check that all of the kernels that worked on the same + * mt_block_idx in the previous m_block are done. + */ + template <typename packLArg, typename LhsPacker> + static void packLhs(const packLArg arg) { + // perform actual packing + LhsPacker pack_lhs; + pack_lhs(arg.blockA, arg.lhs.getSubMapper(arg.m_start, arg.k_start), arg.kc, arg.mc); + } + + /* + * Packs a RHS block of size (kc, nc) starting at (k, n) after checking that + * all kernels in the previous block are done. + * Then for each LHS future, we wait on the future and then call GEBP + * on the area packed by the future (which starts at + * blockA + future_idx * mt * kc) on the LHS and with the full packed + * RHS block. + * The output of this GEBP is written to output(m + i * mt, n). + */ + template <typename packRKArg, typename RhsPacker, typename GebpKernel> + static void packRhsAndKernel(packRKArg arg) { + if (arg.need_to_pack) { + RhsPacker pack_rhs; + pack_rhs(arg.blockB, arg.rhs.getSubMapper(arg.k, arg.n), arg.kc, arg.nc); + } + + GebpKernel gebp; + for (Index mt_block_idx = 0; mt_block_idx < arg.num_blockAs; mt_block_idx++) { + const Index m_base_start = arg.m + arg.mc*mt_block_idx; + if (m_base_start < arg.max_m) { + int blockAId = (arg.k_block_idx * arg.m_blocks + mt_block_idx + arg.m_block_idx) % arg.num_threads; + + wait_until_ready(&(*arg.lhs_futures)[blockAId]); + const Index actual_mc = (std::min)(m_base_start + arg.mc, arg.max_m) - m_base_start; + gebp(arg.output.getSubMapper(m_base_start, arg.n), + (*arg.blockAs)[blockAId], arg.blockB, + actual_mc, arg.kc, arg.nc, 1.0, -1, -1, 0, 0); + + const Index set_idx = blockAId * arg.n_blocks + arg.n_block_idx; + (*arg.kernel_promises)[set_idx].set_value(); + } + } + } +}; + +} // end namespace Eigen + +#endif // EIGEN_USE_THREADS +#endif // EIGEN_CXX11_TENSOR_TENSOR_CONTRACTION_THREAD_POOL_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorConvolution.h b/unsupported/Eigen/CXX11/src/Tensor/TensorConvolution.h new file mode 100644 index 000000000..591fd2464 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorConvolution.h @@ -0,0 +1,912 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_CONVOLUTION_H +#define EIGEN_CXX11_TENSOR_TENSOR_CONVOLUTION_H + +namespace Eigen { + +/** \class TensorConvolution + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor convolution class. + * + * + */ +namespace internal { + + +template <typename Index, typename InputDims, size_t NumKernelDims> class IndexMapper { + public: + IndexMapper(const InputDims& input_dims, const array<Index, NumKernelDims>& kernel_dims, + const array<Index, NumKernelDims>& indices) { + + array<Index, NumDims> dimensions = input_dims; + for (int i = 0; i < NumKernelDims; ++i) { + const Index index = indices[i]; + const Index input_dim = input_dims[index]; + const Index kernel_dim = kernel_dims[i]; + const Index result_dim = input_dim - kernel_dim + 1; + dimensions[index] = result_dim; + } + + array<Index, NumDims> inputStrides; + array<Index, NumDims> outputStrides; + for (int i = 0; i < NumDims; ++i) { + if (i > 0) { + inputStrides[i] = inputStrides[i-1] * input_dims[i-1]; + outputStrides[i] = outputStrides[i-1] * dimensions[i-1]; + } else { + inputStrides[0] = 1; + outputStrides[0] = 1; + } + } + + array<Index, NumDims> cudaInputDimensions; + array<Index, NumDims> cudaOutputDimensions; + array<Index, NumDims> tmp = dimensions; + array<Index, NumDims> ordering; + for (int i = 0; i < NumKernelDims; ++i) { + ordering[i] = indices[i]; + tmp[indices[i]] = -1; + cudaInputDimensions[i] = input_dims[ordering[i]]; + cudaOutputDimensions[i] = dimensions[ordering[i]]; + } + int written = NumKernelDims; + for (int i = 0; i < NumDims; ++i) { + if (tmp[i] >= 0) { + ordering[written] = i; + cudaInputDimensions[written] = input_dims[i]; + cudaOutputDimensions[written] = dimensions[i]; + ++written; + } + } + + for (int i = 0; i < NumDims; ++i) { + m_inputStrides[i] = inputStrides[ordering[i]]; + m_outputStrides[i] = outputStrides[ordering[i]]; + } + + for (int i = 0; i < NumDims; ++i) { + if (i > NumKernelDims) { + m_cudaInputStrides[i] = m_cudaInputStrides[i-1] * cudaInputDimensions[i-1]; + m_cudaOutputStrides[i] = m_cudaOutputStrides[i-1] * cudaOutputDimensions[i-1]; + } else { + m_cudaInputStrides[i] = 1; + m_cudaOutputStrides[i] = 1; + } + } + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaInputPlaneToTensorInputOffset(Index p) const { + Index inputIndex = 0; + for (int d = NumDims - 1; d > NumKernelDims; --d) { + const Index idx = p / m_cudaInputStrides[d]; + inputIndex += idx * m_inputStrides[d]; + p -= idx * m_cudaInputStrides[d]; + } + inputIndex += p * m_inputStrides[NumKernelDims]; + return inputIndex; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaOutputPlaneToTensorOutputOffset(Index p) const { + Index outputIndex = 0; + for (int d = NumDims - 1; d > NumKernelDims; --d) { + const Index idx = p / m_cudaOutputStrides[d]; + outputIndex += idx * m_outputStrides[d]; + p -= idx * m_cudaOutputStrides[d]; + } + outputIndex += p * m_outputStrides[NumKernelDims]; + return outputIndex; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaInputKernelToTensorInputOffset(Index i) const { + return i * m_inputStrides[0]; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaOutputKernelToTensorOutputOffset(Index i) const { + return i * m_outputStrides[0]; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaInputKernelToTensorInputOffset(Index i, Index j) const { + return i * m_inputStrides[0] + j*m_inputStrides[1]; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaOutputKernelToTensorOutputOffset(Index i, Index j) const { + return i * m_outputStrides[0] + j * m_outputStrides[1]; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaInputKernelToTensorInputOffset(Index i, Index j, Index k) const { + return i * m_inputStrides[0] + j*m_inputStrides[1] + k*m_inputStrides[2]; + } + + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Index mapCudaOutputKernelToTensorOutputOffset(Index i, Index j, Index k) const { + return i * m_outputStrides[0] + j*m_outputStrides[1] + k*m_outputStrides[2]; + } + + private: + static const size_t NumDims = internal::array_size<InputDims>::value; + array<Index, NumDims> m_inputStrides; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims> m_cudaInputStrides; + array<Index, NumDims> m_cudaOutputStrides; +}; + + + +template<typename Dimensions, typename InputXprType, typename KernelXprType> +struct traits<TensorConvolutionOp<Dimensions, InputXprType, KernelXprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs are different. + typedef typename promote_storage_type<typename InputXprType::Scalar, + typename KernelXprType::Scalar>::ret Scalar; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename promote_storage_type<typename traits<InputXprType>::StorageKind, + typename traits<KernelXprType>::StorageKind>::ret StorageKind; + typedef typename promote_index_type<typename traits<InputXprType>::Index, + typename traits<KernelXprType>::Index>::type Index; + typedef typename InputXprType::Nested LhsNested; + typedef typename KernelXprType::Nested RhsNested; + typedef typename remove_reference<LhsNested>::type _LhsNested; + typedef typename remove_reference<RhsNested>::type _RhsNested; + static const int NumDimensions = traits<InputXprType>::NumDimensions; + static const int Layout = traits<InputXprType>::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename Dimensions, typename InputXprType, typename KernelXprType> +struct eval<TensorConvolutionOp<Dimensions, InputXprType, KernelXprType>, Eigen::Dense> +{ + typedef const TensorConvolutionOp<Dimensions, InputXprType, KernelXprType>& type; +}; + +template<typename Dimensions, typename InputXprType, typename KernelXprType> +struct nested<TensorConvolutionOp<Dimensions, InputXprType, KernelXprType>, 1, typename eval<TensorConvolutionOp<Dimensions, InputXprType, KernelXprType> >::type> +{ + typedef TensorConvolutionOp<Dimensions, InputXprType, KernelXprType> type; +}; + +} // end namespace internal + + + +template<typename Indices, typename InputXprType, typename KernelXprType> +class TensorConvolutionOp : public TensorBase<TensorConvolutionOp<Indices, InputXprType, KernelXprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorConvolutionOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorConvolutionOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::promote_storage_type<typename InputXprType::CoeffReturnType, + typename KernelXprType::CoeffReturnType>::ret CoeffReturnType; + typedef typename internal::promote_storage_type<typename InputXprType::PacketReturnType, + typename KernelXprType::PacketReturnType>::ret PacketReturnType; + typedef typename Eigen::internal::nested<TensorConvolutionOp>::type Nested; + typedef typename Eigen::internal::traits<TensorConvolutionOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorConvolutionOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorConvolutionOp(const InputXprType& input, const KernelXprType& kernel, const Indices& dims) + : m_input_xpr(input), m_kernel_xpr(kernel), m_indices(dims) {} + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const Indices& indices() const { return m_indices; } + + /** \returns the nested expressions */ + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const typename internal::remove_all<typename InputXprType::Nested>::type& + inputExpression() const { return m_input_xpr; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const typename internal::remove_all<typename KernelXprType::Nested>::type& + kernelExpression() const { return m_kernel_xpr; } + + protected: + typename InputXprType::Nested m_input_xpr; + typename KernelXprType::Nested m_kernel_xpr; + const Indices m_indices; +}; + + +template<typename Indices, typename InputArgType, typename KernelArgType, typename Device> +struct TensorEvaluator<const TensorConvolutionOp<Indices, InputArgType, KernelArgType>, Device> +{ + typedef TensorConvolutionOp<Indices, InputArgType, KernelArgType> XprType; + + static const int NumDims = internal::array_size<typename TensorEvaluator<InputArgType, Device>::Dimensions>::value; + static const int NumKernelDims = internal::array_size<Indices>::value; + typedef typename XprType::Index Index; + typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = TensorEvaluator<InputArgType, Device>::IsAligned & TensorEvaluator<KernelArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<InputArgType, Device>::PacketAccess & TensorEvaluator<KernelArgType, Device>::PacketAccess, + Layout = TensorEvaluator<InputArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_inputImpl(op.inputExpression(), device), m_kernelImpl(op.kernelExpression(), device), m_kernelArg(op.kernelExpression()), m_kernel(NULL), m_local_kernel(false), m_device(device) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<InputArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<KernelArgType, Device>::Layout)), YOU_MADE_A_PROGRAMMING_MISTAKE); + // Only column major tensors are supported for now. + EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE); + + const typename TensorEvaluator<InputArgType, Device>::Dimensions& input_dims = m_inputImpl.dimensions(); + const typename TensorEvaluator<KernelArgType, Device>::Dimensions& kernel_dims = m_kernelImpl.dimensions(); + + m_inputStride[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_inputStride[i] = m_inputStride[i-1] * input_dims[i-1]; + } + + m_dimensions = m_inputImpl.dimensions(); + for (int i = 0; i < NumKernelDims; ++i) { + const Index index = op.indices()[i]; + const Index input_dim = input_dims[index]; + const Index kernel_dim = kernel_dims[i]; + const Index result_dim = input_dim - kernel_dim + 1; + m_dimensions[index] = result_dim; + if (i > 0) { + m_kernelStride[i] = m_kernelStride[i-1] * kernel_dims[i-1]; + } else { + m_kernelStride[0] = 1; + } + m_indexStride[i] = m_inputStride[index]; + } + + m_outputStride[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_outputStride[i] = m_outputStride[i-1] * m_dimensions[i-1]; + } + } + + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + m_inputImpl.evalSubExprsIfNeeded(NULL); + preloadKernel(); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_inputImpl.cleanup(); + if (m_local_kernel) { + m_device.deallocate((void*)m_kernel); + m_local_kernel = false; + } + m_kernel = NULL; + } + + void evalTo(typename XprType::Scalar* buffer) { + evalSubExprsIfNeeded(NULL); + for (int i = 0; i < dimensions().TotalSize(); ++i) { + buffer[i] += coeff(i); + } + cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + CoeffReturnType result = CoeffReturnType(0); + convolve(firstInput(index), 0, NumKernelDims-1, result); + return result; + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC PacketReturnType packet(const Index index) const + { + const int PacketSize = internal::unpacket_traits<PacketReturnType>::size; + Index indices[2] = {index, index+PacketSize-1}; + Index startInputs[2] = {0, 0}; + for (int i = NumDims - 1; i > 0; --i) { + const Index idx0 = indices[0] / m_outputStride[i]; + const Index idx1 = indices[1] / m_outputStride[i]; + startInputs[0] += idx0 * m_inputStride[i]; + startInputs[1] += idx1 * m_inputStride[i]; + indices[0] -= idx0 * m_outputStride[i]; + indices[1] -= idx1 * m_outputStride[i]; + } + startInputs[0] += indices[0]; + startInputs[1] += indices[1]; + + if (startInputs[1]-startInputs[0] == PacketSize-1) { + PacketReturnType result = internal::pset1<PacketReturnType>(0); + convolvePacket(startInputs[0], 0, NumKernelDims-1, result); + return result; + } else { + EIGEN_ALIGN_DEFAULT Scalar data[PacketSize]; + data[0] = Scalar(0); + convolve(startInputs[0], 0, NumKernelDims-1, data[0]); + for (int i = 1; i < PacketSize-1; ++i) { + data[i] = Scalar(0); + convolve(firstInput(index+i), 0, NumKernelDims-1, data[i]); + } + data[PacketSize-1] = Scalar(0); + convolve(startInputs[1], 0, NumKernelDims-1, data[PacketSize-1]); + return internal::pload<PacketReturnType>(data); + } + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + private: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index firstInput(Index index) const { + Index startInput = 0; + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStride[i]; + startInput += idx * m_inputStride[i]; + index -= idx * m_outputStride[i]; + } + startInput += index; + return startInput; + } + + EIGEN_DEVICE_FUNC void convolve(Index firstIndex, Index firstKernel, int DimIndex, CoeffReturnType& accum) const { + for (int j = 0; j < m_kernelImpl.dimensions()[DimIndex]; ++j) { + const Index input = firstIndex + j * m_indexStride[DimIndex]; + const Index kernel = firstKernel + j * m_kernelStride[DimIndex]; + if (DimIndex > 0) { + convolve(input, kernel, DimIndex-1, accum); + } else { + accum += m_inputImpl.coeff(input) * m_kernel[kernel]; + } + } + } + + template <typename Packet> + EIGEN_DEVICE_FUNC void convolvePacket(Index firstIndex, Index firstKernel, int DimIndex, Packet& accum) const { + for (int j = 0; j < m_kernelImpl.dimensions()[DimIndex]; ++j) { + const Index input = firstIndex + j * m_indexStride[DimIndex]; + const Index kernel = firstKernel + j * m_kernelStride[DimIndex]; + if (DimIndex > 0) { + convolvePacket(input, kernel, DimIndex-1, accum); + } else { + accum = internal::pmadd<Packet>(m_inputImpl.template packet<Unaligned>(input), internal::pset1<Packet>(m_kernel[kernel]), accum); + } + } + } + + EIGEN_STRONG_INLINE void preloadKernel() { + // Don't make a local copy of the kernel unless we have to (i.e. it's an + // expression that needs to be evaluated) + const Scalar* in_place = m_kernelImpl.data(); + if (in_place) { + m_kernel = in_place; + m_local_kernel = false; + } else { + size_t kernel_sz = m_kernelImpl.dimensions().TotalSize() * sizeof(Scalar); + Scalar* local = (Scalar*)m_device.allocate(kernel_sz); + typedef TensorEvalToOp<const KernelArgType> EvalTo; + EvalTo evalToTmp(local, m_kernelArg); + internal::TensorExecutor<const EvalTo, Device, TensorEvaluator<KernelArgType, Device>::PacketAccess>::run(evalToTmp, m_device); + + m_kernel = local; + m_local_kernel = true; + } + } + + array<Index, NumDims> m_inputStride; + array<Index, NumDims> m_outputStride; + + array<Index, NumKernelDims> m_indexStride; + array<Index, NumKernelDims> m_kernelStride; + TensorEvaluator<InputArgType, Device> m_inputImpl; + TensorEvaluator<KernelArgType, Device> m_kernelImpl; + Dimensions m_dimensions; + + KernelArgType m_kernelArg; + const Scalar* m_kernel; + bool m_local_kernel; + const Device& m_device; +}; + + + + +// Use an optimized implementation of the evaluation code for GPUs whenever possible. +#if defined(EIGEN_USE_GPU) && defined(__CUDACC__) + +template <int StaticKernelSize> +struct GetKernelSize { + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE int operator() (const int /*kernelSize*/) const { + return StaticKernelSize; + } +}; +template <> +struct GetKernelSize<Dynamic> { + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE int operator() (const int kernelSize) const { + return kernelSize; + } +}; + + + + +template <typename InputEvaluator, typename Index, typename InputDims, int StaticKernelSize> +__global__ void EigenConvolutionKernel1D(InputEvaluator eval, const internal::IndexMapper<Index, InputDims, 1> indexMapper, const float* __restrict kernel, const int numPlanes, const int numX, const int maxX, const int kernelSize, float* buffer) { + extern __shared__ float s[]; + + const int first_x = blockIdx.x * maxX; + const int last_x = (first_x + maxX < numX ? first_x + maxX : numX) - 1; + const int num_x_input = last_x - first_x + GetKernelSize<StaticKernelSize>()(kernelSize); + const int num_x_output = last_x - first_x + 1; + + const int first_plane = blockIdx.y * blockDim.y; + const int plane_stride = blockDim.y * gridDim.y; + + for (int p = first_plane + threadIdx.y; p < numPlanes; p += plane_stride) { + // Load inputs to shared memory + const int plane_input_offset = indexMapper.mapCudaInputPlaneToTensorInputOffset(p); + const int plane_kernel_offset = threadIdx.y * num_x_input; + #pragma unroll + for (int i = threadIdx.x; i < num_x_input; i += blockDim.x) { + const int tensor_index = plane_input_offset + indexMapper.mapCudaInputKernelToTensorInputOffset(i+first_x); + s[i + plane_kernel_offset] = eval.coeff(tensor_index); + } + + __syncthreads(); + + // Compute the convolution + const int plane_output_offset = indexMapper.mapCudaOutputPlaneToTensorOutputOffset(p); + + #pragma unroll + for (int i = threadIdx.x; i < num_x_output; i += blockDim.x) { + const int kernel_offset = plane_kernel_offset + i; + float result = 0.0f; + #pragma unroll + for (int k = 0; k < GetKernelSize<StaticKernelSize>()(kernelSize); ++k) { + result += s[k + kernel_offset] * kernel[k]; + } + const int tensor_index = plane_output_offset + indexMapper.mapCudaOutputKernelToTensorOutputOffset(i+first_x); + buffer[tensor_index] = result; + } + __syncthreads(); + } +}; + + +template <typename InputEvaluator, typename Index, typename InputDims, int StaticKernelSizeX, int StaticKernelSizeY> +__global__ void EigenConvolutionKernel2D(InputEvaluator eval, const internal::IndexMapper<Index, InputDims, 2> indexMapper, const float* __restrict kernel, const int numPlanes, const int numX, const int maxX, const int numY, const int maxY, const int kernelSizeX, const int kernelSizeY, float* buffer) { + extern __shared__ float s[]; + + const int first_x = blockIdx.x * maxX; + const int last_x = (first_x + maxX < numX ? first_x + maxX : numX) - 1; + const int num_x_input = last_x - first_x + GetKernelSize<StaticKernelSizeX>()(kernelSizeX); + const int num_x_output = last_x - first_x + 1; + + const int first_y = blockIdx.y * maxY; + const int last_y = (first_y + maxY < numY ? first_y + maxY : numY) - 1; + const int num_y_input = last_y - first_y + GetKernelSize<StaticKernelSizeY>()(kernelSizeY); + const int num_y_output = last_y - first_y + 1; + + const int first_plane = blockIdx.z * blockDim.z; + const int plane_stride = blockDim.z * gridDim.z; + + for (int p = first_plane + threadIdx.z; p < numPlanes; p += plane_stride) { + + const int plane_input_offset = indexMapper.mapCudaInputPlaneToTensorInputOffset(p); + const int plane_kernel_offset = threadIdx.z * num_y_input; + + // Load inputs to shared memory + #pragma unroll + for (int j = threadIdx.y; j < num_y_input; j += blockDim.y) { + const int input_offset = num_x_input * (j + plane_kernel_offset); + #pragma unroll + for (int i = threadIdx.x; i < num_x_input; i += blockDim.x) { + const int tensor_index = plane_input_offset + indexMapper.mapCudaInputKernelToTensorInputOffset(i+first_x, j+first_y); + s[i + input_offset] = eval.coeff(tensor_index); + } + } + + __syncthreads(); + + // Convolution + const int plane_output_offset = indexMapper.mapCudaOutputPlaneToTensorOutputOffset(p); + + #pragma unroll + for (int j = threadIdx.y; j < num_y_output; j += blockDim.y) { + #pragma unroll + for (int i = threadIdx.x; i < num_x_output; i += blockDim.x) { + float result = 0.0f; + #pragma unroll + for (int l = 0; l < GetKernelSize<StaticKernelSizeY>()(kernelSizeY); ++l) { + const int kernel_offset = kernelSizeX * l; + const int input_offset = i + num_x_input * (j + l + plane_kernel_offset); + #pragma unroll + for (int k = 0; k < GetKernelSize<StaticKernelSizeX>()(kernelSizeX); ++k) { + result += s[k + input_offset] * kernel[k + kernel_offset]; + } + } + const int tensor_index = plane_output_offset + indexMapper.mapCudaOutputKernelToTensorOutputOffset(i+first_x, j+first_y); + buffer[tensor_index] = result; + } + } + + __syncthreads(); + } +}; + + +template <typename InputEvaluator, typename Index, typename InputDims> +__global__ void EigenConvolutionKernel3D(InputEvaluator eval, const internal::IndexMapper<Index, InputDims, 3> indexMapper, const float* __restrict kernel, const size_t numPlanes, const size_t numX, const size_t maxX, const size_t numY, const size_t maxY, const size_t numZ, const size_t maxZ, const size_t kernelSizeX, const size_t kernelSizeY, const size_t kernelSizeZ, float* buffer) { + extern __shared__ float s[]; + + // Load inputs to shared memory + const int first_x = blockIdx.x * maxX; + const int last_x = (first_x + maxX < numX ? first_x + maxX : numX) - 1; + const int num_x_input = last_x - first_x + kernelSizeX; + + const int first_y = blockIdx.y * maxY; + const int last_y = (first_y + maxY < numY ? first_y + maxY : numY) - 1; + const int num_y_input = last_y - first_y + kernelSizeY; + + const int first_z = blockIdx.z * maxZ; + const int last_z = (first_z + maxZ < numZ ? first_z + maxZ : numZ) - 1; + const int num_z_input = last_z - first_z + kernelSizeZ; + + for (int p = 0; p < numPlanes; ++p) { + + const int plane_input_offset = indexMapper.mapCudaInputPlaneToTensorInputOffset(p); + const int plane_kernel_offset = 0; + + for (int k = threadIdx.z; k < num_z_input; k += blockDim.z) { + for (int j = threadIdx.y; j < num_y_input; j += blockDim.y) { + for (int i = threadIdx.x; i < num_x_input; i += blockDim.x) { + const int tensor_index = plane_input_offset + indexMapper.mapCudaInputKernelToTensorInputOffset(i+first_x, j+first_y, k+first_z); + s[i + num_x_input * (j + num_y_input * (k + plane_kernel_offset))] = eval.coeff(tensor_index); + } + } + } + + __syncthreads(); + + // Convolution + const int num_z_output = last_z - first_z + 1; + const int num_y_output = last_y - first_y + 1; + const int num_x_output = last_x - first_x + 1; + const int plane_output_offset = indexMapper.mapCudaOutputPlaneToTensorOutputOffset(p); + + for (int k = threadIdx.z; k < num_z_output; k += blockDim.z) { + for (int j = threadIdx.y; j < num_y_output; j += blockDim.y) { + for (int i = threadIdx.x; i < num_x_output; i += blockDim.x) { + float result = 0.0f; + for (int n = 0; n < kernelSizeZ; ++n) { + for (int m = 0; m < kernelSizeY; ++m) { + for (int l = 0; l < kernelSizeX; ++l) { + result += s[i + l + num_x_input * (j + m + num_y_input * (k + n + plane_kernel_offset))] * kernel[l + kernelSizeX * (m + kernelSizeY * n)]; + } + } + } + const int tensor_index = plane_output_offset + indexMapper.mapCudaOutputKernelToTensorOutputOffset(i+first_x, j+first_y, k+first_z); + buffer[tensor_index] = result; + } + } + } + __syncthreads(); + } +}; + + + +template<typename Indices, typename InputArgType, typename KernelArgType> +struct TensorEvaluator<const TensorConvolutionOp<Indices, InputArgType, KernelArgType>, GpuDevice> +{ + typedef TensorConvolutionOp<Indices, InputArgType, KernelArgType> XprType; + + static const int NumDims = internal::array_size<typename TensorEvaluator<InputArgType, GpuDevice>::Dimensions>::value; + static const int NumKernelDims = internal::array_size<Indices>::value; + typedef typename XprType::Index Index; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename TensorEvaluator<KernelArgType, GpuDevice>::Dimensions KernelDimensions; + + enum { + IsAligned = TensorEvaluator<InputArgType, GpuDevice>::IsAligned & TensorEvaluator<KernelArgType, GpuDevice>::IsAligned, + PacketAccess = false, + Layout = TensorEvaluator<InputArgType, GpuDevice>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const GpuDevice& device) + : m_inputImpl(op.inputExpression(), device), m_kernelArg(op.kernelExpression()), m_kernelImpl(op.kernelExpression(), device), m_indices(op.indices()), m_buf(NULL), m_kernel(NULL), m_local_kernel(false), m_device(device) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<InputArgType, GpuDevice>::Layout) == static_cast<int>(TensorEvaluator<KernelArgType, GpuDevice>::Layout)), YOU_MADE_A_PROGRAMMING_MISTAKE); + // Only column major tensors are supported for now. + EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE); + + const typename TensorEvaluator<InputArgType, GpuDevice>::Dimensions& input_dims = m_inputImpl.dimensions(); + const typename TensorEvaluator<KernelArgType, GpuDevice>::Dimensions& kernel_dims = m_kernelImpl.dimensions(); + + m_dimensions = m_inputImpl.dimensions(); + for (int i = 0; i < NumKernelDims; ++i) { + const Index index = op.indices()[i]; + const Index input_dim = input_dims[index]; + const Index kernel_dim = kernel_dims[i]; + const Index result_dim = input_dim - kernel_dim + 1; + m_dimensions[index] = result_dim; + } + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename InputArgType::Scalar Scalar; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* data) { + preloadKernel(); + m_inputImpl.evalSubExprsIfNeeded(NULL); + if (data) { + executeEval(data); + return false; + } else { + m_buf = (Scalar*)m_device.allocate(dimensions().TotalSize() * sizeof(Scalar)); + executeEval(m_buf); + return true; + } + } + + EIGEN_STRONG_INLINE void cleanup() { + m_inputImpl.cleanup(); + if (m_buf) { + m_device.deallocate(m_buf); + m_buf = NULL; + } + if (m_local_kernel) { + m_device.deallocate((void*)m_kernel); + m_local_kernel = false; + } + m_kernel = NULL; + } + + EIGEN_STRONG_INLINE void preloadKernel() { + // Don't make a local copy of the kernel unless we have to (i.e. it's an + // expression that needs to be evaluated) + const Scalar* in_place = m_kernelImpl.data(); + if (in_place) { + m_kernel = in_place; + m_local_kernel = false; + } else { + size_t kernel_sz = m_kernelImpl.dimensions().TotalSize() * sizeof(Scalar); + Scalar* local = (Scalar*)m_device.allocate(kernel_sz); + typedef TensorEvalToOp<const KernelArgType> EvalTo; + EvalTo evalToTmp(local, m_kernelArg); + internal::TensorExecutor<const EvalTo, GpuDevice, TensorEvaluator<KernelArgType, GpuDevice>::PacketAccess>::run(evalToTmp, m_device); + + m_kernel = local; + m_local_kernel = true; + } + } + + static unsigned int ceil(unsigned int num, unsigned int denom) { + const unsigned int rounded_toward_zero = num / denom; + if (num > rounded_toward_zero * denom) { + return rounded_toward_zero + 1; + } + return rounded_toward_zero; + } + + void executeEval(Scalar* data) const { + typedef typename TensorEvaluator<InputArgType, GpuDevice>::Dimensions InputDims; + + const int maxSharedMem = sharedMemPerBlock(); + const int maxThreadsPerBlock = maxCudaThreadsPerBlock(); + const int maxBlocksPerProcessor = maxCudaThreadsPerMultiProcessor() / maxThreadsPerBlock; + const int numMultiProcessors = getNumCudaMultiProcessors(); + const int warpSize = 32; + + switch (NumKernelDims) { + case 1: { + const int kernel_size = m_kernelImpl.dimensions().TotalSize(); + + const int numX = dimensions()[m_indices[0]]; + const int numP = dimensions().TotalSize() / numX; + + int maxX; + dim3 block_size; + if (m_indices[0] == 0) { + // Maximum the reuse + const int inner_dim = ((maxSharedMem / (sizeof(Scalar)) - kernel_size + 1 + 31) / 32) * 32; + maxX = (std::min<int>)(inner_dim, numX); + const int maxP = (std::min<int>)(maxSharedMem / ((kernel_size - 1 + maxX) * sizeof(Scalar)), numP); + block_size.x = (std::min)(maxThreadsPerBlock, maxX); + block_size.y = (std::min<int>)(maxThreadsPerBlock / block_size.x, maxP); + } + else { + // Read as much as possible alongside the inner most dimension, that is the plane + const int inner_dim = maxSharedMem / ((warpSize + kernel_size) * sizeof(Scalar)); + const int maxP = (std::min<int>)(inner_dim, numP); + maxX = (std::min<int>)(maxSharedMem / (inner_dim * sizeof(Scalar)) - kernel_size + 1, numX); + + block_size.x = (std::min)(warpSize, maxX); + block_size.y = (std::min<int>)(maxThreadsPerBlock/block_size.x, maxP); + } + + const int shared_mem = block_size.y * (maxX + kernel_size - 1) * sizeof(Scalar); + assert(shared_mem <= maxSharedMem); + + const int num_x_blocks = ceil(numX, maxX); + const int blocksPerProcessor = (std::min)(maxBlocksPerProcessor, maxSharedMem / shared_mem); + const int num_y_blocks = ceil(numMultiProcessors * blocksPerProcessor, num_x_blocks); + + dim3 num_blocks(num_x_blocks, min<int>(num_y_blocks, ceil(numP, block_size.y))); + + + //cout << "launching 1D kernel with block_size.x: " << block_size.x << " block_size.y: " << block_size.y << " num_blocks.x: " << num_blocks.x << " num_blocks.y: " << num_blocks.y << " maxX: " << maxX << " shared_mem: " << shared_mem << " in stream " << m_device.stream() << endl; + + const array<Index, 1> indices(m_indices[0]); + const array<Index, 1> kernel_dims(m_kernelImpl.dimensions()[0]); + internal::IndexMapper<Index, InputDims, 1> indexMapper(m_inputImpl.dimensions(), kernel_dims, indices); + switch(kernel_size) { + case 4: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel1D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 4>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, 4, data); + break; + } + case 7: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel1D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 7>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, 7, data); + break; + } + default: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel1D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, Dynamic>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, kernel_size, data); + } + } + break; + } + + case 2: { + const int kernel_size_x = m_kernelImpl.dimensions()[0]; + const int kernel_size_y = m_kernelImpl.dimensions()[1]; + + const int numX = dimensions()[m_indices[0]]; + const int numY = dimensions()[m_indices[1]]; + const int numP = dimensions().TotalSize() / (numX*numY); + + const float scaling_factor = sqrtf(static_cast<float>(maxSharedMem) / (sizeof(Scalar) * kernel_size_y * kernel_size_x)); + + // Snap maxX to warp size + int inner_dim = ((static_cast<int>(scaling_factor * kernel_size_x) - kernel_size_x + 1 + 32) / 32) * 32; + const int maxX = (std::min<int>)(inner_dim, numX); + const int maxY = (std::min<int>)(maxSharedMem / (sizeof(Scalar) * (maxX + kernel_size_x - 1)) - kernel_size_y + 1, numY); + const int maxP = (std::min<int>)(maxSharedMem / ((kernel_size_x - 1 + maxX) * (kernel_size_y - 1 + maxY) * sizeof(Scalar)), numP); + + dim3 block_size; + block_size.x = (std::min)(1024, maxX); + block_size.y = (std::min<int>)(1024/block_size.x, maxY); + block_size.z = (std::min<int>)(1024/(block_size.x*block_size.y), maxP); + + const int shared_mem = block_size.z * (maxX + kernel_size_x - 1) * (maxY + kernel_size_y - 1) * sizeof(Scalar); + assert(shared_mem <= maxSharedMem); + + const int num_x_blocks = ceil(numX, maxX); + const int num_y_blocks = ceil(numY, maxY); + const int blocksPerProcessor = (std::min)(maxBlocksPerProcessor, maxSharedMem / shared_mem); + const int num_z_blocks = ceil(numMultiProcessors * blocksPerProcessor, num_x_blocks * num_y_blocks); + + dim3 num_blocks(num_x_blocks, num_y_blocks, min<int>(num_z_blocks, ceil(numP, block_size.z))); + + + //cout << "launching 2D kernel with block_size.x: " << block_size.x << " block_size.y: " << block_size.y << " block_size.z: " << block_size.z << " num_blocks.x: " << num_blocks.x << " num_blocks.y: " << num_blocks.y << " num_blocks.z: " << num_blocks.z << " maxX: " << maxX << " maxY: " << maxY << " maxP: " << maxP << " shared_mem: " << shared_mem << " in stream " << m_device.stream() << endl; + + const array<Index, 2> indices(m_indices[0], m_indices[1]); + const array<Index, 2> kernel_dims(m_kernelImpl.dimensions()[0], m_kernelImpl.dimensions()[1]); + internal::IndexMapper<Index, InputDims, 2> indexMapper(m_inputImpl.dimensions(), kernel_dims, indices); + switch (kernel_size_x) { + case 4: { + switch (kernel_size_y) { + case 7: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel2D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 4, 7>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, 4, 7, data); + break; + } + default: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel2D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 4, Dynamic>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, 4, kernel_size_y, data); + break; + } + } + break; + } + case 7: { + switch (kernel_size_y) { + case 4: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel2D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 7, 4>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, 7, 4, data); + break; + } + default: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel2D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, 7, Dynamic>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, 7, kernel_size_y, data); + break; + } + } + break; + } + default: { + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel2D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims, Dynamic, Dynamic>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, kernel_size_x, kernel_size_y, data); + break; + } + } + break; + } + + case 3: { + const int kernel_size_x = m_kernelImpl.dimensions()[0]; + const int kernel_size_y = m_kernelImpl.dimensions()[1]; + const int kernel_size_z = m_kernelImpl.dimensions()[2]; + + const int numX = dimensions()[m_indices[0]]; + const int numY = dimensions()[m_indices[1]]; + const int numZ = dimensions()[m_indices[2]]; + const int numP = dimensions().TotalSize() / (numX*numY*numZ); + + const int maxX = (std::min<int>)(128, (std::min<int>)(maxSharedMem / (sizeof(Scalar) * kernel_size_y * kernel_size_z) - kernel_size_x + 1, numX)); + const int maxY = (std::min<int>)(128, (std::min<int>)(maxSharedMem / (sizeof(Scalar) * (maxX + kernel_size_x - 1) * kernel_size_z) - kernel_size_y + 1, numY)); + const int maxZ = (std::min<int>)(128, (std::min<int>)(maxSharedMem / (sizeof(Scalar) * (maxX + kernel_size_x - 1) * (maxY + kernel_size_y - 1)) - kernel_size_z + 1, numZ)); + + dim3 block_size; + block_size.x = (std::min)(32, maxX); + block_size.y = (std::min)(32, maxY); + block_size.z = (std::min<int>)(1024/(block_size.x*block_size.y), maxZ); + dim3 num_blocks(ceil(numX, maxX), ceil(numY, maxY), ceil(numZ, maxZ)); + + const int shared_mem = (maxX + kernel_size_x - 1) * (maxY + kernel_size_y - 1) * (maxZ + kernel_size_z - 1) * sizeof(Scalar); + assert(shared_mem <= maxSharedMem); + + //cout << "launching 3D kernel with block_size.x: " << block_size.x << " block_size.y: " << block_size.y << " block_size.z: " << block_size.z << " num_blocks.x: " << num_blocks.x << " num_blocks.y: " << num_blocks.y << " num_blocks.z: " << num_blocks.z << " shared_mem: " << shared_mem << " in stream " << m_device.stream() << endl; + const array<Index, 3> indices(m_indices[0], m_indices[1], m_indices[2]); + const array<Index, 3> kernel_dims(m_kernelImpl.dimensions()[0], m_kernelImpl.dimensions()[1], m_kernelImpl.dimensions()[2]); + internal::IndexMapper<Index, InputDims, 3> indexMapper(m_inputImpl.dimensions(), kernel_dims, indices); + + LAUNCH_CUDA_KERNEL((EigenConvolutionKernel3D<TensorEvaluator<InputArgType, GpuDevice>, Index, InputDims>), num_blocks, block_size, shared_mem, m_device, m_inputImpl, indexMapper, m_kernel, numP, numX, maxX, numY, maxY, numZ, maxZ, kernel_size_x, kernel_size_y, kernel_size_z, data); + break; + } + + default: { + assert(false && "not supported yet"); + } + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + eigen_assert(m_buf); + eigen_assert(index < m_dimensions.TotalSize()); + return m_buf[index]; + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(const Index index) const + { + eigen_assert(m_buf); + eigen_assert(index < m_dimensions.TotalSize()); + return internal::ploadt<PacketReturnType, LoadMode>(m_buf+index); + } + + private: + // No assignment (copies are needed by the kernels) + TensorEvaluator& operator = (const TensorEvaluator&); + + TensorEvaluator<InputArgType, GpuDevice> m_inputImpl; + TensorEvaluator<KernelArgType, GpuDevice> m_kernelImpl; + KernelArgType m_kernelArg; + Indices m_indices; + Dimensions m_dimensions; + Scalar* m_buf; + const Scalar* m_kernel; + bool m_local_kernel; + + const GpuDevice& m_device; +}; +#endif + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_CONVOLUTION_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorDevice.h b/unsupported/Eigen/CXX11/src/Tensor/TensorDevice.h new file mode 100644 index 000000000..649bdb308 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorDevice.h @@ -0,0 +1,126 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_DEVICE_H +#define EIGEN_CXX11_TENSOR_TENSOR_DEVICE_H + +namespace Eigen { + +/** \class TensorDevice + * \ingroup CXX11_Tensor_Module + * + * \brief Pseudo expression providing an operator = that will evaluate its argument + * on the specified computing 'device' (GPU, thread pool, ...) + * + * Example: + * C.device(EIGEN_GPU) = A + B; + * + * Todo: thread pools. + * Todo: operator +=, -=, *= and so on. + */ + +template <typename ExpressionType, typename DeviceType> class TensorDevice { + public: + TensorDevice(const DeviceType& device, ExpressionType& expression) : m_device(device), m_expression(expression) {} + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator=(const OtherDerived& other) { + typedef TensorAssignOp<ExpressionType, const OtherDerived> Assign; + Assign assign(m_expression, other); + static const bool Vectorize = TensorEvaluator<const Assign, DeviceType>::PacketAccess; + internal::TensorExecutor<const Assign, DeviceType, Vectorize>::run(assign, m_device); + return *this; + } + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator+=(const OtherDerived& other) { + typedef typename OtherDerived::Scalar Scalar; + typedef TensorCwiseBinaryOp<internal::scalar_sum_op<Scalar>, const ExpressionType, const OtherDerived> Sum; + Sum sum(m_expression, other); + typedef TensorAssignOp<ExpressionType, const Sum> Assign; + Assign assign(m_expression, sum); + static const bool Vectorize = TensorEvaluator<const Assign, DeviceType>::PacketAccess; + internal::TensorExecutor<const Assign, DeviceType, Vectorize>::run(assign, m_device); + return *this; + } + + protected: + const DeviceType& m_device; + ExpressionType& m_expression; +}; + + +#ifdef EIGEN_USE_THREADS +template <typename ExpressionType> class TensorDevice<ExpressionType, ThreadPoolDevice> { + public: + TensorDevice(const ThreadPoolDevice& device, ExpressionType& expression) : m_device(device), m_expression(expression) {} + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator=(const OtherDerived& other) { + typedef TensorAssignOp<ExpressionType, const OtherDerived> Assign; + Assign assign(m_expression, other); + static const bool Vectorize = TensorEvaluator<const Assign, ThreadPoolDevice>::PacketAccess; + internal::TensorExecutor<const Assign, ThreadPoolDevice, Vectorize>::run(assign, m_device); + return *this; + } + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator+=(const OtherDerived& other) { + typedef typename OtherDerived::Scalar Scalar; + typedef TensorCwiseBinaryOp<internal::scalar_sum_op<Scalar>, const ExpressionType, const OtherDerived> Sum; + Sum sum(m_expression, other); + typedef TensorAssignOp<ExpressionType, const Sum> Assign; + Assign assign(m_expression, sum); + static const bool Vectorize = TensorEvaluator<const Assign, ThreadPoolDevice>::PacketAccess; + internal::TensorExecutor<const Assign, ThreadPoolDevice, Vectorize>::run(assign, m_device); + return *this; + } + + protected: + const ThreadPoolDevice& m_device; + ExpressionType& m_expression; +}; +#endif + + +#if defined(EIGEN_USE_GPU) && defined(__CUDACC__) +template <typename ExpressionType> class TensorDevice<ExpressionType, GpuDevice> +{ + public: + TensorDevice(const GpuDevice& device, ExpressionType& expression) : m_device(device), m_expression(expression) {} + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator=(const OtherDerived& other) { + typedef TensorAssignOp<ExpressionType, const OtherDerived> Assign; + Assign assign(m_expression, other); + internal::TensorExecutor<const Assign, GpuDevice, false>::run(assign, m_device); + return *this; + } + + template<typename OtherDerived> + EIGEN_STRONG_INLINE TensorDevice& operator+=(const OtherDerived& other) { + typedef typename OtherDerived::Scalar Scalar; + typedef TensorCwiseBinaryOp<internal::scalar_sum_op<Scalar>, const ExpressionType, const OtherDerived> Sum; + Sum sum(m_expression, other); + typedef TensorAssignOp<ExpressionType, const Sum> Assign; + Assign assign(m_expression, sum); + internal::TensorExecutor<const Assign, GpuDevice, false>::run(assign, m_device); + return *this; + } + + protected: + const GpuDevice& m_device; + ExpressionType m_expression; +}; +#endif + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_DEVICE_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorDeviceType.h b/unsupported/Eigen/CXX11/src/Tensor/TensorDeviceType.h new file mode 100644 index 000000000..efd207507 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorDeviceType.h @@ -0,0 +1,190 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_DEVICE_TYPE_H +#define EIGEN_CXX11_TENSOR_TENSOR_DEVICE_TYPE_H + + +namespace Eigen { + +// Default device for the machine (typically a single cpu core) +struct DefaultDevice { + EIGEN_STRONG_INLINE void* allocate(size_t num_bytes) const { + return internal::aligned_malloc(num_bytes); + } + EIGEN_STRONG_INLINE void deallocate(void* buffer) const { + internal::aligned_free(buffer); + } + EIGEN_STRONG_INLINE void memcpy(void* dst, const void* src, size_t n) const { + ::memcpy(dst, src, n); + } + EIGEN_STRONG_INLINE void memset(void* buffer, int c, size_t n) const { + ::memset(buffer, c, n); + } + + EIGEN_STRONG_INLINE size_t numThreads() const { + return 1; + } +}; + + +// Multiple cpu cores +// We should really use a thread pool here but first we need to find a portable thread pool library. +#ifdef EIGEN_USE_THREADS + +typedef std::future<void> Future; +typedef std::promise<void> Promise; + +static EIGEN_STRONG_INLINE void wait_until_ready(const Future* f) { + f->wait(); +} +static EIGEN_STRONG_INLINE void get_when_ready(Future* f) { + f->get(); +} + + +struct ThreadPoolDevice { + ThreadPoolDevice(size_t num_cores) : num_threads_(num_cores) { } + + EIGEN_STRONG_INLINE void* allocate(size_t num_bytes) const { + return internal::aligned_malloc(num_bytes); + } + + EIGEN_STRONG_INLINE void deallocate(void* buffer) const { + internal::aligned_free(buffer); + } + + EIGEN_STRONG_INLINE void memcpy(void* dst, const void* src, size_t n) const { + ::memcpy(dst, src, n); + } + + EIGEN_STRONG_INLINE void memset(void* buffer, int c, size_t n) const { + ::memset(buffer, c, n); + } + + EIGEN_STRONG_INLINE size_t numThreads() const { + return num_threads_; + } + + template <class Function, class... Args> + EIGEN_STRONG_INLINE Future enqueue(Function&& f, Args&&... args) const { + return std::async(std::launch::async, f, args...); + } + template <class Function, class... Args> + EIGEN_STRONG_INLINE void enqueueNoFuture(Function&& f, Args&&... args) const { + std::async(std::launch::async, f, args...); + } + + private: + size_t num_threads_; +}; + +#endif + + +// GPU offloading +#ifdef EIGEN_USE_GPU +static cudaDeviceProp m_deviceProperties; +static bool m_devicePropInitialized = false; + +static void initializeDeviceProp() { + if (!m_devicePropInitialized) { + assert(cudaGetDeviceProperties(&m_deviceProperties, 0) == cudaSuccess); + m_devicePropInitialized = true; + } +} + +static inline int getNumCudaMultiProcessors() { + initializeDeviceProp(); + return m_deviceProperties.multiProcessorCount; +} +static inline int maxCudaThreadsPerBlock() { + initializeDeviceProp(); + return m_deviceProperties.maxThreadsPerBlock; +} +static inline int maxCudaThreadsPerMultiProcessor() { + initializeDeviceProp(); + return m_deviceProperties.maxThreadsPerMultiProcessor; +} +static inline int sharedMemPerBlock() { + initializeDeviceProp(); + return m_deviceProperties.sharedMemPerBlock; +} + +static inline void setCudaSharedMemConfig(cudaSharedMemConfig config) { + cudaError_t status = cudaDeviceSetSharedMemConfig(config); + assert(status == cudaSuccess); +} + +struct GpuDevice { + // The cudastream is not owned: the caller is responsible for its initialization and eventual destruction. + GpuDevice(const cudaStream_t* stream) : stream_(stream) { eigen_assert(stream); } + + EIGEN_STRONG_INLINE const cudaStream_t& stream() const { return *stream_; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void* allocate(size_t num_bytes) const { +#ifndef __CUDA_ARCH__ + void* result; + assert(cudaMalloc(&result, num_bytes) == cudaSuccess); + assert(result != NULL); + return result; +#else + assert(false && "The default device should be used instead to generate kernel code"); + return NULL; +#endif + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void deallocate(void* buffer) const { +#ifndef __CUDA_ARCH__ + assert(buffer != NULL); + assert(cudaFree(buffer) == cudaSuccess); +#else + assert(false && "The default device should be used instead to generate kernel code"); +#endif + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void memcpy(void* dst, const void* src, size_t n) const { +#ifndef __CUDA_ARCH__ + assert(cudaMemcpyAsync(dst, src, n, cudaMemcpyDeviceToDevice, *stream_) == cudaSuccess); +#else + assert(false && "The default device should be used instead to generate kernel code"); +#endif + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void memset(void* buffer, int c, size_t n) const { +#ifndef __CUDA_ARCH__ + assert(cudaMemsetAsync(buffer, c, n, *stream_) == cudaSuccess); +#else + assert(false && "The default device should be used instead to generate kernel code"); +#endif + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t numThreads() const { + // FIXME + return 32; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void synchronize() const { + cudaStreamSynchronize(*stream_); + } + + private: + // TODO: multigpu. + const cudaStream_t* stream_; +}; + +#define LAUNCH_CUDA_KERNEL(kernel, gridsize, blocksize, sharedmem, device, ...) \ + (kernel) <<< (gridsize), (blocksize), (sharedmem), (device).stream() >>> (__VA_ARGS__); \ + assert(cudaGetLastError() == cudaSuccess); + +#endif + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_DEVICE_TYPE_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorDimensions.h b/unsupported/Eigen/CXX11/src/Tensor/TensorDimensions.h new file mode 100644 index 000000000..2ad52b2f9 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorDimensions.h @@ -0,0 +1,380 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_DIMENSIONS_H +#define EIGEN_CXX11_TENSOR_TENSOR_DIMENSIONS_H + + +namespace Eigen { + +/** \internal + * + * \class TensorDimensions + * \ingroup CXX11_Tensor_Module + * + * \brief Set of classes used to encode and store the dimensions of a Tensor. + * + * The Sizes class encodes as part of the type the number of dimensions and the + * sizes corresponding to each dimension. It uses no storage space since it is + * entirely known at compile time. + * The DSizes class is its dynamic sibling: the number of dimensions is known + * at compile time but the sizes are set during execution. + * + * \sa Tensor + */ + +// Can't use std::pair on cuda devices +template <typename Index> struct IndexPair { + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE IndexPair() : first(0), second(0) { } + EIGEN_DEVICE_FUNC EIGEN_ALWAYS_INLINE IndexPair(Index f, Index s) : first(f), second(s) { } + Index first; + Index second; +}; + +// Boilerplate code +namespace internal { + +template<std::size_t n, typename Dimension> struct dget { + static const std::size_t value = get<n, Dimension>::value; +}; + + +template<typename Index, std::size_t NumIndices, std::size_t n, bool RowMajor> +struct fixed_size_tensor_index_linearization_helper +{ + template <typename Dimensions> EIGEN_DEVICE_FUNC + static inline Index run(array<Index, NumIndices> const& indices, + const Dimensions& dimensions) + { + return array_get<RowMajor ? n : (NumIndices - n - 1)>(indices) + + dget<RowMajor ? n : (NumIndices - n - 1), Dimensions>::value * + fixed_size_tensor_index_linearization_helper<Index, NumIndices, n - 1, RowMajor>::run(indices, dimensions); + } +}; + +template<typename Index, std::size_t NumIndices, bool RowMajor> +struct fixed_size_tensor_index_linearization_helper<Index, NumIndices, 0, RowMajor> +{ + template <typename Dimensions> EIGEN_DEVICE_FUNC + static inline Index run(array<Index, NumIndices> const& indices, + const Dimensions&) + { + return array_get<RowMajor ? 0 : NumIndices - 1>(indices); + } +}; + +} // end namespace internal + + +// Fixed size +#ifndef EIGEN_EMULATE_CXX11_META_H +template <typename std::size_t... Indices> +struct Sizes : internal::numeric_list<std::size_t, Indices...> { + typedef internal::numeric_list<std::size_t, Indices...> Base; + static const std::size_t total_size = internal::arg_prod(Indices...); + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t rank() const { + return Base::count; + } + + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE std::size_t TotalSize() { + return internal::arg_prod(Indices...); + } + + Sizes() { } + template <typename DenseIndex> + explicit Sizes(const array<DenseIndex, Base::count>& /*indices*/) { + // todo: add assertion + } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template <typename... DenseIndex> Sizes(DenseIndex...) { } + explicit Sizes(std::initializer_list<std::size_t> /*l*/) { + // todo: add assertion + } +#endif + + template <typename T> Sizes& operator = (const T& /*other*/) { + // add assertion failure if the size of other is different + return *this; + } + + template <typename DenseIndex> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + size_t IndexOfColMajor(const array<DenseIndex, Base::count>& indices) const { + return internal::fixed_size_tensor_index_linearization_helper<DenseIndex, Base::count, Base::count - 1, false>::run(indices, *static_cast<const Base*>(this)); + } + template <typename DenseIndex> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + size_t IndexOfRowMajor(const array<DenseIndex, Base::count>& indices) const { + return internal::fixed_size_tensor_index_linearization_helper<DenseIndex, Base::count, Base::count - 1, true>::run(indices, *static_cast<const Base*>(this)); + } +}; + +template <typename std::size_t... Indices> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE std::size_t array_prod(const Sizes<Indices...>&) { + return Sizes<Indices...>::total_size; +} + +#else + +template <std::size_t n> +struct non_zero_size { + typedef internal::type2val<std::size_t, n> type; +}; +template <> +struct non_zero_size<0> { + typedef internal::null_type type; +}; + +template <std::size_t V1=0, std::size_t V2=0, std::size_t V3=0, std::size_t V4=0, std::size_t V5=0> struct Sizes { + typedef typename internal::make_type_list<typename non_zero_size<V1>::type, typename non_zero_size<V2>::type, typename non_zero_size<V3>::type, typename non_zero_size<V4>::type, typename non_zero_size<V5>::type >::type Base; + static const size_t count = Base::count; + static const std::size_t total_size = internal::arg_prod<Base>::value; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t rank() const { + return count; + } + + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t TotalSize() { + return internal::arg_prod<Base>::value; + } + + Sizes() { } + template <typename DenseIndex> + explicit Sizes(const array<DenseIndex, Base::count>& indices) { + // todo: add assertion + } +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template <typename... DenseIndex> Sizes(DenseIndex... indices) { } + explicit Sizes(std::initializer_list<std::size_t> l) { + // todo: add assertion + } +#else + EIGEN_DEVICE_FUNC explicit Sizes(const DenseIndex i0) { + } + EIGEN_DEVICE_FUNC explicit Sizes(const DenseIndex i0, const DenseIndex i1) { + } + EIGEN_DEVICE_FUNC explicit Sizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2) { + } + EIGEN_DEVICE_FUNC explicit Sizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2, const DenseIndex i3) { + } + EIGEN_DEVICE_FUNC explicit Sizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2, const DenseIndex i3, const DenseIndex i4) { + } +#endif + + template <typename T> Sizes& operator = (const T& other) { + // to do: check the size of other + return *this; + } + + template <typename DenseIndex> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + size_t IndexOfColMajor(const array<DenseIndex, Base::count>& indices) const { + return internal::fixed_size_tensor_index_linearization_helper<DenseIndex, Base::count, Base::count - 1, false>::run(indices, *static_cast<const Base*>(this); + } + template <typename DenseIndex> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + size_t IndexOfRowMajor(const array<DenseIndex, Base::count>& indices) const { + return internal::fixed_size_tensor_index_linearization_helper<DenseIndex, Base::count, Base::count - 1, true>::run(indices, *static_cast<const Base*>(this); + } +}; + +template <std::size_t V1, std::size_t V2, std::size_t V3, std::size_t V4, std::size_t V5> +EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE std::size_t array_prod(const Sizes<V1, V2, V3, V4, V5>&) { + return Sizes<V1, V2, V3, V4, V5>::total_size; +}; + +#endif + +// Boilerplate +namespace internal { +template<typename Index, std::size_t NumIndices, std::size_t n, bool RowMajor> +struct tensor_index_linearization_helper +{ + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Index run(array<Index, NumIndices> const& indices, array<Index, NumIndices> const& dimensions) + { + return array_get<RowMajor ? n : (NumIndices - n - 1)>(indices) + + array_get<RowMajor ? n : (NumIndices - n - 1)>(dimensions) * + tensor_index_linearization_helper<Index, NumIndices, n - 1, RowMajor>::run(indices, dimensions); + } +}; + +template<typename Index, std::size_t NumIndices, bool RowMajor> +struct tensor_index_linearization_helper<Index, NumIndices, 0, RowMajor> +{ + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Index run(array<Index, NumIndices> const& indices, array<Index, NumIndices> const&) + { + return array_get<RowMajor ? 0 : NumIndices - 1>(indices); + } +}; +} // end namespace internal + + + +// Dynamic size +template <typename DenseIndex, std::size_t NumDims> +struct DSizes : array<DenseIndex, NumDims> { + typedef array<DenseIndex, NumDims> Base; + static const std::size_t count = NumDims; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t rank() const { + return NumDims; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t TotalSize() const { + return internal::array_prod(*static_cast<const Base*>(this)); + } + + EIGEN_DEVICE_FUNC DSizes() { + for (int i = 0 ; i < NumDims; ++i) { + (*this)[i] = 0; + } + } + EIGEN_DEVICE_FUNC explicit DSizes(const array<DenseIndex, NumDims>& a) : Base(a) { } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE explicit DSizes(DenseIndex firstDimension, IndexTypes... otherDimensions) { + EIGEN_STATIC_ASSERT(sizeof...(otherDimensions) + 1 == NumDims, YOU_MADE_A_PROGRAMMING_MISTAKE) + (*this) = array<DenseIndex, NumDims>{{firstDimension, otherDimensions...}}; + } +#else + EIGEN_DEVICE_FUNC explicit DSizes(const DenseIndex i0) { + eigen_assert(NumDims == 1); + (*this)[0] = i0; + } + EIGEN_DEVICE_FUNC explicit DSizes(const DenseIndex i0, const DenseIndex i1) { + eigen_assert(NumDims == 2); + (*this)[0] = i0; + (*this)[1] = i1; + } + EIGEN_DEVICE_FUNC explicit DSizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2) { + eigen_assert(NumDims == 3); + (*this)[0] = i0; + (*this)[1] = i1; + (*this)[2] = i2; + } + EIGEN_DEVICE_FUNC explicit DSizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2, const DenseIndex i3) { + eigen_assert(NumDims == 4); + (*this)[0] = i0; + (*this)[1] = i1; + (*this)[2] = i2; + (*this)[3] = i3; + } + EIGEN_DEVICE_FUNC explicit DSizes(const DenseIndex i0, const DenseIndex i1, const DenseIndex i2, const DenseIndex i3, const DenseIndex i4) { + eigen_assert(NumDims == 5); + (*this)[0] = i0; + (*this)[1] = i1; + (*this)[2] = i2; + (*this)[3] = i3; + (*this)[4] = i4; + } +#endif + + EIGEN_DEVICE_FUNC DSizes& operator = (const array<DenseIndex, NumDims>& other) { + *static_cast<Base*>(this) = other; + return *this; + } + + // A constexpr would be so much better here + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t IndexOfColMajor(const array<DenseIndex, NumDims>& indices) const { + return internal::tensor_index_linearization_helper<DenseIndex, NumDims, NumDims - 1, false>::run(indices, *static_cast<const Base*>(this)); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE size_t IndexOfRowMajor(const array<DenseIndex, NumDims>& indices) const { + return internal::tensor_index_linearization_helper<DenseIndex, NumDims, NumDims - 1, true>::run(indices, *static_cast<const Base*>(this)); + } +}; + + + + +// Boilerplate +namespace internal { +template<typename Index, std::size_t NumIndices, std::size_t n, bool RowMajor> +struct tensor_vsize_index_linearization_helper +{ + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Index run(array<Index, NumIndices> const& indices, std::vector<DenseIndex> const& dimensions) + { + return array_get<RowMajor ? n : (NumIndices - n - 1)>(indices) + + array_get<RowMajor ? n : (NumIndices - n - 1)>(dimensions) * + tensor_vsize_index_linearization_helper<Index, NumIndices, n - 1, RowMajor>::run(indices, dimensions); + } +}; + +template<typename Index, std::size_t NumIndices, bool RowMajor> +struct tensor_vsize_index_linearization_helper<Index, NumIndices, 0, RowMajor> +{ + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Index run(array<Index, NumIndices> const& indices, std::vector<DenseIndex> const&) + { + return array_get<RowMajor ? 0 : NumIndices - 1>(indices); + } +}; +} // end namespace internal + + +namespace internal { + +template <typename DenseIndex, std::size_t NumDims> struct array_size<const DSizes<DenseIndex, NumDims> > { + static const size_t value = NumDims; +}; +template <typename DenseIndex, std::size_t NumDims> struct array_size<DSizes<DenseIndex, NumDims> > { + static const size_t value = NumDims; +}; +#ifndef EIGEN_EMULATE_CXX11_META_H +template <typename std::size_t... Indices> struct array_size<const Sizes<Indices...> > { +static const size_t value = Sizes<Indices...>::count; +}; +template <typename std::size_t... Indices> struct array_size<Sizes<Indices...> > { +static const size_t value = Sizes<Indices...>::count; +}; +template <std::size_t n, typename std::size_t... Indices> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE std::size_t array_get(const Sizes<Indices...>&) { + return get<n, internal::numeric_list<std::size_t, Indices...> >::value; +} +#else +template <std::size_t V1, std::size_t V2, std::size_t V3, std::size_t V4, std::size_t V5> struct array_size<const Sizes<V1,V2,V3,V4,V5> > { + static const size_t value = Sizes<V1,V2,V3,V4,V5>::count; +}; +template <std::size_t V1, std::size_t V2, std::size_t V3, std::size_t V4, std::size_t V5> struct array_size<Sizes<V1,V2,V3,V4,V5> > { + static const size_t value = Sizes<V1,V2,V3,V4,V5>::count; +}; +template <std::size_t n, std::size_t V1, std::size_t V2, std::size_t V3, std::size_t V4, std::size_t V5> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE std::size_t array_get(const Sizes<V1,V2,V3,V4,V5>& a) { + return get<n, typename Sizes<V1,V2,V3,V4,V5>::Base>::value; +}; + +#endif + + +template <typename Dims1, typename Dims2, size_t n> +struct sizes_match_up_to_dim { + static inline bool run(Dims1& dims1, Dims2& dims2) { + return (array_get<n>(dims1) == array_get<n>(dims2)) & + sizes_match_up_to_dim<Dims1, Dims2, n-1>::run(dims1, dims2); + } +}; +template <typename Dims1, typename Dims2> +struct sizes_match_up_to_dim<Dims1, Dims2, 0> { + static inline bool run(Dims1& dims1, Dims2& dims2) { + return (array_get<0>(dims1) == array_get<0>(dims2)); + } +}; + +} // end namespace internal + + +template <typename Dims1, typename Dims2> +bool dimensions_match(Dims1& dims1, Dims2& dims2) { + if (internal::array_size<Dims1>::value != internal::array_size<Dims2>::value) { + return false; + } + return internal::sizes_match_up_to_dim<Dims1, Dims2, internal::array_size<Dims1>::value-1>::run(dims1, dims2); +} + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_DIMENSIONS_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorEvalTo.h b/unsupported/Eigen/CXX11/src/Tensor/TensorEvalTo.h new file mode 100644 index 000000000..883e6cab1 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorEvalTo.h @@ -0,0 +1,154 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_EVAL_TO_H +#define EIGEN_CXX11_TENSOR_TENSOR_EVAL_TO_H + +namespace Eigen { + +/** \class TensorForcedEval + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor reshaping class. + * + * + */ +namespace internal { +template<typename XprType> +struct traits<TensorEvalToOp<XprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs are different. + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename XprType> +struct eval<TensorEvalToOp<XprType>, Eigen::Dense> +{ + typedef const TensorEvalToOp<XprType>& type; +}; + +template<typename XprType> +struct nested<TensorEvalToOp<XprType>, 1, typename eval<TensorEvalToOp<XprType> >::type> +{ + typedef TensorEvalToOp<XprType> type; +}; + +} // end namespace internal + + + + +template<typename XprType> +class TensorEvalToOp : public TensorBase<TensorEvalToOp<XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorEvalToOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorEvalToOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorEvalToOp>::type Nested; + typedef typename Eigen::internal::traits<TensorEvalToOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorEvalToOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvalToOp(CoeffReturnType* buffer, const XprType& expr) + : m_xpr(expr), m_buffer(buffer) {} + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC CoeffReturnType* buffer() const { return m_buffer; } + + protected: + typename XprType::Nested m_xpr; + CoeffReturnType* m_buffer; +}; + + + +template<typename ArgType, typename Device> +struct TensorEvaluator<const TensorEvalToOp<ArgType>, Device> +{ + typedef TensorEvalToOp<ArgType> XprType; + typedef typename ArgType::Scalar Scalar; + typedef typename ArgType::Packet Packet; + typedef typename TensorEvaluator<ArgType, Device>::Dimensions Dimensions; + + enum { + IsAligned = true, + PacketAccess = true, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_device(device), m_buffer(op.buffer()) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE ~TensorEvaluator() { + } + + typedef typename XprType::Index Index; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const { return m_impl.dimensions(); } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void evalScalar(Index i) { + m_buffer[i] = m_impl.coeff(i); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void evalPacket(Index i) { + internal::pstoret<CoeffReturnType, PacketReturnType, Aligned>(m_buffer + i, m_impl.template packet<TensorEvaluator<ArgType, Device>::IsAligned ? Aligned : Unaligned>(i)); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_buffer[index]; + } + + template<int LoadMode> + EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return internal::ploadt<Packet, LoadMode>(m_buffer + index); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return NULL; } + + private: + TensorEvaluator<ArgType, Device> m_impl; + const Device& m_device; + CoeffReturnType* m_buffer; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_EVAL_TO_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorEvaluator.h b/unsupported/Eigen/CXX11/src/Tensor/TensorEvaluator.h new file mode 100644 index 000000000..d084880de --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorEvaluator.h @@ -0,0 +1,427 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_EVALUATOR_H +#define EIGEN_CXX11_TENSOR_TENSOR_EVALUATOR_H + +namespace Eigen { + +/** \class TensorEvaluator + * \ingroup CXX11_Tensor_Module + * + * \brief The tensor evaluator classes. + * + * These classes are responsible for the evaluation of the tensor expression. + * + * TODO: add support for more types of expressions, in particular expressions + * leading to lvalues (slicing, reshaping, etc...) + */ + +// Generic evaluator +template<typename Derived, typename Device> +struct TensorEvaluator +{ + typedef typename Derived::Index Index; + typedef typename Derived::Scalar Scalar; + typedef typename Derived::Packet Packet; + typedef typename Derived::Scalar CoeffReturnType; + typedef typename Derived::Packet PacketReturnType; + typedef typename Derived::Dimensions Dimensions; + + // NumDimensions is -1 for variable dim tensors + static const int NumCoords = internal::traits<Derived>::NumDimensions > 0 ? + internal::traits<Derived>::NumDimensions : 0; + + enum { + IsAligned = Derived::IsAligned, + PacketAccess = Derived::PacketAccess, + Layout = Derived::Layout, + CoordAccess = NumCoords > 0, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const Derived& m, const Device& device) + : m_data(const_cast<Scalar*>(m.data())), m_dims(m.dimensions()), m_device(device) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dims; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType* dest) { + if (dest) { + m_device.memcpy((void*)dest, m_data, sizeof(Scalar) * m_dims.TotalSize()); + return false; + } + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const { + eigen_assert(m_data); + return m_data[index]; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) { + eigen_assert(m_data); + return m_data[index]; + } + + template<int LoadMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + PacketReturnType packet(Index index) const + { + return internal::ploadt<Packet, LoadMode>(m_data + index); + } + + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const Packet& x) + { + return internal::pstoret<Scalar, Packet, StoreMode>(m_data + index, x); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<DenseIndex, NumCoords>& coords) const { + eigen_assert(m_data); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return m_data[m_dims.IndexOfColMajor(coords)]; + } else { + return m_data[m_dims.IndexOfRowMajor(coords)]; + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(const array<DenseIndex, NumCoords>& coords) { + eigen_assert(m_data); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return m_data[m_dims.IndexOfColMajor(coords)]; + } else { + return m_data[m_dims.IndexOfRowMajor(coords)]; + } + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return m_data; } + + protected: + Scalar* m_data; + Dimensions m_dims; + const Device& m_device; +}; + + +// Default evaluator for rvalues +template<typename Derived, typename Device> +struct TensorEvaluator<const Derived, Device> +{ + typedef typename Derived::Index Index; + typedef typename Derived::Scalar Scalar; + typedef typename Derived::Packet Packet; + typedef typename Derived::Scalar CoeffReturnType; + typedef typename Derived::Packet PacketReturnType; + typedef typename Derived::Dimensions Dimensions; + + // NumDimensions is -1 for variable dim tensors + static const int NumCoords = internal::traits<Derived>::NumDimensions > 0 ? + internal::traits<Derived>::NumDimensions : 0; + + enum { + IsAligned = Derived::IsAligned, + PacketAccess = Derived::PacketAccess, + Layout = Derived::Layout, + CoordAccess = NumCoords > 0, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const Derived& m, const Device&) + : m_data(m.data()), m_dims(m.dimensions()) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dims; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { return true; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const { + eigen_assert(m_data); +#ifdef __CUDA_ARCH__ + return __ldg(m_data+index); +#else + return m_data[index]; +#endif + } + + template<int LoadMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + PacketReturnType packet(Index index) const + { + return internal::ploadt_ro<Packet, LoadMode>(m_data + index); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<DenseIndex, NumCoords>& coords) const { + eigen_assert(m_data); + const Index index = (static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? m_dims.IndexOfColMajor(coords) + : m_dims.IndexOfRowMajor(coords); +#ifdef __CUDA_ARCH__ + return __ldg(m_data+index); +#else + return m_data[index]; +#endif + } + + EIGEN_DEVICE_FUNC const Scalar* data() const { return m_data; } + + protected: + const Scalar* m_data; + Dimensions m_dims; +}; + + + + +// -------------------- CwiseNullaryOp -------------------- + +template<typename NullaryOp, typename ArgType, typename Device> +struct TensorEvaluator<const TensorCwiseNullaryOp<NullaryOp, ArgType>, Device> +{ + typedef TensorCwiseNullaryOp<NullaryOp, ArgType> XprType; + + enum { + IsAligned = true, + PacketAccess = internal::functor_traits<NullaryOp>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC + TensorEvaluator(const XprType& op, const Device& device) + : m_functor(op.functor()), m_argImpl(op.nestedExpression(), device) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename internal::traits<XprType>::Scalar CoeffReturnType; + typedef typename internal::traits<XprType>::Packet PacketReturnType; + typedef typename TensorEvaluator<ArgType, Device>::Dimensions Dimensions; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const { return m_argImpl.dimensions(); } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { return true; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { } + + EIGEN_DEVICE_FUNC CoeffReturnType coeff(Index index) const + { + return m_functor(index); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return m_functor.packetOp(index); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return NULL; } + + private: + const NullaryOp m_functor; + TensorEvaluator<ArgType, Device> m_argImpl; +}; + + + +// -------------------- CwiseUnaryOp -------------------- + +template<typename UnaryOp, typename ArgType, typename Device> +struct TensorEvaluator<const TensorCwiseUnaryOp<UnaryOp, ArgType>, Device> +{ + typedef TensorCwiseUnaryOp<UnaryOp, ArgType> XprType; + + enum { + IsAligned = TensorEvaluator<ArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess & internal::functor_traits<UnaryOp>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) + : m_functor(op.functor()), + m_argImpl(op.nestedExpression(), device) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename internal::traits<XprType>::Scalar CoeffReturnType; + typedef typename internal::traits<XprType>::Packet PacketReturnType; + typedef typename TensorEvaluator<ArgType, Device>::Dimensions Dimensions; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const { return m_argImpl.dimensions(); } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + m_argImpl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_argImpl.cleanup(); + } + + EIGEN_DEVICE_FUNC CoeffReturnType coeff(Index index) const + { + return m_functor(m_argImpl.coeff(index)); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return m_functor.packetOp(m_argImpl.template packet<LoadMode>(index)); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return NULL; } + + private: + const UnaryOp m_functor; + TensorEvaluator<ArgType, Device> m_argImpl; +}; + + +// -------------------- CwiseBinaryOp -------------------- + +template<typename BinaryOp, typename LeftArgType, typename RightArgType, typename Device> +struct TensorEvaluator<const TensorCwiseBinaryOp<BinaryOp, LeftArgType, RightArgType>, Device> +{ + typedef TensorCwiseBinaryOp<BinaryOp, LeftArgType, RightArgType> XprType; + + enum { + IsAligned = TensorEvaluator<LeftArgType, Device>::IsAligned & TensorEvaluator<RightArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<LeftArgType, Device>::PacketAccess & TensorEvaluator<RightArgType, Device>::PacketAccess & + internal::functor_traits<BinaryOp>::PacketAccess, + Layout = TensorEvaluator<LeftArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) + : m_functor(op.functor()), + m_leftImpl(op.lhsExpression(), device), + m_rightImpl(op.rhsExpression(), device) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<LeftArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<RightArgType, Device>::Layout) || internal::traits<XprType>::NumDimensions == 1), YOU_MADE_A_PROGRAMMING_MISTAKE); + eigen_assert(dimensions_match(m_leftImpl.dimensions(), m_rightImpl.dimensions())); + } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename internal::traits<XprType>::Scalar CoeffReturnType; + typedef typename internal::traits<XprType>::Packet PacketReturnType; + typedef typename TensorEvaluator<LeftArgType, Device>::Dimensions Dimensions; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const + { + // TODO: use right impl instead if right impl dimensions are known at compile time. + return m_leftImpl.dimensions(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { + m_leftImpl.evalSubExprsIfNeeded(NULL); + m_rightImpl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_leftImpl.cleanup(); + m_rightImpl.cleanup(); + } + + EIGEN_DEVICE_FUNC CoeffReturnType coeff(Index index) const + { + return m_functor(m_leftImpl.coeff(index), m_rightImpl.coeff(index)); + } + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return m_functor.packetOp(m_leftImpl.template packet<LoadMode>(index), m_rightImpl.template packet<LoadMode>(index)); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return NULL; } + + private: + const BinaryOp m_functor; + TensorEvaluator<LeftArgType, Device> m_leftImpl; + TensorEvaluator<RightArgType, Device> m_rightImpl; +}; + + +// -------------------- SelectOp -------------------- + +template<typename IfArgType, typename ThenArgType, typename ElseArgType, typename Device> +struct TensorEvaluator<const TensorSelectOp<IfArgType, ThenArgType, ElseArgType>, Device> +{ + typedef TensorSelectOp<IfArgType, ThenArgType, ElseArgType> XprType; + + enum { + IsAligned = TensorEvaluator<ThenArgType, Device>::IsAligned & TensorEvaluator<ElseArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ThenArgType, Device>::PacketAccess & TensorEvaluator<ElseArgType, Device>::PacketAccess/* & + TensorEvaluator<IfArgType>::PacketAccess*/, + Layout = TensorEvaluator<IfArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) + : m_condImpl(op.ifExpression(), device), + m_thenImpl(op.thenExpression(), device), + m_elseImpl(op.elseExpression(), device) + { + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<IfArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<ThenArgType, Device>::Layout)), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((static_cast<int>(TensorEvaluator<IfArgType, Device>::Layout) == static_cast<int>(TensorEvaluator<ElseArgType, Device>::Layout)), YOU_MADE_A_PROGRAMMING_MISTAKE); + eigen_assert(dimensions_match(m_condImpl.dimensions(), m_thenImpl.dimensions())); + eigen_assert(dimensions_match(m_thenImpl.dimensions(), m_elseImpl.dimensions())); + } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename internal::traits<XprType>::Scalar CoeffReturnType; + typedef typename internal::traits<XprType>::Packet PacketReturnType; + typedef typename TensorEvaluator<IfArgType, Device>::Dimensions Dimensions; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const + { + // TODO: use then or else impl instead if they happen to be known at compile time. + return m_condImpl.dimensions(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { + m_condImpl.evalSubExprsIfNeeded(NULL); + m_thenImpl.evalSubExprsIfNeeded(NULL); + m_elseImpl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_condImpl.cleanup(); + m_thenImpl.cleanup(); + m_elseImpl.cleanup(); + } + + EIGEN_DEVICE_FUNC CoeffReturnType coeff(Index index) const + { + return m_condImpl.coeff(index) ? m_thenImpl.coeff(index) : m_elseImpl.coeff(index); + } + template<int LoadMode> + EIGEN_DEVICE_FUNC PacketReturnType packet(Index index) const + { + static const int PacketSize = internal::unpacket_traits<PacketReturnType>::size; + internal::Selector<PacketSize> select; + for (Index i = 0; i < PacketSize; ++i) { + select.select[i] = m_condImpl.coeff(index+i); + } + return internal::pblend(select, + m_thenImpl.template packet<LoadMode>(index), + m_elseImpl.template packet<LoadMode>(index)); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return NULL; } + + private: + TensorEvaluator<IfArgType, Device> m_condImpl; + TensorEvaluator<ThenArgType, Device> m_thenImpl; + TensorEvaluator<ElseArgType, Device> m_elseImpl; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_EVALUATOR_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorExecutor.h b/unsupported/Eigen/CXX11/src/Tensor/TensorExecutor.h new file mode 100644 index 000000000..05ac9bd2f --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorExecutor.h @@ -0,0 +1,244 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_EXECUTOR_H +#define EIGEN_CXX11_TENSOR_TENSOR_EXECUTOR_H + +namespace Eigen { + +/** \class TensorExecutor + * \ingroup CXX11_Tensor_Module + * + * \brief The tensor executor class. + * + * This class is responsible for launch the evaluation of the expression on + * the specified computing device. + */ +namespace internal { + +template <typename Device, typename Expression> +struct IsVectorizable { + static const bool value = TensorEvaluator<Expression, Device>::PacketAccess; +}; + +// Default strategy: the expression is evaluated with a single cpu thread. +template<typename Expression, typename Device = DefaultDevice, bool Vectorizable = IsVectorizable<Device, Expression>::value> +class TensorExecutor +{ + public: + typedef typename Expression::Index Index; + EIGEN_DEVICE_FUNC + static inline void run(const Expression& expr, const Device& device = Device()) + { + TensorEvaluator<Expression, Device> evaluator(expr, device); + const bool needs_assign = evaluator.evalSubExprsIfNeeded(NULL); + if (needs_assign) + { + const Index size = array_prod(evaluator.dimensions()); + for (Index i = 0; i < size; ++i) { + evaluator.evalScalar(i); + } + } + evaluator.cleanup(); + } +}; + + +template<typename Expression> +class TensorExecutor<Expression, DefaultDevice, true> +{ + public: + typedef typename Expression::Index Index; + static inline void run(const Expression& expr, const DefaultDevice& device = DefaultDevice()) + { + TensorEvaluator<Expression, DefaultDevice> evaluator(expr, device); + const bool needs_assign = evaluator.evalSubExprsIfNeeded(NULL); + if (needs_assign) + { + const Index size = array_prod(evaluator.dimensions()); + static const int PacketSize = unpacket_traits<typename TensorEvaluator<Expression, DefaultDevice>::PacketReturnType>::size; + const Index VectorizedSize = (size / PacketSize) * PacketSize; + + for (Index i = 0; i < VectorizedSize; i += PacketSize) { + evaluator.evalPacket(i); + } + for (Index i = VectorizedSize; i < size; ++i) { + evaluator.evalScalar(i); + } + } + evaluator.cleanup(); + } +}; + + + +// Multicore strategy: the index space is partitioned and each partition is executed on a single core +#ifdef EIGEN_USE_THREADS +template <typename Evaluator, typename Index, bool Vectorizable = Evaluator::PacketAccess> +struct EvalRange { + static void run(Evaluator evaluator, const Index first, const Index last) { + eigen_assert(last > first); + for (Index i = first; i < last; ++i) { + evaluator.evalScalar(i); + } + } +}; + +template <typename Evaluator, typename Index> +struct EvalRange<Evaluator, Index, true> { + static void run(Evaluator evaluator, const Index first, const Index last) { + eigen_assert(last > first); + + Index i = first; + static const int PacketSize = unpacket_traits<typename Evaluator::PacketReturnType>::size; + if (last - first > PacketSize) { + eigen_assert(first % PacketSize == 0); + Index lastPacket = last - (last % PacketSize); + for (; i < lastPacket; i += PacketSize) { + evaluator.evalPacket(i); + } + } + + for (; i < last; ++i) { + evaluator.evalScalar(i); + } + } +}; + +template<typename Expression, bool Vectorizable> +class TensorExecutor<Expression, ThreadPoolDevice, Vectorizable> +{ + public: + typedef typename Expression::Index Index; + static inline void run(const Expression& expr, const ThreadPoolDevice& device) + { + typedef TensorEvaluator<Expression, ThreadPoolDevice> Evaluator; + Evaluator evaluator(expr, device); + const bool needs_assign = evaluator.evalSubExprsIfNeeded(NULL); + if (needs_assign) + { + const Index size = array_prod(evaluator.dimensions()); + + static const int PacketSize = Vectorizable ? unpacket_traits<typename Evaluator::PacketReturnType>::size : 1; + + int blocksz = std::ceil<int>(static_cast<float>(size)/device.numThreads()) + PacketSize - 1; + const Index blocksize = std::max<Index>(PacketSize, (blocksz - (blocksz % PacketSize))); + const Index numblocks = size / blocksize; + + Index i = 0; + std::vector<Future> results; + results.reserve(numblocks); + for (int i = 0; i < numblocks; ++i) { + results.push_back(device.enqueue(&EvalRange<Evaluator, Index>::run, evaluator, i*blocksize, (i+1)*blocksize)); + } + + if (numblocks * blocksize < size) { + EvalRange<Evaluator, Index>::run(evaluator, numblocks * blocksize, size); + } + + for (int i = 0; i < numblocks; ++i) { + get_when_ready(&results[i]); + } + + } + evaluator.cleanup(); + } +}; +#endif + + +// GPU: the evaluation of the expression is offloaded to a GPU. +#if defined(EIGEN_USE_GPU) && defined(__CUDACC__) +template <typename Evaluator, typename Index> +__global__ void +__launch_bounds__(1024) +EigenMetaKernel_NonVectorizable(Evaluator eval, Index size) { + + const Index first_index = blockIdx.x * blockDim.x + threadIdx.x; + const Index step_size = blockDim.x * gridDim.x; + + // Use the scalar path + for (Index i = first_index; i < size; i += step_size) { + eval.evalScalar(i); + } +} + +template <typename Evaluator, typename Index> +__global__ void +__launch_bounds__(1024) +EigenMetaKernel_Vectorizable(Evaluator eval, Index size) { + + const Index first_index = blockIdx.x * blockDim.x + threadIdx.x; + const Index step_size = blockDim.x * gridDim.x; + + // Use the vector path + const Index PacketSize = unpacket_traits<typename Evaluator::PacketReturnType>::size; + const Index vectorized_step_size = step_size * PacketSize; + const Index vectorized_size = (size / PacketSize) * PacketSize; + for (Index i = first_index * PacketSize; i < vectorized_size; + i += vectorized_step_size) { + eval.evalPacket(i); + } + for (Index i = vectorized_size + first_index; i < size; i += step_size) { + eval.evalScalar(i); + } +} + +template <typename Expression> +struct IsVectorizable<GpuDevice, Expression> { + static const bool value = TensorEvaluator<Expression, GpuDevice>::PacketAccess && TensorEvaluator<Expression, GpuDevice>::IsAligned; +}; + +template<typename Expression> +class TensorExecutor<Expression, GpuDevice, false> +{ + public: + typedef typename Expression::Index Index; + static inline void run(const Expression& expr, const GpuDevice& device) + { + TensorEvaluator<Expression, GpuDevice> evaluator(expr, device); + const bool needs_assign = evaluator.evalSubExprsIfNeeded(NULL); + if (needs_assign) + { + const int num_blocks = getNumCudaMultiProcessors() * maxCudaThreadsPerMultiProcessor() / maxCudaThreadsPerBlock(); + const int block_size = maxCudaThreadsPerBlock(); + const Index size = array_prod(evaluator.dimensions()); + LAUNCH_CUDA_KERNEL((EigenMetaKernel_NonVectorizable<TensorEvaluator<Expression, GpuDevice>, Index>), num_blocks, block_size, 0, device, evaluator, size); + } + evaluator.cleanup(); + } +}; + +template<typename Expression> +class TensorExecutor<Expression, GpuDevice, true> +{ + public: + typedef typename Expression::Index Index; + static inline void run(const Expression& expr, const GpuDevice& device) + { + TensorEvaluator<Expression, GpuDevice> evaluator(expr, device); + const bool needs_assign = evaluator.evalSubExprsIfNeeded(NULL); + if (needs_assign) + { + const int num_blocks = getNumCudaMultiProcessors() * maxCudaThreadsPerMultiProcessor() / maxCudaThreadsPerBlock(); + const int block_size = maxCudaThreadsPerBlock(); + const Index size = array_prod(evaluator.dimensions()); + LAUNCH_CUDA_KERNEL((EigenMetaKernel_Vectorizable<TensorEvaluator<Expression, GpuDevice>, Index>), num_blocks, block_size, 0, device, evaluator, size); + } + evaluator.cleanup(); + } +}; + +#endif + +} // end namespace internal + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_EXECUTOR_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorExpr.h b/unsupported/Eigen/CXX11/src/Tensor/TensorExpr.h new file mode 100644 index 000000000..b66b3ec2c --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorExpr.h @@ -0,0 +1,300 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_EXPR_H +#define EIGEN_CXX11_TENSOR_TENSOR_EXPR_H + +namespace Eigen { + +/** \class TensorExpr + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor expression classes. + * + * The TensorCwiseNullaryOp class applies a nullary operators to an expression. + * This is typically used to generate constants. + * + * The TensorCwiseUnaryOp class represents an expression where a unary operator + * (e.g. cwiseSqrt) is applied to an expression. + * + * The TensorCwiseBinaryOp class represents an expression where a binary + * operator (e.g. addition) is applied to a lhs and a rhs expression. + * + */ +namespace internal { +template<typename NullaryOp, typename XprType> +struct traits<TensorCwiseNullaryOp<NullaryOp, XprType> > + : traits<XprType> +{ + typedef typename XprType::Packet Packet; + typedef traits<XprType> XprTraits; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::Nested XprTypeNested; + typedef typename remove_reference<XprTypeNested>::type _XprTypeNested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; + + enum { + Flags = 0, + }; +}; + +} // end namespace internal + + + +template<typename NullaryOp, typename XprType> +class TensorCwiseNullaryOp : public TensorBase<TensorCwiseNullaryOp<NullaryOp, XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorCwiseNullaryOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorCwiseNullaryOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef TensorCwiseNullaryOp<NullaryOp, XprType> Nested; + typedef typename Eigen::internal::traits<TensorCwiseNullaryOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorCwiseNullaryOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorCwiseNullaryOp(const XprType& xpr, const NullaryOp& func = NullaryOp()) + : m_xpr(xpr), m_functor(func) {} + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + nestedExpression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC + const NullaryOp& functor() const { return m_functor; } + + protected: + typename XprType::Nested m_xpr; + const NullaryOp m_functor; +}; + + + +namespace internal { +template<typename UnaryOp, typename XprType> +struct traits<TensorCwiseUnaryOp<UnaryOp, XprType> > + : traits<XprType> +{ + // TODO(phli): Add InputScalar, InputPacket. Check references to + // current Scalar/Packet to see if the intent is Input or Output. + typedef typename result_of<UnaryOp(typename XprType::Scalar)>::type Scalar; + typedef traits<XprType> XprTraits; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename XprType::Nested XprTypeNested; + typedef typename remove_reference<XprTypeNested>::type _XprTypeNested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename UnaryOp, typename XprType> +struct eval<TensorCwiseUnaryOp<UnaryOp, XprType>, Eigen::Dense> +{ + typedef const TensorCwiseUnaryOp<UnaryOp, XprType>& type; +}; + +template<typename UnaryOp, typename XprType> +struct nested<TensorCwiseUnaryOp<UnaryOp, XprType>, 1, typename eval<TensorCwiseUnaryOp<UnaryOp, XprType> >::type> +{ + typedef TensorCwiseUnaryOp<UnaryOp, XprType> type; +}; + +} // end namespace internal + + + +template<typename UnaryOp, typename XprType> +class TensorCwiseUnaryOp : public TensorBase<TensorCwiseUnaryOp<UnaryOp, XprType>, ReadOnlyAccessors> +{ + public: + // TODO(phli): Add InputScalar, InputPacket. Check references to + // current Scalar/Packet to see if the intent is Input or Output. + typedef typename Eigen::internal::traits<TensorCwiseUnaryOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorCwiseUnaryOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef Scalar CoeffReturnType; + typedef typename internal::packet_traits<CoeffReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorCwiseUnaryOp>::type Nested; + typedef typename Eigen::internal::traits<TensorCwiseUnaryOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorCwiseUnaryOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorCwiseUnaryOp(const XprType& xpr, const UnaryOp& func = UnaryOp()) + : m_xpr(xpr), m_functor(func) {} + + EIGEN_DEVICE_FUNC + const UnaryOp& functor() const { return m_functor; } + + /** \returns the nested expression */ + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + nestedExpression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const UnaryOp m_functor; +}; + + +namespace internal { +template<typename BinaryOp, typename LhsXprType, typename RhsXprType> +struct traits<TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs + // are different. + // TODO(phli): Add Lhs/RhsScalar, Lhs/RhsPacket. Check references to + // current Scalar/Packet to see if the intent is Inputs or Output. + typedef typename result_of< + BinaryOp(typename LhsXprType::Scalar, + typename RhsXprType::Scalar)>::type Scalar; + typedef traits<LhsXprType> XprTraits; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename promote_storage_type< + typename traits<LhsXprType>::StorageKind, + typename traits<RhsXprType>::StorageKind>::ret StorageKind; + typedef typename promote_index_type< + typename traits<LhsXprType>::Index, + typename traits<RhsXprType>::Index>::type Index; + typedef typename LhsXprType::Nested LhsNested; + typedef typename RhsXprType::Nested RhsNested; + typedef typename remove_reference<LhsNested>::type _LhsNested; + typedef typename remove_reference<RhsNested>::type _RhsNested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename BinaryOp, typename LhsXprType, typename RhsXprType> +struct eval<TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType>, Eigen::Dense> +{ + typedef const TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType>& type; +}; + +template<typename BinaryOp, typename LhsXprType, typename RhsXprType> +struct nested<TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType>, 1, typename eval<TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType> >::type> +{ + typedef TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType> type; +}; + +} // end namespace internal + + + +template<typename BinaryOp, typename LhsXprType, typename RhsXprType> +class TensorCwiseBinaryOp : public TensorBase<TensorCwiseBinaryOp<BinaryOp, LhsXprType, RhsXprType>, ReadOnlyAccessors> +{ + public: + // TODO(phli): Add Lhs/RhsScalar, Lhs/RhsPacket. Check references to + // current Scalar/Packet to see if the intent is Inputs or Output. + typedef typename Eigen::internal::traits<TensorCwiseBinaryOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorCwiseBinaryOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef Scalar CoeffReturnType; + typedef typename internal::packet_traits<CoeffReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorCwiseBinaryOp>::type Nested; + typedef typename Eigen::internal::traits<TensorCwiseBinaryOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorCwiseBinaryOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorCwiseBinaryOp(const LhsXprType& lhs, const RhsXprType& rhs, const BinaryOp& func = BinaryOp()) + : m_lhs_xpr(lhs), m_rhs_xpr(rhs), m_functor(func) {} + + EIGEN_DEVICE_FUNC + const BinaryOp& functor() const { return m_functor; } + + /** \returns the nested expressions */ + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename LhsXprType::Nested>::type& + lhsExpression() const { return m_lhs_xpr; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename RhsXprType::Nested>::type& + rhsExpression() const { return m_rhs_xpr; } + + protected: + typename LhsXprType::Nested m_lhs_xpr; + typename RhsXprType::Nested m_rhs_xpr; + const BinaryOp m_functor; +}; + + +namespace internal { +template<typename IfXprType, typename ThenXprType, typename ElseXprType> +struct traits<TensorSelectOp<IfXprType, ThenXprType, ElseXprType> > + : traits<ThenXprType> +{ + typedef typename traits<ThenXprType>::Scalar Scalar; + typedef traits<ThenXprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename promote_storage_type<typename traits<ThenXprType>::StorageKind, + typename traits<ElseXprType>::StorageKind>::ret StorageKind; + typedef typename promote_index_type<typename traits<ElseXprType>::Index, + typename traits<ThenXprType>::Index>::type Index; + typedef typename IfXprType::Nested IfNested; + typedef typename ThenXprType::Nested ThenNested; + typedef typename ElseXprType::Nested ElseNested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename IfXprType, typename ThenXprType, typename ElseXprType> +struct eval<TensorSelectOp<IfXprType, ThenXprType, ElseXprType>, Eigen::Dense> +{ + typedef const TensorSelectOp<IfXprType, ThenXprType, ElseXprType>& type; +}; + +template<typename IfXprType, typename ThenXprType, typename ElseXprType> +struct nested<TensorSelectOp<IfXprType, ThenXprType, ElseXprType>, 1, typename eval<TensorSelectOp<IfXprType, ThenXprType, ElseXprType> >::type> +{ + typedef TensorSelectOp<IfXprType, ThenXprType, ElseXprType> type; +}; + +} // end namespace internal + + +template<typename IfXprType, typename ThenXprType, typename ElseXprType> +class TensorSelectOp : public TensorBase<TensorSelectOp<IfXprType, ThenXprType, ElseXprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorSelectOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorSelectOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::promote_storage_type<typename ThenXprType::CoeffReturnType, + typename ElseXprType::CoeffReturnType>::ret CoeffReturnType; + typedef typename internal::promote_storage_type<typename ThenXprType::PacketReturnType, + typename ElseXprType::PacketReturnType>::ret PacketReturnType; + typedef typename Eigen::internal::nested<TensorSelectOp>::type Nested; + typedef typename Eigen::internal::traits<TensorSelectOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorSelectOp>::Index Index; + + TensorSelectOp(const IfXprType& a_condition, + const ThenXprType& a_then, + const ElseXprType& a_else) + : m_condition(a_condition), m_then(a_then), m_else(a_else) + { } + + const IfXprType& ifExpression() const { return m_condition; } + + const ThenXprType& thenExpression() const { return m_then; } + + const ElseXprType& elseExpression() const { return m_else; } + + protected: + typename IfXprType::Nested m_condition; + typename ThenXprType::Nested m_then; + typename ElseXprType::Nested m_else; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_EXPR_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorFixedSize.h b/unsupported/Eigen/CXX11/src/Tensor/TensorFixedSize.h new file mode 100644 index 000000000..94b3f957b --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorFixedSize.h @@ -0,0 +1,253 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_FIXED_SIZE_H +#define EIGEN_CXX11_TENSOR_TENSOR_FIXED_SIZE_H + +namespace Eigen { + +/** \class TensorFixedSize + * \ingroup CXX11_Tensor_Module + * + * \brief The fixed sized version of the tensor class. + * + * The fixed sized equivalent of + * Eigen::Tensor<float, 3> t(3, 5, 7); + * is + * Eigen::TensorFixedSize<float, Size<3,5,7>> t; + */ + +template<typename Scalar_, typename Dimensions_, int Options_> +class TensorFixedSize : public TensorBase<TensorFixedSize<Scalar_, Dimensions_, Options_> > +{ + public: + typedef TensorFixedSize<Scalar_, Dimensions_, Options_> Self; + typedef TensorBase<TensorFixedSize<Scalar_, Dimensions_, Options_> > Base; + typedef typename Eigen::internal::nested<Self>::type Nested; + typedef typename internal::traits<Self>::StorageKind StorageKind; + typedef typename internal::traits<Self>::Index Index; + typedef Scalar_ Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename NumTraits<Scalar>::Real RealScalar; + typedef typename Base::CoeffReturnType CoeffReturnType; + + static const int Options = Options_; + + enum { + IsAligned = bool(EIGEN_ALIGN), + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = Options_ & RowMajor ? RowMajor : ColMajor, + CoordAccess = true, + }; + + typedef Dimensions_ Dimensions; + static const std::size_t NumIndices = Dimensions::count; + + protected: + TensorStorage<Scalar, NumIndices, Dimensions::total_size, Options, Dimensions> m_storage; + + public: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index rank() const { return NumIndices; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index dimension(std::size_t n) const { return m_storage.dimensions()[n]; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_storage.dimensions(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index size() const { return m_storage.size(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar *data() { return m_storage.data(); } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar *data() const { return m_storage.data(); } + + // This makes EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED + // work, because that uses base().coeffRef() - and we don't yet + // implement a similar class hierarchy + inline Self& base() { return *this; } + inline const Self& base() const { return *this; } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> + inline const Scalar& coeff(Index firstIndex, IndexTypes... otherIndices) const + { + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return coeff(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& coeff(const array<Index, NumIndices>& indices) const + { + eigen_internal_assert(checkIndexRange(indices)); + return m_storage.data()[linearizedIndex(indices)]; + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& coeff(Index index) const + { + eigen_internal_assert(index >= 0 && index < size()); + return m_storage.data()[index]; + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> + inline Scalar& coeffRef(Index firstIndex, IndexTypes... otherIndices) + { + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return coeffRef(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(const array<Index, NumIndices>& indices) + { + eigen_internal_assert(checkIndexRange(indices)); + return m_storage.data()[linearizedIndex(indices)]; + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) + { + eigen_internal_assert(index >= 0 && index < size()); + return m_storage.data()[index]; + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> + inline const Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) const + { + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return this->operator()(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(const array<Index, NumIndices>& indices) const + { + eigen_assert(checkIndexRange(indices)); + return coeff(indices); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index index) const + { + eigen_internal_assert(index >= 0 && index < size()); + return coeff(index); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator[](Index index) const + { + // The bracket operator is only for vectors, use the parenthesis operator instead. + EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE); + return coeff(index); + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> + inline Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) + { + // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) + return operator()(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(const array<Index, NumIndices>& indices) + { + eigen_assert(checkIndexRange(indices)); + return coeffRef(indices); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index index) + { + eigen_assert(index >= 0 && index < size()); + return coeffRef(index); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator[](Index index) + { + // The bracket operator is only for vectors, use the parenthesis operator instead + EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + return coeffRef(index); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorFixedSize() + : m_storage() + { + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorFixedSize(const Self& other) + : m_storage(other.m_storage) + { + } + +#ifdef EIGEN_HAVE_RVALUE_REFERENCES + inline TensorFixedSize(Self&& other) + : m_storage(other.m_storage) + { + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorFixedSize& operator=(const TensorFixedSize& other) + { + // FIXME: check that the dimensions of other match the dimensions of *this. + // Unfortunately this isn't possible yet when the rhs is an expression. + typedef TensorAssignOp<Self, const TensorFixedSize> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorFixedSize& operator=(const OtherDerived& other) + { + // FIXME: check that the dimensions of other match the dimensions of *this. + // Unfortunately this isn't possible yet when the rhs is an expression. + typedef TensorAssignOp<Self, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + + protected: + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE bool checkIndexRange(const array<Index, NumIndices>& /*indices*/) const + { + using internal::array_apply_and_reduce; + using internal::array_zip_and_reduce; + using internal::greater_equal_zero_op; + using internal::logical_and_op; + using internal::lesser_op; + + return true; + // check whether the indices are all >= 0 + /* array_apply_and_reduce<logical_and_op, greater_equal_zero_op>(indices) && + // check whether the indices fit in the dimensions + array_zip_and_reduce<logical_and_op, lesser_op>(indices, m_storage.dimensions());*/ + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index linearizedIndex(const array<Index, NumIndices>& indices) const + { + if (Options&RowMajor) { + return m_storage.dimensions().IndexOfRowMajor(indices); + } else { + return m_storage.dimensions().IndexOfColMajor(indices); + } + } +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_FIXED_SIZE_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorForcedEval.h b/unsupported/Eigen/CXX11/src/Tensor/TensorForcedEval.h new file mode 100644 index 000000000..41a36cb75 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorForcedEval.h @@ -0,0 +1,151 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_FORCED_EVAL_H +#define EIGEN_CXX11_TENSOR_TENSOR_FORCED_EVAL_H + +namespace Eigen { + +/** \class TensorForcedEval + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor reshaping class. + * + * + */ +namespace internal { +template<typename XprType> +struct traits<TensorForcedEvalOp<XprType> > +{ + // Type promotion to handle the case where the types of the lhs and the rhs are different. + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename traits<XprType>::StorageKind StorageKind; + typedef typename traits<XprType>::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; + + enum { + Flags = 0, + }; +}; + +template<typename XprType> +struct eval<TensorForcedEvalOp<XprType>, Eigen::Dense> +{ + typedef const TensorForcedEvalOp<XprType>& type; +}; + +template<typename XprType> +struct nested<TensorForcedEvalOp<XprType>, 1, typename eval<TensorForcedEvalOp<XprType> >::type> +{ + typedef TensorForcedEvalOp<XprType> type; +}; + +} // end namespace internal + + + +template<typename XprType> +class TensorForcedEvalOp : public TensorBase<TensorForcedEvalOp<XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorForcedEvalOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorForcedEvalOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorForcedEvalOp>::type Nested; + typedef typename Eigen::internal::traits<TensorForcedEvalOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorForcedEvalOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorForcedEvalOp(const XprType& expr) + : m_xpr(expr) {} + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; +}; + + +template<typename ArgType, typename Device> +struct TensorEvaluator<const TensorForcedEvalOp<ArgType>, Device> +{ + typedef TensorForcedEvalOp<ArgType> XprType; + typedef typename ArgType::Scalar Scalar; + typedef typename ArgType::Packet Packet; + typedef typename TensorEvaluator<ArgType, Device>::Dimensions Dimensions; + + enum { + IsAligned = true, + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = TensorEvaluator<ArgType, Device>::Layout, + }; + + EIGEN_DEVICE_FUNC TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_op(op.expression()), m_device(device), m_buffer(NULL) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC const Dimensions& dimensions() const { return m_impl.dimensions(); } + + EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType*) { + m_impl.evalSubExprsIfNeeded(NULL); + const Index numValues = m_impl.dimensions().TotalSize(); + m_buffer = (CoeffReturnType*)m_device.allocate(numValues * sizeof(CoeffReturnType)); + // Should initialize the memory in case we're dealing with non POD types. + if (!internal::is_arithmetic<CoeffReturnType>::value) { + for (Index i = 0; i < numValues; ++i) { + new(m_buffer+i) CoeffReturnType(); + } + } + typedef TensorEvalToOp<const ArgType> EvalTo; + EvalTo evalToTmp(m_buffer, m_op); + internal::TensorExecutor<const EvalTo, Device, TensorEvaluator<ArgType, Device>::PacketAccess>::run(evalToTmp, m_device); + m_impl.cleanup(); + return true; + } + EIGEN_STRONG_INLINE void cleanup() { + m_device.deallocate(m_buffer); + m_buffer = NULL; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_buffer[index]; + } + + template<int LoadMode> + EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return internal::ploadt<Packet, LoadMode>(m_buffer + index); + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return m_buffer; } + + private: + TensorEvaluator<ArgType, Device> m_impl; + const ArgType m_op; + const Device& m_device; + CoeffReturnType* m_buffer; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_FORCED_EVAL_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorForwardDeclarations.h b/unsupported/Eigen/CXX11/src/Tensor/TensorForwardDeclarations.h new file mode 100644 index 000000000..7bec2b10a --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorForwardDeclarations.h @@ -0,0 +1,54 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_FORWARD_DECLARATIONS_H +#define EIGEN_CXX11_TENSOR_TENSOR_FORWARD_DECLARATIONS_H + +namespace Eigen { + +template<typename Scalar_, std::size_t NumIndices_, int Options_ = 0> class Tensor; +template<typename Scalar_, typename Dimensions, int Options_ = 0> class TensorFixedSize; +template<typename PlainObjectType, int Options_ = Unaligned> class TensorMap; +template<typename PlainObjectType> class TensorRef; +template<typename Derived, int AccessLevel = internal::accessors_level<Derived>::value> class TensorBase; + +template<typename NullaryOp, typename PlainObjectType> class TensorCwiseNullaryOp; +template<typename UnaryOp, typename XprType> class TensorCwiseUnaryOp; +template<typename BinaryOp, typename LeftXprType, typename RightXprType> class TensorCwiseBinaryOp; +template<typename IfXprType, typename ThenXprType, typename ElseXprType> class TensorSelectOp; +template<typename Op, typename Dims, typename XprType> class TensorReductionOp; +template<typename Axis, typename LeftXprType, typename RightXprType> class TensorConcatenationOp; +template<typename Dimensions, typename LeftXprType, typename RightXprType> class TensorContractionOp; +template<typename Dimensions, typename InputXprType, typename KernelXprType> class TensorConvolutionOp; +template<typename PatchDim, typename XprType> class TensorPatchOp; +template<DenseIndex Rows, DenseIndex Cols, typename XprType> class TensorImagePatchOp; +template<typename Broadcast, typename XprType> class TensorBroadcastingOp; +template<DenseIndex DimId, typename XprType> class TensorChippingOp; +template<typename NewDimensions, typename XprType> class TensorReshapingOp; +template<typename XprType> class TensorLayoutSwapOp; +template<typename StartIndices, typename Sizes, typename XprType> class TensorSlicingOp; +template<typename ReverseDimensions, typename XprType> class TensorReverseOp; +template<typename PaddingDimensions, typename XprType> class TensorPaddingOp; +template<typename Shuffle, typename XprType> class TensorShufflingOp; +template<typename Strides, typename XprType> class TensorStridingOp; +template<typename LeftXprType, typename RightXprType> class TensorAssignOp; + +template<typename XprType> class TensorEvalToOp; +template<typename XprType> class TensorForcedEvalOp; + +template<typename ExpressionType, typename DeviceType> class TensorDevice; +template<typename Derived, typename Device> struct TensorEvaluator; + +namespace internal { +template<typename Expression, typename Device, bool Vectorizable> class TensorExecutor; +} // end namespace internal + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_FORWARD_DECLARATIONS_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorFunctors.h b/unsupported/Eigen/CXX11/src/Tensor/TensorFunctors.h new file mode 100644 index 000000000..38586d067 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorFunctors.h @@ -0,0 +1,338 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_FUNCTORS_H +#define EIGEN_CXX11_TENSOR_TENSOR_FUNCTORS_H + +namespace Eigen { +namespace internal { + +// Standard reduction functors +template <typename T> struct SumReducer +{ + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const T t, T* accum) const { + (*accum) += t; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reducePacket(const Packet& p, Packet* accum) const { + (*accum) = padd<Packet>(*accum, p); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T initialize() const { + return static_cast<T>(0); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet initializePacket() const { + return pset1<Packet>(0); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalize(const T accum) const { + return accum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet finalizePacket(const Packet& vaccum) const { + return vaccum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalizeBoth(const T saccum, const Packet& vaccum) const { + return saccum + predux(vaccum); + } +}; + +template <typename T> struct MeanReducer +{ + static const bool PacketAccess = true; + MeanReducer() : scalarCount_(0), packetCount_(0) { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const T t, T* accum) { + (*accum) += t; + scalarCount_++; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reducePacket(const Packet& p, Packet* accum) { + (*accum) = padd<Packet>(*accum, p); + packetCount_++; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T initialize() const { + return static_cast<T>(0); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet initializePacket() const { + return pset1<Packet>(0); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalize(const T accum) const { + return accum / scalarCount_; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet finalizePacket(const Packet& vaccum) const { + return pdiv(vaccum, pset1<Packet>(packetCount_)); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalizeBoth(const T saccum, const Packet& vaccum) const { + return (saccum + predux(vaccum)) / (scalarCount_ + packetCount_ * packet_traits<Packet>::size); + } + + protected: + int scalarCount_; + int packetCount_; +}; + +template <typename T> struct MaxReducer +{ + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const T t, T* accum) const { + if (t > *accum) { *accum = t; } + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reducePacket(const Packet& p, Packet* accum) const { + (*accum) = pmax<Packet>(*accum, p); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T initialize() const { + return -(std::numeric_limits<T>::max)(); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet initializePacket() const { + return pset1<Packet>(-(std::numeric_limits<T>::max)()); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalize(const T accum) const { + return accum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet finalizePacket(const Packet& vaccum) const { + return vaccum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalizeBoth(const T saccum, const Packet& vaccum) const { + return (std::max)(saccum, predux_max(vaccum)); + } +}; + +template <typename T> struct MinReducer +{ + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const T t, T* accum) const { + if (t < *accum) { *accum = t; } + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reducePacket(const Packet& p, Packet* accum) const { + (*accum) = pmin<Packet>(*accum, p); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T initialize() const { + return (std::numeric_limits<T>::max)(); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet initializePacket() const { + return pset1<Packet>((std::numeric_limits<T>::max)()); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalize(const T accum) const { + return accum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet finalizePacket(const Packet& vaccum) const { + return vaccum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalizeBoth(const T saccum, const Packet& vaccum) const { + return (std::min)(saccum, predux_min(vaccum)); + } +}; + + +template <typename T> struct ProdReducer +{ + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const T t, T* accum) const { + (*accum) *= t; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reducePacket(const Packet& p, Packet* accum) const { + (*accum) = pmul<Packet>(*accum, p); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T initialize() const { + return static_cast<T>(1); + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet initializePacket() const { + return pset1<Packet>(1); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalize(const T accum) const { + return accum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Packet finalizePacket(const Packet& vaccum) const { + return vaccum; + } + template <typename Packet> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T finalizeBoth(const T saccum, const Packet& vaccum) const { + return saccum * predux_mul(vaccum); + } +}; + +#if !defined (EIGEN_USE_GPU) || !defined(__CUDACC__) || !defined(__CUDA_ARCH__) +// We're not compiling a cuda kernel +template <typename T> struct UniformRandomGenerator { + + static const bool PacketAccess = true; + + template<typename Index> + T operator()(Index, Index = 0) const { + return random<T>(); + } + template<typename Index> + typename internal::packet_traits<T>::type packetOp(Index, Index = 0) const { + const int packetSize = internal::packet_traits<T>::size; + EIGEN_ALIGN_DEFAULT T values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = random<T>(); + } + return internal::pload<typename internal::packet_traits<T>::type>(values); + } +}; + +#else + +// We're compiling a cuda kernel +template <typename T> struct UniformRandomGenerator; + +template <> struct UniformRandomGenerator<float> { + + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC UniformRandomGenerator() { + const int tid = blockIdx.x * blockDim.x + threadIdx.x; + curand_init(0, tid, 0, &m_state); + } + + template<typename Index> EIGEN_DEVICE_FUNC + float operator()(Index, Index = 0) const { + return curand_uniform(&m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + float4 packetOp(Index, Index = 0) const { + return curand_uniform4(&m_state); + } + + private: + mutable curandStatePhilox4_32_10_t m_state; +}; + +template <> struct UniformRandomGenerator<double> { + + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC UniformRandomGenerator() { + const int tid = blockIdx.x * blockDim.x + threadIdx.x; + curand_init(0, tid, 0, &m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + double operator()(Index, Index = 0) const { + return curand_uniform_double(&m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + double2 packetOp(Index, Index = 0) const { + return curand_uniform2_double(&m_state); + } + + private: + mutable curandStatePhilox4_32_10_t m_state; +}; + +#endif + + +#if (!defined (EIGEN_USE_GPU) || !defined(__CUDACC__) || !defined(__CUDA_ARCH__)) && __cplusplus > 199711 +// We're not compiling a cuda kernel +template <typename T> struct NormalRandomGenerator { + + static const bool PacketAccess = true; + + NormalRandomGenerator() : m_distribution(0, 1) {} + NormalRandomGenerator(const NormalRandomGenerator& other) : m_distribution(other.m_distribution) { } + + template<typename Index> + T operator()(Index, Index = 0) const { + return m_distribution(m_generator); + } + template<typename Index> + typename internal::packet_traits<T>::type packetOp(Index, Index = 0) const { + const int packetSize = internal::packet_traits<T>::size; + EIGEN_ALIGN_DEFAULT T values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = m_distribution(m_generator); + } + return internal::pload<typename internal::packet_traits<T>::type>(values); + } + + mutable std::normal_distribution<T> m_distribution; + mutable std::default_random_engine m_generator; +}; + +#elif defined (EIGEN_USE_GPU) && defined(__CUDACC__) && defined(__CUDA_ARCH__) + +// We're compiling a cuda kernel +template <typename T> struct NormalRandomGenerator; + +template <> struct NormalRandomGenerator<float> { + + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC NormalRandomGenerator() { + const int tid = blockIdx.x * blockDim.x + threadIdx.x; + curand_init(0, tid, 0, &m_state); + } + + template<typename Index> EIGEN_DEVICE_FUNC + float operator()(Index, Index = 0) const { + return curand_normal(&m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + float4 packetOp(Index, Index = 0) const { + return curand_normal4(&m_state); + } + + private: + mutable curandStatePhilox4_32_10_t m_state; +}; + +template <> struct NormalRandomGenerator<double> { + + static const bool PacketAccess = true; + + EIGEN_DEVICE_FUNC NormalRandomGenerator() { + const int tid = blockIdx.x * blockDim.x + threadIdx.x; + curand_init(0, tid, 0, &m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + double operator()(Index, Index = 0) const { + return curand_normal_double(&m_state); + } + template<typename Index> EIGEN_DEVICE_FUNC + double2 packetOp(Index, Index = 0) const { + return curand_normal2_double(&m_state); + } + + private: + mutable curandStatePhilox4_32_10_t m_state; +}; + +#endif + + +} // end namespace internal +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_FUNCTORS_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorIO.h b/unsupported/Eigen/CXX11/src/Tensor/TensorIO.h new file mode 100644 index 000000000..a9d0f6c39 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorIO.h @@ -0,0 +1,53 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_IO_H +#define EIGEN_CXX11_TENSOR_TENSOR_IO_H + +namespace Eigen { + +namespace internal { +template<> +struct significant_decimals_impl<std::string> + : significant_decimals_default_impl<std::string, true> +{}; +} + + +template <typename T> +std::ostream& operator << (std::ostream& os, const TensorBase<T, ReadOnlyAccessors>& expr) { + // Evaluate the expression if needed + TensorForcedEvalOp<const T> eval = expr.eval(); + TensorEvaluator<const TensorForcedEvalOp<const T>, DefaultDevice> tensor(eval, DefaultDevice()); + tensor.evalSubExprsIfNeeded(NULL); + + typedef typename internal::remove_const<typename T::Scalar>::type Scalar; + typedef typename T::Index Index; + typedef typename TensorEvaluator<const TensorForcedEvalOp<const T>, DefaultDevice>::Dimensions Dimensions; + const Index total_size = internal::array_prod(tensor.dimensions()); + + // Print the tensor as a 1d vector or a 2d matrix. + if (internal::array_size<Dimensions>::value == 1) { + Map<const Array<Scalar, Dynamic, 1> > array(const_cast<Scalar*>(tensor.data()), total_size); + os << array; + } else { + const Index first_dim = tensor.dimensions()[0]; + static const int layout = TensorEvaluator<const TensorForcedEvalOp<const T>, DefaultDevice>::Layout; + Map<const Array<Scalar, Dynamic, Dynamic, layout> > matrix(const_cast<Scalar*>(tensor.data()), first_dim, total_size/first_dim); + os << matrix; + } + + // Cleanup. + tensor.cleanup(); + return os; +} + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_IO_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorImagePatch.h b/unsupported/Eigen/CXX11/src/Tensor/TensorImagePatch.h new file mode 100644 index 000000000..bf0e7edfb --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorImagePatch.h @@ -0,0 +1,382 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_IMAGE_PATCH_H +#define EIGEN_CXX11_TENSOR_TENSOR_IMAGE_PATCH_H + +namespace Eigen { + +/** \class TensorImagePatch + * \ingroup CXX11_Tensor_Module + * + * \brief Patch extraction specialized for image processing. + * This assumes that the input has a least 3 dimensions ordered as follow: + * 1st dimension: channels (of size d) + * 2nd dimension: rows (of size r) + * 3rd dimension: columns (of size c) + * There can be additional dimensions such as time (for video) or batch (for + * bulk processing after the first 3. + * Calling the image patch code with patch_rows and patch_cols is equivalent + * to calling the regular patch extraction code with parameters d, patch_rows, + * patch_cols, and 1 for all the additional dimensions. + */ +namespace internal { +template<DenseIndex Rows, DenseIndex Cols, typename XprType> +struct traits<TensorImagePatchOp<Rows, Cols, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions + 1; + static const int Layout = XprTraits::Layout; +}; + +template<DenseIndex Rows, DenseIndex Cols, typename XprType> +struct eval<TensorImagePatchOp<Rows, Cols, XprType>, Eigen::Dense> +{ + typedef const TensorImagePatchOp<Rows, Cols, XprType>& type; +}; + +template<DenseIndex Rows, DenseIndex Cols, typename XprType> +struct nested<TensorImagePatchOp<Rows, Cols, XprType>, 1, typename eval<TensorImagePatchOp<Rows, Cols, XprType> >::type> +{ + typedef TensorImagePatchOp<Rows, Cols, XprType> type; +}; + +} // end namespace internal + +template<DenseIndex Rows, DenseIndex Cols, typename XprType> +class TensorImagePatchOp : public TensorBase<TensorImagePatchOp<Rows, Cols, XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorImagePatchOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorImagePatchOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorImagePatchOp>::type Nested; + typedef typename Eigen::internal::traits<TensorImagePatchOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorImagePatchOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorImagePatchOp(const XprType& expr, DenseIndex patch_rows, DenseIndex patch_cols, + DenseIndex row_strides, DenseIndex col_strides, + PaddingType padding_type) + : m_xpr(expr), m_patch_rows(patch_rows), m_patch_cols(patch_cols), + m_row_strides(row_strides), m_col_strides(col_strides), + m_padding_type(padding_type) {} + + EIGEN_DEVICE_FUNC + DenseIndex patch_rows() const { return m_patch_rows; } + EIGEN_DEVICE_FUNC + DenseIndex patch_cols() const { return m_patch_cols; } + EIGEN_DEVICE_FUNC + DenseIndex row_strides() const { return m_row_strides; } + EIGEN_DEVICE_FUNC + DenseIndex col_strides() const { return m_col_strides; } + EIGEN_DEVICE_FUNC + PaddingType padding_type() const { return m_padding_type; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const DenseIndex m_patch_rows; + const DenseIndex m_patch_cols; + const DenseIndex m_row_strides; + const DenseIndex m_col_strides; + const PaddingType m_padding_type; +}; + + +// Eval as rvalue +template<DenseIndex Rows, DenseIndex Cols, typename ArgType, typename Device> +struct TensorEvaluator<const TensorImagePatchOp<Rows, Cols, ArgType>, Device> +{ + typedef TensorImagePatchOp<Rows, Cols, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value + 1; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = NumDims == 5, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + // Only column major tensors are supported for now. + EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE); + + EIGEN_STATIC_ASSERT(NumDims >= 4, YOU_MADE_A_PROGRAMMING_MISTAKE); + + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + + // Caches a few variables. + m_inputRows = input_dims[1]; + m_inputCols = input_dims[2]; + + m_row_strides = op.row_strides(); + m_col_strides = op.col_strides(); + + // We only support same strides for both dimensions and square patches. + eigen_assert(m_row_strides == m_col_strides); + + switch (op.padding_type()) { + case PADDING_VALID: + m_outputRows = ceil((m_inputRows - op.patch_rows() + 1.f) / static_cast<float>(m_row_strides)); + m_outputCols = ceil((m_inputCols - op.patch_cols() + 1.f) / static_cast<float>(m_col_strides)); + // Calculate the padding + m_rowPaddingTop = ((m_outputRows - 1) * m_row_strides + op.patch_rows() - m_inputRows) / 2; + m_colPaddingLeft = ((m_outputCols - 1) * m_col_strides + op.patch_cols() - m_inputCols) / 2; + break; + case PADDING_SAME: + m_outputRows = ceil(m_inputRows / static_cast<float>(m_row_strides)); + m_outputCols = ceil(m_inputCols / static_cast<float>(m_col_strides)); + // Calculate the padding + m_rowPaddingTop = ((m_outputRows - 1) * m_row_strides + op.patch_rows() - m_inputRows) / 2; + m_colPaddingLeft = ((m_outputCols - 1) * m_col_strides + op.patch_cols() - m_inputCols) / 2; + break; + default: + eigen_assert(false && "unexpected padding"); + } + + // Dimensions for result of extraction. + // 0: depth + // 1: patch_rows + // 2: patch_cols + // 3: number of patches + // 4 and beyond: anything else (such as batch). + m_dimensions[0] = input_dims[0]; + m_dimensions[1] = op.patch_rows(); + m_dimensions[2] = op.patch_cols(); + m_dimensions[3] = m_outputRows * m_outputCols; + for (int i = 4; i < NumDims; ++i) { + m_dimensions[i] = input_dims[i-1]; + } + + // Strides for moving the patch in various dimensions. + m_colStride = m_dimensions[1]; + m_patchStride = m_colStride * m_dimensions[2] * m_dimensions[0]; + m_otherStride = m_patchStride * m_dimensions[3]; + + // Strides for navigating through the input tensor. + m_rowInputStride = input_dims[0]; + m_colInputStride = input_dims[0] * input_dims[1]; + m_patchInputStride = input_dims[0] * input_dims[1] * input_dims[2]; + + // Fast representations of different variables. + m_fastOtherStride = internal::TensorIntDivisor<Index>(m_otherStride); + m_fastPatchStride = internal::TensorIntDivisor<Index>(m_patchStride); + m_fastColStride = internal::TensorIntDivisor<Index>(m_colStride); + // Number of patches in the width dimension. + m_fastOutputRows = internal::TensorIntDivisor<Index>(m_outputRows); + m_fastDimZero = internal::TensorIntDivisor<Index>(m_dimensions[0]); + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + // Patch index corresponding to the passed in index. + const Index patchIndex = index / m_fastPatchStride; + + // Find the offset of the element wrt the location of the first element. + const Index patchOffset = (index - patchIndex * m_patchStride) / m_fastDimZero; + + // Other ways to index this element. + const Index otherIndex = (NumDims == 4) ? 0 : index / m_fastOtherStride; + const Index patch2DIndex = (NumDims == 4) ? patchIndex : (index - otherIndex * m_otherStride) / m_fastPatchStride; + + const Index colIndex = patch2DIndex / m_fastOutputRows; + const Index colOffset = patchOffset / m_fastColStride; + + // Calculate col index in the input original tensor. + const Index inputCol = colIndex * m_col_strides + colOffset - m_colPaddingLeft; + if (inputCol < 0 || inputCol >= m_inputCols) { + return Scalar(0); + } + const Index rowIndex = patch2DIndex - colIndex * m_outputRows; + const Index rowOffset = patchOffset - colOffset * m_colStride; + + // Calculate row index in the original input tensor. + const Index inputRow = rowIndex * m_row_strides + rowOffset - m_rowPaddingTop; + if (inputRow < 0 || inputRow >= m_inputRows) { + return Scalar(0); + } + + const Index depth = index - (index / m_fastDimZero) * m_dimensions[0]; + + const Index inputIndex = depth + inputRow * m_rowInputStride + inputCol * m_colInputStride + otherIndex * m_patchInputStride; + return m_impl.coeff(inputIndex); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const Index packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + const Index indices[2] = {index, index + packetSize - 1}; + const Index patchIndex = indices[0] / m_fastPatchStride; + if (patchIndex != indices[1] / m_fastPatchStride) { + return packetWithPossibleZero(index); + } + const Index otherIndex = (NumDims == 4) ? 0 : indices[0] / m_fastOtherStride; + eigen_assert(otherIndex == indices[1] / m_fastOtherStride); + + // Find the offset of the element wrt the location of the first element. + const Index patchOffsets[2] = {(indices[0] - patchIndex * m_patchStride) / m_fastDimZero, + (indices[1] - patchIndex * m_patchStride) / m_fastDimZero}; + + const Index patch2DIndex = (NumDims == 4) ? patchIndex : (indices[0] - otherIndex * m_otherStride) / m_fastPatchStride; + eigen_assert(patch2DIndex == (indices[1] - otherIndex * m_otherStride) / m_fastPatchStride); + + const Index colIndex = patch2DIndex / m_fastOutputRows; + const Index colOffsets[2] = {patchOffsets[0] / m_fastColStride, patchOffsets[1] / m_fastColStride}; + + // Calculate col indices in the original input tensor. + const Index inputCols[2] = {colIndex * m_col_strides + colOffsets[0] - + m_colPaddingLeft, colIndex * m_col_strides + colOffsets[1] - m_colPaddingLeft}; + if (inputCols[1] < 0 || inputCols[0] >= m_inputCols) { + // all zeros + return internal::pset1<PacketReturnType>(Scalar(0)); + } + + if (inputCols[0] == inputCols[1]) { + const Index rowIndex = patch2DIndex - colIndex * m_outputRows; + const Index rowOffsets[2] = {patchOffsets[0] - colOffsets[0]*m_colStride, patchOffsets[1] - colOffsets[1]*m_colStride}; + eigen_assert(rowOffsets[0] <= rowOffsets[1]); + // Calculate col indices in the original input tensor. + const Index inputRows[2] = {rowIndex * m_row_strides + rowOffsets[0] - + m_rowPaddingTop, rowIndex * m_row_strides + rowOffsets[1] - m_rowPaddingTop}; + + if (inputRows[1] < 0 || inputRows[0] >= m_inputRows) { + // all zeros + return internal::pset1<PacketReturnType>(Scalar(0)); + } + + if (inputRows[0] >= 0 && inputRows[1] < m_inputRows) { + // no padding + const Index depth = index - (index / m_fastDimZero) * m_dimensions[0]; + const Index inputIndex = depth + inputRows[0] * m_rowInputStride + inputCols[0] * m_colInputStride + otherIndex * m_patchInputStride; + return m_impl.template packet<Unaligned>(inputIndex); + } + } + + return packetWithPossibleZero(index); + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + const TensorEvaluator<ArgType, Device>& impl() const { return m_impl; } + + Index rowPaddingTop() const { return m_rowPaddingTop; } + Index colPaddingLeft() const { return m_colPaddingLeft; } + Index outputRows() const { return m_outputRows; } + Index outputCols() const { return m_outputCols; } + Index userRowStride() const { return m_row_strides; } + Index userColStride() const { return m_col_strides; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<Index, NumDims>& coords) const + { + // Location of the first element of the patch. + // 0: d, 1: patch_rows, 2: patch_cols, 3: number of patches, 4: number of batches + const Index patchIndex = coords[3]; + + array<Index, NumDims-1> inputCoords; + inputCoords[0] = coords[0]; // depth + inputCoords[1] = patchIndex / m_inputCols + coords[1] - m_rowPaddingTop; + inputCoords[2] = patchIndex - patchIndex / m_inputCols * m_inputCols + coords[2] - m_colPaddingLeft; + inputCoords[3] = coords[4]; // batch + // If the computed coordinates are outside the original image perimeter, return 0. + if (inputCoords[1] < 0 || inputCoords[1] >= m_inputRows || + inputCoords[2] < 0 || inputCoords[2] >= m_inputCols) { + return Scalar(0); + } + if (TensorEvaluator<ArgType, Device>::CoordAccess) { + return m_impl.coeff(inputCoords); + } else { + Index inputIndex = + inputCoords[3] * m_patchInputStride + + inputCoords[2] * m_colInputStride + + inputCoords[1] * m_rowInputStride + + inputCoords[0]; + return m_impl.coeff(inputIndex); + } + } + + protected: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetWithPossibleZero(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + Dimensions m_dimensions; + + Index m_otherStride; + Index m_patchStride; + Index m_colStride; + Index m_row_strides; + Index m_col_strides; + internal::TensorIntDivisor<Index> m_fastOtherStride; + internal::TensorIntDivisor<Index> m_fastPatchStride; + internal::TensorIntDivisor<Index> m_fastColStride; + + Index m_rowInputStride; + Index m_colInputStride; + Index m_patchInputStride; + + Index m_inputRows; + Index m_inputCols; + + Index m_outputRows; + Index m_outputCols; + + Index m_rowPaddingTop; + Index m_colPaddingLeft; + + internal::TensorIntDivisor<Index> m_fastOutputRows; + internal::TensorIntDivisor<Index> m_fastDimZero; + + TensorEvaluator<ArgType, Device> m_impl; +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_IMAGE_PATCH_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorIndexList.h b/unsupported/Eigen/CXX11/src/Tensor/TensorIndexList.h new file mode 100644 index 000000000..eed0a9f05 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorIndexList.h @@ -0,0 +1,419 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_INDEX_LIST_H +#define EIGEN_CXX11_TENSOR_TENSOR_INDEX_LIST_H + +#ifdef EIGEN_HAS_CONSTEXPR + +namespace Eigen { + +/** \internal + * + * \class TensorIndexList + * \ingroup CXX11_Tensor_Module + * + * \brief Set of classes used to encode a set of Tensor dimensions/indices. + * + * The indices in the list can be known at compile time or at runtime. A mix + * of static and dynamic indices can also be provided if needed. The tensor + * code will attempt to take advantage of the indices that are known at + * compile time to optimize the code it generates. + * + * This functionality requires a c++11 compliant compiler. If your compiler + * is older you need to use arrays of indices instead. + * + * Several examples are provided in the cxx11_tensor_index_list.cpp file. + * + * \sa Tensor + */ + +template <DenseIndex n> +struct type2index { + static const DenseIndex value = n; + constexpr operator DenseIndex() const { return n; } + void set(DenseIndex val) { + eigen_assert(val == n); + } +}; + +namespace internal { +template <typename T> +void update_value(T& val, DenseIndex new_val) { + val = new_val; +} +template <DenseIndex n> +void update_value(type2index<n>& val, DenseIndex new_val) { + val.set(new_val); +} + +template <typename T> +struct is_compile_time_constant { + static constexpr bool value = false; +}; + +template <DenseIndex idx> +struct is_compile_time_constant<type2index<idx> > { + static constexpr bool value = true; +}; +template <DenseIndex idx> +struct is_compile_time_constant<const type2index<idx> > { + static constexpr bool value = true; +}; +template <DenseIndex idx> +struct is_compile_time_constant<type2index<idx>& > { + static constexpr bool value = true; +}; +template <DenseIndex idx> +struct is_compile_time_constant<const type2index<idx>& > { + static constexpr bool value = true; +}; + +template <DenseIndex Idx> +struct tuple_coeff { + template <typename... T> + static constexpr DenseIndex get(const DenseIndex i, const std::tuple<T...>& t) { + return std::get<Idx>(t) * (i == Idx) + tuple_coeff<Idx-1>::get(i, t) * (i != Idx); + } + template <typename... T> + static void set(const DenseIndex i, std::tuple<T...>& t, const DenseIndex value) { + if (i == Idx) { + update_value(std::get<Idx>(t), value); + } else { + tuple_coeff<Idx-1>::set(i, t, value); + } + } + + template <typename... T> + static constexpr bool value_known_statically(const DenseIndex i, const std::tuple<T...>& t) { + return ((i == Idx) & is_compile_time_constant<typename std::tuple_element<Idx, std::tuple<T...> >::type>::value) || + tuple_coeff<Idx-1>::value_known_statically(i, t); + } + + template <typename... T> + static constexpr bool values_up_to_known_statically(const std::tuple<T...>& t) { + return is_compile_time_constant<typename std::tuple_element<Idx, std::tuple<T...> >::type>::value && + tuple_coeff<Idx-1>::values_up_to_known_statically(t); + } + + template <typename... T> + static constexpr bool values_up_to_statically_known_to_increase(const std::tuple<T...>& t) { + return is_compile_time_constant<typename std::tuple_element<Idx, std::tuple<T...> >::type>::value && + is_compile_time_constant<typename std::tuple_element<Idx-1, std::tuple<T...> >::type>::value && + std::get<Idx>(t) > std::get<Idx-1>(t) && + tuple_coeff<Idx-1>::values_up_to_statically_known_to_increase(t); + } +}; + +template <> +struct tuple_coeff<0> { + template <typename... T> + static constexpr DenseIndex get(const DenseIndex i, const std::tuple<T...>& t) { + // eigen_assert (i == 0); // gcc fails to compile assertions in constexpr + return std::get<0>(t) * (i == 0); + } + template <typename... T> + static void set(const DenseIndex i, std::tuple<T...>& t, const DenseIndex value) { + eigen_assert (i == 0); + update_value(std::get<0>(t), value); + } + template <typename... T> + static constexpr bool value_known_statically(const DenseIndex i, const std::tuple<T...>&) { + // eigen_assert (i == 0); // gcc fails to compile assertions in constexpr + return is_compile_time_constant<typename std::tuple_element<0, std::tuple<T...> >::type>::value & (i == 0); + } + + template <typename... T> + static constexpr bool values_up_to_known_statically(const std::tuple<T...>&) { + return is_compile_time_constant<typename std::tuple_element<0, std::tuple<T...> >::type>::value; + } + + template <typename... T> + static constexpr bool values_up_to_statically_known_to_increase(const std::tuple<T...>&) { + return true; + } +}; +} // namespace internal + + +template<typename FirstType, typename... OtherTypes> +struct IndexList : std::tuple<FirstType, OtherTypes...> { + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC constexpr DenseIndex operator[] (const DenseIndex i) const { + return internal::tuple_coeff<std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value-1>::get(i, *this); + } + EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC void set(const DenseIndex i, const DenseIndex value) { + return internal::tuple_coeff<std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value-1>::set(i, *this, value); + } + + constexpr IndexList(const std::tuple<FirstType, OtherTypes...>& other) : std::tuple<FirstType, OtherTypes...>(other) { } + constexpr IndexList() : std::tuple<FirstType, OtherTypes...>() { } + + constexpr bool value_known_statically(const DenseIndex i) const { + return internal::tuple_coeff<std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value-1>::value_known_statically(i, *this); + } + constexpr bool all_values_known_statically() const { + return internal::tuple_coeff<std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value-1>::values_up_to_known_statically(*this); + } + + constexpr bool values_statically_known_to_increase() const { + return internal::tuple_coeff<std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value-1>::values_up_to_statically_known_to_increase(*this); + } +}; + + +template<typename FirstType, typename... OtherTypes> +constexpr IndexList<FirstType, OtherTypes...> make_index_list(FirstType val1, OtherTypes... other_vals) { + return std::make_tuple(val1, other_vals...); +} + + +namespace internal { + +template<typename FirstType, typename... OtherTypes> size_t array_prod(const IndexList<FirstType, OtherTypes...>& sizes) { + size_t result = 1; + for (int i = 0; i < array_size<IndexList<FirstType, OtherTypes...> >::value; ++i) { + result *= sizes[i]; + } + return result; +}; + +template<typename FirstType, typename... OtherTypes> struct array_size<IndexList<FirstType, OtherTypes...> > { + static const size_t value = std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value; +}; +template<typename FirstType, typename... OtherTypes> struct array_size<const IndexList<FirstType, OtherTypes...> > { + static const size_t value = std::tuple_size<std::tuple<FirstType, OtherTypes...> >::value; +}; + +template<DenseIndex n, typename FirstType, typename... OtherTypes> constexpr DenseIndex array_get(IndexList<FirstType, OtherTypes...>& a) { + return std::get<n>(a); +} +template<DenseIndex n, typename FirstType, typename... OtherTypes> constexpr DenseIndex array_get(const IndexList<FirstType, OtherTypes...>& a) { + return std::get<n>(a); +} + +template <typename T> +struct index_known_statically { + constexpr bool operator() (DenseIndex) const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_known_statically<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_known_statically<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i); + } +}; + +template <typename T> +struct all_indices_known_statically { + constexpr bool operator() () const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct all_indices_known_statically<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() () const { + return IndexList<FirstType, OtherTypes...>().all_values_known_statically(); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct all_indices_known_statically<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() () const { + return IndexList<FirstType, OtherTypes...>().all_values_known_statically(); + } +}; + +template <typename T> +struct indices_statically_known_to_increase { + constexpr bool operator() () const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct indices_statically_known_to_increase<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() () const { + return IndexList<FirstType, OtherTypes...>().values_statically_known_to_increase(); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct indices_statically_known_to_increase<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() () const { + return IndexList<FirstType, OtherTypes...>().values_statically_known_to_increase(); + } +}; + +template <typename Tx> +struct index_statically_eq { + constexpr bool operator() (DenseIndex, DenseIndex) const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_eq<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] == value); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_eq<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] == value); + } +}; + +template <typename T> +struct index_statically_ne { + constexpr bool operator() (DenseIndex, DenseIndex) const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_ne<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] != value); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_ne<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] != value); + } +}; + + +template <typename T> +struct index_statically_gt { + constexpr bool operator() (DenseIndex, DenseIndex) const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_gt<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] > value); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_gt<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] > value); + } +}; + +template <typename T> +struct index_statically_lt { + constexpr bool operator() (DenseIndex, DenseIndex) const { + return false; + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_lt<IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] < value); + } +}; + +template <typename FirstType, typename... OtherTypes> +struct index_statically_lt<const IndexList<FirstType, OtherTypes...> > { + constexpr bool operator() (const DenseIndex i, const DenseIndex value) const { + return IndexList<FirstType, OtherTypes...>().value_known_statically(i) & + (IndexList<FirstType, OtherTypes...>()[i] < value); + } +}; + +} // end namespace internal +} // end namespace Eigen + +#else + +namespace Eigen { +namespace internal { + +// No C++11 support +template <typename T> +struct index_known_statically { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() (DenseIndex) const{ + return false; + } +}; + +template <typename T> +struct all_indices_known_statically { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() () const { + return false; + } +}; + +template <typename T> +struct indices_statically_known_to_increase { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() () const { + return false; + } +}; + +template <typename T> +struct index_statically_eq { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() (DenseIndex, DenseIndex) const{ + return false; + } +}; + +template <typename T> +struct index_statically_ne { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() (DenseIndex, DenseIndex) const{ + return false; + } +}; + +template <typename T> +struct index_statically_gt { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() (DenseIndex, DenseIndex) const{ + return false; + } +}; + +template <typename T> +struct index_statically_lt { + EIGEN_ALWAYS_INLINE EIGEN_DEVICE_FUNC bool operator() (DenseIndex, DenseIndex) const{ + return false; + } +}; + +} // end namespace internal +} // end namespace Eigen + +#endif + +#endif // EIGEN_CXX11_TENSOR_TENSOR_INDEX_LIST_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorInitializer.h b/unsupported/Eigen/CXX11/src/Tensor/TensorInitializer.h new file mode 100644 index 000000000..4303e3536 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorInitializer.h @@ -0,0 +1,70 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_INITIALIZER_H +#define EIGEN_CXX11_TENSOR_TENSOR_INITIALIZER_H + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + +#include <initializer_list> + +namespace Eigen { + +/** \class TensorInitializer + * \ingroup CXX11_Tensor_Module + * + * \brief Helper template to initialize Tensors from std::initializer_lists. + */ +namespace internal { + +template <typename Derived, int N> +struct Initializer { + typedef std::initializer_list< + typename Initializer<Derived, N - 1>::InitList> InitList; + + static void run(TensorEvaluator<Derived, DefaultDevice>& tensor, + Eigen::array<typename traits<Derived>::Index, traits<Derived>::NumDimensions>* indices, + const InitList& vals) { + int i = 0; + for (auto v : vals) { + (*indices)[traits<Derived>::NumDimensions - N] = i++; + Initializer<Derived, N - 1>::run(tensor, indices, v); + } + } +}; + +template <typename Derived> +struct Initializer<Derived, 1> { + typedef std::initializer_list<typename traits<Derived>::Scalar> InitList; + + static void run(TensorEvaluator<Derived, DefaultDevice>& tensor, + Eigen::array<typename traits<Derived>::Index, traits<Derived>::NumDimensions>* indices, + const InitList& vals) { + int i = 0; + // There is likely a faster way to do that than iterating. + for (auto v : vals) { + (*indices)[traits<Derived>::NumDimensions - 1] = i++; + tensor.coeffRef(*indices) = v; + } + } +}; + +template <typename Derived, int N> +void initialize_tensor(TensorEvaluator<Derived, DefaultDevice>& tensor, + const typename Initializer<Derived, traits<Derived>::NumDimensions>::InitList& vals) { + Eigen::array<typename traits<Derived>::Index, traits<Derived>::NumDimensions> indices; + Initializer<Derived, traits<Derived>::NumDimensions>::run(tensor, &indices, vals); +} + +} // namespace internal +} // namespace Eigen + +#endif // EIGEN_HAS_VARIADIC_TEMPLATES + +#endif // EIGEN_CXX11_TENSOR_TENSOR_INITIALIZER_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorIntDiv.h b/unsupported/Eigen/CXX11/src/Tensor/TensorIntDiv.h new file mode 100644 index 000000000..2714117ab --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorIntDiv.h @@ -0,0 +1,86 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_INTDIV_H +#define EIGEN_CXX11_TENSOR_TENSOR_INTDIV_H + + +namespace Eigen { + +/** \internal + * + * \class TensorIntDiv + * \ingroup CXX11_Tensor_Module + * + * \brief Fast integer division by a constant. + * + * See the paper from Granlund and Montgomery for explanation. + * (at http://dx.doi.org/10.1145/773473.178249) + * + * \sa Tensor + */ + +namespace internal { + +template <typename T> +struct TensorIntDivisor { + public: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorIntDivisor() { + multiplier = 0; + shift1 = 0; + shift2 = 0; + } + + // Must have 1 <= divider <= 2^31-1 + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorIntDivisor(const T divider) { + const int N = 32; + eigen_assert(divider > 0); + eigen_assert(divider <= (1<<(N-1)) - 1); + + // fast ln2 +#ifndef __CUDA_ARCH__ + const int leading_zeros = __builtin_clz(divider); +#else + const int leading_zeros = __clz(divider); +#endif + const int log_div = N - (leading_zeros+1); + + multiplier = (static_cast<uint64_t>(1) << (N+log_div)) / divider - (static_cast<uint64_t>(1) << N) + 1; + shift1 = log_div > 1 ? 1 : log_div; + shift2 = log_div > 1 ? log_div-1 : 0; + } + + // Must have 0 <= numerator <= 2^32-1 + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T divide(const T numerator) const { + const int N = 32; + eigen_assert(numerator >= 0); + eigen_assert(numerator <= (1ull<<N) - 1); + + uint32_t t1 = (multiplier * numerator) >> 32; + uint32_t t = (static_cast<uint32_t>(numerator) - t1) >> shift1; + return (t1 + t) >> shift2; + } + + private: + uint64_t multiplier; + int32_t shift1; + int32_t shift2; +}; + + +template <typename T> +static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T operator / (const T& numerator, const TensorIntDivisor<T>& divisor) { + return divisor.divide(numerator); +} + + +} // end namespace internal +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_INTDIV_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorLayoutSwap.h b/unsupported/Eigen/CXX11/src/Tensor/TensorLayoutSwap.h new file mode 100644 index 000000000..c119b30e2 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorLayoutSwap.h @@ -0,0 +1,198 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_LAYOUT_SWAP_H +#define EIGEN_CXX11_TENSOR_TENSOR_LAYOUT_SWAP_H + +namespace Eigen { + +/** \class TensorLayoutSwap + * \ingroup CXX11_Tensor_Module + * + * \brief Swap the layout from col-major to row-major, or row-major + * to col-major, and invert the order of the dimensions. + * + * Beware: the dimensions are reversed by this operation. If you want to + * preserve the ordering of the dimensions, you need to combine this + * operation with a shuffle. + * + * \example: + * Tensor<float, 2, ColMajor> input(2, 4); + * Tensor<float, 2, RowMajor> output = input.swap_layout(); + * eigen_assert(output.dimension(0) == 4); + * eigen_assert(output.dimension(1) == 2); + * + * array<int, 2> shuffle(1, 0); + * output = input.swap_layout().shuffle(shuffle); + * eigen_assert(output.dimension(0) == 2); + * eigen_assert(output.dimension(1) == 4); + * + */ +namespace internal { +template<typename XprType> +struct traits<TensorLayoutSwapOp<XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = traits<XprType>::NumDimensions; + static const int Layout = (traits<XprType>::Layout == ColMajor) ? RowMajor : ColMajor; +}; + +template<typename XprType> +struct eval<TensorLayoutSwapOp<XprType>, Eigen::Dense> +{ + typedef const TensorLayoutSwapOp<XprType>& type; +}; + +template<typename XprType> +struct nested<TensorLayoutSwapOp<XprType>, 1, typename eval<TensorLayoutSwapOp<XprType> >::type> +{ + typedef TensorLayoutSwapOp<XprType> type; +}; + +} // end namespace internal + + + +template<typename XprType> +class TensorLayoutSwapOp : public TensorBase<TensorLayoutSwapOp<XprType>, WriteAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorLayoutSwapOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorLayoutSwapOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorLayoutSwapOp>::type Nested; + typedef typename Eigen::internal::traits<TensorLayoutSwapOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorLayoutSwapOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorLayoutSwapOp(const XprType& expr) + : m_xpr(expr) {} + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorLayoutSwapOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorLayoutSwapOp, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + protected: + typename XprType::Nested m_xpr; +}; + + +// Eval as rvalue +template<typename ArgType, typename Device> +struct TensorEvaluator<const TensorLayoutSwapOp<ArgType>, Device> +{ + typedef TensorLayoutSwapOp<ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = TensorEvaluator<ArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = (static_cast<int>(TensorEvaluator<ArgType, Device>::Layout) == static_cast<int>(ColMajor)) ? RowMajor : ColMajor, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + for(int i = 0; i < NumDims; ++i) { + m_dimensions[i] = m_impl.dimensions()[NumDims-1-i]; + } + } + + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType* data) { + return m_impl.evalSubExprsIfNeeded(data); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(index); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return m_impl.template packet<LoadMode>(index); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return m_impl.data(); } + + const TensorEvaluator<ArgType, Device>& impl() const { return m_impl; } + + protected: + TensorEvaluator<ArgType, Device> m_impl; + Dimensions m_dimensions; +}; + + +// Eval as lvalue +template<typename ArgType, typename Device> + struct TensorEvaluator<TensorLayoutSwapOp<ArgType>, Device> + : public TensorEvaluator<const TensorLayoutSwapOp<ArgType>, Device> +{ + typedef TensorEvaluator<const TensorLayoutSwapOp<ArgType>, Device> Base; + typedef TensorLayoutSwapOp<ArgType> XprType; + + enum { + IsAligned = TensorEvaluator<ArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = (static_cast<int>(TensorEvaluator<ArgType, Device>::Layout) == static_cast<int>(ColMajor)) ? RowMajor : ColMajor, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) + { + return this->m_impl.coeffRef(index); + } + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + this->m_impl.template writePacket<StoreMode>(index, x); + } +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_LAYOUT_SWAP_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorMap.h b/unsupported/Eigen/CXX11/src/Tensor/TensorMap.h new file mode 100644 index 000000000..2cb2bc7a6 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorMap.h @@ -0,0 +1,291 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_MAP_H +#define EIGEN_CXX11_TENSOR_TENSOR_MAP_H + +namespace Eigen { + +/** \class TensorMap + * \ingroup CXX11_Tensor_Module + * + * \brief A tensor expression mapping an existing array of data. + * + */ + +template<typename PlainObjectType, int Options_> class TensorMap : public TensorBase<TensorMap<PlainObjectType, Options_> > +{ + public: + typedef TensorMap<PlainObjectType, Options_> Self; + typedef typename PlainObjectType::Base Base; + typedef typename Eigen::internal::nested<Self>::type Nested; + typedef typename internal::traits<PlainObjectType>::StorageKind StorageKind; + typedef typename internal::traits<PlainObjectType>::Index Index; + typedef typename internal::traits<PlainObjectType>::Scalar Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename NumTraits<Scalar>::Real RealScalar; + typedef typename Base::CoeffReturnType CoeffReturnType; + + /* typedef typename internal::conditional< + bool(internal::is_lvalue<PlainObjectType>::value), + Scalar *, + const Scalar *>::type + PointerType;*/ + typedef Scalar* PointerType; + typedef PointerType PointerArgType; + + static const int Options = Options_; + + static const Index NumIndices = PlainObjectType::NumIndices; + typedef typename PlainObjectType::Dimensions Dimensions; + + enum { + IsAligned = ((int(Options_)&Aligned)==Aligned), + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = PlainObjectType::Layout, + CoordAccess = true, + }; + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index firstDimension, IndexTypes... otherDimensions) : m_data(dataPtr), m_dimensions(firstDimension, otherDimensions...) { + // The number of dimensions used to construct a tensor must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT((sizeof...(otherDimensions) + 1 == NumIndices || NumIndices == Dynamic), YOU_MADE_A_PROGRAMMING_MISTAKE) + } +#else + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index firstDimension) : m_data(dataPtr), m_dimensions(firstDimension) { + // The number of dimensions used to construct a tensor must be equal to the rank of the tensor. + EIGEN_STATIC_ASSERT((1 == NumIndices || NumIndices == Dynamic), YOU_MADE_A_PROGRAMMING_MISTAKE) + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index dim1, Index dim2) : m_data(dataPtr), m_dimensions(dim1, dim2) { + EIGEN_STATIC_ASSERT(2 == NumIndices || NumIndices == Dynamic, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index dim1, Index dim2, Index dim3) : m_data(dataPtr), m_dimensions(dim1, dim2, dim3) { + EIGEN_STATIC_ASSERT(3 == NumIndices || NumIndices == Dynamic, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index dim1, Index dim2, Index dim3, Index dim4) : m_data(dataPtr), m_dimensions(dim1, dim2, dim3, dim4) { + EIGEN_STATIC_ASSERT(4 == NumIndices || NumIndices == Dynamic, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, Index dim1, Index dim2, Index dim3, Index dim4, Index dim5) : m_data(dataPtr), m_dimensions(dim1, dim2, dim3, dim4, dim5) { + EIGEN_STATIC_ASSERT(5 == NumIndices || NumIndices == Dynamic, YOU_MADE_A_PROGRAMMING_MISTAKE) + } +#endif + + inline TensorMap(PointerArgType dataPtr, const array<Index, NumIndices>& dimensions) + : m_data(dataPtr), m_dimensions(dimensions) + { } + + template <typename Dimensions> + EIGEN_STRONG_INLINE TensorMap(PointerArgType dataPtr, const Dimensions& dimensions) + : m_data(dataPtr), m_dimensions(dimensions) + { } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index rank() const { return m_dimensions.rank(); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index dimension(Index n) const { return m_dimensions[n]; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index size() const { return m_dimensions.TotalSize(); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar* data() { return m_data; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar* data() const { return m_data; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(const array<Index, NumIndices>& indices) const + { + // eigen_assert(checkIndexRange(indices)); + if (PlainObjectType::Options&RowMajor) { + const Index index = m_dimensions.IndexOfRowMajor(indices); + return m_data[index]; + } else { + const Index index = m_dimensions.IndexOfColMajor(indices); + return m_data[index]; + } + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) const + { + static_assert(sizeof...(otherIndices) + 1 == NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); + if (PlainObjectType::Options&RowMajor) { + const Index index = m_dimensions.IndexOfRowMajor(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + return m_data[index]; + } else { + const Index index = m_dimensions.IndexOfColMajor(array<Index, NumIndices>{{firstIndex, otherIndices...}}); + return m_data[index]; + } + } +#else + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index index) const + { + eigen_internal_assert(index >= 0 && index < size()); + return m_data[index]; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1) const + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i1 + i0 * m_dimensions[0]; + return m_data[index]; + } else { + const Index index = i0 + i1 * m_dimensions[0]; + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2) const + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i2 + m_dimensions[1] * (i1 + m_dimensions[0] * i0); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * i2); + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2, Index i3) const + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i3 + m_dimensions[3] * (i2 + m_dimensions[2] * (i1 + m_dimensions[1] * i0)); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * (i2 + m_dimensions[2] * i3)); + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar& operator()(Index i0, Index i1, Index i2, Index i3, Index i4) const + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i4 + m_dimensions[4] * (i3 + m_dimensions[3] * (i2 + m_dimensions[2] * (i1 + m_dimensions[1] * i0))); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * (i2 + m_dimensions[2] * (i3 + m_dimensions[3] * i4))); + return m_data[index]; + } + } +#endif + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(const array<Index, NumIndices>& indices) + { + // eigen_assert(checkIndexRange(indices)); + if (PlainObjectType::Options&RowMajor) { + const Index index = m_dimensions.IndexOfRowMajor(indices); + return m_data[index]; + } else { + const Index index = m_dimensions.IndexOfColMajor(indices); + return m_data[index]; + } + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index firstIndex, IndexTypes... otherIndices) + { + static_assert(sizeof...(otherIndices) + 1 == NumIndices || NumIndices == Dynamic, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor."); + const std::size_t NumDims = sizeof...(otherIndices) + 1; + if (PlainObjectType::Options&RowMajor) { + const Index index = m_dimensions.IndexOfRowMajor(array<Index, NumDims>{{firstIndex, otherIndices...}}); + return m_data[index]; + } else { + const Index index = m_dimensions.IndexOfColMajor(array<Index, NumDims>{{firstIndex, otherIndices...}}); + return m_data[index]; + } + } +#else + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index index) + { + eigen_internal_assert(index >= 0 && index < size()); + return m_data[index]; + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1) + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i1 + i0 * m_dimensions[0]; + return m_data[index]; + } else { + const Index index = i0 + i1 * m_dimensions[0]; + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2) + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i2 + m_dimensions[1] * (i1 + m_dimensions[0] * i0); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * i2); + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3) + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i3 + m_dimensions[3] * (i2 + m_dimensions[2] * (i1 + m_dimensions[1] * i0)); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * (i2 + m_dimensions[2] * i3)); + return m_data[index]; + } + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3, Index i4) + { + if (PlainObjectType::Options&RowMajor) { + const Index index = i4 + m_dimensions[4] * (i3 + m_dimensions[3] * (i2 + m_dimensions[2] * (i1 + m_dimensions[1] * i0))); + return m_data[index]; + } else { + const Index index = i0 + m_dimensions[0] * (i1 + m_dimensions[1] * (i2 + m_dimensions[2] * (i3 + m_dimensions[3] * i4))); + return m_data[index]; + } + } +#endif + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Self& operator=(const Self& other) + { + typedef TensorAssignOp<Self, const Self> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + Self& operator=(const OtherDerived& other) + { + typedef TensorAssignOp<Self, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice>::run(assign, DefaultDevice()); + return *this; + } + + private: + Scalar* m_data; + Dimensions m_dimensions; +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_MAP_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorMorphing.h b/unsupported/Eigen/CXX11/src/Tensor/TensorMorphing.h new file mode 100644 index 000000000..a93f48ccb --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorMorphing.h @@ -0,0 +1,600 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_MORPHING_H +#define EIGEN_CXX11_TENSOR_TENSOR_MORPHING_H + +namespace Eigen { + +/** \class TensorReshaping + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor reshaping class. + * + * + */ +namespace internal { +template<typename NewDimensions, typename XprType> +struct traits<TensorReshapingOp<NewDimensions, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = array_size<NewDimensions>::value; + static const int Layout = XprTraits::Layout; +}; + +template<typename NewDimensions, typename XprType> +struct eval<TensorReshapingOp<NewDimensions, XprType>, Eigen::Dense> +{ + typedef const TensorReshapingOp<NewDimensions, XprType>& type; +}; + +template<typename NewDimensions, typename XprType> +struct nested<TensorReshapingOp<NewDimensions, XprType>, 1, typename eval<TensorReshapingOp<NewDimensions, XprType> >::type> +{ + typedef TensorReshapingOp<NewDimensions, XprType> type; +}; + +} // end namespace internal + + + +template<typename NewDimensions, typename XprType> +class TensorReshapingOp : public TensorBase<TensorReshapingOp<NewDimensions, XprType>, WriteAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorReshapingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorReshapingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorReshapingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorReshapingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorReshapingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorReshapingOp(const XprType& expr, const NewDimensions& dims) + : m_xpr(expr), m_dims(dims) {} + + EIGEN_DEVICE_FUNC + const NewDimensions& dimensions() const { return m_dims; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorReshapingOp& operator = (const TensorReshapingOp& other) + { + typedef TensorAssignOp<TensorReshapingOp, const TensorReshapingOp> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorReshapingOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorReshapingOp, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + protected: + typename XprType::Nested m_xpr; + const NewDimensions m_dims; +}; + + +// Eval as rvalue +template<typename NewDimensions, typename ArgType, typename Device> +struct TensorEvaluator<const TensorReshapingOp<NewDimensions, ArgType>, Device> +{ + typedef TensorReshapingOp<NewDimensions, ArgType> XprType; + typedef NewDimensions Dimensions; + + enum { + IsAligned = TensorEvaluator<ArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_dimensions(op.dimensions()) + { + // The total size of the reshaped tensor must be equal to the total size + // of the input tensor. + eigen_assert(internal::array_prod(m_impl.dimensions()) == internal::array_prod(op.dimensions())); + } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType* data) { + return m_impl.evalSubExprsIfNeeded(data); + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(index); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + return m_impl.template packet<LoadMode>(index); + } + + EIGEN_DEVICE_FUNC CoeffReturnType* data() const { return m_impl.data(); } + + const TensorEvaluator<ArgType, Device>& impl() const { return m_impl; } + + protected: + TensorEvaluator<ArgType, Device> m_impl; + NewDimensions m_dimensions; +}; + + +// Eval as lvalue +template<typename NewDimensions, typename ArgType, typename Device> + struct TensorEvaluator<TensorReshapingOp<NewDimensions, ArgType>, Device> + : public TensorEvaluator<const TensorReshapingOp<NewDimensions, ArgType>, Device> + +{ + typedef TensorEvaluator<const TensorReshapingOp<NewDimensions, ArgType>, Device> Base; + typedef TensorReshapingOp<NewDimensions, ArgType> XprType; + typedef NewDimensions Dimensions; + + enum { + IsAligned = TensorEvaluator<ArgType, Device>::IsAligned, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) + { + return this->m_impl.coeffRef(index); + } + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + this->m_impl.template writePacket<StoreMode>(index, x); + } +}; + + +/** \class TensorSlicing + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor slicing class. + * + * + */ +namespace internal { +template<typename StartIndices, typename Sizes, typename XprType> +struct traits<TensorSlicingOp<StartIndices, Sizes, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = array_size<StartIndices>::value; + static const int Layout = XprTraits::Layout; +}; + +template<typename StartIndices, typename Sizes, typename XprType> +struct eval<TensorSlicingOp<StartIndices, Sizes, XprType>, Eigen::Dense> +{ + typedef const TensorSlicingOp<StartIndices, Sizes, XprType>& type; +}; + +template<typename StartIndices, typename Sizes, typename XprType> +struct nested<TensorSlicingOp<StartIndices, Sizes, XprType>, 1, typename eval<TensorSlicingOp<StartIndices, Sizes, XprType> >::type> +{ + typedef TensorSlicingOp<StartIndices, Sizes, XprType> type; +}; + +} // end namespace internal + + + +template<typename StartIndices, typename Sizes, typename XprType> +class TensorSlicingOp : public TensorBase<TensorSlicingOp<StartIndices, Sizes, XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorSlicingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorSlicingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorSlicingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorSlicingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorSlicingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorSlicingOp(const XprType& expr, const StartIndices& indices, const Sizes& sizes) + : m_xpr(expr), m_indices(indices), m_sizes(sizes) {} + + EIGEN_DEVICE_FUNC + const StartIndices& startIndices() const { return m_indices; } + EIGEN_DEVICE_FUNC + const Sizes& sizes() const { return m_sizes; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorSlicingOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorSlicingOp, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorSlicingOp& operator = (const TensorSlicingOp& other) + { + typedef TensorAssignOp<TensorSlicingOp, const TensorSlicingOp> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + + protected: + typename XprType::Nested m_xpr; + const StartIndices m_indices; + const Sizes m_sizes; +}; + + +// Eval as rvalue +template<typename StartIndices, typename Sizes, typename ArgType, typename Device> +struct TensorEvaluator<const TensorSlicingOp<StartIndices, Sizes, ArgType>, Device> +{ + typedef TensorSlicingOp<StartIndices, Sizes, ArgType> XprType; + static const int NumDims = internal::array_size<Sizes>::value; + + enum { + // Alignment can't be guaranteed at compile time since it depends on the + // slice offsets and sizes. + IsAligned = /*TensorEvaluator<ArgType, Device>::IsAligned*/false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = TensorEvaluator<ArgType, Device>::CoordAccess, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_device(device), m_dimensions(op.sizes()), m_offsets(op.startIndices()) + { + for (int i = 0; i < internal::array_size<Dimensions>::value; ++i) { + eigen_assert(m_impl.dimensions()[i] >= op.sizes()[i] + op.startIndices()[i]); + } + + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + const Sizes& output_dims = op.sizes(); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_inputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_inputStrides[i] = m_inputStrides[i-1] * input_dims[i-1]; + } + + m_outputStrides[0] = 1; + m_fastOutputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_outputStrides[i] = m_outputStrides[i-1] * output_dims[i-1]; + m_fastOutputStrides[i] = internal::TensorIntDivisor<Index>(m_outputStrides[i]); + } + } else { + m_inputStrides[NumDims-1] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + m_inputStrides[i] = m_inputStrides[i+1] * input_dims[i+1]; + } + + m_outputStrides[NumDims-1] = 1; + m_fastOutputStrides[NumDims-1] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + m_outputStrides[i] = m_outputStrides[i+1] * output_dims[i+1]; + m_fastOutputStrides[i] = internal::TensorIntDivisor<Index>(m_outputStrides[i]); + } + } + } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef Sizes Dimensions; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(CoeffReturnType* data) { + m_impl.evalSubExprsIfNeeded(NULL); + if (internal::is_arithmetic<Scalar>::value && data && m_impl.data()) { + Index contiguous_values = 1; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = 0; i < NumDims; ++i) { + contiguous_values *= dimensions()[i]; + if (dimensions()[i] != m_impl.dimensions()[i]) { + break; + } + } + } else { + for (int i = NumDims-1; i >= 0; --i) { + contiguous_values *= dimensions()[i]; + if (dimensions()[i] != m_impl.dimensions()[i]) { + break; + } + } + } + // Use memcpy if it's going to be faster than using the regular evaluation. + if (contiguous_values > 2 * m_device.numThreads()) { + Scalar* src = m_impl.data(); + for (int i = 0; i < internal::array_prod(dimensions()); i += contiguous_values) { + Index offset = srcCoeff(i); + m_device.memcpy((void*)(data+i), src+offset, contiguous_values * sizeof(Scalar)); + } + return false; + } + } + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(srcCoeff(index)); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + Index inputIndices[] = {0, 0}; + Index indices[] = {index, index + packetSize - 1}; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx0 = indices[0] / m_fastOutputStrides[i]; + const Index idx1 = indices[1] / m_fastOutputStrides[i]; + inputIndices[0] += (idx0 + m_offsets[i]) * m_inputStrides[i]; + inputIndices[1] += (idx1 + m_offsets[i]) * m_inputStrides[i]; + indices[0] -= idx0 * m_outputStrides[i]; + indices[1] -= idx1 * m_outputStrides[i]; + } + inputIndices[0] += (indices[0] + m_offsets[0]); + inputIndices[1] += (indices[1] + m_offsets[0]); + } else { + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx0 = indices[0] / m_fastOutputStrides[i]; + const Index idx1 = indices[1] / m_fastOutputStrides[i]; + inputIndices[0] += (idx0 + m_offsets[i]) * m_inputStrides[i]; + inputIndices[1] += (idx1 + m_offsets[i]) * m_inputStrides[i]; + indices[0] -= idx0 * m_outputStrides[i]; + indices[1] -= idx1 * m_outputStrides[i]; + } + inputIndices[0] += (indices[0] + m_offsets[NumDims-1]); + inputIndices[1] += (indices[1] + m_offsets[NumDims-1]); + } + if (inputIndices[1] - inputIndices[0] == packetSize - 1) { + PacketReturnType rslt = m_impl.template packet<Unaligned>(inputIndices[0]); + return rslt; + } + else { + typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + values[0] = m_impl.coeff(inputIndices[0]); + values[packetSize-1] = m_impl.coeff(inputIndices[1]); + for (int i = 1; i < packetSize-1; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<Index, NumDims>& coords) + { + array<Index, NumDims> inputCoords; + for (int i = 0; i < NumDims; ++i) { + inputCoords = coords[i] + this->m_offsets[i]; + } + return m_impl.coeff(inputCoords); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType* data() const { + Scalar* result = m_impl.data(); + if (result) { + Index offset = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = 0; i < NumDims; ++i) { + if (m_dimensions[i] != m_impl.dimensions()[i]) { + offset += m_offsets[i] * m_inputStrides[i]; + for (int j = i+1; j < NumDims; ++j) { + if (m_dimensions[j] > 1) { + return NULL; + } + offset += m_offsets[j] * m_inputStrides[j]; + } + break; + } + } + } else { + for (int i = NumDims - 1; i >= 0; --i) { + if (m_dimensions[i] != m_impl.dimensions()[i]) { + offset += m_offsets[i] * m_inputStrides[i]; + for (int j = i-1; j >= 0; --j) { + if (m_dimensions[j] > 1) { + return NULL; + } + offset += m_offsets[j] * m_inputStrides[j]; + } + break; + } + } + } + return result + offset; + } + return NULL; + } + + protected: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const + { + Index inputIndex = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_fastOutputStrides[i]; + inputIndex += (idx + m_offsets[i]) * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + inputIndex += (index + m_offsets[0]); + } else { + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_fastOutputStrides[i]; + inputIndex += (idx + m_offsets[i]) * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + inputIndex += (index + m_offsets[NumDims-1]); + } + return inputIndex; + } + + array<Index, NumDims> m_outputStrides; + array<internal::TensorIntDivisor<Index>, NumDims> m_fastOutputStrides; + array<Index, NumDims> m_inputStrides; + TensorEvaluator<ArgType, Device> m_impl; + const Device& m_device; + Dimensions m_dimensions; + const StartIndices m_offsets; +}; + + +// Eval as lvalue +template<typename StartIndices, typename Sizes, typename ArgType, typename Device> +struct TensorEvaluator<TensorSlicingOp<StartIndices, Sizes, ArgType>, Device> + : public TensorEvaluator<const TensorSlicingOp<StartIndices, Sizes, ArgType>, Device> +{ + typedef TensorEvaluator<const TensorSlicingOp<StartIndices, Sizes, ArgType>, Device> Base; + typedef TensorSlicingOp<StartIndices, Sizes, ArgType> XprType; + static const int NumDims = internal::array_size<Sizes>::value; + + enum { + IsAligned = /*TensorEvaluator<ArgType, Device>::IsAligned*/false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = TensorEvaluator<ArgType, Device>::CoordAccess, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) + { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef Sizes Dimensions; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) + { + return this->m_impl.coeffRef(this->srcCoeff(index)); + } + + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + Index inputIndices[] = {0, 0}; + Index indices[] = {index, index + packetSize - 1}; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx0 = indices[0] / this->m_fastOutputStrides[i]; + const Index idx1 = indices[1] / this->m_fastOutputStrides[i]; + inputIndices[0] += (idx0 + this->m_offsets[i]) * this->m_inputStrides[i]; + inputIndices[1] += (idx1 + this->m_offsets[i]) * this->m_inputStrides[i]; + indices[0] -= idx0 * this->m_outputStrides[i]; + indices[1] -= idx1 * this->m_outputStrides[i]; + } + inputIndices[0] += (indices[0] + this->m_offsets[0]); + inputIndices[1] += (indices[1] + this->m_offsets[0]); + } else { + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx0 = indices[0] / this->m_fastOutputStrides[i]; + const Index idx1 = indices[1] / this->m_fastOutputStrides[i]; + inputIndices[0] += (idx0 + this->m_offsets[i]) * this->m_inputStrides[i]; + inputIndices[1] += (idx1 + this->m_offsets[i]) * this->m_inputStrides[i]; + indices[0] -= idx0 * this->m_outputStrides[i]; + indices[1] -= idx1 * this->m_outputStrides[i]; + } + inputIndices[0] += (indices[0] + this->m_offsets[NumDims-1]); + inputIndices[1] += (indices[1] + this->m_offsets[NumDims-1]); + } + if (inputIndices[1] - inputIndices[0] == packetSize - 1) { + this->m_impl.template writePacket<StoreMode>(inputIndices[0], x); + } + else { + EIGEN_ALIGN_DEFAULT CoeffReturnType values[packetSize]; + internal::pstore<CoeffReturnType, PacketReturnType>(values, x); + this->m_impl.coeffRef(inputIndices[0]) = values[0]; + this->m_impl.coeffRef(inputIndices[1]) = values[packetSize-1]; + for (int i = 1; i < packetSize-1; ++i) { + this->coeffRef(index+i) = values[i]; + } + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(const array<Index, NumDims>& coords) + { + array<Index, NumDims> inputCoords; + for (int i = 0; i < NumDims; ++i) { + inputCoords = coords[i] + this->m_offsets[i]; + } + return this->m_impl.coeffRef(inputCoords); + } +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_MORPHING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorPadding.h b/unsupported/Eigen/CXX11/src/Tensor/TensorPadding.h new file mode 100644 index 000000000..2a7dd45c0 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorPadding.h @@ -0,0 +1,361 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_PADDING_H +#define EIGEN_CXX11_TENSOR_TENSOR_PADDING_H + +namespace Eigen { + +/** \class TensorPadding + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor padding class. + * At the moment only 0-padding is supported. + * + */ +namespace internal { +template<typename PaddingDimensions, typename XprType> +struct traits<TensorPaddingOp<PaddingDimensions, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename PaddingDimensions, typename XprType> +struct eval<TensorPaddingOp<PaddingDimensions, XprType>, Eigen::Dense> +{ + typedef const TensorPaddingOp<PaddingDimensions, XprType>& type; +}; + +template<typename PaddingDimensions, typename XprType> +struct nested<TensorPaddingOp<PaddingDimensions, XprType>, 1, typename eval<TensorPaddingOp<PaddingDimensions, XprType> >::type> +{ + typedef TensorPaddingOp<PaddingDimensions, XprType> type; +}; + +} // end namespace internal + + + +template<typename PaddingDimensions, typename XprType> +class TensorPaddingOp : public TensorBase<TensorPaddingOp<PaddingDimensions, XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorPaddingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorPaddingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorPaddingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorPaddingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorPaddingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorPaddingOp(const XprType& expr, const PaddingDimensions& padding_dims) + : m_xpr(expr), m_padding_dims(padding_dims) {} + + EIGEN_DEVICE_FUNC + const PaddingDimensions& padding() const { return m_padding_dims; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const PaddingDimensions m_padding_dims; +}; + + +// Eval as rvalue +template<typename PaddingDimensions, typename ArgType, typename Device> +struct TensorEvaluator<const TensorPaddingOp<PaddingDimensions, ArgType>, Device> +{ + typedef TensorPaddingOp<PaddingDimensions, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<PaddingDimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = true, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_padding(op.padding()) + { + // Compute dimensions + m_dimensions = m_impl.dimensions(); + for (int i = 0; i < NumDims; ++i) { + m_dimensions[i] += m_padding[i].first + m_padding[i].second; + } + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_inputStrides[0] = 1; + m_outputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_inputStrides[i] = m_inputStrides[i-1] * input_dims[i-1]; + m_outputStrides[i] = m_outputStrides[i-1] * m_dimensions[i-1]; + } + m_outputStrides[NumDims] = m_outputStrides[NumDims-1] * m_dimensions[NumDims-1]; + } else { + m_inputStrides[NumDims - 1] = 1; + m_outputStrides[NumDims] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + m_inputStrides[i] = m_inputStrides[i+1] * input_dims[i+1]; + m_outputStrides[i+1] = m_outputStrides[i+2] * m_dimensions[i+1]; + } + m_outputStrides[0] = m_outputStrides[1] * m_dimensions[0]; + } + } + + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + eigen_assert(index < dimensions().TotalSize()); + Index inputIndex = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStrides[i]; + if (idx < m_padding[i].first || idx >= m_dimensions[i] - m_padding[i].second) { + return Scalar(0); + } + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + if (index < m_padding[0].first || index >= m_dimensions[0] - m_padding[0].second) { + return Scalar(0); + } + inputIndex += (index - m_padding[0].first); + } else { + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_outputStrides[i+1]; + if (idx < m_padding[i].first || idx >= m_dimensions[i] - m_padding[i].second) { + return Scalar(0); + } + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + index -= idx * m_outputStrides[i+1]; + } + if (index < m_padding[NumDims-1].first || + index >= m_dimensions[NumDims-1] - m_padding[NumDims-1].second) { + return Scalar(0); + } + inputIndex += (index - m_padding[NumDims-1].first); + } + return m_impl.coeff(inputIndex); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return packetColMajor(index); + } + return packetRowMajor(index); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<Index, NumDims>& coords) const + { + Index inputIndex; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + const Index idx = coords[0]; + if (idx < m_padding[0].first || idx >= m_dimensions[0] - m_padding[0].second) { + return Scalar(0); + } + inputIndex = idx - m_padding[0].first; + for (int i = 1; i < NumDims; ++i) { + const Index idx = coords[i]; + if (idx < m_padding[i].first || idx >= m_dimensions[i] - m_padding[i].second) { + return Scalar(0); + } + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + } + } else { + const Index idx = coords[NumDims-1]; + if (idx < m_padding[NumDims-1].first || idx >= m_dimensions[NumDims-1] - m_padding[NumDims-1].second) { + return Scalar(0); + } + inputIndex = idx - m_padding[NumDims-1].first; + for (int i = NumDims - 2; i >= 0; --i) { + const Index idx = coords[i]; + if (idx < m_padding[i].first || idx >= m_dimensions[i] - m_padding[i].second) { + return Scalar(0); + } + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + } + } + return m_impl.coeff(inputIndex); + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetColMajor(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + const Index initialIndex = index; + Index inputIndex = 0; + for (int i = NumDims - 1; i > 0; --i) { + const Index first = index; + const Index last = index + packetSize - 1; + const Index lastPaddedLeft = m_padding[i].first * m_outputStrides[i]; + const Index firstPaddedRight = (m_dimensions[i] - m_padding[i].second) * m_outputStrides[i]; + const Index lastPaddedRight = m_outputStrides[i+1]; + + if (last < lastPaddedLeft) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= firstPaddedRight && last < lastPaddedRight) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= lastPaddedLeft && last < firstPaddedRight) { + // all the coefficient are between the 2 padding zones. + const Index idx = index / m_outputStrides[i]; + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + else { + // Every other case + return packetWithPossibleZero(initialIndex); + } + } + + const Index last = index + packetSize - 1; + const Index first = index; + const Index lastPaddedLeft = m_padding[0].first; + const Index firstPaddedRight = (m_dimensions[0] - m_padding[0].second); + const Index lastPaddedRight = m_outputStrides[1]; + + if (last < lastPaddedLeft) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= firstPaddedRight && last < lastPaddedRight) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= lastPaddedLeft && last < firstPaddedRight) { + // all the coefficient are between the 2 padding zones. + inputIndex += (index - m_padding[0].first); + return m_impl.template packet<Unaligned>(inputIndex); + } + // Every other case + return packetWithPossibleZero(initialIndex); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetRowMajor(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + const Index initialIndex = index; + Index inputIndex = 0; + + for (int i = 0; i < NumDims - 1; ++i) { + const Index first = index; + const Index last = index + packetSize - 1; + const Index lastPaddedLeft = m_padding[i].first * m_outputStrides[i+1]; + const Index firstPaddedRight = (m_dimensions[i] - m_padding[i].second) * m_outputStrides[i+1]; + const Index lastPaddedRight = m_outputStrides[i]; + + if (last < lastPaddedLeft) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= firstPaddedRight && last < lastPaddedRight) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= lastPaddedLeft && last < firstPaddedRight) { + // all the coefficient are between the 2 padding zones. + const Index idx = index / m_outputStrides[i+1]; + inputIndex += (idx - m_padding[i].first) * m_inputStrides[i]; + index -= idx * m_outputStrides[i+1]; + } + else { + // Every other case + return packetWithPossibleZero(initialIndex); + } + } + + const Index last = index + packetSize - 1; + const Index first = index; + const Index lastPaddedLeft = m_padding[NumDims-1].first; + const Index firstPaddedRight = (m_dimensions[NumDims-1] - m_padding[NumDims-1].second); + const Index lastPaddedRight = m_outputStrides[NumDims-1]; + + if (last < lastPaddedLeft) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= firstPaddedRight && last < lastPaddedRight) { + // all the coefficient are in the padding zone. + return internal::pset1<PacketReturnType>(Scalar(0)); + } + else if (first >= lastPaddedLeft && last < firstPaddedRight) { + // all the coefficient are between the 2 padding zones. + inputIndex += (index - m_padding[NumDims-1].first); + return m_impl.template packet<Unaligned>(inputIndex); + } + // Every other case + return packetWithPossibleZero(initialIndex); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packetWithPossibleZero(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + Dimensions m_dimensions; + array<Index, NumDims+1> m_outputStrides; + array<Index, NumDims> m_inputStrides; + TensorEvaluator<ArgType, Device> m_impl; + PaddingDimensions m_padding; +}; + + + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_PADDING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorPatch.h b/unsupported/Eigen/CXX11/src/Tensor/TensorPatch.h new file mode 100644 index 000000000..8a42ab6b1 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorPatch.h @@ -0,0 +1,248 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_PATCH_H +#define EIGEN_CXX11_TENSOR_TENSOR_PATCH_H + +namespace Eigen { + +/** \class TensorPatch + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor patch class. + * + * + */ +namespace internal { +template<typename PatchDim, typename XprType> +struct traits<TensorPatchOp<PatchDim, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions + 1; + static const int Layout = XprTraits::Layout; +}; + +template<typename PatchDim, typename XprType> +struct eval<TensorPatchOp<PatchDim, XprType>, Eigen::Dense> +{ + typedef const TensorPatchOp<PatchDim, XprType>& type; +}; + +template<typename PatchDim, typename XprType> +struct nested<TensorPatchOp<PatchDim, XprType>, 1, typename eval<TensorPatchOp<PatchDim, XprType> >::type> +{ + typedef TensorPatchOp<PatchDim, XprType> type; +}; + +} // end namespace internal + + + +template<typename PatchDim, typename XprType> +class TensorPatchOp : public TensorBase<TensorPatchOp<PatchDim, XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorPatchOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorPatchOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorPatchOp>::type Nested; + typedef typename Eigen::internal::traits<TensorPatchOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorPatchOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorPatchOp(const XprType& expr, const PatchDim& patch_dims) + : m_xpr(expr), m_patch_dims(patch_dims) {} + + EIGEN_DEVICE_FUNC + const PatchDim& patch_dims() const { return m_patch_dims; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const PatchDim m_patch_dims; +}; + + +// Eval as rvalue +template<typename PatchDim, typename ArgType, typename Device> +struct TensorEvaluator<const TensorPatchOp<PatchDim, ArgType>, Device> +{ + typedef TensorPatchOp<PatchDim, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value + 1; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = true, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + // Only column major tensors are supported for now. + EIGEN_STATIC_ASSERT((static_cast<int>(Layout) == static_cast<int>(ColMajor)), YOU_MADE_A_PROGRAMMING_MISTAKE); + + Index num_patches = 1; + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + const PatchDim& patch_dims = op.patch_dims(); + for (int i = 0; i < NumDims-1; ++i) { + m_dimensions[i] = patch_dims[i]; + num_patches *= (input_dims[i] - patch_dims[i] + 1); + } + m_dimensions[NumDims-1] = num_patches; + + m_inputStrides[0] = 1; + m_patchStrides[0] = 1; + for (int i = 1; i < NumDims-1; ++i) { + m_inputStrides[i] = m_inputStrides[i-1] * input_dims[i-1]; + m_patchStrides[i] = m_patchStrides[i-1] * (input_dims[i-1] - patch_dims[i-1] + 1); + } + m_outputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_outputStrides[i] = m_outputStrides[i-1] * m_dimensions[i-1]; + } + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + // Find the location of the first element of the patch. + Index patchIndex = index / m_outputStrides[NumDims - 1]; + // Find the offset of the element wrt the location of the first element. + Index patchOffset = index - patchIndex * m_outputStrides[NumDims - 1]; + + Index inputIndex = 0; + for (int i = NumDims - 2; i > 0; --i) { + const Index patchIdx = patchIndex / m_patchStrides[i]; + patchIndex -= patchIdx * m_patchStrides[i]; + const Index offsetIdx = patchOffset / m_outputStrides[i]; + patchOffset -= offsetIdx * m_outputStrides[i]; + inputIndex += (patchIdx + offsetIdx) * m_inputStrides[i]; + } + inputIndex += (patchIndex + patchOffset); + return m_impl.coeff(inputIndex); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + Index indices[2] = {index, index + packetSize - 1}; + Index patchIndices[2] = {indices[0] / m_outputStrides[NumDims - 1], + indices[1] / m_outputStrides[NumDims - 1]}; + Index patchOffsets[2] = {indices[0] - patchIndices[0] * m_outputStrides[NumDims - 1], + indices[1] - patchIndices[1] * m_outputStrides[NumDims - 1]}; + + Index inputIndices[2] = {0, 0}; + for (int i = NumDims - 2; i > 0; --i) { + const Index patchIdx[2] = {patchIndices[0] / m_patchStrides[i], + patchIndices[1] / m_patchStrides[i]}; + patchIndices[0] -= patchIdx[0] * m_patchStrides[i]; + patchIndices[1] -= patchIdx[1] * m_patchStrides[i]; + + const Index offsetIdx[2] = {patchOffsets[0] / m_outputStrides[i], + patchOffsets[1] / m_outputStrides[i]}; + patchOffsets[0] -= offsetIdx[0] * m_outputStrides[i]; + patchOffsets[1] -= offsetIdx[1] * m_outputStrides[i]; + + inputIndices[0] += (patchIdx[0] + offsetIdx[0]) * m_inputStrides[i]; + inputIndices[1] += (patchIdx[1] + offsetIdx[1]) * m_inputStrides[i]; + } + inputIndices[0] += (patchIndices[0] + patchOffsets[0]); + inputIndices[1] += (patchIndices[1] + patchOffsets[1]); + + if (inputIndices[1] - inputIndices[0] == packetSize - 1) { + PacketReturnType rslt = m_impl.template packet<Unaligned>(inputIndices[0]); + return rslt; + } + else { + EIGEN_ALIGN_DEFAULT CoeffReturnType values[packetSize]; + values[0] = m_impl.coeff(inputIndices[0]); + values[packetSize-1] = m_impl.coeff(inputIndices[1]); + for (int i = 1; i < packetSize-1; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(const array<Index, NumDims>& coords) const + { + // Location of the first element of the patch. + const Index patchIndex = coords[NumDims - 1]; + + if (TensorEvaluator<ArgType, Device>::CoordAccess) { + array<Index, NumDims-1> inputCoords; + for (int i = NumDims - 2; i > 0; --i) { + const Index patchIdx = patchIndex / m_patchStrides[i]; + patchIndex -= patchIdx * m_patchStrides[i]; + const Index offsetIdx = coords[i]; + inputCoords[i] = coords[i] + patchIdx; + } + inputCoords[0] = (patchIndex + coords[0]); + return m_impl.coeff(inputCoords); + } + else { + Index inputIndex = 0; + for (int i = NumDims - 2; i > 0; --i) { + const Index patchIdx = patchIndex / m_patchStrides[i]; + patchIndex -= patchIdx * m_patchStrides[i]; + const Index offsetIdx = coords[i]; + inputIndex += (patchIdx + offsetIdx) * m_inputStrides[i]; + } + inputIndex += (patchIndex + coords[0]); + return m_impl.coeff(inputIndex); + } + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + Dimensions m_dimensions; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims-1> m_inputStrides; + array<Index, NumDims-1> m_patchStrides; + + TensorEvaluator<ArgType, Device> m_impl; +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_PATCH_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorReduction.h b/unsupported/Eigen/CXX11/src/Tensor/TensorReduction.h new file mode 100644 index 000000000..de5747905 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorReduction.h @@ -0,0 +1,426 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_REDUCTION_H +#define EIGEN_CXX11_TENSOR_TENSOR_REDUCTION_H + +namespace Eigen { + +/** \class TensorReduction + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor reduction class. + * + */ + +namespace internal { +template<typename Op, typename Dims, typename XprType> +struct traits<TensorReductionOp<Op, Dims, XprType> > + : traits<XprType> +{ + typedef typename traits<XprType>::Scalar Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename traits<XprType>::StorageKind StorageKind; + typedef typename traits<XprType>::Index Index; + typedef typename XprType::Nested Nested; +}; + +template<typename Op, typename Dims, typename XprType> +struct eval<TensorReductionOp<Op, Dims, XprType>, Eigen::Dense> +{ + typedef const TensorReductionOp<Op, Dims, XprType>& type; +}; + +template<typename Op, typename Dims, typename XprType> +struct nested<TensorReductionOp<Op, Dims, XprType>, 1, typename eval<TensorReductionOp<Op, Dims, XprType> >::type> +{ + typedef TensorReductionOp<Op, Dims, XprType> type; +}; + + +template <typename ReducedDims, int NumTensorDims, int Layout> +struct are_inner_most_dims { + static const bool value = false; +}; +template <typename ReducedDims, int NumTensorDims, int Layout> +struct preserve_inner_most_dims { + static const bool value = false; +}; + +#ifdef EIGEN_HAS_CONSTEXPR +template <typename ReducedDims, int NumTensorDims> +struct are_inner_most_dims<ReducedDims, NumTensorDims, ColMajor>{ + static const bool value = indices_statically_known_to_increase<ReducedDims>()() && + index_statically_eq<ReducedDims>()(0, 0) && + index_statically_eq<ReducedDims>()(array_size<ReducedDims>::value-1, array_size<ReducedDims>::value-1); +}; +template <typename ReducedDims, int NumTensorDims> +struct are_inner_most_dims<ReducedDims, NumTensorDims, RowMajor>{ + static const bool value = indices_statically_known_to_increase<ReducedDims>()() && + index_statically_eq<ReducedDims>()(0, NumTensorDims - array_size<ReducedDims>::value) && + index_statically_eq<ReducedDims>()(array_size<ReducedDims>::value - 1, NumTensorDims - 1); +}; +template <typename ReducedDims, int NumTensorDims> +struct preserve_inner_most_dims<ReducedDims, NumTensorDims, ColMajor>{ + static const bool value = indices_statically_known_to_increase<ReducedDims>()() && + index_statically_gt<ReducedDims>()(0, 0); +}; +template <typename ReducedDims, int NumTensorDims> +struct preserve_inner_most_dims<ReducedDims, NumTensorDims, RowMajor>{ + static const bool value = indices_statically_known_to_increase<ReducedDims>()() && + index_statically_lt<ReducedDims>()(array_size<ReducedDims>::value - 1, NumTensorDims - 1); +}; +#endif + + +template <int DimIndex, typename Self, typename Op> +struct GenericDimReducer { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const Self& self, typename Self::Index firstIndex, Op& reducer, typename Self::CoeffReturnType* accum) { + EIGEN_STATIC_ASSERT(DimIndex > 0, YOU_MADE_A_PROGRAMMING_MISTAKE); + for (int j = 0; j < self.m_reducedDims[DimIndex]; ++j) { + const typename Self::Index input = firstIndex + j * self.m_reducedStrides[DimIndex]; + GenericDimReducer<DimIndex-1, Self, Op>::reduce(self, input, reducer, accum); + } + } +}; +template <typename Self, typename Op> +struct GenericDimReducer<0, Self, Op> { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const Self& self, typename Self::Index firstIndex, Op& reducer, typename Self::CoeffReturnType* accum) { + for (int j = 0; j < self.m_reducedDims[0]; ++j) { + const typename Self::Index input = firstIndex + j * self.m_reducedStrides[0]; + reducer.reduce(self.m_impl.coeff(input), accum); + } + } +}; + +template <typename Self, typename Op, bool Vectorizable = (Self::InputPacketAccess & Op::PacketAccess)> +struct InnerMostDimReducer { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Self::CoeffReturnType reduce(const Self& self, typename Self::Index firstIndex, typename Self::Index numValuesToReduce, Op& reducer) { + typename Self::CoeffReturnType accum = reducer.initialize(); + for (typename Self::Index j = 0; j < numValuesToReduce; ++j) { + reducer.reduce(self.m_impl.coeff(firstIndex + j), &accum); + } + return reducer.finalize(accum); + } +}; + +template <typename Self, typename Op> +struct InnerMostDimReducer<Self, Op, true> { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE typename Self::CoeffReturnType reduce(const Self& self, typename Self::Index firstIndex, typename Self::Index numValuesToReduce, Op& reducer) { + const int packetSize = internal::unpacket_traits<typename Self::PacketReturnType>::size; + const typename Self::Index VectorizedSize = (numValuesToReduce / packetSize) * packetSize; + typename Self::PacketReturnType p = reducer.template initializePacket<typename Self::PacketReturnType>(); + for (typename Self::Index j = 0; j < VectorizedSize; j += packetSize) { + reducer.reducePacket(self.m_impl.template packet<Unaligned>(firstIndex + j), &p); + } + typename Self::CoeffReturnType accum = reducer.initialize(); + for (typename Self::Index j = VectorizedSize; j < numValuesToReduce; ++j) { + reducer.reduce(self.m_impl.coeff(firstIndex + j), &accum); + } + return reducer.finalizeBoth(accum, p); + } +}; + +template <int DimIndex, typename Self, typename Op, bool vectorizable = (Self::InputPacketAccess & Op::PacketAccess)> +struct InnerMostDimPreserver { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const Self&, typename Self::Index, Op&, typename Self::PacketReturnType*) { + eigen_assert(false && "should never be called"); + } +}; + +template <int DimIndex, typename Self, typename Op> +struct InnerMostDimPreserver<DimIndex, Self, Op, true> { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const Self& self, typename Self::Index firstIndex, Op& reducer, typename Self::PacketReturnType* accum) { + EIGEN_STATIC_ASSERT(DimIndex > 0, YOU_MADE_A_PROGRAMMING_MISTAKE); + for (int j = 0; j < self.m_reducedDims[DimIndex]; ++j) { + const typename Self::Index input = firstIndex + j * self.m_reducedStrides[DimIndex]; + InnerMostDimPreserver<DimIndex-1, Self, Op>::reduce(self, input, reducer, accum); + } + } +}; + +template <typename Self, typename Op> +struct InnerMostDimPreserver<0, Self, Op, true> { + static EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void reduce(const Self& self, typename Self::Index firstIndex, Op& reducer, typename Self::PacketReturnType* accum) { + for (int j = 0; j < self.m_reducedDims[0]; ++j) { + const typename Self::Index input = firstIndex + j * self.m_reducedStrides[0]; + reducer.reducePacket(self.m_impl.template packet<Unaligned>(input), accum); + } + } +}; + +} // end namespace internal + + +template <typename Op, typename Dims, typename XprType> +class TensorReductionOp : public TensorBase<TensorReductionOp<Op, Dims, XprType>, ReadOnlyAccessors> { + public: + typedef typename Eigen::internal::traits<TensorReductionOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorReductionOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + typedef typename Eigen::internal::nested<TensorReductionOp>::type Nested; + typedef typename Eigen::internal::traits<TensorReductionOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorReductionOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + TensorReductionOp(const XprType& expr, const Dims& dims) : m_expr(expr), m_dims(dims) + { } + TensorReductionOp(const XprType& expr, const Dims& dims, const Op& reducer) : m_expr(expr), m_dims(dims), m_reducer(reducer) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const XprType& expression() const { return m_expr; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const Dims& dims() const { return m_dims; } + const Op& reducer() const { return m_reducer; } + + protected: + typename XprType::Nested m_expr; + const Dims m_dims; + const Op m_reducer; +}; + + +// Eval as rvalue +template<typename Op, typename Dims, typename ArgType, typename Device> +struct TensorEvaluator<const TensorReductionOp<Op, Dims, ArgType>, Device> +{ + typedef TensorReductionOp<Op, Dims, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumInputDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + static const int NumReducedDims = internal::array_size<Dims>::value; + static const int NumOutputDims = (NumInputDims==NumReducedDims) ? 1 : NumInputDims - NumReducedDims; + typedef DSizes<Index, NumOutputDims> Dimensions; + typedef typename XprType::Scalar Scalar; + typedef TensorEvaluator<const TensorReductionOp<Op, Dims, ArgType>, Device> Self; + static const bool InputPacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess; + + enum { + IsAligned = false, + PacketAccess = Self::InputPacketAccess && Op::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + static const bool ReducingInnerMostDims = internal::are_inner_most_dims<Dims, NumInputDims, Layout>::value; + static const bool PreservingInnerMostDims = internal::preserve_inner_most_dims<Dims, NumInputDims, Layout>::value; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device), m_reducer(op.reducer()) + { + EIGEN_STATIC_ASSERT(NumInputDims >= NumReducedDims, YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((!ReducingInnerMostDims | !PreservingInnerMostDims | (NumReducedDims == NumInputDims)), + YOU_MADE_A_PROGRAMMING_MISTAKE); + + // Bitmap indicating if an input dimension is reduced or not. + array<bool, NumInputDims> reduced; + for (int i = 0; i < NumInputDims; ++i) { + reduced[i] = false; + } + for (int i = 0; i < NumReducedDims; ++i) { + eigen_assert(op.dims()[i] >= 0); + eigen_assert(op.dims()[i] < NumInputDims); + reduced[op.dims()[i]] = true; + } + + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + int outputIndex = 0; + int reduceIndex = 0; + for (int i = 0; i < NumInputDims; ++i) { + if (reduced[i]) { + m_reducedDims[reduceIndex] = input_dims[i]; + ++reduceIndex; + } else { + m_dimensions[outputIndex] = input_dims[i]; + ++outputIndex; + } + } + + // Precompute output strides. + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_outputStrides[0] = 1; + for (int i = 1; i < NumOutputDims; ++i) { + m_outputStrides[i] = m_outputStrides[i - 1] * m_dimensions[i - 1]; + } + } else { + m_outputStrides[NumOutputDims - 1] = 1; + for (int i = NumOutputDims - 2; i >= 0; --i) { + m_outputStrides[i] = m_outputStrides[i + 1] * m_dimensions[i + 1]; + } + } + + // Precompute input strides. + array<Index, NumInputDims> input_strides; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + input_strides[0] = 1; + for (int i = 1; i < NumInputDims; ++i) { + input_strides[i] = input_strides[i-1] * input_dims[i-1]; + } + } else { + input_strides[NumInputDims - 1] = 1; + for (int i = NumInputDims - 2; i >= 0; --i) { + input_strides[i] = input_strides[i + 1] * input_dims[i + 1]; + } + } + + outputIndex = 0; + reduceIndex = 0; + for (int i = 0; i < NumInputDims; ++i) { + if (reduced[i]) { + m_reducedStrides[reduceIndex] = input_strides[i]; + ++reduceIndex; + } else { + m_preservedStrides[outputIndex] = input_strides[i]; + ++outputIndex; + } + } + + // Special case for full reductions + if (NumInputDims == NumReducedDims) { + m_dimensions[0] = 1; + m_preservedStrides[0] = internal::array_prod(input_dims); + } + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + typedef typename internal::remove_const<typename XprType::CoeffReturnType>::type CoeffReturnType; + typedef typename internal::remove_const<typename XprType::PacketReturnType>::type PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + Op reducer(m_reducer); + if (ReducingInnerMostDims) { + const Index num_values_to_reduce = + (static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? m_preservedStrides[0] : m_preservedStrides[NumOutputDims - 1]; + return internal::InnerMostDimReducer<Self, Op>::reduce(*this, firstInput(index), + num_values_to_reduce, reducer); + } else { + typename Self::CoeffReturnType accum = reducer.initialize(); + internal::GenericDimReducer<NumReducedDims-1, Self, Op>::reduce(*this, firstInput(index), reducer, &accum); + return reducer.finalize(accum); + } + } + + // TODO(bsteiner): provide a more efficient implementation. + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index + packetSize - 1 < dimensions().TotalSize()); + + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + if (ReducingInnerMostDims) { + const Index num_values_to_reduce = + (static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? m_preservedStrides[0] : m_preservedStrides[NumOutputDims - 1]; + const Index firstIndex = firstInput(index); + for (Index i = 0; i < packetSize; ++i) { + Op reducer(m_reducer); + values[i] = internal::InnerMostDimReducer<Self, Op>::reduce(*this, firstIndex + i * num_values_to_reduce, + num_values_to_reduce, reducer); + } + } else if (PreservingInnerMostDims) { + const Index firstIndex = firstInput(index); + const int innermost_dim = (static_cast<int>(Layout) == static_cast<int>(ColMajor)) ? 0 : NumOutputDims - 1; + // TBD: extend this the the n innermost dimensions that we preserve. + if (((firstIndex % m_dimensions[innermost_dim]) + packetSize - 1) < m_dimensions[innermost_dim]) { + Op reducer(m_reducer); + typename Self::PacketReturnType accum = reducer.template initializePacket<typename Self::PacketReturnType>(); + internal::InnerMostDimPreserver<NumReducedDims-1, Self, Op>::reduce(*this, firstIndex, reducer, &accum); + return reducer.finalizePacket(accum); + } else { + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index + i); + } + } + } else { + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index + i); + } + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + private: + template <int, typename, typename> friend struct internal::GenericDimReducer; + template <typename, typename, bool> friend struct internal::InnerMostDimReducer; + template <int, typename, typename, bool> friend struct internal::InnerMostDimPreserver; + + // Returns the Index in the input tensor of the first value that needs to be + // used to compute the reduction at output index "index". + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index firstInput(Index index) const { + if (ReducingInnerMostDims) { + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + return index * m_preservedStrides[0]; + } else { + return index * m_preservedStrides[NumOutputDims - 1]; + } + } + // TBD: optimize the case where we preserve the innermost dimensions. + Index startInput = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumOutputDims - 1; i > 0; --i) { + // This is index_i in the output tensor. + const Index idx = index / m_outputStrides[i]; + startInput += idx * m_preservedStrides[i]; + index -= idx * m_outputStrides[i]; + } + startInput += index * m_preservedStrides[0]; + } else { + for (int i = 0; i < NumOutputDims - 1; ++i) { + // This is index_i in the output tensor. + const Index idx = index / m_outputStrides[i]; + startInput += idx * m_preservedStrides[i]; + index -= idx * m_outputStrides[i]; + } + startInput += index * m_preservedStrides[NumOutputDims - 1]; + } + return startInput; + } + + // Dimensions of the output of the operation. + Dimensions m_dimensions; + // Precomputed strides for the output tensor. + array<Index, NumOutputDims> m_outputStrides; + // Subset of strides of the input tensor for the non-reduced dimensions. + // Indexed by output dimensions. + array<Index, NumOutputDims> m_preservedStrides; + + // Subset of strides of the input tensor for the reduced dimensions. + // Indexed by reduced dimensions. + array<Index, NumReducedDims> m_reducedStrides; + // Size of the input dimensions that are reduced. + // Indexed by reduced dimensions. + array<Index, NumReducedDims> m_reducedDims; + + // Evaluator for the input expression. + TensorEvaluator<ArgType, Device> m_impl; + + // Operation to apply for computing the reduction. + Op m_reducer; +}; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_REDUCTION_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorRef.h b/unsupported/Eigen/CXX11/src/Tensor/TensorRef.h new file mode 100644 index 000000000..0a87e67eb --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorRef.h @@ -0,0 +1,429 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_REF_H +#define EIGEN_CXX11_TENSOR_TENSOR_REF_H + +namespace Eigen { + +namespace internal { + +template <typename Dimensions, typename Scalar> +class TensorLazyBaseEvaluator { + public: + TensorLazyBaseEvaluator() : m_refcount(0) { } + virtual ~TensorLazyBaseEvaluator() { } + + virtual const Dimensions& dimensions() const = 0; + virtual const Scalar* data() const = 0; + + virtual const Scalar coeff(DenseIndex index) const = 0; + virtual Scalar& coeffRef(DenseIndex index) = 0; + + void incrRefCount() { ++m_refcount; } + void decrRefCount() { --m_refcount; } + int refCount() const { return m_refcount; } + + private: + // No copy, no assigment; + TensorLazyBaseEvaluator(const TensorLazyBaseEvaluator& other); + TensorLazyBaseEvaluator& operator = (const TensorLazyBaseEvaluator& other); + + int m_refcount; +}; + +static char dummy[8]; + +template <typename Dimensions, typename Expr, typename Device> +class TensorLazyEvaluatorReadOnly : public TensorLazyBaseEvaluator<Dimensions, typename TensorEvaluator<Expr, Device>::Scalar> { + public: + // typedef typename TensorEvaluator<Expr, Device>::Dimensions Dimensions; + typedef typename TensorEvaluator<Expr, Device>::Scalar Scalar; + + TensorLazyEvaluatorReadOnly(const Expr& expr, const Device& device) : m_impl(expr, device) { + m_dims = m_impl.dimensions(); + m_impl.evalSubExprsIfNeeded(NULL); + } + virtual ~TensorLazyEvaluatorReadOnly() { + m_impl.cleanup(); + } + + virtual const Dimensions& dimensions() const { + return m_dims; + } + virtual const Scalar* data() const { + return m_impl.data(); + } + + virtual const Scalar coeff(DenseIndex index) const { + return m_impl.coeff(index); + } + virtual Scalar& coeffRef(DenseIndex /*index*/) { + eigen_assert(false && "can't reference the coefficient of a rvalue"); + return *reinterpret_cast<Scalar*>(dummy); + }; + + protected: + TensorEvaluator<Expr, Device> m_impl; + Dimensions m_dims; +}; + +template <typename Dimensions, typename Expr, typename Device> +class TensorLazyEvaluatorWritable : public TensorLazyEvaluatorReadOnly<Dimensions, Expr, Device> { + public: + typedef TensorLazyEvaluatorReadOnly<Dimensions, Expr, Device> Base; + typedef typename Base::Scalar Scalar; + + TensorLazyEvaluatorWritable(const Expr& expr, const Device& device) : Base(expr, device) { + } + virtual ~TensorLazyEvaluatorWritable() { + } + + virtual Scalar& coeffRef(DenseIndex index) { + return this->m_impl.coeffRef(index); + } +}; + +template <typename Dimensions, typename Expr, typename Device> +class TensorLazyEvaluator : public internal::conditional<bool(internal::is_lvalue<Expr>::value), + TensorLazyEvaluatorWritable<Dimensions, Expr, Device>, + TensorLazyEvaluatorReadOnly<Dimensions, const Expr, Device> >::type { + public: + typedef typename internal::conditional<bool(internal::is_lvalue<Expr>::value), + TensorLazyEvaluatorWritable<Dimensions, Expr, Device>, + TensorLazyEvaluatorReadOnly<Dimensions, const Expr, Device> >::type Base; + typedef typename Base::Scalar Scalar; + + TensorLazyEvaluator(const Expr& expr, const Device& device) : Base(expr, device) { + } + virtual ~TensorLazyEvaluator() { + } +}; + +} // namespace internal + + +/** \class TensorRef + * \ingroup CXX11_Tensor_Module + * + * \brief A reference to a tensor expression + * The expression will be evaluated lazily (as much as possible). + * + */ +template<typename PlainObjectType> class TensorRef : public TensorBase<TensorRef<PlainObjectType> > +{ + public: + typedef TensorRef<PlainObjectType> Self; + typedef typename PlainObjectType::Base Base; + typedef typename Eigen::internal::nested<Self>::type Nested; + typedef typename internal::traits<PlainObjectType>::StorageKind StorageKind; + typedef typename internal::traits<PlainObjectType>::Index Index; + typedef typename internal::traits<PlainObjectType>::Scalar Scalar; + typedef typename internal::packet_traits<Scalar>::type Packet; + typedef typename NumTraits<Scalar>::Real RealScalar; + typedef typename Base::CoeffReturnType CoeffReturnType; + typedef Scalar* PointerType; + typedef PointerType PointerArgType; + + static const Index NumIndices = PlainObjectType::NumIndices; + typedef typename PlainObjectType::Dimensions Dimensions; + + enum { + IsAligned = false, + PacketAccess = false, + Layout = PlainObjectType::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_STRONG_INLINE TensorRef() : m_evaluator(NULL) { + } + + template <typename Expression> + EIGEN_STRONG_INLINE TensorRef(const Expression& expr) : m_evaluator(new internal::TensorLazyEvaluator<Dimensions, Expression, DefaultDevice>(expr, DefaultDevice())) { + m_evaluator->incrRefCount(); + } + + template <typename Expression> + EIGEN_STRONG_INLINE TensorRef& operator = (const Expression& expr) { + unrefEvaluator(); + m_evaluator = new internal::TensorLazyEvaluator<Dimensions, Expression, DefaultDevice>(expr, DefaultDevice()); + m_evaluator->incrRefCount(); + return *this; + } + + ~TensorRef() { + unrefEvaluator(); + } + + TensorRef(const TensorRef& other) : m_evaluator(other.m_evaluator) { + eigen_assert(m_evaluator->refCount() > 0); + m_evaluator->incrRefCount(); + } + + TensorRef& operator = (const TensorRef& other) { + if (this != &other) { + unrefEvaluator(); + m_evaluator = other.m_evaluator; + eigen_assert(m_evaluator->refCount() > 0); + m_evaluator->incrRefCount(); + } + return *this; + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index rank() const { return m_evaluator->dimensions().size(); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index dimension(Index n) const { return m_evaluator->dimensions()[n]; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_evaluator->dimensions(); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Index size() const { return m_evaluator->dimensions().TotalSize(); } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar* data() const { return m_evaluator->data(); } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index index) const + { + return m_evaluator->coeff(index); + } + +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index firstIndex, IndexTypes... otherIndices) const + { + const std::size_t NumIndices = (sizeof...(otherIndices) + 1); + const array<Index, NumIndices> indices{{firstIndex, otherIndices...}}; + return coeff(indices); + } + template<typename... IndexTypes> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index firstIndex, IndexTypes... otherIndices) + { + const std::size_t NumIndices = (sizeof...(otherIndices) + 1); + const array<Index, NumIndices> indices{{firstIndex, otherIndices...}}; + return coeffRef(indices); + } +#else + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index i0, Index i1) const + { + array<Index, 2> indices; + indices[0] = i0; + indices[1] = i1; + return coeff(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index i0, Index i1, Index i2) const + { + array<Index, 3> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + return coeff(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index i0, Index i1, Index i2, Index i3) const + { + array<Index, 4> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + indices[3] = i3; + return coeff(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar operator()(Index i0, Index i1, Index i2, Index i3, Index i4) const + { + array<Index, 5> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + indices[3] = i3; + indices[4] = i4; + return coeff(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index i0, Index i1) + { + array<Index, 2> indices; + indices[0] = i0; + indices[1] = i1; + return coeffRef(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index i0, Index i1, Index i2) + { + array<Index, 3> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + return coeffRef(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3) + { + array<Index, 4> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + indices[3] = i3; + return coeffRef(indices); + } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index i0, Index i1, Index i2, Index i3, Index i4) + { + array<Index, 5> indices; + indices[0] = i0; + indices[1] = i1; + indices[2] = i2; + indices[3] = i3; + indices[4] = i4; + return coeffRef(indices); + } +#endif + + template <std::size_t NumIndices> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar coeff(const array<Index, NumIndices>& indices) const + { + const Dimensions& dims = this->dimensions(); + Index index = 0; + if (PlainObjectType::Options & RowMajor) { + index += indices[0]; + for (int i = 1; i < NumIndices; ++i) { + index = index * dims[i] + indices[i]; + } + } else { + index += indices[NumIndices-1]; + for (int i = NumIndices-2; i >= 0; --i) { + index = index * dims[i] + indices[i]; + } + } + return m_evaluator->coeff(index); + } + template <std::size_t NumIndices> EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(const array<Index, NumIndices>& indices) + { + const Dimensions& dims = this->dimensions(); + Index index = 0; + if (PlainObjectType::Options & RowMajor) { + index += indices[0]; + for (int i = 1; i < NumIndices; ++i) { + index = index * dims[i] + indices[i]; + } + } else { + index += indices[NumIndices-1]; + for (int i = NumIndices-2; i >= 0; --i) { + index = index * dims[i] + indices[i]; + } + } + return m_evaluator->coeffRef(index); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const Scalar coeff(Index index) const + { + return m_evaluator->coeff(index); + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) + { + return m_evaluator->coeffRef(index); + } + + private: + EIGEN_STRONG_INLINE void unrefEvaluator() { + if (m_evaluator) { + m_evaluator->decrRefCount(); + if (m_evaluator->refCount() == 0) { + delete m_evaluator; + } + } + } + + internal::TensorLazyBaseEvaluator<Dimensions, Scalar>* m_evaluator; +}; + + +// evaluator for rvalues +template<typename Derived, typename Device> +struct TensorEvaluator<const TensorRef<Derived>, Device> +{ + typedef typename Derived::Index Index; + typedef typename Derived::Scalar Scalar; + typedef typename Derived::Packet Packet; + typedef typename Derived::Scalar CoeffReturnType; + typedef typename Derived::Packet PacketReturnType; + typedef typename Derived::Dimensions Dimensions; + + enum { + IsAligned = false, + PacketAccess = false, + Layout = TensorRef<Derived>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const TensorRef<Derived>& m, const Device&) + : m_ref(m) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_ref.dimensions(); } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + return true; + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const { + return m_ref.coeff(index); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) { + return m_ref.coeffRef(index); + } + + Scalar* data() const { return m_ref.data(); } + + protected: + TensorRef<Derived> m_ref; +}; + + +// evaluator for lvalues +template<typename Derived, typename Device> +struct TensorEvaluator<TensorRef<Derived>, Device> : public TensorEvaluator<const TensorRef<Derived>, Device> +{ + typedef typename Derived::Index Index; + typedef typename Derived::Scalar Scalar; + typedef typename Derived::Packet Packet; + typedef typename Derived::Scalar CoeffReturnType; + typedef typename Derived::Packet PacketReturnType; + typedef typename Derived::Dimensions Dimensions; + + typedef TensorEvaluator<const TensorRef<Derived>, Device> Base; + + enum { + IsAligned = false, + PacketAccess = false, + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(TensorRef<Derived>& m, const Device& d) : Base(m, d) + { } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) { + return this->m_ref.coeffRef(index); + } +}; + + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_REF_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorReverse.h b/unsupported/Eigen/CXX11/src/Tensor/TensorReverse.h new file mode 100644 index 000000000..ad21e966b --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorReverse.h @@ -0,0 +1,207 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Navdeep Jaitly <ndjaitly@google.com> +// Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_REVERSE_H +#define EIGEN_CXX11_TENSOR_TENSOR_REVERSE_H +namespace Eigen { + +/** \class TensorReverse + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor reverse elements class. + * + */ +namespace internal { +template<typename ReverseDimensions, typename XprType> +struct traits<TensorReverseOp<ReverseDimensions, + XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename ReverseDimensions, typename XprType> +struct eval<TensorReverseOp<ReverseDimensions, XprType>, Eigen::Dense> +{ + typedef const TensorReverseOp<ReverseDimensions, XprType>& type; +}; + +template<typename ReverseDimensions, typename XprType> +struct nested<TensorReverseOp<ReverseDimensions, XprType>, 1, + typename eval<TensorReverseOp<ReverseDimensions, XprType> >::type> +{ + typedef TensorReverseOp<ReverseDimensions, XprType> type; +}; + +} // end namespace internal + + + + +template<typename ReverseDimensions, typename XprType> +class TensorReverseOp : public TensorBase<TensorReverseOp<ReverseDimensions, + XprType>, ReadOnlyAccessors> +{ + public: + typedef typename Eigen::internal::traits<TensorReverseOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorReverseOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorReverseOp>::type Nested; + typedef typename Eigen::internal::traits<TensorReverseOp>::StorageKind + StorageKind; + typedef typename Eigen::internal::traits<TensorReverseOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorReverseOp(const XprType& expr, + const ReverseDimensions& reverse_dims) + : m_xpr(expr), m_reverse_dims(reverse_dims) {} + + EIGEN_DEVICE_FUNC + const ReverseDimensions& reverse() const { return m_reverse_dims; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + protected: + typename XprType::Nested m_xpr; + const ReverseDimensions m_reverse_dims; +}; + + +// Eval as rvalue +template<typename ReverseDimensions, typename ArgType, typename Device> +struct TensorEvaluator<const TensorReverseOp<ReverseDimensions, ArgType>, Device> +{ + typedef TensorReverseOp<ReverseDimensions, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<ReverseDimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, + const Device& device) + : m_impl(op.expression(), device), m_reverse(op.reverse()) + { + // Compute strides + m_dimensions = m_impl.dimensions(); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_strides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_strides[i] = m_strides[i-1] * m_dimensions[i-1]; + } + } else { + m_strides[NumDims-1] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + m_strides[i] = m_strides[i+1] * m_dimensions[i+1]; + } + } + } + + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar*) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + eigen_assert(index < dimensions().TotalSize()); + Index inputIndex = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + Index idx = index / m_strides[i]; + index -= idx * m_strides[i]; + if (m_reverse[i]) { + idx = m_dimensions[i] - idx - 1; + } + inputIndex += idx * m_strides[i] ; + } + if (m_reverse[0]) { + inputIndex += (m_dimensions[0] - index - 1); + } else { + inputIndex += index; + } + return m_impl.coeff(inputIndex); + } else { + for (int i = 0; i < NumDims - 1; ++i) { + Index idx = index / m_strides[i]; + index -= idx * m_strides[i]; + if (m_reverse[i]) { + idx = m_dimensions[i] - idx - 1; + } + inputIndex += idx * m_strides[i] ; + } + if (m_reverse[NumDims-1]) { + inputIndex += (m_dimensions[NumDims-1] - index - 1); + } else { + inputIndex += index; + } + return m_impl.coeff(inputIndex); + } + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + // TODO(ndjaitly): write a better packing routine that uses + // local structure. + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type + values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + Dimensions m_dimensions; + array<Index, NumDims> m_strides; + TensorEvaluator<ArgType, Device> m_impl; + ReverseDimensions m_reverse; +}; + + + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_REVERSE_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorShuffling.h b/unsupported/Eigen/CXX11/src/Tensor/TensorShuffling.h new file mode 100644 index 000000000..1012ecd69 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorShuffling.h @@ -0,0 +1,259 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_SHUFFLING_H +#define EIGEN_CXX11_TENSOR_TENSOR_SHUFFLING_H + +namespace Eigen { + +/** \class TensorShuffling + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor shuffling class. + * + * + */ +namespace internal { +template<typename Shuffle, typename XprType> +struct traits<TensorShufflingOp<Shuffle, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename Shuffle, typename XprType> +struct eval<TensorShufflingOp<Shuffle, XprType>, Eigen::Dense> +{ + typedef const TensorShufflingOp<Shuffle, XprType>& type; +}; + +template<typename Shuffle, typename XprType> +struct nested<TensorShufflingOp<Shuffle, XprType>, 1, typename eval<TensorShufflingOp<Shuffle, XprType> >::type> +{ + typedef TensorShufflingOp<Shuffle, XprType> type; +}; + +} // end namespace internal + + + +template<typename Shuffle, typename XprType> +class TensorShufflingOp : public TensorBase<TensorShufflingOp<Shuffle, XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorShufflingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorShufflingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorShufflingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorShufflingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorShufflingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorShufflingOp(const XprType& expr, const Shuffle& shuffle) + : m_xpr(expr), m_shuffle(shuffle) {} + + EIGEN_DEVICE_FUNC + const Shuffle& shuffle() const { return m_shuffle; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorShufflingOp& operator = (const TensorShufflingOp& other) + { + typedef TensorAssignOp<TensorShufflingOp, const TensorShufflingOp> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorShufflingOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorShufflingOp, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + protected: + typename XprType::Nested m_xpr; + const Shuffle m_shuffle; +}; + + +// Eval as rvalue +template<typename Shuffle, typename ArgType, typename Device> +struct TensorEvaluator<const TensorShufflingOp<Shuffle, ArgType>, Device> +{ + typedef TensorShufflingOp<Shuffle, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + IsAligned = false, + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + const Shuffle& shuffle = op.shuffle(); + for (int i = 0; i < NumDims; ++i) { + m_dimensions[i] = input_dims[shuffle[i]]; + } + + array<Index, NumDims> inputStrides; + + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + inputStrides[0] = 1; + m_outputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + inputStrides[i] = inputStrides[i - 1] * input_dims[i - 1]; + m_outputStrides[i] = m_outputStrides[i - 1] * m_dimensions[i - 1]; + } + } else { + inputStrides[NumDims - 1] = 1; + m_outputStrides[NumDims - 1] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + inputStrides[i] = inputStrides[i + 1] * input_dims[i + 1]; + m_outputStrides[i] = m_outputStrides[i + 1] * m_dimensions[i + 1]; + } + } + + for (int i = 0; i < NumDims; ++i) { + m_inputStrides[i] = inputStrides[shuffle[i]]; + } + } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(srcCoeff(index)); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const { + Index inputIndex = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStrides[i]; + inputIndex += idx * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + return inputIndex + index * m_inputStrides[0]; + } else { + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_outputStrides[i]; + inputIndex += idx * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + return inputIndex + index * m_inputStrides[NumDims - 1]; + } + } + + Dimensions m_dimensions; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims> m_inputStrides; + TensorEvaluator<ArgType, Device> m_impl; +}; + + +// Eval as lvalue +template<typename Shuffle, typename ArgType, typename Device> +struct TensorEvaluator<TensorShufflingOp<Shuffle, ArgType>, Device> + : public TensorEvaluator<const TensorShufflingOp<Shuffle, ArgType>, Device> +{ + typedef TensorEvaluator<const TensorShufflingOp<Shuffle, ArgType>, Device> Base; + + typedef TensorShufflingOp<Shuffle, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + typedef typename XprType::Scalar Scalar; + + enum { + IsAligned = false, + PacketAccess = (internal::packet_traits<Scalar>::size > 1), + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) + { } + + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType& coeffRef(Index index) + { + return this->m_impl.coeffRef(this->srcCoeff(index)); + } + + template <int StoreMode> EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + static const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + internal::pstore<CoeffReturnType, PacketReturnType>(values, x); + for (int i = 0; i < packetSize; ++i) { + this->coeffRef(index+i) = values[i]; + } + } +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_SHUFFLING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorStorage.h b/unsupported/Eigen/CXX11/src/Tensor/TensorStorage.h index a34600ee6..1b227e8c2 100644 --- a/unsupported/Eigen/CXX11/src/Tensor/TensorStorage.h +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorStorage.h @@ -30,39 +30,70 @@ namespace Eigen { * * \sa Tensor */ -template<typename T, std::size_t NumIndices_, DenseIndex Size, int Options_, typename Dimensions = void> class TensorStorage; +template<typename T, DenseIndex NumIndices_, DenseIndex Size, int Options_, typename Dimensions = void> class TensorStorage; + + +// Pure fixed-size storage +template<typename T, DenseIndex NumIndices_, DenseIndex Size, int Options_, typename FixedDimensions> +class TensorStorage +{ + private: + EIGEN_ALIGN_DEFAULT T m_data[Size]; + FixedDimensions m_dimensions; + + public: + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorStorage() { + EIGEN_STATIC_ASSERT(Size == FixedDimensions::total_size, YOU_MADE_A_PROGRAMMING_MISTAKE) + } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE T *data() { return m_data; } + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const T *data() const { return m_data; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE const FixedDimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE DenseIndex size() const { return m_dimensions.TotalSize(); } +}; + + // pure-dynamic, but without specification of all dimensions explicitly -template<typename T, std::size_t NumIndices_, int Options_> +template<typename T, DenseIndex NumIndices_, int Options_> class TensorStorage<T, NumIndices_, Dynamic, Options_, void> : public TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_numeric_list_repeated<DenseIndex, NumIndices_, Dynamic>::type> { - typedef TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_numeric_list_repeated<DenseIndex, NumIndices_, Dynamic>::type> Base_; + typedef TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_numeric_list_repeated<DenseIndex, NumIndices_, Dynamic>::type> Base_; + public: - TensorStorage() = default; - TensorStorage(const TensorStorage<T, NumIndices_, Dynamic, Options_, void>&) = default; - TensorStorage(TensorStorage<T, NumIndices_, Dynamic, Options_, void>&&) = default; + TensorStorage() { } + TensorStorage(const TensorStorage<T, NumIndices_, Dynamic, Options_, void>& other) : Base_(other) { } + TensorStorage(internal::constructor_without_unaligned_array_assert) : Base_(internal::constructor_without_unaligned_array_assert()) {} - TensorStorage(DenseIndex size, const std::array<DenseIndex, NumIndices_>& dimensions) : Base_(size, dimensions) {} - TensorStorage<T, NumIndices_, Dynamic, Options_, void>& operator=(const TensorStorage<T, NumIndices_, Dynamic, Options_, void>&) = default; + TensorStorage(DenseIndex size, const array<DenseIndex, NumIndices_>& dimensions) : Base_(size, dimensions) {} + + // TensorStorage<T, NumIndices_, Dynamic, Options_, void>& operator=(const TensorStorage<T, NumIndices_, Dynamic, Options_, void>&) = default; }; // pure dynamic -template<typename T, std::size_t NumIndices_, int Options_> +template<typename T, DenseIndex NumIndices_, int Options_> class TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_numeric_list_repeated<DenseIndex, NumIndices_, Dynamic>::type> { T *m_data; - std::array<DenseIndex, NumIndices_> m_dimensions; + DSizes<DenseIndex, NumIndices_> m_dimensions; typedef TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_numeric_list_repeated<DenseIndex, NumIndices_, Dynamic>::type> Self_; public: - TensorStorage() : m_data(0), m_dimensions(internal::template repeat<NumIndices_, DenseIndex>(0)) {} + TensorStorage() : m_data(0), m_dimensions() {} TensorStorage(internal::constructor_without_unaligned_array_assert) : m_data(0), m_dimensions(internal::template repeat<NumIndices_, DenseIndex>(0)) {} - TensorStorage(DenseIndex size, const std::array<DenseIndex, NumIndices_>& dimensions) - : m_data(internal::conditional_aligned_new_auto<T,(Options_&DontAlign)==0>(size)), m_dimensions(dimensions) - { EIGEN_INTERNAL_TENSOR_STORAGE_CTOR_PLUGIN } - TensorStorage(const Self_& other) + TensorStorage(DenseIndex size, const array<DenseIndex, NumIndices_>& dimensions) + : m_data(internal::conditional_aligned_new_auto<T,(Options_&DontAlign)==0>(size)), m_dimensions(dimensions) + { EIGEN_INTERNAL_TENSOR_STORAGE_CTOR_PLUGIN } + TensorStorage(const Self_& other) : m_data(internal::conditional_aligned_new_auto<T,(Options_&DontAlign)==0>(internal::array_prod(other.m_dimensions))) , m_dimensions(other.m_dimensions) { @@ -76,32 +107,19 @@ class TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_nu } return *this; } - TensorStorage(Self_&& other) - : m_data(std::move(other.m_data)), m_dimensions(std::move(other.m_dimensions)) - { - other.m_data = nullptr; - } - Self_& operator=(Self_&& other) - { - using std::swap; - swap(m_data, other.m_data); - swap(m_dimensions, other.m_dimensions); - return *this; - } + ~TensorStorage() { internal::conditional_aligned_delete_auto<T,(Options_&DontAlign)==0>(m_data, internal::array_prod(m_dimensions)); } void swap(Self_& other) { std::swap(m_data,other.m_data); std::swap(m_dimensions,other.m_dimensions); } - std::array<DenseIndex, NumIndices_> dimensions(void) const {return m_dimensions;} - void conservativeResize(DenseIndex size, const std::array<DenseIndex, NumIndices_>& nbDimensions) - { - m_data = internal::conditional_aligned_realloc_new_auto<T,(Options_&DontAlign)==0>(m_data, size, internal::array_prod(m_dimensions)); - m_dimensions = nbDimensions; - } - void resize(DenseIndex size, const std::array<DenseIndex, NumIndices_>& nbDimensions) + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const DSizes<DenseIndex, NumIndices_>& dimensions() const {return m_dimensions;} + + EIGEN_DEVICE_FUNC void resize(DenseIndex size, const array<DenseIndex, NumIndices_>& nbDimensions) { - if(size != internal::array_prod(m_dimensions)) + const DenseIndex currentSz = internal::array_prod(m_dimensions); + if(size != currentSz) { - internal::conditional_aligned_delete_auto<T,(Options_&DontAlign)==0>(m_data, internal::array_prod(m_dimensions)); + internal::conditional_aligned_delete_auto<T,(Options_&DontAlign)==0>(m_data, currentSz); if (size) m_data = internal::conditional_aligned_new_auto<T,(Options_&DontAlign)==0>(size); else @@ -110,16 +128,13 @@ class TensorStorage<T, NumIndices_, Dynamic, Options_, typename internal::gen_nu } m_dimensions = nbDimensions; } - const T *data() const { return m_data; } - T *data() { return m_data; } -}; -// TODO: implement fixed-size stuff + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE T *data() { return m_data; } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const T *data() const { return m_data; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex size() const { return m_dimensions.TotalSize(); } +}; } // end namespace Eigen #endif // EIGEN_CXX11_TENSOR_TENSORSTORAGE_H - -/* - * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle; - */ diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorStriding.h b/unsupported/Eigen/CXX11/src/Tensor/TensorStriding.h new file mode 100644 index 000000000..00cb8e373 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorStriding.h @@ -0,0 +1,325 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_STRIDING_H +#define EIGEN_CXX11_TENSOR_TENSOR_STRIDING_H + +namespace Eigen { + +/** \class TensorStriding + * \ingroup CXX11_Tensor_Module + * + * \brief Tensor striding class. + * + * + */ +namespace internal { +template<typename Strides, typename XprType> +struct traits<TensorStridingOp<Strides, XprType> > : public traits<XprType> +{ + typedef typename XprType::Scalar Scalar; + typedef traits<XprType> XprTraits; + typedef typename packet_traits<Scalar>::type Packet; + typedef typename XprTraits::StorageKind StorageKind; + typedef typename XprTraits::Index Index; + typedef typename XprType::Nested Nested; + typedef typename remove_reference<Nested>::type _Nested; + static const int NumDimensions = XprTraits::NumDimensions; + static const int Layout = XprTraits::Layout; +}; + +template<typename Strides, typename XprType> +struct eval<TensorStridingOp<Strides, XprType>, Eigen::Dense> +{ + typedef const TensorStridingOp<Strides, XprType>& type; +}; + +template<typename Strides, typename XprType> +struct nested<TensorStridingOp<Strides, XprType>, 1, typename eval<TensorStridingOp<Strides, XprType> >::type> +{ + typedef TensorStridingOp<Strides, XprType> type; +}; + +} // end namespace internal + + + +template<typename Strides, typename XprType> +class TensorStridingOp : public TensorBase<TensorStridingOp<Strides, XprType> > +{ + public: + typedef typename Eigen::internal::traits<TensorStridingOp>::Scalar Scalar; + typedef typename Eigen::internal::traits<TensorStridingOp>::Packet Packet; + typedef typename Eigen::NumTraits<Scalar>::Real RealScalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + typedef typename Eigen::internal::nested<TensorStridingOp>::type Nested; + typedef typename Eigen::internal::traits<TensorStridingOp>::StorageKind StorageKind; + typedef typename Eigen::internal::traits<TensorStridingOp>::Index Index; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorStridingOp(const XprType& expr, const Strides& dims) + : m_xpr(expr), m_dims(dims) {} + + EIGEN_DEVICE_FUNC + const Strides& strides() const { return m_dims; } + + EIGEN_DEVICE_FUNC + const typename internal::remove_all<typename XprType::Nested>::type& + expression() const { return m_xpr; } + + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorStridingOp& operator = (const TensorStridingOp& other) + { + typedef TensorAssignOp<TensorStridingOp, const TensorStridingOp> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + template<typename OtherDerived> + EIGEN_DEVICE_FUNC + EIGEN_STRONG_INLINE TensorStridingOp& operator = (const OtherDerived& other) + { + typedef TensorAssignOp<TensorStridingOp, const OtherDerived> Assign; + Assign assign(*this, other); + internal::TensorExecutor<const Assign, DefaultDevice, false>::run(assign, DefaultDevice()); + return *this; + } + + protected: + typename XprType::Nested m_xpr; + const Strides m_dims; +}; + + +// Eval as rvalue +template<typename Strides, typename ArgType, typename Device> +struct TensorEvaluator<const TensorStridingOp<Strides, ArgType>, Device> +{ + typedef TensorStridingOp<Strides, ArgType> XprType; + typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = /*TensorEvaluator<ArgType, Device>::IsAligned*/false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : m_impl(op.expression(), device) + { + m_dimensions = m_impl.dimensions(); + for (int i = 0; i < NumDims; ++i) { + m_dimensions[i] = ceilf(static_cast<float>(m_dimensions[i]) / op.strides()[i]); + } + + const typename TensorEvaluator<ArgType, Device>::Dimensions& input_dims = m_impl.dimensions(); + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + m_outputStrides[0] = 1; + m_inputStrides[0] = 1; + for (int i = 1; i < NumDims; ++i) { + m_outputStrides[i] = m_outputStrides[i-1] * m_dimensions[i-1]; + m_inputStrides[i] = m_inputStrides[i-1] * input_dims[i-1]; + m_inputStrides[i-1] *= op.strides()[i-1]; + } + m_inputStrides[NumDims-1] *= op.strides()[NumDims-1]; + } else { // RowMajor + m_outputStrides[NumDims-1] = 1; + m_inputStrides[NumDims-1] = 1; + for (int i = NumDims - 2; i >= 0; --i) { + m_outputStrides[i] = m_outputStrides[i+1] * m_dimensions[i+1]; + m_inputStrides[i] = m_inputStrides[i+1] * input_dims[i+1]; + m_inputStrides[i+1] *= op.strides()[i+1]; + } + m_inputStrides[0] *= op.strides()[0]; + } + } + + typedef typename XprType::Scalar Scalar; + typedef typename XprType::CoeffReturnType CoeffReturnType; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions& dimensions() const { return m_dimensions; } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE bool evalSubExprsIfNeeded(Scalar* /*data*/) { + m_impl.evalSubExprsIfNeeded(NULL); + return true; + } + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void cleanup() { + m_impl.cleanup(); + } + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE CoeffReturnType coeff(Index index) const + { + return m_impl.coeff(srcCoeff(index)); + } + + template<int LoadMode> + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PacketReturnType packet(Index index) const + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < dimensions().TotalSize()); + + Index inputIndices[] = {0, 0}; + Index indices[] = {index, index + packetSize - 1}; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx0 = indices[0] / m_outputStrides[i]; + const Index idx1 = indices[1] / m_outputStrides[i]; + inputIndices[0] += idx0 * m_inputStrides[i]; + inputIndices[1] += idx1 * m_inputStrides[i]; + indices[0] -= idx0 * m_outputStrides[i]; + indices[1] -= idx1 * m_outputStrides[i]; + } + inputIndices[0] += indices[0] * m_inputStrides[0]; + inputIndices[1] += indices[1] * m_inputStrides[0]; + } else { // RowMajor + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx0 = indices[0] / m_outputStrides[i]; + const Index idx1 = indices[1] / m_outputStrides[i]; + inputIndices[0] += idx0 * m_inputStrides[i]; + inputIndices[1] += idx1 * m_inputStrides[i]; + indices[0] -= idx0 * m_outputStrides[i]; + indices[1] -= idx1 * m_outputStrides[i]; + } + inputIndices[0] += indices[0] * m_inputStrides[NumDims-1]; + inputIndices[1] += indices[1] * m_inputStrides[NumDims-1]; + } + if (inputIndices[1] - inputIndices[0] == packetSize - 1) { + PacketReturnType rslt = m_impl.template packet<Unaligned>(inputIndices[0]); + return rslt; + } + else { + EIGEN_ALIGN_DEFAULT typename internal::remove_const<CoeffReturnType>::type values[packetSize]; + values[0] = m_impl.coeff(inputIndices[0]); + values[packetSize-1] = m_impl.coeff(inputIndices[1]); + for (int i = 1; i < packetSize-1; ++i) { + values[i] = coeff(index+i); + } + PacketReturnType rslt = internal::pload<PacketReturnType>(values); + return rslt; + } + } + + EIGEN_DEVICE_FUNC Scalar* data() const { return NULL; } + + protected: + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index srcCoeff(Index index) const + { + Index inputIndex = 0; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx = index / m_outputStrides[i]; + inputIndex += idx * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + inputIndex += index * m_inputStrides[0]; + } else { // RowMajor + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx = index / m_outputStrides[i]; + inputIndex += idx * m_inputStrides[i]; + index -= idx * m_outputStrides[i]; + } + inputIndex += index * m_inputStrides[NumDims-1]; + } + return inputIndex; + } + + Dimensions m_dimensions; + array<Index, NumDims> m_outputStrides; + array<Index, NumDims> m_inputStrides; + TensorEvaluator<ArgType, Device> m_impl; +}; + + +// Eval as lvalue +template<typename Strides, typename ArgType, typename Device> +struct TensorEvaluator<TensorStridingOp<Strides, ArgType>, Device> + : public TensorEvaluator<const TensorStridingOp<Strides, ArgType>, Device> +{ + typedef TensorStridingOp<Strides, ArgType> XprType; + typedef TensorEvaluator<const XprType, Device> Base; + // typedef typename XprType::Index Index; + static const int NumDims = internal::array_size<typename TensorEvaluator<ArgType, Device>::Dimensions>::value; + // typedef DSizes<Index, NumDims> Dimensions; + + enum { + IsAligned = /*TensorEvaluator<ArgType, Device>::IsAligned*/false, + PacketAccess = TensorEvaluator<ArgType, Device>::PacketAccess, + Layout = TensorEvaluator<ArgType, Device>::Layout, + CoordAccess = false, // to be implemented + }; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE TensorEvaluator(const XprType& op, const Device& device) + : Base(op, device) { } + + typedef typename XprType::Index Index; + typedef typename XprType::Scalar Scalar; + typedef typename XprType::PacketReturnType PacketReturnType; + + EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(Index index) + { + return this->m_impl.coeffRef(this->srcCoeff(index)); + } + + template <int StoreMode> EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE + void writePacket(Index index, const PacketReturnType& x) + { + const int packetSize = internal::unpacket_traits<PacketReturnType>::size; + EIGEN_STATIC_ASSERT(packetSize > 1, YOU_MADE_A_PROGRAMMING_MISTAKE) + eigen_assert(index+packetSize-1 < this->dimensions().TotalSize()); + + Index inputIndices[] = {0, 0}; + Index indices[] = {index, index + packetSize - 1}; + if (static_cast<int>(Layout) == static_cast<int>(ColMajor)) { + for (int i = NumDims - 1; i > 0; --i) { + const Index idx0 = indices[0] / this->m_outputStrides[i]; + const Index idx1 = indices[1] / this->m_outputStrides[i]; + inputIndices[0] += idx0 * this->m_inputStrides[i]; + inputIndices[1] += idx1 * this->m_inputStrides[i]; + indices[0] -= idx0 * this->m_outputStrides[i]; + indices[1] -= idx1 * this->m_outputStrides[i]; + } + inputIndices[0] += indices[0] * this->m_inputStrides[0]; + inputIndices[1] += indices[1] * this->m_inputStrides[0]; + } else { // RowMajor + for (int i = 0; i < NumDims - 1; ++i) { + const Index idx0 = indices[0] / this->m_outputStrides[i]; + const Index idx1 = indices[1] / this->m_outputStrides[i]; + inputIndices[0] += idx0 * this->m_inputStrides[i]; + inputIndices[1] += idx1 * this->m_inputStrides[i]; + indices[0] -= idx0 * this->m_outputStrides[i]; + indices[1] -= idx1 * this->m_outputStrides[i]; + } + inputIndices[0] += indices[0] * this->m_inputStrides[NumDims-1]; + inputIndices[1] += indices[1] * this->m_inputStrides[NumDims-1]; + } + if (inputIndices[1] - inputIndices[0] == packetSize - 1) { + this->m_impl.template writePacket<Unaligned>(inputIndices[0], x); + } + else { + EIGEN_ALIGN_DEFAULT Scalar values[packetSize]; + internal::pstore<Scalar, PacketReturnType>(values, x); + this->m_impl.coeffRef(inputIndices[0]) = values[0]; + this->m_impl.coeffRef(inputIndices[1]) = values[packetSize-1]; + for (int i = 1; i < packetSize-1; ++i) { + this->coeffRef(index+i) = values[i]; + } + } + } +}; + + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_STRIDING_H diff --git a/unsupported/Eigen/CXX11/src/Tensor/TensorTraits.h b/unsupported/Eigen/CXX11/src/Tensor/TensorTraits.h new file mode 100644 index 000000000..a844a4d68 --- /dev/null +++ b/unsupported/Eigen/CXX11/src/Tensor/TensorTraits.h @@ -0,0 +1,256 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#ifndef EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H +#define EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H + +namespace Eigen { +namespace internal { + + +template<typename Scalar, int Options> +class compute_tensor_flags +{ + enum { + is_dynamic_size_storage = 1, + + aligned_bit = + ( + ((Options&DontAlign)==0) && ( +#if EIGEN_ALIGN_STATICALLY + (!is_dynamic_size_storage) +#else + 0 +#endif + || +#if EIGEN_ALIGN + is_dynamic_size_storage +#else + 0 +#endif + ) + ) ? AlignedBit : 0, + packet_access_bit = packet_traits<Scalar>::Vectorizable && aligned_bit ? PacketAccessBit : 0 + }; + + public: + enum { ret = packet_access_bit | aligned_bit}; +}; + + +template<typename Scalar_, std::size_t NumIndices_, int Options_> +struct traits<Tensor<Scalar_, NumIndices_, Options_> > +{ + typedef Scalar_ Scalar; + typedef Dense StorageKind; + typedef DenseIndex Index; + static const int NumDimensions = NumIndices_; + static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor; + enum { + Options = Options_, + Flags = compute_tensor_flags<Scalar_, Options_>::ret | LvalueBit, + }; +}; + + +template<typename Scalar_, typename Dimensions, int Options_> +struct traits<TensorFixedSize<Scalar_, Dimensions, Options_> > +{ + typedef Scalar_ Scalar; + typedef Dense StorageKind; + typedef DenseIndex Index; + static const int NumDimensions = array_size<Dimensions>::value; + static const int Layout = Options_ & RowMajor ? RowMajor : ColMajor; + enum { + Options = Options_, + Flags = compute_tensor_flags<Scalar_, Options_>::ret | LvalueBit, + }; +}; + + +template<typename PlainObjectType, int Options_> +struct traits<TensorMap<PlainObjectType, Options_> > + : public traits<PlainObjectType> +{ + typedef traits<PlainObjectType> BaseTraits; + typedef typename BaseTraits::Scalar Scalar; + typedef typename BaseTraits::StorageKind StorageKind; + typedef typename BaseTraits::Index Index; + static const int NumDimensions = BaseTraits::NumDimensions; + static const int Layout = BaseTraits::Layout; + enum { + Options = Options_, + Flags = ((BaseTraits::Flags | LvalueBit) & ~AlignedBit) | (Options&Aligned ? AlignedBit : 0), + }; +}; + +template<typename PlainObjectType> +struct traits<TensorRef<PlainObjectType> > + : public traits<PlainObjectType> +{ + typedef traits<PlainObjectType> BaseTraits; + typedef typename BaseTraits::Scalar Scalar; + typedef typename BaseTraits::StorageKind StorageKind; + typedef typename BaseTraits::Index Index; + static const int NumDimensions = BaseTraits::NumDimensions; + static const int Layout = BaseTraits::Layout; + enum { + Options = BaseTraits::Options, + Flags = ((BaseTraits::Flags | LvalueBit) & ~AlignedBit) | (Options&Aligned ? AlignedBit : 0), + }; +}; + + +template<typename _Scalar, std::size_t NumIndices_, int Options> +struct eval<Tensor<_Scalar, NumIndices_, Options>, Eigen::Dense> +{ + typedef const Tensor<_Scalar, NumIndices_, Options>& type; +}; + +template<typename _Scalar, std::size_t NumIndices_, int Options> +struct eval<const Tensor<_Scalar, NumIndices_, Options>, Eigen::Dense> +{ + typedef const Tensor<_Scalar, NumIndices_, Options>& type; +}; + +template<typename Scalar_, typename Dimensions, int Options> +struct eval<TensorFixedSize<Scalar_, Dimensions, Options>, Eigen::Dense> +{ + typedef const TensorFixedSize<Scalar_, Dimensions, Options>& type; +}; + +template<typename Scalar_, typename Dimensions, int Options> +struct eval<const TensorFixedSize<Scalar_, Dimensions, Options>, Eigen::Dense> +{ + typedef const TensorFixedSize<Scalar_, Dimensions, Options>& type; +}; + +template<typename PlainObjectType, int Options> +struct eval<TensorMap<PlainObjectType, Options>, Eigen::Dense> +{ + typedef const TensorMap<PlainObjectType, Options>& type; +}; + +template<typename PlainObjectType, int Options> +struct eval<const TensorMap<PlainObjectType, Options>, Eigen::Dense> +{ + typedef const TensorMap<PlainObjectType, Options>& type; +}; + +template<typename PlainObjectType> +struct eval<TensorRef<PlainObjectType>, Eigen::Dense> +{ + typedef const TensorRef<PlainObjectType>& type; +}; + +template<typename PlainObjectType> +struct eval<const TensorRef<PlainObjectType>, Eigen::Dense> +{ + typedef const TensorRef<PlainObjectType>& type; +}; + + +template <typename Scalar_, std::size_t NumIndices_, int Options_> +struct nested<Tensor<Scalar_, NumIndices_, Options_> > +{ + typedef const Tensor<Scalar_, NumIndices_, Options_>& type; +}; + +template <typename Scalar_, std::size_t NumIndices_, int Options_> +struct nested<const Tensor<Scalar_, NumIndices_, Options_> > +{ + typedef const Tensor<Scalar_, NumIndices_, Options_>& type; +}; + +template <typename Scalar_, typename Dimensions, int Options> +struct nested<TensorFixedSize<Scalar_, Dimensions, Options> > +{ + typedef const TensorFixedSize<Scalar_, Dimensions, Options>& type; +}; + +template <typename Scalar_, typename Dimensions, int Options> +struct nested<const TensorFixedSize<Scalar_, Dimensions, Options> > +{ + typedef const TensorFixedSize<Scalar_, Dimensions, Options>& type; +}; + + +template <typename PlainObjectType, int Options> +struct nested<TensorMap<PlainObjectType, Options> > +{ + typedef const TensorMap<PlainObjectType, Options>& type; +}; + +template <typename PlainObjectType, int Options> +struct nested<const TensorMap<PlainObjectType, Options> > +{ + typedef const TensorMap<PlainObjectType, Options>& type; +}; + +template <typename PlainObjectType> +struct nested<TensorRef<PlainObjectType> > +{ + typedef const TensorRef<PlainObjectType>& type; +}; + +template <typename PlainObjectType> +struct nested<const TensorRef<PlainObjectType> > +{ + typedef const TensorRef<PlainObjectType>& type; +}; + +} // end namespace internal + +// Convolutional layers take in an input tensor of shape (D, R, C, B), or (D, C, +// R, B), and convolve it with a set of filters, which can also be presented as +// a tensor (D, K, K, M), where M is the number of filters, K is the filter +// size, and each 3-dimensional tensor of size (D, K, K) is a filter. For +// simplicity we assume that we always use square filters (which is usually the +// case in images), hence the two Ks in the tensor dimension. It also takes in +// a few additional parameters: +// Stride (S): The convolution stride is the offset between locations where we +// apply the filters. A larger stride means that the output will be +// spatially smaller. +// Padding (P): The padding we apply to the input tensor along the R and C +// dimensions. This is usually used to make sure that the spatial +// dimensions of the output matches our intention. +// +// Two types of padding are often used: +// SAME: The pad value is computed so that the output will have size +// R/S and C/S. +// VALID: no padding is carried out. +// When we do padding, the padded values at the padded locations are usually +// zero. +// +// The output dimensions for convolution, when given all the parameters above, +// are as follows: +// When Padding = SAME: the output size is (B, R', C', M), where +// R' = ceil(float(R) / float(S)) +// C' = ceil(float(C) / float(S)) +// where ceil is the ceiling function. The input tensor is padded with 0 as +// needed. The number of padded rows and columns are computed as: +// Pr = ((R' - 1) * S + K - R) / 2 +// Pc = ((C' - 1) * S + K - C) / 2 +// when the stride is 1, we have the simplified case R'=R, C'=C, Pr=Pc=(K-1)/2. +// This is where SAME comes from - the output has the same size as the input has. +// When Padding = VALID: the output size is computed as +// R' = ceil(float(R - K + 1) / float(S)) +// C' = ceil(float(C - K + 1) / float(S)) +// and the number of padded rows and columns are computed in the same way as in +// the SAME case. +// When the stride is 1, we have the simplified case R'=R-K+1, C'=C-K+1, Pr=0, +// Pc=0. +typedef enum { + PADDING_VALID = 1, + PADDING_SAME = 2, +} PaddingType; + +} // end namespace Eigen + +#endif // EIGEN_CXX11_TENSOR_TENSOR_TRAITS_H diff --git a/unsupported/Eigen/OpenGLSupport b/unsupported/Eigen/OpenGLSupport index 4ed545174..6ca1b1217 100644 --- a/unsupported/Eigen/OpenGLSupport +++ b/unsupported/Eigen/OpenGLSupport @@ -178,11 +178,11 @@ template<typename Scalar> void glLoadMatrix(const Transform<Scalar,3,Affine>& t) template<typename Scalar> void glLoadMatrix(const Transform<Scalar,3,Projective>& t) { glLoadMatrix(t.matrix()); } template<typename Scalar> void glLoadMatrix(const Transform<Scalar,3,AffineCompact>& t) { glLoadMatrix(Transform<Scalar,3,Affine>(t).matrix()); } -static void glRotate(const Rotation2D<float>& rot) +inline void glRotate(const Rotation2D<float>& rot) { glRotatef(rot.angle()*180.f/float(M_PI), 0.f, 0.f, 1.f); } -static void glRotate(const Rotation2D<double>& rot) +inline void glRotate(const Rotation2D<double>& rot) { glRotated(rot.angle()*180.0/M_PI, 0.0, 0.0, 1.0); } @@ -246,18 +246,18 @@ EIGEN_GL_FUNC1_SPECIALIZATION_MAT(glGet,GLenum,_,double, 4,4,Doublev) #ifdef GL_VERSION_2_0 -static void glUniform2fv_ei (GLint loc, const float* v) { glUniform2fv(loc,1,v); } -static void glUniform2iv_ei (GLint loc, const int* v) { glUniform2iv(loc,1,v); } +inline void glUniform2fv_ei (GLint loc, const float* v) { glUniform2fv(loc,1,v); } +inline void glUniform2iv_ei (GLint loc, const int* v) { glUniform2iv(loc,1,v); } -static void glUniform3fv_ei (GLint loc, const float* v) { glUniform3fv(loc,1,v); } -static void glUniform3iv_ei (GLint loc, const int* v) { glUniform3iv(loc,1,v); } +inline void glUniform3fv_ei (GLint loc, const float* v) { glUniform3fv(loc,1,v); } +inline void glUniform3iv_ei (GLint loc, const int* v) { glUniform3iv(loc,1,v); } -static void glUniform4fv_ei (GLint loc, const float* v) { glUniform4fv(loc,1,v); } -static void glUniform4iv_ei (GLint loc, const int* v) { glUniform4iv(loc,1,v); } +inline void glUniform4fv_ei (GLint loc, const float* v) { glUniform4fv(loc,1,v); } +inline void glUniform4iv_ei (GLint loc, const int* v) { glUniform4iv(loc,1,v); } -static void glUniformMatrix2fv_ei (GLint loc, const float* v) { glUniformMatrix2fv(loc,1,false,v); } -static void glUniformMatrix3fv_ei (GLint loc, const float* v) { glUniformMatrix3fv(loc,1,false,v); } -static void glUniformMatrix4fv_ei (GLint loc, const float* v) { glUniformMatrix4fv(loc,1,false,v); } +inline void glUniformMatrix2fv_ei (GLint loc, const float* v) { glUniformMatrix2fv(loc,1,false,v); } +inline void glUniformMatrix3fv_ei (GLint loc, const float* v) { glUniformMatrix3fv(loc,1,false,v); } +inline void glUniformMatrix4fv_ei (GLint loc, const float* v) { glUniformMatrix4fv(loc,1,false,v); } EIGEN_GL_FUNC1_DECLARATION (glUniform,GLint,const) @@ -294,9 +294,9 @@ EIGEN_GL_FUNC1_SPECIALIZATION_MAT(glUniform,GLint,const,float, 4,3,Matrix #ifdef GL_VERSION_3_0 -static void glUniform2uiv_ei (GLint loc, const unsigned int* v) { glUniform2uiv(loc,1,v); } -static void glUniform3uiv_ei (GLint loc, const unsigned int* v) { glUniform3uiv(loc,1,v); } -static void glUniform4uiv_ei (GLint loc, const unsigned int* v) { glUniform4uiv(loc,1,v); } +inline void glUniform2uiv_ei (GLint loc, const unsigned int* v) { glUniform2uiv(loc,1,v); } +inline void glUniform3uiv_ei (GLint loc, const unsigned int* v) { glUniform3uiv(loc,1,v); } +inline void glUniform4uiv_ei (GLint loc, const unsigned int* v) { glUniform4uiv(loc,1,v); } EIGEN_GL_FUNC1_SPECIALIZATION_VEC(glUniform,GLint,const,unsigned int, 2,2uiv_ei) EIGEN_GL_FUNC1_SPECIALIZATION_VEC(glUniform,GLint,const,unsigned int, 3,3uiv_ei) @@ -305,9 +305,9 @@ EIGEN_GL_FUNC1_SPECIALIZATION_VEC(glUniform,GLint,const,unsigned int, 4,4uiv_ei) #endif #ifdef GL_ARB_gpu_shader_fp64 -static void glUniform2dv_ei (GLint loc, const double* v) { glUniform2dv(loc,1,v); } -static void glUniform3dv_ei (GLint loc, const double* v) { glUniform3dv(loc,1,v); } -static void glUniform4dv_ei (GLint loc, const double* v) { glUniform4dv(loc,1,v); } +inline void glUniform2dv_ei (GLint loc, const double* v) { glUniform2dv(loc,1,v); } +inline void glUniform3dv_ei (GLint loc, const double* v) { glUniform3dv(loc,1,v); } +inline void glUniform4dv_ei (GLint loc, const double* v) { glUniform4dv(loc,1,v); } EIGEN_GL_FUNC1_SPECIALIZATION_VEC(glUniform,GLint,const,double, 2,2dv_ei) EIGEN_GL_FUNC1_SPECIALIZATION_VEC(glUniform,GLint,const,double, 3,3dv_ei) diff --git a/unsupported/Eigen/src/IterativeSolvers/DGMRES.h b/unsupported/Eigen/src/IterativeSolvers/DGMRES.h index 0e1b7d977..52eb65a2f 100644 --- a/unsupported/Eigen/src/IterativeSolvers/DGMRES.h +++ b/unsupported/Eigen/src/IterativeSolvers/DGMRES.h @@ -150,7 +150,7 @@ class DGMRES : public IterativeSolverBase<DGMRES<_MatrixType,_Preconditioner> > m_error = Base::m_tolerance; typename Dest::ColXpr xj(x,j); - dgmres(*mp_matrix, b.col(j), xj, Base::m_preconditioner); + dgmres(mp_matrix, b.col(j), xj, Base::m_preconditioner); } m_info = failed ? NumericalIssue : m_error <= Base::m_tolerance ? Success diff --git a/unsupported/Eigen/src/IterativeSolvers/GMRES.h b/unsupported/Eigen/src/IterativeSolvers/GMRES.h index 60f5f662c..6e847e110 100644 --- a/unsupported/Eigen/src/IterativeSolvers/GMRES.h +++ b/unsupported/Eigen/src/IterativeSolvers/GMRES.h @@ -250,21 +250,8 @@ struct traits<GMRES<_MatrixType,_Preconditioner> > * \endcode * * By default the iterations start with x=0 as an initial guess of the solution. - * One can control the start using the solveWithGuess() method. Here is a step by - * step execution example starting with a random guess and printing the evolution - * of the estimated error: - * * \code - * x = VectorXd::Random(n); - * solver.setMaxIterations(1); - * int i = 0; - * do { - * x = solver.solveWithGuess(b,x); - * std::cout << i << " : " << solver.error() << std::endl; - * ++i; - * } while (solver.info()!=Success && i<100); - * \endcode - * Note that such a step by step excution is slightly slower. - * + * One can control the start using the solveWithGuess() method. + * * \sa class SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner */ template< typename _MatrixType, typename _Preconditioner> @@ -327,7 +314,7 @@ public: m_error = Base::m_tolerance; typename Dest::ColXpr xj(x,j); - if(!internal::gmres(*mp_matrix, b.col(j), xj, Base::m_preconditioner, m_iterations, m_restart, m_error)) + if(!internal::gmres(mp_matrix, b.col(j), xj, Base::m_preconditioner, m_iterations, m_restart, m_error)) failed = true; } m_info = failed ? NumericalIssue diff --git a/unsupported/Eigen/src/IterativeSolvers/MINRES.h b/unsupported/Eigen/src/IterativeSolvers/MINRES.h index eccdce24c..2845b9cfd 100644 --- a/unsupported/Eigen/src/IterativeSolvers/MINRES.h +++ b/unsupported/Eigen/src/IterativeSolvers/MINRES.h @@ -165,8 +165,8 @@ namespace Eigen { * The vectors x and b can be either dense or sparse. * * \tparam _MatrixType the type of the sparse matrix A, can be a dense or a sparse matrix. - * \tparam _UpLo the triangular part that will be used for the computations. It can be Lower - * or Upper. Default is Lower. + * \tparam _UpLo the triangular part that will be used for the computations. It can be Lower, + * Upper, or Lower|Upper in which the full matrix entries will be considered. Default is Lower. * \tparam _Preconditioner the type of the preconditioner. Default is DiagonalPreconditioner * * The maximal number of iterations and tolerance value can be controlled via the setMaxIterations() @@ -189,20 +189,7 @@ namespace Eigen { * \endcode * * By default the iterations start with x=0 as an initial guess of the solution. - * One can control the start using the solveWithGuess() method. Here is a step by - * step execution example starting with a random guess and printing the evolution - * of the estimated error: - * * \code - * x = VectorXd::Random(n); - * mr.setMaxIterations(1); - * int i = 0; - * do { - * x = mr.solveWithGuess(b,x); - * std::cout << i << " : " << mr.error() << std::endl; - * ++i; - * } while (mr.info()!=Success && i<100); - * \endcode - * Note that such a step by step excution is slightly slower. + * One can control the start using the solveWithGuess() method. * * \sa class ConjugateGradient, BiCGSTAB, SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner */ @@ -250,6 +237,11 @@ namespace Eigen { template<typename Rhs,typename Dest> void _solve_with_guess_impl(const Rhs& b, Dest& x) const { + typedef typename internal::conditional<UpLo==(Lower|Upper), + Ref<const MatrixType>&, + SparseSelfAdjointView<const Ref<const MatrixType>, UpLo> + >::type MatrixWrapperType; + m_iterations = Base::maxIterations(); m_error = Base::m_tolerance; @@ -259,7 +251,7 @@ namespace Eigen { m_error = Base::m_tolerance; typename Dest::ColXpr xj(x,j); - internal::minres(mp_matrix->template selfadjointView<UpLo>(), b.col(j), xj, + internal::minres(MatrixWrapperType(mp_matrix), b.col(j), xj, Base::m_preconditioner, m_iterations, m_error); } diff --git a/unsupported/Eigen/src/MatrixFunctions/MatrixLogarithm.h b/unsupported/Eigen/src/MatrixFunctions/MatrixLogarithm.h index 42b60b9b1..22bfdc4ac 100644 --- a/unsupported/Eigen/src/MatrixFunctions/MatrixLogarithm.h +++ b/unsupported/Eigen/src/MatrixFunctions/MatrixLogarithm.h @@ -53,15 +53,20 @@ void matrix_log_compute_2x2(const MatrixType& A, MatrixType& result) result(1,0) = Scalar(0); result(1,1) = logA11; - if (A(0,0) == A(1,1)) { + Scalar y = A(1,1) - A(0,0); + if (y==Scalar(0)) + { result(0,1) = A(0,1) / A(0,0); - } else if ((abs(A(0,0)) < 0.5*abs(A(1,1))) || (abs(A(0,0)) > 2*abs(A(1,1)))) { - result(0,1) = A(0,1) * (logA11 - logA00) / (A(1,1) - A(0,0)); - } else { + } + else if ((abs(A(0,0)) < 0.5*abs(A(1,1))) || (abs(A(0,0)) > 2*abs(A(1,1)))) + { + result(0,1) = A(0,1) * (logA11 - logA00) / y; + } + else + { // computation in previous branch is inaccurate if A(1,1) \approx A(0,0) int unwindingNumber = static_cast<int>(ceil((imag(logA11 - logA00) - M_PI) / (2*M_PI))); - Scalar y = A(1,1) - A(0,0), x = A(1,1) + A(0,0); - result(0,1) = A(0,1) * (Scalar(2) * numext::atanh2(y,x) + Scalar(0,2*M_PI*unwindingNumber)) / y; + result(0,1) = A(0,1) * (numext::log1p(y/A(0,0)) + Scalar(0,2*M_PI*unwindingNumber)) / y; } } diff --git a/unsupported/Eigen/src/MatrixFunctions/MatrixPower.h b/unsupported/Eigen/src/MatrixFunctions/MatrixPower.h index ee665c18e..1e5a59c55 100644 --- a/unsupported/Eigen/src/MatrixFunctions/MatrixPower.h +++ b/unsupported/Eigen/src/MatrixFunctions/MatrixPower.h @@ -299,7 +299,7 @@ MatrixPowerAtomic<MatrixType>::computeSuperDiag(const ComplexScalar& curr, const ComplexScalar logCurr = log(curr); ComplexScalar logPrev = log(prev); int unwindingNumber = ceil((numext::imag(logCurr - logPrev) - M_PI) / (2*M_PI)); - ComplexScalar w = numext::atanh2(curr - prev, curr + prev) + ComplexScalar(0, M_PI*unwindingNumber); + ComplexScalar w = numext::log1p((curr-prev)/prev)/RealScalar(2) + ComplexScalar(0, M_PI*unwindingNumber); return RealScalar(2) * exp(RealScalar(0.5) * p * (logCurr + logPrev)) * sinh(p * w) / (curr - prev); } @@ -311,7 +311,7 @@ MatrixPowerAtomic<MatrixType>::computeSuperDiag(RealScalar curr, RealScalar prev using std::log; using std::sinh; - RealScalar w = numext::atanh2(curr - prev, curr + prev); + RealScalar w = numext::log1p((curr-prev)/prev)/RealScalar(2); return 2 * exp(p * (log(curr) + log(prev)) / 2) * sinh(p * w) / (curr - prev); } diff --git a/unsupported/Eigen/src/Polynomials/PolynomialUtils.h b/unsupported/Eigen/src/Polynomials/PolynomialUtils.h index 2bb8bc84a..40ba65b7e 100644 --- a/unsupported/Eigen/src/Polynomials/PolynomialUtils.h +++ b/unsupported/Eigen/src/Polynomials/PolynomialUtils.h @@ -56,7 +56,7 @@ T poly_eval( const Polynomials& poly, const T& x ) for( DenseIndex i=1; i<poly.size(); ++i ){ val = val*inv_x + poly[i]; } - return std::pow(x,(T)(poly.size()-1)) * val; + return numext::pow(x,(T)(poly.size()-1)) * val; } } diff --git a/unsupported/test/CMakeLists.txt b/unsupported/test/CMakeLists.txt index 97849a25a..7b6751f00 100644 --- a/unsupported/test/CMakeLists.txt +++ b/unsupported/test/CMakeLists.txt @@ -50,7 +50,7 @@ if(MPFR_FOUND) include_directories(${MPFR_INCLUDES} ./mpreal) ei_add_property(EIGEN_TESTED_BACKENDS "MPFR C++, ") set(EIGEN_MPFR_TEST_LIBRARIES ${MPFR_LIBRARIES} ${GMP_LIBRARIES}) - ei_add_test(mpreal_support "" "${EIGEN_MPFR_TEST_LIBRARIES}" ) +# ei_add_test(mpreal_support "" "${EIGEN_MPFR_TEST_LIBRARIES}" ) else() ei_add_property(EIGEN_MISSING_BACKENDS "MPFR C++, ") endif() @@ -76,8 +76,9 @@ if(NOT EIGEN_TEST_NO_OPENGL) find_package(GLUT) find_package(GLEW) if(OPENGL_FOUND AND GLUT_FOUND AND GLEW_FOUND) + include_directories(${OPENGL_INCLUDE_DIR} ${GLUT_INCLUDE_DIR} ${GLEW_INCLUDE_DIRS}) ei_add_property(EIGEN_TESTED_BACKENDS "OpenGL, ") - set(EIGEN_GL_LIB ${GLUT_LIBRARIES} ${GLEW_LIBRARIES}) + set(EIGEN_GL_LIB ${GLUT_LIBRARIES} ${GLEW_LIBRARIES} ${OPENGL_LIBRARIES}) ei_add_test(openglsupport "" "${EIGEN_GL_LIB}" ) else() ei_add_property(EIGEN_MISSING_BACKENDS "OpenGL, ") @@ -94,12 +95,50 @@ ei_add_test(minres) ei_add_test(levenberg_marquardt) ei_add_test(kronecker_product) -option(EIGEN_TEST_CXX11 "Enable testing of C++11 features (e.g. Tensor module)." OFF) +option(EIGEN_TEST_CXX11 "Enable testing of C++11 features (e.g. Tensor module)." ON) if(EIGEN_TEST_CXX11) - # FIXME: add C++11 compiler switch in some portable way - # (MSVC doesn't need any for example, so this will - # clash there) + # It should be safe to always run these tests as there is some fallback code for + # older compiler that don't support cxx11. ei_add_test(cxx11_meta "-std=c++0x") ei_add_test(cxx11_tensor_simple "-std=c++0x") - ei_add_test(cxx11_tensor_symmetry "-std=c++0x") +# ei_add_test(cxx11_tensor_symmetry "-std=c++0x") + ei_add_test(cxx11_tensor_assign "-std=c++0x") + ei_add_test(cxx11_tensor_dimension "-std=c++0x") + ei_add_test(cxx11_tensor_index_list "-std=c++0x") + ei_add_test(cxx11_tensor_comparisons "-std=c++0x") + ei_add_test(cxx11_tensor_contraction "-std=c++0x") + ei_add_test(cxx11_tensor_convolution "-std=c++0x") + ei_add_test(cxx11_tensor_expr "-std=c++0x") + ei_add_test(cxx11_tensor_forced_eval "-std=c++0x") + ei_add_test(cxx11_tensor_fixed_size "-std=c++0x") + ei_add_test(cxx11_tensor_const "-std=c++0x") + ei_add_test(cxx11_tensor_of_const_values "-std=c++0x") + ei_add_test(cxx11_tensor_of_complex "-std=c++0x") + ei_add_test(cxx11_tensor_of_strings "-std=c++0x") + ei_add_test(cxx11_tensor_intdiv "-std=c++0x") + ei_add_test(cxx11_tensor_lvalue "-std=c++0x") + ei_add_test(cxx11_tensor_map "-std=c++0x") + ei_add_test(cxx11_tensor_broadcasting "-std=c++0x") + ei_add_test(cxx11_tensor_chipping "-std=c++0x") + ei_add_test(cxx11_tensor_concatenation "-std=c++0x") + ei_add_test(cxx11_tensor_morphing "-std=c++0x") + ei_add_test(cxx11_tensor_padding "-std=c++0x") + ei_add_test(cxx11_tensor_patch "-std=c++0x") + ei_add_test(cxx11_tensor_image_patch "-std=c++0x") + ei_add_test(cxx11_tensor_reduction "-std=c++0x") + ei_add_test(cxx11_tensor_shuffling "-std=c++0x") + ei_add_test(cxx11_tensor_striding "-std=c++0x") + ei_add_test(cxx11_tensor_thread_pool "-std=c++0x") + ei_add_test(cxx11_tensor_ref "-std=c++0x") + ei_add_test(cxx11_tensor_random "-std=c++0x") + ei_add_test(cxx11_tensor_casts "-std=c++0x") + ei_add_test(cxx11_tensor_reverse "-std=c++0x") + ei_add_test(cxx11_tensor_layout_swap "-std=c++0x") + ei_add_test(cxx11_tensor_io "-std=c++0x") + + # These tests needs nvcc +# ei_add_test(cxx11_tensor_device "-std=c++0x") +# ei_add_test(cxx11_tensor_cuda "-std=c++0x") +# ei_add_test(cxx11_tensor_contract_cuda "-std=c++0x") + endif() diff --git a/unsupported/test/cxx11_tensor_assign.cpp b/unsupported/test/cxx11_tensor_assign.cpp new file mode 100644 index 000000000..d16aaf847 --- /dev/null +++ b/unsupported/test/cxx11_tensor_assign.cpp @@ -0,0 +1,370 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_1d() +{ + Tensor<int, 1> vec1(6); + Tensor<int, 1, RowMajor> vec2(6); + vec1(0) = 4; vec2(0) = 0; + vec1(1) = 8; vec2(1) = 1; + vec1(2) = 15; vec2(2) = 2; + vec1(3) = 16; vec2(3) = 3; + vec1(4) = 23; vec2(4) = 4; + vec1(5) = 42; vec2(5) = 5; + + int col_major[6]; + int row_major[6]; + memset(col_major, 0, 6*sizeof(int)); + memset(row_major, 0, 6*sizeof(int)); + TensorMap<Tensor<int, 1>> vec3(col_major, 6); + TensorMap<Tensor<int, 1, RowMajor>> vec4(row_major, 6); + + vec3 = vec1; + vec4 = vec2; + + VERIFY_IS_EQUAL(vec3(0), 4); + VERIFY_IS_EQUAL(vec3(1), 8); + VERIFY_IS_EQUAL(vec3(2), 15); + VERIFY_IS_EQUAL(vec3(3), 16); + VERIFY_IS_EQUAL(vec3(4), 23); + VERIFY_IS_EQUAL(vec3(5), 42); + + VERIFY_IS_EQUAL(vec4(0), 0); + VERIFY_IS_EQUAL(vec4(1), 1); + VERIFY_IS_EQUAL(vec4(2), 2); + VERIFY_IS_EQUAL(vec4(3), 3); + VERIFY_IS_EQUAL(vec4(4), 4); + VERIFY_IS_EQUAL(vec4(5), 5); + + vec1.setZero(); + vec2.setZero(); + vec1 = vec3; + vec2 = vec4; + + VERIFY_IS_EQUAL(vec1(0), 4); + VERIFY_IS_EQUAL(vec1(1), 8); + VERIFY_IS_EQUAL(vec1(2), 15); + VERIFY_IS_EQUAL(vec1(3), 16); + VERIFY_IS_EQUAL(vec1(4), 23); + VERIFY_IS_EQUAL(vec1(5), 42); + + VERIFY_IS_EQUAL(vec2(0), 0); + VERIFY_IS_EQUAL(vec2(1), 1); + VERIFY_IS_EQUAL(vec2(2), 2); + VERIFY_IS_EQUAL(vec2(3), 3); + VERIFY_IS_EQUAL(vec2(4), 4); + VERIFY_IS_EQUAL(vec2(5), 5); +} + +static void test_2d() +{ + Tensor<int, 2> mat1(2,3); + Tensor<int, 2, RowMajor> mat2(2,3); + + mat1(0,0) = 0; + mat1(0,1) = 1; + mat1(0,2) = 2; + mat1(1,0) = 3; + mat1(1,1) = 4; + mat1(1,2) = 5; + + mat2(0,0) = 0; + mat2(0,1) = 1; + mat2(0,2) = 2; + mat2(1,0) = 3; + mat2(1,1) = 4; + mat2(1,2) = 5; + + int col_major[6]; + int row_major[6]; + memset(col_major, 0, 6*sizeof(int)); + memset(row_major, 0, 6*sizeof(int)); + TensorMap<Tensor<int, 2>> mat3(row_major, 2, 3); + TensorMap<Tensor<int, 2, RowMajor>> mat4(col_major, 2, 3); + + mat3 = mat1; + mat4 = mat2; + + VERIFY_IS_EQUAL(mat3(0,0), 0); + VERIFY_IS_EQUAL(mat3(0,1), 1); + VERIFY_IS_EQUAL(mat3(0,2), 2); + VERIFY_IS_EQUAL(mat3(1,0), 3); + VERIFY_IS_EQUAL(mat3(1,1), 4); + VERIFY_IS_EQUAL(mat3(1,2), 5); + + VERIFY_IS_EQUAL(mat4(0,0), 0); + VERIFY_IS_EQUAL(mat4(0,1), 1); + VERIFY_IS_EQUAL(mat4(0,2), 2); + VERIFY_IS_EQUAL(mat4(1,0), 3); + VERIFY_IS_EQUAL(mat4(1,1), 4); + VERIFY_IS_EQUAL(mat4(1,2), 5); + + mat1.setZero(); + mat2.setZero(); + mat1 = mat3; + mat2 = mat4; + + VERIFY_IS_EQUAL(mat1(0,0), 0); + VERIFY_IS_EQUAL(mat1(0,1), 1); + VERIFY_IS_EQUAL(mat1(0,2), 2); + VERIFY_IS_EQUAL(mat1(1,0), 3); + VERIFY_IS_EQUAL(mat1(1,1), 4); + VERIFY_IS_EQUAL(mat1(1,2), 5); + + VERIFY_IS_EQUAL(mat2(0,0), 0); + VERIFY_IS_EQUAL(mat2(0,1), 1); + VERIFY_IS_EQUAL(mat2(0,2), 2); + VERIFY_IS_EQUAL(mat2(1,0), 3); + VERIFY_IS_EQUAL(mat2(1,1), 4); + VERIFY_IS_EQUAL(mat2(1,2), 5); +} + +static void test_3d() +{ + Tensor<int, 3> mat1(2,3,7); + Tensor<int, 3, RowMajor> mat2(2,3,7); + + int val = 0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + mat2(i,j,k) = val; + val++; + } + } + } + + int col_major[2*3*7]; + int row_major[2*3*7]; + memset(col_major, 0, 2*3*7*sizeof(int)); + memset(row_major, 0, 2*3*7*sizeof(int)); + TensorMap<Tensor<int, 3>> mat3(col_major, 2, 3, 7); + TensorMap<Tensor<int, 3, RowMajor>> mat4(row_major, 2, 3, 7); + + mat3 = mat1; + mat4 = mat2; + + val = 0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(mat3(i,j,k), val); + VERIFY_IS_EQUAL(mat4(i,j,k), val); + val++; + } + } + } + + mat1.setZero(); + mat2.setZero(); + mat1 = mat3; + mat2 = mat4; + + val = 0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(mat1(i,j,k), val); + VERIFY_IS_EQUAL(mat2(i,j,k), val); + val++; + } + } + } +} + +static void test_same_type() +{ + Tensor<int, 1> orig_tensor(5); + Tensor<int, 1> dest_tensor(5); + orig_tensor.setRandom(); + dest_tensor.setRandom(); + int* orig_data = orig_tensor.data(); + int* dest_data = dest_tensor.data(); + dest_tensor = orig_tensor; + VERIFY_IS_EQUAL(orig_tensor.data(), orig_data); + VERIFY_IS_EQUAL(dest_tensor.data(), dest_data); + for (int i = 0; i < 5; ++i) { + VERIFY_IS_EQUAL(dest_tensor(i), orig_tensor(i)); + } + + TensorFixedSize<int, Sizes<5> > orig_array; + TensorFixedSize<int, Sizes<5> > dest_array; + orig_array.setRandom(); + dest_array.setRandom(); + orig_data = orig_array.data(); + dest_data = dest_array.data(); + dest_array = orig_array; + VERIFY_IS_EQUAL(orig_array.data(), orig_data); + VERIFY_IS_EQUAL(dest_array.data(), dest_data); + for (int i = 0; i < 5; ++i) { + VERIFY_IS_EQUAL(dest_array(i), orig_array(i)); + } + + int orig[5] = {1, 2, 3, 4, 5}; + int dest[5] = {6, 7, 8, 9, 10}; + TensorMap<Tensor<int, 1> > orig_map(orig, 5); + TensorMap<Tensor<int, 1> > dest_map(dest, 5); + orig_data = orig_map.data(); + dest_data = dest_map.data(); + dest_map = orig_map; + VERIFY_IS_EQUAL(orig_map.data(), orig_data); + VERIFY_IS_EQUAL(dest_map.data(), dest_data); + for (int i = 0; i < 5; ++i) { + VERIFY_IS_EQUAL(dest[i], i+1); + } +} + +static void test_auto_resize() +{ + Tensor<int, 1> tensor1; + Tensor<int, 1> tensor2(3); + Tensor<int, 1> tensor3(5); + Tensor<int, 1> tensor4(7); + + Tensor<int, 1> new_tensor(5); + new_tensor.setRandom(); + + tensor1 = tensor2 = tensor3 = tensor4 = new_tensor; + + VERIFY_IS_EQUAL(tensor1.dimension(0), new_tensor.dimension(0)); + VERIFY_IS_EQUAL(tensor2.dimension(0), new_tensor.dimension(0)); + VERIFY_IS_EQUAL(tensor3.dimension(0), new_tensor.dimension(0)); + VERIFY_IS_EQUAL(tensor4.dimension(0), new_tensor.dimension(0)); + for (int i = 0; i < new_tensor.dimension(0); ++i) { + VERIFY_IS_EQUAL(tensor1(i), new_tensor(i)); + VERIFY_IS_EQUAL(tensor2(i), new_tensor(i)); + VERIFY_IS_EQUAL(tensor3(i), new_tensor(i)); + VERIFY_IS_EQUAL(tensor4(i), new_tensor(i)); + } +} + + +static void test_compound_assign() +{ + Tensor<int, 1> start_tensor(10); + Tensor<int, 1> offset_tensor(10); + start_tensor.setRandom(); + offset_tensor.setRandom(); + + Tensor<int, 1> tensor = start_tensor; + tensor += offset_tensor; + for (int i = 0; i < 10; ++i) { + VERIFY_IS_EQUAL(tensor(i), start_tensor(i) + offset_tensor(i)); + } + + tensor = start_tensor; + tensor -= offset_tensor; + for (int i = 0; i < 10; ++i) { + VERIFY_IS_EQUAL(tensor(i), start_tensor(i) - offset_tensor(i)); + } + + tensor = start_tensor; + tensor *= offset_tensor; + for (int i = 0; i < 10; ++i) { + VERIFY_IS_EQUAL(tensor(i), start_tensor(i) * offset_tensor(i)); + } + + tensor = start_tensor; + tensor /= offset_tensor; + for (int i = 0; i < 10; ++i) { + VERIFY_IS_EQUAL(tensor(i), start_tensor(i) / offset_tensor(i)); + } +} + +static void test_std_initializers_tensor() { +#ifdef EIGEN_HAS_VARIADIC_TEMPLATES + Tensor<int, 1> a(3); + a.setValues({0, 1, 2}); + VERIFY_IS_EQUAL(a(0), 0); + VERIFY_IS_EQUAL(a(1), 1); + VERIFY_IS_EQUAL(a(2), 2); + + // It fills the top-left slice. + a.setValues({10, 20}); + VERIFY_IS_EQUAL(a(0), 10); + VERIFY_IS_EQUAL(a(1), 20); + VERIFY_IS_EQUAL(a(2), 2); + + // Chaining. + Tensor<int, 1> a2(3); + a2 = a.setValues({100, 200, 300}); + VERIFY_IS_EQUAL(a(0), 100); + VERIFY_IS_EQUAL(a(1), 200); + VERIFY_IS_EQUAL(a(2), 300); + VERIFY_IS_EQUAL(a2(0), 100); + VERIFY_IS_EQUAL(a2(1), 200); + VERIFY_IS_EQUAL(a2(2), 300); + + Tensor<int, 2> b(2, 3); + b.setValues({{0, 1, 2}, {3, 4, 5}}); + VERIFY_IS_EQUAL(b(0, 0), 0); + VERIFY_IS_EQUAL(b(0, 1), 1); + VERIFY_IS_EQUAL(b(0, 2), 2); + VERIFY_IS_EQUAL(b(1, 0), 3); + VERIFY_IS_EQUAL(b(1, 1), 4); + VERIFY_IS_EQUAL(b(1, 2), 5); + + // It fills the top-left slice. + b.setValues({{10, 20}, {30}}); + VERIFY_IS_EQUAL(b(0, 0), 10); + VERIFY_IS_EQUAL(b(0, 1), 20); + VERIFY_IS_EQUAL(b(0, 2), 2); + VERIFY_IS_EQUAL(b(1, 0), 30); + VERIFY_IS_EQUAL(b(1, 1), 4); + VERIFY_IS_EQUAL(b(1, 2), 5); + + Eigen::Tensor<int, 3> c(3, 2, 4); + c.setValues({{{0, 1, 2, 3}, {4, 5, 6, 7}}, + {{10, 11, 12, 13}, {14, 15, 16, 17}}, + {{20, 21, 22, 23}, {24, 25, 26, 27}}}); + VERIFY_IS_EQUAL(c(0, 0, 0), 0); + VERIFY_IS_EQUAL(c(0, 0, 1), 1); + VERIFY_IS_EQUAL(c(0, 0, 2), 2); + VERIFY_IS_EQUAL(c(0, 0, 3), 3); + VERIFY_IS_EQUAL(c(0, 1, 0), 4); + VERIFY_IS_EQUAL(c(0, 1, 1), 5); + VERIFY_IS_EQUAL(c(0, 1, 2), 6); + VERIFY_IS_EQUAL(c(0, 1, 3), 7); + VERIFY_IS_EQUAL(c(1, 0, 0), 10); + VERIFY_IS_EQUAL(c(1, 0, 1), 11); + VERIFY_IS_EQUAL(c(1, 0, 2), 12); + VERIFY_IS_EQUAL(c(1, 0, 3), 13); + VERIFY_IS_EQUAL(c(1, 1, 0), 14); + VERIFY_IS_EQUAL(c(1, 1, 1), 15); + VERIFY_IS_EQUAL(c(1, 1, 2), 16); + VERIFY_IS_EQUAL(c(1, 1, 3), 17); + VERIFY_IS_EQUAL(c(2, 0, 0), 20); + VERIFY_IS_EQUAL(c(2, 0, 1), 21); + VERIFY_IS_EQUAL(c(2, 0, 2), 22); + VERIFY_IS_EQUAL(c(2, 0, 3), 23); + VERIFY_IS_EQUAL(c(2, 1, 0), 24); + VERIFY_IS_EQUAL(c(2, 1, 1), 25); + VERIFY_IS_EQUAL(c(2, 1, 2), 26); + VERIFY_IS_EQUAL(c(2, 1, 3), 27); +#endif // EIGEN_HAS_VARIADIC_TEMPLATES +} + +void test_cxx11_tensor_assign() +{ + CALL_SUBTEST(test_1d()); + CALL_SUBTEST(test_2d()); + CALL_SUBTEST(test_3d()); + CALL_SUBTEST(test_same_type()); + CALL_SUBTEST(test_auto_resize()); + CALL_SUBTEST(test_compound_assign()); + CALL_SUBTEST(test_std_initializers_tensor()); +} diff --git a/unsupported/test/cxx11_tensor_broadcasting.cpp b/unsupported/test/cxx11_tensor_broadcasting.cpp new file mode 100644 index 000000000..2ddf47234 --- /dev/null +++ b/unsupported/test/cxx11_tensor_broadcasting.cpp @@ -0,0 +1,194 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template <int DataLayout> +static void test_simple_broadcasting() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> broadcasts; + broadcasts[0] = 1; + broadcasts[1] = 1; + broadcasts[2] = 1; + broadcasts[3] = 1; + + Tensor<float, 4, DataLayout> no_broadcast; + no_broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(no_broadcast.dimension(0), 2); + VERIFY_IS_EQUAL(no_broadcast.dimension(1), 3); + VERIFY_IS_EQUAL(no_broadcast.dimension(2), 5); + VERIFY_IS_EQUAL(no_broadcast.dimension(3), 7); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), no_broadcast(i,j,k,l)); + } + } + } + } + + broadcasts[0] = 2; + broadcasts[1] = 3; + broadcasts[2] = 1; + broadcasts[3] = 4; + Tensor<float, 4, DataLayout> broadcast; + broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(broadcast.dimension(0), 4); + VERIFY_IS_EQUAL(broadcast.dimension(1), 9); + VERIFY_IS_EQUAL(broadcast.dimension(2), 5); + VERIFY_IS_EQUAL(broadcast.dimension(3), 28); + + for (int i = 0; i < 4; ++i) { + for (int j = 0; j < 9; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 28; ++l) { + VERIFY_IS_EQUAL(tensor(i%2,j%3,k%5,l%7), broadcast(i,j,k,l)); + } + } + } + } +} + + +template <int DataLayout> +static void test_vectorized_broadcasting() +{ + Tensor<float, 3, DataLayout> tensor(8,3,5); + tensor.setRandom(); + array<ptrdiff_t, 3> broadcasts; + broadcasts[0] = 2; + broadcasts[1] = 3; + broadcasts[2] = 4; + + Tensor<float, 3, DataLayout> broadcast; + broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(broadcast.dimension(0), 16); + VERIFY_IS_EQUAL(broadcast.dimension(1), 9); + VERIFY_IS_EQUAL(broadcast.dimension(2), 20); + + for (int i = 0; i < 16; ++i) { + for (int j = 0; j < 9; ++j) { + for (int k = 0; k < 20; ++k) { + VERIFY_IS_EQUAL(tensor(i%8,j%3,k%5), broadcast(i,j,k)); + } + } + } + + tensor.resize(11,3,5); + tensor.setRandom(); + broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(broadcast.dimension(0), 22); + VERIFY_IS_EQUAL(broadcast.dimension(1), 9); + VERIFY_IS_EQUAL(broadcast.dimension(2), 20); + + for (int i = 0; i < 22; ++i) { + for (int j = 0; j < 9; ++j) { + for (int k = 0; k < 20; ++k) { + VERIFY_IS_EQUAL(tensor(i%11,j%3,k%5), broadcast(i,j,k)); + } + } + } +} + + +template <int DataLayout> +static void test_static_broadcasting() +{ + Tensor<float, 3, DataLayout> tensor(8,3,5); + tensor.setRandom(); + +#ifdef EIGEN_HAS_CONSTEXPR + Eigen::IndexList<Eigen::type2index<2>, Eigen::type2index<3>, Eigen::type2index<4>> broadcasts; +#else + Eigen::array<int, 3> broadcasts; + broadcasts[0] = 2; + broadcasts[1] = 3; + broadcasts[2] = 4; +#endif + + Tensor<float, 3, DataLayout> broadcast; + broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(broadcast.dimension(0), 16); + VERIFY_IS_EQUAL(broadcast.dimension(1), 9); + VERIFY_IS_EQUAL(broadcast.dimension(2), 20); + + for (int i = 0; i < 16; ++i) { + for (int j = 0; j < 9; ++j) { + for (int k = 0; k < 20; ++k) { + VERIFY_IS_EQUAL(tensor(i%8,j%3,k%5), broadcast(i,j,k)); + } + } + } + + tensor.resize(11,3,5); + tensor.setRandom(); + broadcast = tensor.broadcast(broadcasts); + + VERIFY_IS_EQUAL(broadcast.dimension(0), 22); + VERIFY_IS_EQUAL(broadcast.dimension(1), 9); + VERIFY_IS_EQUAL(broadcast.dimension(2), 20); + + for (int i = 0; i < 22; ++i) { + for (int j = 0; j < 9; ++j) { + for (int k = 0; k < 20; ++k) { + VERIFY_IS_EQUAL(tensor(i%11,j%3,k%5), broadcast(i,j,k)); + } + } + } +} + + +template <int DataLayout> +static void test_fixed_size_broadcasting() +{ + // Need to add a [] operator to the Size class for this to work +#if 0 + Tensor<float, 1, DataLayout> t1(10); + t1.setRandom(); + TensorFixedSize<float, Sizes<1>, DataLayout> t2; + t2 = t2.constant(20.0f); + + Tensor<float, 1, DataLayout> t3 = t1 + t2.broadcast(Eigen::array<int, 1>{{10}}); + for (int i = 0; i < 10; ++i) { + VERIFY_IS_APPROX(t3(i), t1(i) + t2(0)); + } + + TensorMap<TensorFixedSize<float, Sizes<1>, DataLayout> > t4(t2.data(), {{1}}); + Tensor<float, 1, DataLayout> t5 = t1 + t4.broadcast(Eigen::array<int, 1>{{10}}); + for (int i = 0; i < 10; ++i) { + VERIFY_IS_APPROX(t5(i), t1(i) + t2(0)); + } +#endif +} + + +void test_cxx11_tensor_broadcasting() +{ + CALL_SUBTEST(test_simple_broadcasting<ColMajor>()); + CALL_SUBTEST(test_simple_broadcasting<RowMajor>()); + CALL_SUBTEST(test_vectorized_broadcasting<ColMajor>()); + CALL_SUBTEST(test_vectorized_broadcasting<RowMajor>()); + CALL_SUBTEST(test_static_broadcasting<ColMajor>()); + CALL_SUBTEST(test_static_broadcasting<RowMajor>()); + CALL_SUBTEST(test_fixed_size_broadcasting<ColMajor>()); + CALL_SUBTEST(test_fixed_size_broadcasting<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_casts.cpp b/unsupported/test/cxx11_tensor_casts.cpp new file mode 100644 index 000000000..4f7ff7067 --- /dev/null +++ b/unsupported/test/cxx11_tensor_casts.cpp @@ -0,0 +1,41 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::array; + +static void test_simple_cast() +{ + Tensor<float, 2> ftensor(20,30); + ftensor.setRandom(); + Tensor<char, 2> chartensor(20,30); + chartensor.setRandom(); + Tensor<std::complex<float>, 2> cplextensor(20,30); + cplextensor.setRandom(); + + chartensor = ftensor.cast<char>(); + cplextensor = ftensor.cast<std::complex<float>>(); + + for (int i = 0; i < 20; ++i) { + for (int j = 0; j < 30; ++j) { + VERIFY_IS_EQUAL(chartensor(i,j), static_cast<char>(ftensor(i,j))); + VERIFY_IS_EQUAL(cplextensor(i,j), static_cast<std::complex<float>>(ftensor(i,j))); + } + } +} + + +void test_cxx11_tensor_casts() +{ + CALL_SUBTEST(test_simple_cast()); +} diff --git a/unsupported/test/cxx11_tensor_chipping.cpp b/unsupported/test/cxx11_tensor_chipping.cpp new file mode 100644 index 000000000..d83417872 --- /dev/null +++ b/unsupported/test/cxx11_tensor_chipping.cpp @@ -0,0 +1,397 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template<int DataLayout> +static void test_simple_chip() +{ + Tensor<float, 5, DataLayout> tensor(2,3,5,7,11); + tensor.setRandom(); + + Tensor<float, 4, DataLayout> chip1; + chip1 = tensor.template chip<0>(1); + + VERIFY_IS_EQUAL(chip1.dimension(0), 3); + VERIFY_IS_EQUAL(chip1.dimension(1), 5); + VERIFY_IS_EQUAL(chip1.dimension(2), 7); + VERIFY_IS_EQUAL(chip1.dimension(3), 11); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip1(i,j,k,l), tensor(1,i,j,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip2 = tensor.template chip<1>(1); + VERIFY_IS_EQUAL(chip2.dimension(0), 2); + VERIFY_IS_EQUAL(chip2.dimension(1), 5); + VERIFY_IS_EQUAL(chip2.dimension(2), 7); + VERIFY_IS_EQUAL(chip2.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip2(i,j,k,l), tensor(i,1,j,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip3 = tensor.template chip<2>(2); + VERIFY_IS_EQUAL(chip3.dimension(0), 2); + VERIFY_IS_EQUAL(chip3.dimension(1), 3); + VERIFY_IS_EQUAL(chip3.dimension(2), 7); + VERIFY_IS_EQUAL(chip3.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip3(i,j,k,l), tensor(i,j,2,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip4(tensor.template chip<3>(5)); + VERIFY_IS_EQUAL(chip4.dimension(0), 2); + VERIFY_IS_EQUAL(chip4.dimension(1), 3); + VERIFY_IS_EQUAL(chip4.dimension(2), 5); + VERIFY_IS_EQUAL(chip4.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(chip4(i,j,k,l), tensor(i,j,k,5,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip5(tensor.template chip<4>(7)); + VERIFY_IS_EQUAL(chip5.dimension(0), 2); + VERIFY_IS_EQUAL(chip5.dimension(1), 3); + VERIFY_IS_EQUAL(chip5.dimension(2), 5); + VERIFY_IS_EQUAL(chip5.dimension(3), 7); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(chip5(i,j,k,l), tensor(i,j,k,l,7)); + } + } + } + } +} + +template<int DataLayout> +static void test_dynamic_chip() +{ + Tensor<float, 5, DataLayout> tensor(2,3,5,7,11); + tensor.setRandom(); + + Tensor<float, 4, DataLayout> chip1; + chip1 = tensor.chip(1, 0); + VERIFY_IS_EQUAL(chip1.dimension(0), 3); + VERIFY_IS_EQUAL(chip1.dimension(1), 5); + VERIFY_IS_EQUAL(chip1.dimension(2), 7); + VERIFY_IS_EQUAL(chip1.dimension(3), 11); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip1(i,j,k,l), tensor(1,i,j,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip2 = tensor.chip(1, 1); + VERIFY_IS_EQUAL(chip2.dimension(0), 2); + VERIFY_IS_EQUAL(chip2.dimension(1), 5); + VERIFY_IS_EQUAL(chip2.dimension(2), 7); + VERIFY_IS_EQUAL(chip2.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip2(i,j,k,l), tensor(i,1,j,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip3 = tensor.chip(2, 2); + VERIFY_IS_EQUAL(chip3.dimension(0), 2); + VERIFY_IS_EQUAL(chip3.dimension(1), 3); + VERIFY_IS_EQUAL(chip3.dimension(2), 7); + VERIFY_IS_EQUAL(chip3.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + VERIFY_IS_EQUAL(chip3(i,j,k,l), tensor(i,j,2,k,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip4(tensor.chip(5, 3)); + VERIFY_IS_EQUAL(chip4.dimension(0), 2); + VERIFY_IS_EQUAL(chip4.dimension(1), 3); + VERIFY_IS_EQUAL(chip4.dimension(2), 5); + VERIFY_IS_EQUAL(chip4.dimension(3), 11); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(chip4(i,j,k,l), tensor(i,j,k,5,l)); + } + } + } + } + + Tensor<float, 4, DataLayout> chip5(tensor.chip(7, 4)); + VERIFY_IS_EQUAL(chip5.dimension(0), 2); + VERIFY_IS_EQUAL(chip5.dimension(1), 3); + VERIFY_IS_EQUAL(chip5.dimension(2), 5); + VERIFY_IS_EQUAL(chip5.dimension(3), 7); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(chip5(i,j,k,l), tensor(i,j,k,l,7)); + } + } + } + } +} + +template<int DataLayout> +static void test_chip_in_expr() { + Tensor<float, 5, DataLayout> input1(2,3,5,7,11); + input1.setRandom(); + Tensor<float, 4, DataLayout> input2(3,5,7,11); + input2.setRandom(); + + Tensor<float, 4, DataLayout> result = input1.template chip<0>(0) + input2; + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 11; ++l) { + float expected = input1(0,i,j,k,l) + input2(i,j,k,l); + VERIFY_IS_EQUAL(result(i,j,k,l), expected); + } + } + } + } + + Tensor<float, 3, DataLayout> input3(3,7,11); + input3.setRandom(); + Tensor<float, 3, DataLayout> result2 = input1.template chip<0>(0).template chip<1>(2) + input3; + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 7; ++j) { + for (int k = 0; k < 11; ++k) { + float expected = input1(0,i,2,j,k) + input3(i,j,k); + VERIFY_IS_EQUAL(result2(i,j,k), expected); + } + } + } +} + +template<int DataLayout> +static void test_chip_as_lvalue() +{ + Tensor<float, 5, DataLayout> input1(2,3,5,7,11); + input1.setRandom(); + + Tensor<float, 4, DataLayout> input2(3,5,7,11); + input2.setRandom(); + Tensor<float, 5, DataLayout> tensor = input1; + tensor.template chip<0>(1) = input2; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (i != 1) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input2(j,k,l,m)); + } + } + } + } + } + } + + Tensor<float, 4, DataLayout> input3(2,5,7,11); + input3.setRandom(); + tensor = input1; + tensor.template chip<1>(1) = input3; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (j != 1) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input3(i,k,l,m)); + } + } + } + } + } + } + + Tensor<float, 4, DataLayout> input4(2,3,7,11); + input4.setRandom(); + tensor = input1; + tensor.template chip<2>(3) = input4; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (k != 3) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input4(i,j,l,m)); + } + } + } + } + } + } + + Tensor<float, 4, DataLayout> input5(2,3,5,11); + input5.setRandom(); + tensor = input1; + tensor.template chip<3>(4) = input5; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (l != 4) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input5(i,j,k,m)); + } + } + } + } + } + } + + Tensor<float, 4, DataLayout> input6(2,3,5,7); + input6.setRandom(); + tensor = input1; + tensor.template chip<4>(5) = input6; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (m != 5) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input6(i,j,k,l)); + } + } + } + } + } + } + + Tensor<float, 5, DataLayout> input7(2,3,5,7,11); + input7.setRandom(); + tensor = input1; + tensor.chip(0, 0) = input7.chip(0, 0); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + for (int m = 0; m < 11; ++m) { + if (i != 0) { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input1(i,j,k,l,m)); + } else { + VERIFY_IS_EQUAL(tensor(i,j,k,l,m), input7(i,j,k,l,m)); + } + } + } + } + } + } +} + + +template<int DataLayout> +static void test_chip_raw_data() +{ + Tensor<float, 5, DataLayout> tensor(2,3,5,7,11); + tensor.setRandom(); + + typedef TensorEvaluator<decltype(tensor.template chip<4>(3)), DefaultDevice> Evaluator4; + auto chip = Evaluator4(tensor.template chip<4>(3), DefaultDevice()); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + int chip_index; + if (DataLayout == ColMajor) { + chip_index = i + 2 * (j + 3 * (k + 5 * l)); + } else { + chip_index = 11 * (l + 7 * (k + 5 * (j + 3 * i))); + } + VERIFY_IS_EQUAL(chip.data()[chip_index], tensor(i,j,k,l,3)); + } + } + } + } + + typedef TensorEvaluator<decltype(tensor.template chip<0>(0)), DefaultDevice> Evaluator0; + auto chip0 = Evaluator0(tensor.template chip<0>(0), DefaultDevice()); + VERIFY_IS_EQUAL(chip0.data(), static_cast<float*>(0)); + + typedef TensorEvaluator<decltype(tensor.template chip<1>(0)), DefaultDevice> Evaluator1; + auto chip1 = Evaluator1(tensor.template chip<1>(0), DefaultDevice()); + VERIFY_IS_EQUAL(chip1.data(), static_cast<float*>(0)); + + typedef TensorEvaluator<decltype(tensor.template chip<2>(0)), DefaultDevice> Evaluator2; + auto chip2 = Evaluator2(tensor.template chip<2>(0), DefaultDevice()); + VERIFY_IS_EQUAL(chip2.data(), static_cast<float*>(0)); + + typedef TensorEvaluator<decltype(tensor.template chip<3>(0)), DefaultDevice> Evaluator3; + auto chip3 = Evaluator3(tensor.template chip<3>(0), DefaultDevice()); + VERIFY_IS_EQUAL(chip3.data(), static_cast<float*>(0)); +} + +void test_cxx11_tensor_chipping() +{ + CALL_SUBTEST(test_simple_chip<ColMajor>()); + CALL_SUBTEST(test_simple_chip<RowMajor>()); + CALL_SUBTEST(test_dynamic_chip<ColMajor>()); + CALL_SUBTEST(test_dynamic_chip<RowMajor>()); + CALL_SUBTEST(test_chip_in_expr<ColMajor>()); + CALL_SUBTEST(test_chip_in_expr<RowMajor>()); + CALL_SUBTEST(test_chip_as_lvalue<ColMajor>()); + CALL_SUBTEST(test_chip_as_lvalue<RowMajor>()); + CALL_SUBTEST(test_chip_raw_data<ColMajor>()); + CALL_SUBTEST(test_chip_raw_data<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_comparisons.cpp b/unsupported/test/cxx11_tensor_comparisons.cpp new file mode 100644 index 000000000..186f56ac3 --- /dev/null +++ b/unsupported/test/cxx11_tensor_comparisons.cpp @@ -0,0 +1,84 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_orderings() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<bool, 3> lt(2,3,7); + Tensor<bool, 3> le(2,3,7); + Tensor<bool, 3> gt(2,3,7); + Tensor<bool, 3> ge(2,3,7); + + mat1.setRandom(); + mat2.setRandom(); + + lt = mat1 < mat2; + le = mat1 <= mat2; + gt = mat1 > mat2; + ge = mat1 >= mat2; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(lt(i,j,k), mat1(i,j,k) < mat2(i,j,k)); + VERIFY_IS_EQUAL(le(i,j,k), mat1(i,j,k) <= mat2(i,j,k)); + VERIFY_IS_EQUAL(gt(i,j,k), mat1(i,j,k) > mat2(i,j,k)); + VERIFY_IS_EQUAL(ge(i,j,k), mat1(i,j,k) >= mat2(i,j,k)); + } + } + } +} + + +static void test_equality() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + + mat1.setRandom(); + mat2.setRandom(); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + if (random() < 0.5) { + mat2(i,j,k) = mat1(i,j,k); + } + } + } + } + + Tensor<bool, 3> eq(2,3,7); + Tensor<bool, 3> ne(2,3,7); + eq = (mat1 == mat2); + ne = (mat1 != mat2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(eq(i,j,k), mat1(i,j,k) == mat2(i,j,k)); + VERIFY_IS_EQUAL(ne(i,j,k), mat1(i,j,k) != mat2(i,j,k)); + } + } + } +} + + +void test_cxx11_tensor_comparisons() +{ + CALL_SUBTEST(test_orderings()); + CALL_SUBTEST(test_equality()); +} diff --git a/unsupported/test/cxx11_tensor_concatenation.cpp b/unsupported/test/cxx11_tensor_concatenation.cpp new file mode 100644 index 000000000..9fdf33c16 --- /dev/null +++ b/unsupported/test/cxx11_tensor_concatenation.cpp @@ -0,0 +1,116 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template<int DataLayout> +static void test_dimension_failures() +{ + Tensor<int, 3, DataLayout> left(2, 3, 1); + Tensor<int, 3, DataLayout> right(3, 3, 1); + left.setRandom(); + right.setRandom(); + + // Okay; other dimensions are equal. + Tensor<int, 3, DataLayout> concatenation = left.concatenate(right, 0); + + // Dimension mismatches. + VERIFY_RAISES_ASSERT(concatenation = left.concatenate(right, 1)); + VERIFY_RAISES_ASSERT(concatenation = left.concatenate(right, 2)); + + // Axis > NumDims or < 0. + VERIFY_RAISES_ASSERT(concatenation = left.concatenate(right, 3)); + VERIFY_RAISES_ASSERT(concatenation = left.concatenate(right, -1)); +} + +template<int DataLayout> +static void test_static_dimension_failure() +{ + Tensor<int, 2, DataLayout> left(2, 3); + Tensor<int, 3, DataLayout> right(2, 3, 1); + +#ifdef CXX11_TENSOR_CONCATENATION_STATIC_DIMENSION_FAILURE + // Technically compatible, but we static assert that the inputs have same + // NumDims. + Tensor<int, 3, DataLayout> concatenation = left.concatenate(right, 0); +#endif + + // This can be worked around in this case. + Tensor<int, 3, DataLayout> concatenation = left + .reshape(Tensor<int, 3>::Dimensions{{2, 3, 1}}) + .concatenate(right, 0); + Tensor<int, 2, DataLayout> alternative = left + .concatenate(right.reshape(Tensor<int, 2>::Dimensions{{2, 3}}), 0); +} + +template<int DataLayout> +static void test_simple_concatenation() +{ + Tensor<int, 3, DataLayout> left(2, 3, 1); + Tensor<int, 3, DataLayout> right(2, 3, 1); + left.setRandom(); + right.setRandom(); + + Tensor<int, 3, DataLayout> concatenation = left.concatenate(right, 0); + VERIFY_IS_EQUAL(concatenation.dimension(0), 4); + VERIFY_IS_EQUAL(concatenation.dimension(1), 3); + VERIFY_IS_EQUAL(concatenation.dimension(2), 1); + for (int j = 0; j < 3; ++j) { + for (int i = 0; i < 2; ++i) { + VERIFY_IS_EQUAL(concatenation(i, j, 0), left(i, j, 0)); + } + for (int i = 2; i < 4; ++i) { + VERIFY_IS_EQUAL(concatenation(i, j, 0), right(i - 2, j, 0)); + } + } + + concatenation = left.concatenate(right, 1); + VERIFY_IS_EQUAL(concatenation.dimension(0), 2); + VERIFY_IS_EQUAL(concatenation.dimension(1), 6); + VERIFY_IS_EQUAL(concatenation.dimension(2), 1); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_EQUAL(concatenation(i, j, 0), left(i, j, 0)); + } + for (int j = 3; j < 6; ++j) { + VERIFY_IS_EQUAL(concatenation(i, j, 0), right(i, j - 3, 0)); + } + } + + concatenation = left.concatenate(right, 2); + VERIFY_IS_EQUAL(concatenation.dimension(0), 2); + VERIFY_IS_EQUAL(concatenation.dimension(1), 3); + VERIFY_IS_EQUAL(concatenation.dimension(2), 2); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_EQUAL(concatenation(i, j, 0), left(i, j, 0)); + VERIFY_IS_EQUAL(concatenation(i, j, 1), right(i, j, 0)); + } + } +} + + +// TODO(phli): Add test once we have a real vectorized implementation. +// static void test_vectorized_concatenation() {} + + +void test_cxx11_tensor_concatenation() +{ + CALL_SUBTEST(test_dimension_failures<ColMajor>()); + CALL_SUBTEST(test_dimension_failures<RowMajor>()); + CALL_SUBTEST(test_static_dimension_failure<ColMajor>()); + CALL_SUBTEST(test_static_dimension_failure<RowMajor>()); + CALL_SUBTEST(test_simple_concatenation<ColMajor>()); + CALL_SUBTEST(test_simple_concatenation<RowMajor>()); + // CALL_SUBTEST(test_vectorized_concatenation()); +} diff --git a/unsupported/test/cxx11_tensor_const.cpp b/unsupported/test/cxx11_tensor_const.cpp new file mode 100644 index 000000000..0ffb02afd --- /dev/null +++ b/unsupported/test/cxx11_tensor_const.cpp @@ -0,0 +1,39 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> +using Eigen::Tensor; + + + + +static void test_simple_assign() +{ + Tensor<int, 3> random(2,3,7); + random.setRandom(); + + TensorMap<Tensor<const int, 3> > constant(random.data(), 2, 3, 7); + Tensor<int, 3> result(2,3,7); + result = constant; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL((result(i,j,k)), random(i,j,k)); + } + } + } +} + +void test_cxx11_tensor_const() +{ + CALL_SUBTEST(test_simple_assign()); +} diff --git a/unsupported/test/cxx11_tensor_contract_cuda.cpp b/unsupported/test/cxx11_tensor_contract_cuda.cpp new file mode 100644 index 000000000..9599607c6 --- /dev/null +++ b/unsupported/test/cxx11_tensor_contract_cuda.cpp @@ -0,0 +1,121 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// Copyright (C) 2014 Navdeep Jaitly <ndjaitly@google.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#define EIGEN_TEST_NO_LONGDOUBLE +#define EIGEN_TEST_NO_COMPLEX +#define EIGEN_TEST_FUNC cxx11_tensor_cuda +#define EIGEN_DEFAULT_DENSE_INDEX_TYPE int +#define EIGEN_USE_GPU + + +#include "main.h" +#include <unsupported/Eigen/CXX11/Tensor> + +using Eigen::Tensor; +typedef Tensor<float, 1>::DimensionPair DimPair; + +template<int DataLayout> +static void test_cuda_contraction(int m_size, int k_size, int n_size) +{ + cout<<"Calling with ("<<m_size<<","<<k_size<<","<<n_size<<")"<<std::endl; + // with these dimensions, the output has 300 * 140 elements, which is + // more than 30 * 1024, which is the number of threads in blocks on + // a 15 SM GK110 GPU + Tensor<float, 2, DataLayout> t_left(Eigen::array<int, 2>(m_size, k_size)); + Tensor<float, 2, DataLayout> t_right(Eigen::array<int, 2>(k_size, n_size)); + Tensor<float, 2, DataLayout> t_result(Eigen::array<int, 2>(m_size, n_size)); + Tensor<float, 2, DataLayout> t_result_gpu(Eigen::array<int, 2>(m_size, n_size)); + Eigen::array<DimPair, 1> dims(DimPair(1, 0)); + + t_left.setRandom(); + t_right.setRandom(); + + std::size_t t_left_bytes = t_left.size() * sizeof(float); + std::size_t t_right_bytes = t_right.size() * sizeof(float); + std::size_t t_result_bytes = t_result.size() * sizeof(float); + + float* d_t_left; + float* d_t_right; + float* d_t_result; + + cudaMalloc((void**)(&d_t_left), t_left_bytes); + cudaMalloc((void**)(&d_t_right), t_right_bytes); + cudaMalloc((void**)(&d_t_result), t_result_bytes); + + cudaMemcpy(d_t_left, t_left.data(), t_left_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_t_right, t_right.data(), t_right_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 2, DataLayout> > + gpu_t_left(d_t_left, Eigen::array<int, 2>(m_size, k_size)); + Eigen::TensorMap<Eigen::Tensor<float, 2, DataLayout> > + gpu_t_right(d_t_right, Eigen::array<int, 2>(k_size, n_size)); + Eigen::TensorMap<Eigen::Tensor<float, 2, DataLayout> > + gpu_t_result(d_t_result, Eigen::array<int, 2>(m_size, n_size)); + + + gpu_t_result.device(gpu_device) = gpu_t_left.contract(gpu_t_right, dims); + t_result = t_left.contract(t_right, dims); + + cudaMemcpy(t_result_gpu.data(), d_t_result, t_result_bytes, cudaMemcpyDeviceToHost); + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + if (fabs(t_result.data()[i] - t_result_gpu.data()[i]) >= 1e-4) { + cout << "mismatch detected at index " << i << ": " << t_result.data()[i] + << " vs " << t_result_gpu.data()[i] << endl; + assert(false); + } + } + + cudaFree((void*)d_t_left); + cudaFree((void*)d_t_right); + cudaFree((void*)d_t_result); +} + + +void test_cxx11_tensor_cuda() +{ + cout<<"Calling contraction tests"<<std::endl; + CALL_SUBTEST(test_cuda_contraction<ColMajor>(128, 128, 128)); + CALL_SUBTEST(test_cuda_contraction<RowMajor>(128, 128, 128)); + for (int k = 32; k < 256; k++) { + CALL_SUBTEST(test_cuda_contraction<ColMajor>(128, k, 128)); + CALL_SUBTEST(test_cuda_contraction<RowMajor>(128, k, 128)); + } + for (int k = 32; k < 256; k++) { + CALL_SUBTEST(test_cuda_contraction<ColMajor>(128, 128, k)); + CALL_SUBTEST(test_cuda_contraction<RowMajor>(128, 128, k)); + } + for (int k = 32; k < 256; k++) { + CALL_SUBTEST(test_cuda_contraction<ColMajor>(k, 128, 128)); + CALL_SUBTEST(test_cuda_contraction<RowMajor>(k, 128, 128)); + } + + int m_sizes[] = {31, 39, 63, 64, 65, + 127, 129, 255, 257, 511, + 512, 513, 1023, 1024, 1025 }; + int n_sizes[] = {31, 39, 63, 64, 65, + 127, 129, 255, 257, 511, + 512, 513, 1023, 1024, 1025 }; + + int k_sizes[] = { 31, 39, 63, 64, 65, + 95, 96, 127, 129, 255, + 257, 511, 512, 513, 1023, + 1024, 1025}; + + for (int i = 0; i <15; i++) + for (int j = 0; j < 15; j++) + for (int k = 0; k < 17; k++) { + CALL_SUBTEST(test_cuda_contraction<ColMajor>(m_sizes[i], n_sizes[j], k_sizes[k])); + CALL_SUBTEST(test_cuda_contraction<RowMajor>(m_sizes[i], n_sizes[j], k_sizes[k])); + } +} diff --git a/unsupported/test/cxx11_tensor_contraction.cpp b/unsupported/test/cxx11_tensor_contraction.cpp new file mode 100644 index 000000000..2bcae90b8 --- /dev/null +++ b/unsupported/test/cxx11_tensor_contraction.cpp @@ -0,0 +1,480 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::DefaultDevice; +using Eigen::Tensor; + +typedef Tensor<float, 1>::DimensionPair DimPair; + +template<int DataLayout> +static void test_evals() +{ + Tensor<float, 2, DataLayout> mat1(2, 3); + Tensor<float, 2, DataLayout> mat2(2, 3); + Tensor<float, 2, DataLayout> mat3(3, 2); + + mat1.setRandom(); + mat2.setRandom(); + mat3.setRandom(); + + Tensor<float, 2, DataLayout> mat4(3,3); + mat4.setZero(); + Eigen::array<DimPair, 1> dims3({{DimPair(0, 0)}}); + typedef TensorEvaluator<decltype(mat1.contract(mat2, dims3)), DefaultDevice> Evaluator; + Evaluator eval(mat1.contract(mat2, dims3), DefaultDevice()); + eval.evalTo(mat4.data()); + EIGEN_STATIC_ASSERT(Evaluator::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + VERIFY_IS_EQUAL(eval.dimensions()[0], 3); + VERIFY_IS_EQUAL(eval.dimensions()[1], 3); + + VERIFY_IS_APPROX(mat4(0,0), mat1(0,0)*mat2(0,0) + mat1(1,0)*mat2(1,0)); + VERIFY_IS_APPROX(mat4(0,1), mat1(0,0)*mat2(0,1) + mat1(1,0)*mat2(1,1)); + VERIFY_IS_APPROX(mat4(0,2), mat1(0,0)*mat2(0,2) + mat1(1,0)*mat2(1,2)); + VERIFY_IS_APPROX(mat4(1,0), mat1(0,1)*mat2(0,0) + mat1(1,1)*mat2(1,0)); + VERIFY_IS_APPROX(mat4(1,1), mat1(0,1)*mat2(0,1) + mat1(1,1)*mat2(1,1)); + VERIFY_IS_APPROX(mat4(1,2), mat1(0,1)*mat2(0,2) + mat1(1,1)*mat2(1,2)); + VERIFY_IS_APPROX(mat4(2,0), mat1(0,2)*mat2(0,0) + mat1(1,2)*mat2(1,0)); + VERIFY_IS_APPROX(mat4(2,1), mat1(0,2)*mat2(0,1) + mat1(1,2)*mat2(1,1)); + VERIFY_IS_APPROX(mat4(2,2), mat1(0,2)*mat2(0,2) + mat1(1,2)*mat2(1,2)); + + Tensor<float, 2, DataLayout> mat5(2,2); + mat5.setZero(); + Eigen::array<DimPair, 1> dims4({{DimPair(1, 1)}}); + typedef TensorEvaluator<decltype(mat1.contract(mat2, dims4)), DefaultDevice> Evaluator2; + Evaluator2 eval2(mat1.contract(mat2, dims4), DefaultDevice()); + eval2.evalTo(mat5.data()); + EIGEN_STATIC_ASSERT(Evaluator2::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + VERIFY_IS_EQUAL(eval2.dimensions()[0], 2); + VERIFY_IS_EQUAL(eval2.dimensions()[1], 2); + + VERIFY_IS_APPROX(mat5(0,0), mat1(0,0)*mat2(0,0) + mat1(0,1)*mat2(0,1) + mat1(0,2)*mat2(0,2)); + VERIFY_IS_APPROX(mat5(0,1), mat1(0,0)*mat2(1,0) + mat1(0,1)*mat2(1,1) + mat1(0,2)*mat2(1,2)); + VERIFY_IS_APPROX(mat5(1,0), mat1(1,0)*mat2(0,0) + mat1(1,1)*mat2(0,1) + mat1(1,2)*mat2(0,2)); + VERIFY_IS_APPROX(mat5(1,1), mat1(1,0)*mat2(1,0) + mat1(1,1)*mat2(1,1) + mat1(1,2)*mat2(1,2)); + + Tensor<float, 2, DataLayout> mat6(2,2); + mat6.setZero(); + Eigen::array<DimPair, 1> dims6({{DimPair(1, 0)}}); + typedef TensorEvaluator<decltype(mat1.contract(mat3, dims6)), DefaultDevice> Evaluator3; + Evaluator3 eval3(mat1.contract(mat3, dims6), DefaultDevice()); + eval3.evalTo(mat6.data()); + EIGEN_STATIC_ASSERT(Evaluator3::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + VERIFY_IS_EQUAL(eval3.dimensions()[0], 2); + VERIFY_IS_EQUAL(eval3.dimensions()[1], 2); + + VERIFY_IS_APPROX(mat6(0,0), mat1(0,0)*mat3(0,0) + mat1(0,1)*mat3(1,0) + mat1(0,2)*mat3(2,0)); + VERIFY_IS_APPROX(mat6(0,1), mat1(0,0)*mat3(0,1) + mat1(0,1)*mat3(1,1) + mat1(0,2)*mat3(2,1)); + VERIFY_IS_APPROX(mat6(1,0), mat1(1,0)*mat3(0,0) + mat1(1,1)*mat3(1,0) + mat1(1,2)*mat3(2,0)); + VERIFY_IS_APPROX(mat6(1,1), mat1(1,0)*mat3(0,1) + mat1(1,1)*mat3(1,1) + mat1(1,2)*mat3(2,1)); +} + +template<int DataLayout> +static void test_scalar() +{ + Tensor<float, 1, DataLayout> vec1({6}); + Tensor<float, 1, DataLayout> vec2({6}); + + vec1.setRandom(); + vec2.setRandom(); + + Tensor<float, 1, DataLayout> scalar(1); + scalar.setZero(); + Eigen::array<DimPair, 1> dims({{DimPair(0, 0)}}); + typedef TensorEvaluator<decltype(vec1.contract(vec2, dims)), DefaultDevice> Evaluator; + Evaluator eval(vec1.contract(vec2, dims), DefaultDevice()); + eval.evalTo(scalar.data()); + EIGEN_STATIC_ASSERT(Evaluator::NumDims==1ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + + float expected = 0.0f; + for (int i = 0; i < 6; ++i) { + expected += vec1(i) * vec2(i); + } + VERIFY_IS_APPROX(scalar(0), expected); +} + +template<int DataLayout> +static void test_multidims() +{ + Tensor<float, 3, DataLayout> mat1(2, 2, 2); + Tensor<float, 4, DataLayout> mat2(2, 2, 2, 2); + + mat1.setRandom(); + mat2.setRandom(); + + Tensor<float, 3, DataLayout> mat3(2, 2, 2); + mat3.setZero(); + Eigen::array<DimPair, 2> dims({{DimPair(1, 2), DimPair(2, 3)}}); + typedef TensorEvaluator<decltype(mat1.contract(mat2, dims)), DefaultDevice> Evaluator; + Evaluator eval(mat1.contract(mat2, dims), DefaultDevice()); + eval.evalTo(mat3.data()); + EIGEN_STATIC_ASSERT(Evaluator::NumDims==3ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + VERIFY_IS_EQUAL(eval.dimensions()[0], 2); + VERIFY_IS_EQUAL(eval.dimensions()[1], 2); + VERIFY_IS_EQUAL(eval.dimensions()[2], 2); + + VERIFY_IS_APPROX(mat3(0,0,0), mat1(0,0,0)*mat2(0,0,0,0) + mat1(0,1,0)*mat2(0,0,1,0) + + mat1(0,0,1)*mat2(0,0,0,1) + mat1(0,1,1)*mat2(0,0,1,1)); + VERIFY_IS_APPROX(mat3(0,0,1), mat1(0,0,0)*mat2(0,1,0,0) + mat1(0,1,0)*mat2(0,1,1,0) + + mat1(0,0,1)*mat2(0,1,0,1) + mat1(0,1,1)*mat2(0,1,1,1)); + VERIFY_IS_APPROX(mat3(0,1,0), mat1(0,0,0)*mat2(1,0,0,0) + mat1(0,1,0)*mat2(1,0,1,0) + + mat1(0,0,1)*mat2(1,0,0,1) + mat1(0,1,1)*mat2(1,0,1,1)); + VERIFY_IS_APPROX(mat3(0,1,1), mat1(0,0,0)*mat2(1,1,0,0) + mat1(0,1,0)*mat2(1,1,1,0) + + mat1(0,0,1)*mat2(1,1,0,1) + mat1(0,1,1)*mat2(1,1,1,1)); + VERIFY_IS_APPROX(mat3(1,0,0), mat1(1,0,0)*mat2(0,0,0,0) + mat1(1,1,0)*mat2(0,0,1,0) + + mat1(1,0,1)*mat2(0,0,0,1) + mat1(1,1,1)*mat2(0,0,1,1)); + VERIFY_IS_APPROX(mat3(1,0,1), mat1(1,0,0)*mat2(0,1,0,0) + mat1(1,1,0)*mat2(0,1,1,0) + + mat1(1,0,1)*mat2(0,1,0,1) + mat1(1,1,1)*mat2(0,1,1,1)); + VERIFY_IS_APPROX(mat3(1,1,0), mat1(1,0,0)*mat2(1,0,0,0) + mat1(1,1,0)*mat2(1,0,1,0) + + mat1(1,0,1)*mat2(1,0,0,1) + mat1(1,1,1)*mat2(1,0,1,1)); + VERIFY_IS_APPROX(mat3(1,1,1), mat1(1,0,0)*mat2(1,1,0,0) + mat1(1,1,0)*mat2(1,1,1,0) + + mat1(1,0,1)*mat2(1,1,0,1) + mat1(1,1,1)*mat2(1,1,1,1)); +} + +template<int DataLayout> +static void test_holes() { + Tensor<float, 4, DataLayout> t1(2, 5, 7, 3); + Tensor<float, 5, DataLayout> t2(2, 7, 11, 13, 3); + t1.setRandom(); + t2.setRandom(); + + Eigen::array<DimPair, 2> dims({{DimPair(0, 0), DimPair(3, 4)}}); + Tensor<float, 5, DataLayout> result = t1.contract(t2, dims); + VERIFY_IS_EQUAL(result.dimension(0), 5); + VERIFY_IS_EQUAL(result.dimension(1), 7); + VERIFY_IS_EQUAL(result.dimension(2), 7); + VERIFY_IS_EQUAL(result.dimension(3), 11); + VERIFY_IS_EQUAL(result.dimension(4), 13); + + for (int i = 0; i < 5; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 5; ++l) { + for (int m = 0; m < 5; ++m) { + VERIFY_IS_APPROX(result(i, j, k, l, m), + t1(0, i, j, 0) * t2(0, k, l, m, 0) + + t1(1, i, j, 0) * t2(1, k, l, m, 0) + + t1(0, i, j, 1) * t2(0, k, l, m, 1) + + t1(1, i, j, 1) * t2(1, k, l, m, 1) + + t1(0, i, j, 2) * t2(0, k, l, m, 2) + + t1(1, i, j, 2) * t2(1, k, l, m, 2)); + } + } + } + } + } +} + +template<int DataLayout> +static void test_full_redux() +{ + Tensor<float, 2, DataLayout> t1(2, 2); + Tensor<float, 3, DataLayout> t2(2, 2, 2); + t1.setRandom(); + t2.setRandom(); + + Eigen::array<DimPair, 2> dims({{DimPair(0, 0), DimPair(1, 1)}}); + Tensor<float, 1, DataLayout> result = t1.contract(t2, dims); + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) + t1(1, 0) * t2(1, 0, 0) + + t1(0, 1) * t2(0, 1, 0) + t1(1, 1) * t2(1, 1, 0)); + VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(0, 0, 1) + t1(1, 0) * t2(1, 0, 1) + + t1(0, 1) * t2(0, 1, 1) + t1(1, 1) * t2(1, 1, 1)); + + dims[0] = DimPair(1, 0); + dims[1] = DimPair(2, 1); + result = t2.contract(t1, dims); + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) + t1(1, 0) * t2(0, 1, 0) + + t1(0, 1) * t2(0, 0, 1) + t1(1, 1) * t2(0, 1, 1)); + VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(1, 0, 0) + t1(1, 0) * t2(1, 1, 0) + + t1(0, 1) * t2(1, 0, 1) + t1(1, 1) * t2(1, 1, 1)); +} + +template<int DataLayout> +static void test_contraction_of_contraction() +{ + Tensor<float, 2, DataLayout> t1(2, 2); + Tensor<float, 2, DataLayout> t2(2, 2); + Tensor<float, 2, DataLayout> t3(2, 2); + Tensor<float, 2, DataLayout> t4(2, 2); + t1.setRandom(); + t2.setRandom(); + t3.setRandom(); + t4.setRandom(); + + Eigen::array<DimPair, 1> dims({{DimPair(1, 0)}}); + auto contract1 = t1.contract(t2, dims); + auto diff = t3 - contract1; + auto contract2 = t1.contract(t4, dims); + Tensor<float, 2, DataLayout> result = contract2.contract(diff, dims); + + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_EQUAL(result.dimension(1), 2); + + Eigen::Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> + m1(t1.data(), 2, 2), m2(t2.data(), 2, 2), m3(t3.data(), 2, 2), + m4(t4.data(), 2, 2); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> + expected = (m1 * m4) * (m3 - m1 * m2); + + VERIFY_IS_APPROX(result(0, 0), expected(0, 0)); + VERIFY_IS_APPROX(result(0, 1), expected(0, 1)); + VERIFY_IS_APPROX(result(1, 0), expected(1, 0)); + VERIFY_IS_APPROX(result(1, 1), expected(1, 1)); +} + +template<int DataLayout> +static void test_expr() +{ + Tensor<float, 2, DataLayout> mat1(2, 3); + Tensor<float, 2, DataLayout> mat2(3, 2); + mat1.setRandom(); + mat2.setRandom(); + + Tensor<float, 2, DataLayout> mat3(2,2); + + Eigen::array<DimPair, 1> dims({{DimPair(1, 0)}}); + mat3 = mat1.contract(mat2, dims); + + VERIFY_IS_APPROX(mat3(0,0), mat1(0,0)*mat2(0,0) + mat1(0,1)*mat2(1,0) + mat1(0,2)*mat2(2,0)); + VERIFY_IS_APPROX(mat3(0,1), mat1(0,0)*mat2(0,1) + mat1(0,1)*mat2(1,1) + mat1(0,2)*mat2(2,1)); + VERIFY_IS_APPROX(mat3(1,0), mat1(1,0)*mat2(0,0) + mat1(1,1)*mat2(1,0) + mat1(1,2)*mat2(2,0)); + VERIFY_IS_APPROX(mat3(1,1), mat1(1,0)*mat2(0,1) + mat1(1,1)*mat2(1,1) + mat1(1,2)*mat2(2,1)); +} + +template<int DataLayout> +static void test_out_of_order_contraction() +{ + Tensor<float, 3, DataLayout> mat1(2, 2, 2); + Tensor<float, 3, DataLayout> mat2(2, 2, 2); + + mat1.setRandom(); + mat2.setRandom(); + + Tensor<float, 2, DataLayout> mat3(2, 2); + + Eigen::array<DimPair, 2> dims({{DimPair(2, 0), DimPair(0, 2)}}); + mat3 = mat1.contract(mat2, dims); + + VERIFY_IS_APPROX(mat3(0, 0), + mat1(0,0,0)*mat2(0,0,0) + mat1(1,0,0)*mat2(0,0,1) + + mat1(0,0,1)*mat2(1,0,0) + mat1(1,0,1)*mat2(1,0,1)); + VERIFY_IS_APPROX(mat3(1, 0), + mat1(0,1,0)*mat2(0,0,0) + mat1(1,1,0)*mat2(0,0,1) + + mat1(0,1,1)*mat2(1,0,0) + mat1(1,1,1)*mat2(1,0,1)); + VERIFY_IS_APPROX(mat3(0, 1), + mat1(0,0,0)*mat2(0,1,0) + mat1(1,0,0)*mat2(0,1,1) + + mat1(0,0,1)*mat2(1,1,0) + mat1(1,0,1)*mat2(1,1,1)); + VERIFY_IS_APPROX(mat3(1, 1), + mat1(0,1,0)*mat2(0,1,0) + mat1(1,1,0)*mat2(0,1,1) + + mat1(0,1,1)*mat2(1,1,0) + mat1(1,1,1)*mat2(1,1,1)); + + Eigen::array<DimPair, 2> dims2({{DimPair(0, 2), DimPair(2, 0)}}); + mat3 = mat1.contract(mat2, dims2); + + VERIFY_IS_APPROX(mat3(0, 0), + mat1(0,0,0)*mat2(0,0,0) + mat1(1,0,0)*mat2(0,0,1) + + mat1(0,0,1)*mat2(1,0,0) + mat1(1,0,1)*mat2(1,0,1)); + VERIFY_IS_APPROX(mat3(1, 0), + mat1(0,1,0)*mat2(0,0,0) + mat1(1,1,0)*mat2(0,0,1) + + mat1(0,1,1)*mat2(1,0,0) + mat1(1,1,1)*mat2(1,0,1)); + VERIFY_IS_APPROX(mat3(0, 1), + mat1(0,0,0)*mat2(0,1,0) + mat1(1,0,0)*mat2(0,1,1) + + mat1(0,0,1)*mat2(1,1,0) + mat1(1,0,1)*mat2(1,1,1)); + VERIFY_IS_APPROX(mat3(1, 1), + mat1(0,1,0)*mat2(0,1,0) + mat1(1,1,0)*mat2(0,1,1) + + mat1(0,1,1)*mat2(1,1,0) + mat1(1,1,1)*mat2(1,1,1)); + +} + +template<int DataLayout> +static void test_consistency() +{ + // this does something like testing (A*B)^T = (B^T * A^T) + + Tensor<float, 3, DataLayout> mat1(4, 3, 5); + Tensor<float, 5, DataLayout> mat2(3, 2, 1, 5, 4); + mat1.setRandom(); + mat2.setRandom(); + + Tensor<float, 4, DataLayout> mat3(5, 2, 1, 5); + Tensor<float, 4, DataLayout> mat4(2, 1, 5, 5); + + // contract on dimensions of size 4 and 3 + Eigen::array<DimPair, 2> dims1({{DimPair(0, 4), DimPair(1, 0)}}); + Eigen::array<DimPair, 2> dims2({{DimPair(4, 0), DimPair(0, 1)}}); + + mat3 = mat1.contract(mat2, dims1); + mat4 = mat2.contract(mat1, dims2); + + // check that these are equal except for ordering of dimensions + if (DataLayout == ColMajor) { + for (size_t i = 0; i < 5; i++) { + for (size_t j = 0; j < 10; j++) { + VERIFY_IS_APPROX(mat3.data()[i + 5 * j], mat4.data()[j + 10 * i]); + } + } + } else { + // Row major + for (size_t i = 0; i < 5; i++) { + for (size_t j = 0; j < 10; j++) { + VERIFY_IS_APPROX(mat3.data()[10 * i + j], mat4.data()[i + 5 * j]); + } + } + } +} + +template<int DataLayout> +static void test_large_contraction() +{ + Tensor<float, 4, DataLayout> t_left(30, 50, 8, 31); + Tensor<float, 5, DataLayout> t_right(8, 31, 7, 20, 10); + Tensor<float, 5, DataLayout> t_result(30, 50, 7, 20, 10); + + t_left.setRandom(); + t_right.setRandom(); + + // Add a little offset so that the results won't be close to zero. + t_left += t_left.constant(1.0f); + t_right += t_right.constant(1.0f); + + typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf; + MapXf m_left(t_left.data(), 1500, 248); + MapXf m_right(t_right.data(), 248, 1400); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(1500, 1400); + + // this contraction should be equivalent to a single matrix multiplication + Eigen::array<DimPair, 2> dims({{DimPair(2, 0), DimPair(3, 1)}}); + + // compute results by separate methods + t_result = t_left.contract(t_right, dims); + m_result = m_left * m_right; + + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + VERIFY(&t_result.data()[i] != &m_result.data()[i]); + VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]); + } +} + +template<int DataLayout> +static void test_matrix_vector() +{ + Tensor<float, 2, DataLayout> t_left(30, 50); + Tensor<float, 1, DataLayout> t_right(50); + Tensor<float, 1, DataLayout> t_result(30); + + t_left.setRandom(); + t_right.setRandom(); + + typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf; + MapXf m_left(t_left.data(), 30, 50); + MapXf m_right(t_right.data(), 50, 1); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(30, 1); + + // this contraction should be equivalent to a single matrix multiplication + Eigen::array<DimPair, 1> dims{{DimPair(1, 0)}}; + + // compute results by separate methods + t_result = t_left.contract(t_right, dims); + m_result = m_left * m_right; + + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1)); + } +} + + +template<int DataLayout> +static void test_tensor_vector() +{ + Tensor<float, 3, DataLayout> t_left(7, 13, 17); + Tensor<float, 2, DataLayout> t_right(1, 7); + + t_left.setRandom(); + t_right.setRandom(); + + typedef typename Tensor<float, 1, DataLayout>::DimensionPair DimensionPair; + Eigen::array<DimensionPair, 1> dim_pair01{{{0, 1}}}; + Tensor<float, 3, DataLayout> t_result = t_left.contract(t_right, dim_pair01); + + typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf; + MapXf m_left(t_left.data(), 7, 13*17); + MapXf m_right(t_right.data(), 1, 7); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left.transpose() * m_right.transpose(); + + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1)); + } +} + + +template<int DataLayout> +static void test_small_blocking_factors() +{ + Tensor<float, 4, DataLayout> t_left(30, 5, 3, 31); + Tensor<float, 5, DataLayout> t_right(3, 31, 7, 20, 1); + t_left.setRandom(); + t_right.setRandom(); + + // Add a little offset so that the results won't be close to zero. + t_left += t_left.constant(1.0f); + t_right += t_right.constant(1.0f); + + // Force the cache sizes, which results in smaller blocking factors. + Eigen::setCpuCacheSizes(896, 1920, 2944); + + // this contraction should be equivalent to a single matrix multiplication + Eigen::array<DimPair, 2> dims({{DimPair(2, 0), DimPair(3, 1)}}); + Tensor<float, 5, DataLayout> t_result; + t_result = t_left.contract(t_right, dims); + + // compute result using a simple eigen matrix product + Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_left(t_left.data(), 150, 93); + Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_right(t_right.data(), 93, 140); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left * m_right; + + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]); + } +} + + +void test_cxx11_tensor_contraction() +{ + CALL_SUBTEST(test_evals<ColMajor>()); + CALL_SUBTEST(test_evals<RowMajor>()); + CALL_SUBTEST(test_scalar<ColMajor>()); + CALL_SUBTEST(test_scalar<RowMajor>()); + CALL_SUBTEST(test_multidims<ColMajor>()); + CALL_SUBTEST(test_multidims<RowMajor>()); + CALL_SUBTEST(test_holes<ColMajor>()); + CALL_SUBTEST(test_holes<RowMajor>()); + CALL_SUBTEST(test_full_redux<ColMajor>()); + CALL_SUBTEST(test_full_redux<RowMajor>()); + CALL_SUBTEST(test_contraction_of_contraction<ColMajor>()); + CALL_SUBTEST(test_contraction_of_contraction<RowMajor>()); + CALL_SUBTEST(test_expr<ColMajor>()); + CALL_SUBTEST(test_expr<RowMajor>()); + CALL_SUBTEST(test_out_of_order_contraction<ColMajor>()); + CALL_SUBTEST(test_out_of_order_contraction<RowMajor>()); + CALL_SUBTEST(test_consistency<ColMajor>()); + CALL_SUBTEST(test_consistency<RowMajor>()); + CALL_SUBTEST(test_large_contraction<ColMajor>()); + CALL_SUBTEST(test_large_contraction<RowMajor>()); + CALL_SUBTEST(test_matrix_vector<ColMajor>()); + CALL_SUBTEST(test_matrix_vector<RowMajor>()); + CALL_SUBTEST(test_tensor_vector<ColMajor>()); + CALL_SUBTEST(test_tensor_vector<RowMajor>()); + CALL_SUBTEST(test_small_blocking_factors<ColMajor>()); + CALL_SUBTEST(test_small_blocking_factors<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_convolution.cpp b/unsupported/test/cxx11_tensor_convolution.cpp new file mode 100644 index 000000000..4672db463 --- /dev/null +++ b/unsupported/test/cxx11_tensor_convolution.cpp @@ -0,0 +1,141 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::DefaultDevice; + +static void test_evals() +{ + Tensor<float, 2> input(3, 3); + Tensor<float, 1> kernel(2); + + input.setRandom(); + kernel.setRandom(); + + Tensor<float, 2> result(2,3); + result.setZero(); + Eigen::array<Tensor<float, 2>::Index, 1> dims3({0}); + + typedef TensorEvaluator<decltype(input.convolve(kernel, dims3)), DefaultDevice> Evaluator; + Evaluator eval(input.convolve(kernel, dims3), DefaultDevice()); + eval.evalTo(result.data()); + EIGEN_STATIC_ASSERT(Evaluator::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE); + VERIFY_IS_EQUAL(eval.dimensions()[0], 2); + VERIFY_IS_EQUAL(eval.dimensions()[1], 3); + + VERIFY_IS_APPROX(result(0,0), input(0,0)*kernel(0) + input(1,0)*kernel(1)); // index 0 + VERIFY_IS_APPROX(result(0,1), input(0,1)*kernel(0) + input(1,1)*kernel(1)); // index 2 + VERIFY_IS_APPROX(result(0,2), input(0,2)*kernel(0) + input(1,2)*kernel(1)); // index 4 + VERIFY_IS_APPROX(result(1,0), input(1,0)*kernel(0) + input(2,0)*kernel(1)); // index 1 + VERIFY_IS_APPROX(result(1,1), input(1,1)*kernel(0) + input(2,1)*kernel(1)); // index 3 + VERIFY_IS_APPROX(result(1,2), input(1,2)*kernel(0) + input(2,2)*kernel(1)); // index 5 +} + + +static void test_expr() +{ + Tensor<float, 2> input(3, 3); + Tensor<float, 2> kernel(2, 2); + input.setRandom(); + kernel.setRandom(); + + Tensor<float, 2> result(2,2); + Eigen::array<ptrdiff_t, 2> dims({0, 1}); + result = input.convolve(kernel, dims); + + VERIFY_IS_APPROX(result(0,0), input(0,0)*kernel(0,0) + input(0,1)*kernel(0,1) + + input(1,0)*kernel(1,0) + input(1,1)*kernel(1,1)); + VERIFY_IS_APPROX(result(0,1), input(0,1)*kernel(0,0) + input(0,2)*kernel(0,1) + + input(1,1)*kernel(1,0) + input(1,2)*kernel(1,1)); + VERIFY_IS_APPROX(result(1,0), input(1,0)*kernel(0,0) + input(1,1)*kernel(0,1) + + input(2,0)*kernel(1,0) + input(2,1)*kernel(1,1)); + VERIFY_IS_APPROX(result(1,1), input(1,1)*kernel(0,0) + input(1,2)*kernel(0,1) + + input(2,1)*kernel(1,0) + input(2,2)*kernel(1,1)); +} + + +static void test_modes() { + Tensor<float, 1> input(3); + Tensor<float, 1> kernel(3); + input(0) = 1.0f; + input(1) = 2.0f; + input(2) = 3.0f; + kernel(0) = 0.5f; + kernel(1) = 1.0f; + kernel(2) = 0.0f; + + const Eigen::array<ptrdiff_t, 1> dims{{0}}; + Eigen::array<std::pair<ptrdiff_t, ptrdiff_t>, 1> padding; + + // Emulate VALID mode (as defined in + // http://docs.scipy.org/doc/numpy/reference/generated/numpy.convolve.html). + padding[0] = std::make_pair(0, 0); + Tensor<float, 1> valid(1); + valid = input.pad(padding).convolve(kernel, dims); + VERIFY_IS_EQUAL(valid.dimension(0), 1); + VERIFY_IS_APPROX(valid(0), 2.5f); + + // Emulate SAME mode (as defined in + // http://docs.scipy.org/doc/numpy/reference/generated/numpy.convolve.html). + padding[0] = std::make_pair(1, 1); + Tensor<float, 1> same(3); + same = input.pad(padding).convolve(kernel, dims); + VERIFY_IS_EQUAL(same.dimension(0), 3); + VERIFY_IS_APPROX(same(0), 1.0f); + VERIFY_IS_APPROX(same(1), 2.5f); + VERIFY_IS_APPROX(same(2), 4.0f); + + // Emulate FULL mode (as defined in + // http://docs.scipy.org/doc/numpy/reference/generated/numpy.convolve.html). + padding[0] = std::make_pair(2, 2); + Tensor<float, 1> full(5); + full = input.pad(padding).convolve(kernel, dims); + VERIFY_IS_EQUAL(full.dimension(0), 5); + VERIFY_IS_APPROX(full(0), 0.0f); + VERIFY_IS_APPROX(full(1), 1.0f); + VERIFY_IS_APPROX(full(2), 2.5f); + VERIFY_IS_APPROX(full(3), 4.0f); + VERIFY_IS_APPROX(full(4), 1.5f); +} + + +static void test_strides() { + Tensor<float, 1> input(13); + Tensor<float, 1> kernel(3); + input.setRandom(); + kernel.setRandom(); + + const Eigen::array<ptrdiff_t, 1> dims{{0}}; + const Eigen::array<ptrdiff_t, 1> stride_of_3{{3}}; + const Eigen::array<ptrdiff_t, 1> stride_of_2{{2}}; + + Tensor<float, 1> result; + result = input.stride(stride_of_3).convolve(kernel, dims).stride(stride_of_2); + + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_APPROX(result(0), (input(0)*kernel(0) + input(3)*kernel(1) + + input(6)*kernel(2))); + VERIFY_IS_APPROX(result(1), (input(6)*kernel(0) + input(9)*kernel(1) + + input(12)*kernel(2))); +} + + + + +void test_cxx11_tensor_convolution() +{ + CALL_SUBTEST(test_evals()); + CALL_SUBTEST(test_expr()); + CALL_SUBTEST(test_modes()); + CALL_SUBTEST(test_strides()); +} diff --git a/unsupported/test/cxx11_tensor_cuda.cpp b/unsupported/test/cxx11_tensor_cuda.cpp new file mode 100644 index 000000000..8c1ca1bf8 --- /dev/null +++ b/unsupported/test/cxx11_tensor_cuda.cpp @@ -0,0 +1,514 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +// TODO(mdevin): Free the cuda memory. + +#define EIGEN_TEST_NO_LONGDOUBLE +#define EIGEN_TEST_NO_COMPLEX +#define EIGEN_TEST_FUNC cxx11_tensor_cuda +#define EIGEN_DEFAULT_DENSE_INDEX_TYPE int +#define EIGEN_USE_GPU + + +#include "main.h" +#include <unsupported/Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +void test_cuda_elementwise_small() { + Tensor<float, 1> in1(Eigen::array<int, 1>(2)); + Tensor<float, 1> in2(Eigen::array<int, 1>(2)); + Tensor<float, 1> out(Eigen::array<int, 1>(2)); + in1.setRandom(); + in2.setRandom(); + + std::size_t in1_bytes = in1.size() * sizeof(float); + std::size_t in2_bytes = in2.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_in1; + float* d_in2; + float* d_out; + cudaMalloc((void**)(&d_in1), in1_bytes); + cudaMalloc((void**)(&d_in2), in2_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_in1, in1.data(), in1_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_in2, in2.data(), in2_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 1>, Eigen::Aligned> gpu_in1( + d_in1, Eigen::array<int, 1>(2)); + Eigen::TensorMap<Eigen::Tensor<float, 1>, Eigen::Aligned> gpu_in2( + d_in2, Eigen::array<int, 1>(2)); + Eigen::TensorMap<Eigen::Tensor<float, 1>, Eigen::Aligned> gpu_out( + d_out, Eigen::array<int, 1>(2)); + + gpu_out.device(gpu_device) = gpu_in1 + gpu_in2; + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, + gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 2; ++i) { + VERIFY_IS_APPROX( + out(Eigen::array<int, 1>(i)), + in1(Eigen::array<int, 1>(i)) + in2(Eigen::array<int, 1>(i))); + } +} + +void test_cuda_elementwise() +{ + Tensor<float, 3> in1(Eigen::array<int, 3>(72,53,97)); + Tensor<float, 3> in2(Eigen::array<int, 3>(72,53,97)); + Tensor<float, 3> in3(Eigen::array<int, 3>(72,53,97)); + Tensor<float, 3> out(Eigen::array<int, 3>(72,53,97)); + in1.setRandom(); + in2.setRandom(); + in3.setRandom(); + + std::size_t in1_bytes = in1.size() * sizeof(float); + std::size_t in2_bytes = in2.size() * sizeof(float); + std::size_t in3_bytes = in3.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_in1; + float* d_in2; + float* d_in3; + float* d_out; + cudaMalloc((void**)(&d_in1), in1_bytes); + cudaMalloc((void**)(&d_in2), in2_bytes); + cudaMalloc((void**)(&d_in3), in3_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_in1, in1.data(), in1_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_in2, in2.data(), in2_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_in3, in3.data(), in3_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_in1(d_in1, Eigen::array<int, 3>(72,53,97)); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_in2(d_in2, Eigen::array<int, 3>(72,53,97)); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_in3(d_in3, Eigen::array<int, 3>(72,53,97)); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_out(d_out, Eigen::array<int, 3>(72,53,97)); + + gpu_out.device(gpu_device) = gpu_in1 + gpu_in2 * gpu_in3; + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 53; ++j) { + for (int k = 0; k < 97; ++k) { + VERIFY_IS_APPROX(out(Eigen::array<int, 3>(i,j,k)), in1(Eigen::array<int, 3>(i,j,k)) + in2(Eigen::array<int, 3>(i,j,k)) * in3(Eigen::array<int, 3>(i,j,k))); + } + } + } +} + + +void test_cuda_reduction() +{ + Tensor<float, 4> in1(Eigen::array<int, 4>(72,53,97,113)); + Tensor<float, 2> out(Eigen::array<int, 2>(72,97)); + in1.setRandom(); + + std::size_t in1_bytes = in1.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_in1; + float* d_out; + cudaMalloc((void**)(&d_in1), in1_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_in1, in1.data(), in1_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 4> > gpu_in1(d_in1, Eigen::array<int, 4>(72,53,97,113)); + Eigen::TensorMap<Eigen::Tensor<float, 2> > gpu_out(d_out, Eigen::array<int, 2>(72,97)); + + array<int, 2> reduction_axis; + reduction_axis[0] = 1; + reduction_axis[1] = 3; + + gpu_out.device(gpu_device) = gpu_in1.maximum(reduction_axis); + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 97; ++j) { + float expected = 0; + for (int k = 0; k < 53; ++k) { + for (int l = 0; l < 113; ++l) { + expected = + std::max<float>(expected, in1(Eigen::array<int, 4>(i, k, j, l))); + } + } + VERIFY_IS_APPROX(out(Eigen::array<int, 2>(i,j)), expected); + } + } +} + +template<int DataLayout> +static void test_cuda_contraction() +{ + // with these dimensions, the output has 300 * 140 elements, which is + // more than 30 * 1024, which is the number of threads in blocks on + // a 15 SM GK110 GPU + Tensor<float, 4, DataLayout> t_left(Eigen::array<int, 4>(6, 50, 3, 31)); + Tensor<float, 5, DataLayout> t_right(Eigen::array<int, 5>(3, 31, 7, 20, 1)); + Tensor<float, 5, DataLayout> t_result(Eigen::array<int, 5>(6, 50, 7, 20, 1)); + + t_left.setRandom(); + t_right.setRandom(); + + std::size_t t_left_bytes = t_left.size() * sizeof(float); + std::size_t t_right_bytes = t_right.size() * sizeof(float); + std::size_t t_result_bytes = t_result.size() * sizeof(float); + + float* d_t_left; + float* d_t_right; + float* d_t_result; + + cudaMalloc((void**)(&d_t_left), t_left_bytes); + cudaMalloc((void**)(&d_t_right), t_right_bytes); + cudaMalloc((void**)(&d_t_result), t_result_bytes); + + cudaMemcpy(d_t_left, t_left.data(), t_left_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_t_right, t_right.data(), t_right_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 4, DataLayout> > + gpu_t_left(d_t_left, Eigen::array<int, 4>(6, 50, 3, 31)); + Eigen::TensorMap<Eigen::Tensor<float, 5, DataLayout> > + gpu_t_right(d_t_right, Eigen::array<int, 5>(3, 31, 7, 20, 1)); + Eigen::TensorMap<Eigen::Tensor<float, 5, DataLayout> > + gpu_t_result(d_t_result, Eigen::array<int, 5>(6, 50, 7, 20, 1)); + + typedef Eigen::Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> > MapXf; + MapXf m_left(t_left.data(), 300, 93); + MapXf m_right(t_right.data(), 93, 140); + Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(300, 140); + + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 2> dims; + dims[0] = DimPair(2, 0); + dims[1] = DimPair(3, 1); + + m_result = m_left * m_right; + gpu_t_result.device(gpu_device) = gpu_t_left.contract(gpu_t_right, dims); + + cudaMemcpy(t_result.data(), d_t_result, t_result_bytes, cudaMemcpyDeviceToHost); + + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + cout << "mismatch detected at index " << i << ": " << t_result.data()[i] << " vs " << m_result.data()[i] << endl; + assert(false); + } + } +} + +static void test_cuda_convolution_1d() +{ + Tensor<float, 4> input(Eigen::array<int, 4>(74,37,11,137)); + Tensor<float, 1> kernel(Eigen::array<int, 1>(4)); + Tensor<float, 4> out(Eigen::array<int, 4>(74,34,11,137)); + input = input.constant(10.0f) + input.random(); + kernel = kernel.constant(7.0f) + kernel.random(); + + std::size_t input_bytes = input.size() * sizeof(float); + std::size_t kernel_bytes = kernel.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_input; + float* d_kernel; + float* d_out; + cudaMalloc((void**)(&d_input), input_bytes); + cudaMalloc((void**)(&d_kernel), kernel_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_input, input.data(), input_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_kernel, kernel.data(), kernel_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 4> > gpu_input(d_input, Eigen::array<int, 4>(74,37,11,137)); + Eigen::TensorMap<Eigen::Tensor<float, 1> > gpu_kernel(d_kernel, Eigen::array<int, 1>(4)); + Eigen::TensorMap<Eigen::Tensor<float, 4> > gpu_out(d_out, Eigen::array<int, 4>(74,34,11,137)); + + Eigen::array<int, 1> dims(1); + gpu_out.device(gpu_device) = gpu_input.convolve(gpu_kernel, dims); + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 74; ++i) { + for (int j = 0; j < 34; ++j) { + for (int k = 0; k < 11; ++k) { + for (int l = 0; l < 137; ++l) { + const float result = out(Eigen::array<int, 4>(i,j,k,l)); + const float expected = input(Eigen::array<int, 4>(i,j+0,k,l)) * kernel(Eigen::array<int, 1>(0)) + + input(Eigen::array<int, 4>(i,j+1,k,l)) * kernel(Eigen::array<int, 1>(1)) + + input(Eigen::array<int, 4>(i,j+2,k,l)) * kernel(Eigen::array<int, 1>(2)) + + input(Eigen::array<int, 4>(i,j+3,k,l)) * kernel(Eigen::array<int, 1>(3)); + VERIFY_IS_APPROX(result, expected); + } + } + } + } +} + + +static void test_cuda_convolution_2d() +{ + Tensor<float, 4> input(Eigen::array<int, 4>(74,37,11,137)); + Tensor<float, 2> kernel(Eigen::array<int, 2>(3,4)); + Tensor<float, 4> out(Eigen::array<int, 4>(74,35,8,137)); + input = input.constant(10.0f) + input.random(); + kernel = kernel.constant(7.0f) + kernel.random(); + + std::size_t input_bytes = input.size() * sizeof(float); + std::size_t kernel_bytes = kernel.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_input; + float* d_kernel; + float* d_out; + cudaMalloc((void**)(&d_input), input_bytes); + cudaMalloc((void**)(&d_kernel), kernel_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_input, input.data(), input_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_kernel, kernel.data(), kernel_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 4> > gpu_input(d_input, Eigen::array<int, 4>(74,37,11,137)); + Eigen::TensorMap<Eigen::Tensor<float, 2> > gpu_kernel(d_kernel, Eigen::array<int, 2>(3,4)); + Eigen::TensorMap<Eigen::Tensor<float, 4> > gpu_out(d_out, Eigen::array<int, 4>(74,35,8,137)); + + Eigen::array<int, 2> dims(1,2); + gpu_out.device(gpu_device) = gpu_input.convolve(gpu_kernel, dims); + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 74; ++i) { + for (int j = 0; j < 35; ++j) { + for (int k = 0; k < 8; ++k) { + for (int l = 0; l < 137; ++l) { + const float result = out(Eigen::array<int, 4>(i,j,k,l)); + const float expected = input(Eigen::array<int, 4>(i,j+0,k+0,l)) * kernel(Eigen::array<int, 2>(0,0)) + + input(Eigen::array<int, 4>(i,j+1,k+0,l)) * kernel(Eigen::array<int, 2>(1,0)) + + input(Eigen::array<int, 4>(i,j+2,k+0,l)) * kernel(Eigen::array<int, 2>(2,0)) + + input(Eigen::array<int, 4>(i,j+0,k+1,l)) * kernel(Eigen::array<int, 2>(0,1)) + + input(Eigen::array<int, 4>(i,j+1,k+1,l)) * kernel(Eigen::array<int, 2>(1,1)) + + input(Eigen::array<int, 4>(i,j+2,k+1,l)) * kernel(Eigen::array<int, 2>(2,1)) + + input(Eigen::array<int, 4>(i,j+0,k+2,l)) * kernel(Eigen::array<int, 2>(0,2)) + + input(Eigen::array<int, 4>(i,j+1,k+2,l)) * kernel(Eigen::array<int, 2>(1,2)) + + input(Eigen::array<int, 4>(i,j+2,k+2,l)) * kernel(Eigen::array<int, 2>(2,2)) + + input(Eigen::array<int, 4>(i,j+0,k+3,l)) * kernel(Eigen::array<int, 2>(0,3)) + + input(Eigen::array<int, 4>(i,j+1,k+3,l)) * kernel(Eigen::array<int, 2>(1,3)) + + input(Eigen::array<int, 4>(i,j+2,k+3,l)) * kernel(Eigen::array<int, 2>(2,3)); + VERIFY_IS_APPROX(result, expected); + } + } + } + } +} + + +static void test_cuda_convolution_3d() +{ + Tensor<float, 5> input(Eigen::array<int, 5>(74,37,11,137,17)); + Tensor<float, 3> kernel(Eigen::array<int, 3>(3,4,2)); + Tensor<float, 5> out(Eigen::array<int, 5>(74,35,8,136,17)); + input = input.constant(10.0f) + input.random(); + kernel = kernel.constant(7.0f) + kernel.random(); + + std::size_t input_bytes = input.size() * sizeof(float); + std::size_t kernel_bytes = kernel.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_input; + float* d_kernel; + float* d_out; + cudaMalloc((void**)(&d_input), input_bytes); + cudaMalloc((void**)(&d_kernel), kernel_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_input, input.data(), input_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_kernel, kernel.data(), kernel_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<float, 5> > gpu_input(d_input, Eigen::array<int, 5>(74,37,11,137,17)); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_kernel(d_kernel, Eigen::array<int, 3>(3,4,2)); + Eigen::TensorMap<Eigen::Tensor<float, 5> > gpu_out(d_out, Eigen::array<int, 5>(74,35,8,136,17)); + + Eigen::array<int, 3> dims(1,2,3); + gpu_out.device(gpu_device) = gpu_input.convolve(gpu_kernel, dims); + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 74; ++i) { + for (int j = 0; j < 35; ++j) { + for (int k = 0; k < 8; ++k) { + for (int l = 0; l < 136; ++l) { + for (int m = 0; m < 17; ++m) { + const float result = out(Eigen::array<int, 5>(i,j,k,l,m)); + const float expected = input(Eigen::array<int, 5>(i,j+0,k+0,l+0,m)) * kernel(Eigen::array<int, 3>(0,0,0)) + + input(Eigen::array<int, 5>(i,j+1,k+0,l+0,m)) * kernel(Eigen::array<int, 3>(1,0,0)) + + input(Eigen::array<int, 5>(i,j+2,k+0,l+0,m)) * kernel(Eigen::array<int, 3>(2,0,0)) + + input(Eigen::array<int, 5>(i,j+0,k+1,l+0,m)) * kernel(Eigen::array<int, 3>(0,1,0)) + + input(Eigen::array<int, 5>(i,j+1,k+1,l+0,m)) * kernel(Eigen::array<int, 3>(1,1,0)) + + input(Eigen::array<int, 5>(i,j+2,k+1,l+0,m)) * kernel(Eigen::array<int, 3>(2,1,0)) + + input(Eigen::array<int, 5>(i,j+0,k+2,l+0,m)) * kernel(Eigen::array<int, 3>(0,2,0)) + + input(Eigen::array<int, 5>(i,j+1,k+2,l+0,m)) * kernel(Eigen::array<int, 3>(1,2,0)) + + input(Eigen::array<int, 5>(i,j+2,k+2,l+0,m)) * kernel(Eigen::array<int, 3>(2,2,0)) + + input(Eigen::array<int, 5>(i,j+0,k+3,l+0,m)) * kernel(Eigen::array<int, 3>(0,3,0)) + + input(Eigen::array<int, 5>(i,j+1,k+3,l+0,m)) * kernel(Eigen::array<int, 3>(1,3,0)) + + input(Eigen::array<int, 5>(i,j+2,k+3,l+0,m)) * kernel(Eigen::array<int, 3>(2,3,0)) + + input(Eigen::array<int, 5>(i,j+0,k+0,l+1,m)) * kernel(Eigen::array<int, 3>(0,0,1)) + + input(Eigen::array<int, 5>(i,j+1,k+0,l+1,m)) * kernel(Eigen::array<int, 3>(1,0,1)) + + input(Eigen::array<int, 5>(i,j+2,k+0,l+1,m)) * kernel(Eigen::array<int, 3>(2,0,1)) + + input(Eigen::array<int, 5>(i,j+0,k+1,l+1,m)) * kernel(Eigen::array<int, 3>(0,1,1)) + + input(Eigen::array<int, 5>(i,j+1,k+1,l+1,m)) * kernel(Eigen::array<int, 3>(1,1,1)) + + input(Eigen::array<int, 5>(i,j+2,k+1,l+1,m)) * kernel(Eigen::array<int, 3>(2,1,1)) + + input(Eigen::array<int, 5>(i,j+0,k+2,l+1,m)) * kernel(Eigen::array<int, 3>(0,2,1)) + + input(Eigen::array<int, 5>(i,j+1,k+2,l+1,m)) * kernel(Eigen::array<int, 3>(1,2,1)) + + input(Eigen::array<int, 5>(i,j+2,k+2,l+1,m)) * kernel(Eigen::array<int, 3>(2,2,1)) + + input(Eigen::array<int, 5>(i,j+0,k+3,l+1,m)) * kernel(Eigen::array<int, 3>(0,3,1)) + + input(Eigen::array<int, 5>(i,j+1,k+3,l+1,m)) * kernel(Eigen::array<int, 3>(1,3,1)) + + input(Eigen::array<int, 5>(i,j+2,k+3,l+1,m)) * kernel(Eigen::array<int, 3>(2,3,1)); + VERIFY_IS_APPROX(result, expected); + } + } + } + } + } +} + +static float* CudaCopyFloat(float* data, int size) { + const int nbytes = size * sizeof(float); + float* result = NULL; + if (cudaMalloc((void**)(&result), nbytes) != cudaSuccess) { + return NULL; + } else { + if (data != NULL) { + cudaMemcpy(result, data, nbytes, cudaMemcpyHostToDevice); + } + return result; + } +} + +static void test_cuda_constant_broadcast() +{ + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Tensor<float, 1> t1(10); + for (int i = 0; i < 10; ++i) { + t1(i) = 10.0f * i; + } + float* t1_cuda = CudaCopyFloat(t1.data(), t1.size()); + Eigen::TensorMap<Eigen::Tensor<float, 1> > t1_gpu(t1_cuda, 10); + + Tensor<float, 1> t2(1); + t2 = t2.constant(20.0f); + float* t2_cuda = CudaCopyFloat(t2.data(), t2.size()); + Eigen::TensorMap<Eigen::TensorFixedSize<float, Sizes<1> > > t2_gpu(t2_cuda, 1); + + float* t3_cuda = CudaCopyFloat(NULL, 10); + Eigen::TensorMap<Eigen::Tensor<float, 1> > t3_gpu(t3_cuda, 10); + + t3_gpu.device(gpu_device) = + t1_gpu + t2_gpu.broadcast(Eigen::array<int, 1>(10)); + + Eigen::Tensor<float, 1> t3(10); + cudaMemcpy(t3.data(), t3_gpu.data(), 10 * sizeof(float), + cudaMemcpyDeviceToHost); + + for (int i = 0; i < 10; ++i) { + VERIFY_IS_APPROX(t3(i), t1(i) + t2(0)); + } +} + + +void test_cuda_cast() +{ + Tensor<double, 3> in(Eigen::array<int, 3>(72,53,97)); + Tensor<float, 3> out(Eigen::array<int, 3>(72,53,97)); + in.setRandom(); + + std::size_t in_bytes = in.size() * sizeof(double); + std::size_t out_bytes = out.size() * sizeof(float); + + double* d_in; + float* d_out; + cudaMalloc((void**)(&d_in), in_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_in, in.data(), in_bytes, cudaMemcpyHostToDevice); + + cudaStream_t stream; + assert(cudaStreamCreate(&stream) == cudaSuccess); + Eigen::GpuDevice gpu_device(&stream); + + Eigen::TensorMap<Eigen::Tensor<double, 3> > gpu_in(d_in, Eigen::array<int, 3>(72,53,97)); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_out(d_out, Eigen::array<int, 3>(72,53,97)); + + gpu_out.device(gpu_device) = gpu_in.template cast<float>(); + + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess); + assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 53; ++j) { + for (int k = 0; k < 97; ++k) { + VERIFY_IS_APPROX(out(Eigen::array<int, 3>(i,j,k)), static_cast<float>(in(Eigen::array<int, 3>(i,j,k)))); + } + } + } +} + + +void test_cxx11_tensor_cuda() +{ + CALL_SUBTEST(test_cuda_elementwise_small()); + CALL_SUBTEST(test_cuda_elementwise()); + CALL_SUBTEST(test_cuda_reduction()); + CALL_SUBTEST(test_cuda_contraction<ColMajor>()); + CALL_SUBTEST(test_cuda_contraction<RowMajor>()); + CALL_SUBTEST(test_cuda_convolution_1d()); + CALL_SUBTEST(test_cuda_convolution_2d()); + CALL_SUBTEST(test_cuda_convolution_3d()); + CALL_SUBTEST(test_cuda_constant_broadcast()); + CALL_SUBTEST(test_cuda_cast()); +} diff --git a/unsupported/test/cxx11_tensor_device.cpp b/unsupported/test/cxx11_tensor_device.cpp new file mode 100644 index 000000000..f2d7e4ce6 --- /dev/null +++ b/unsupported/test/cxx11_tensor_device.cpp @@ -0,0 +1,391 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#define EIGEN_TEST_NO_LONGDOUBLE +#define EIGEN_TEST_NO_COMPLEX +#define EIGEN_TEST_FUNC cxx11_tensor_device +#define EIGEN_DEFAULT_DENSE_INDEX_TYPE int +#define EIGEN_USE_GPU + + +#include "main.h" +#include <unsupported/Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +// Context for evaluation on cpu +struct CPUContext { + CPUContext(const Eigen::Tensor<float, 3>& in1, Eigen::Tensor<float, 3>& in2, Eigen::Tensor<float, 3>& out) : in1_(in1), in2_(in2), out_(out), kernel_1d_(2), kernel_2d_(2,2), kernel_3d_(2,2,2) { + kernel_1d_(0) = 3.14f; + kernel_1d_(1) = 2.7f; + + kernel_2d_(0,0) = 3.14f; + kernel_2d_(1,0) = 2.7f; + kernel_2d_(0,1) = 0.2f; + kernel_2d_(1,1) = 7.0f; + + kernel_3d_(0,0,0) = 3.14f; + kernel_3d_(0,1,0) = 2.7f; + kernel_3d_(0,0,1) = 0.2f; + kernel_3d_(0,1,1) = 7.0f; + kernel_3d_(1,0,0) = -1.0f; + kernel_3d_(1,1,0) = -0.3f; + kernel_3d_(1,0,1) = -0.7f; + kernel_3d_(1,1,1) = -0.5f; + } + + const Eigen::DefaultDevice& device() const { return cpu_device_; } + + const Eigen::Tensor<float, 3>& in1() const { return in1_; } + const Eigen::Tensor<float, 3>& in2() const { return in2_; } + Eigen::Tensor<float, 3>& out() { return out_; } + const Eigen::Tensor<float, 1>& kernel1d() const { return kernel_1d_; } + const Eigen::Tensor<float, 2>& kernel2d() const { return kernel_2d_; } + const Eigen::Tensor<float, 3>& kernel3d() const { return kernel_3d_; } + + private: + const Eigen::Tensor<float, 3>& in1_; + const Eigen::Tensor<float, 3>& in2_; + Eigen::Tensor<float, 3>& out_; + + Eigen::Tensor<float, 1> kernel_1d_; + Eigen::Tensor<float, 2> kernel_2d_; + Eigen::Tensor<float, 3> kernel_3d_; + + Eigen::DefaultDevice cpu_device_; +}; + + +// Context for evaluation on GPU +struct GPUContext { + GPUContext(const Eigen::TensorMap<Eigen::Tensor<float, 3> >& in1, Eigen::TensorMap<Eigen::Tensor<float, 3> >& in2, Eigen::TensorMap<Eigen::Tensor<float, 3> >& out) : in1_(in1), in2_(in2), out_(out), gpu_device_(&stream_) { + assert(cudaMalloc((void**)(&kernel_1d_), 2*sizeof(float)) == cudaSuccess); + float kernel_1d_val[] = {3.14f, 2.7f}; + assert(cudaMemcpy(kernel_1d_, kernel_1d_val, 2*sizeof(float), cudaMemcpyHostToDevice) == cudaSuccess); + + assert(cudaMalloc((void**)(&kernel_2d_), 4*sizeof(float)) == cudaSuccess); + float kernel_2d_val[] = {3.14f, 2.7f, 0.2f, 7.0f}; + assert(cudaMemcpy(kernel_2d_, kernel_2d_val, 4*sizeof(float), cudaMemcpyHostToDevice) == cudaSuccess); + + assert(cudaMalloc((void**)(&kernel_3d_), 8*sizeof(float)) == cudaSuccess); + float kernel_3d_val[] = {3.14f, -1.0f, 2.7f, -0.3f, 0.2f, -0.7f, 7.0f, -0.5f}; + assert(cudaMemcpy(kernel_3d_, kernel_3d_val, 8*sizeof(float), cudaMemcpyHostToDevice) == cudaSuccess); + + assert(cudaStreamCreate(&stream_) == cudaSuccess); + } + ~GPUContext() { + assert(cudaFree(kernel_1d_) == cudaSuccess); + assert(cudaFree(kernel_2d_) == cudaSuccess); + assert(cudaFree(kernel_3d_) == cudaSuccess); + assert(cudaStreamDestroy(stream_) == cudaSuccess); + } + + const Eigen::GpuDevice& device() const { return gpu_device_; } + + const Eigen::TensorMap<Eigen::Tensor<float, 3> >& in1() const { return in1_; } + const Eigen::TensorMap<Eigen::Tensor<float, 3> >& in2() const { return in2_; } + Eigen::TensorMap<Eigen::Tensor<float, 3> >& out() { return out_; } + Eigen::TensorMap<Eigen::Tensor<float, 1> > kernel1d() const { return Eigen::TensorMap<Eigen::Tensor<float, 1> >(kernel_1d_, 2); } + Eigen::TensorMap<Eigen::Tensor<float, 2> > kernel2d() const { return Eigen::TensorMap<Eigen::Tensor<float, 2> >(kernel_2d_, 2, 2); } + Eigen::TensorMap<Eigen::Tensor<float, 3> > kernel3d() const { return Eigen::TensorMap<Eigen::Tensor<float, 3> >(kernel_3d_, 2, 2, 2); } + + private: + const Eigen::TensorMap<Eigen::Tensor<float, 3> >& in1_; + const Eigen::TensorMap<Eigen::Tensor<float, 3> >& in2_; + Eigen::TensorMap<Eigen::Tensor<float, 3> >& out_; + + float* kernel_1d_; + float* kernel_2d_; + float* kernel_3d_; + + cudaStream_t stream_; + Eigen::GpuDevice gpu_device_; +}; + + +// The actual expression to evaluate +template <typename Context> +static void test_contextual_eval(Context* context) +{ + context->out().device(context->device()) = context->in1() + context->in2() * 3.14f + context->in1().constant(2.718f); +} + +template <typename Context> +static void test_forced_contextual_eval(Context* context) +{ + context->out().device(context->device()) = (context->in1() + context->in2()).eval() * 3.14f + context->in1().constant(2.718f); +} + +template <typename Context> +static void test_compound_assignment(Context* context) +{ + context->out().device(context->device()) = context->in1().constant(2.718f); + context->out().device(context->device()) += context->in1() + context->in2() * 3.14f; +} + + +template <typename Context> +static void test_contraction(Context* context) +{ + Eigen::array<std::pair<int, int>, 2> dims; + dims[0] = std::make_pair(1, 1); + dims[1] = std::make_pair(2, 2); + + Eigen::array<int, 2> shape(40, 50*70); + + Eigen::DSizes<int, 2> indices(0,0); + Eigen::DSizes<int, 2> sizes(40,40); + + context->out().reshape(shape).slice(indices, sizes).device(context->device()) = context->in1().contract(context->in2(), dims); +} + + +template <typename Context> +static void test_1d_convolution(Context* context) +{ + Eigen::DSizes<int, 3> indices(0,0,0); + Eigen::DSizes<int, 3> sizes(40,49,70); + + Eigen::array<int, 1> dims(1); + context->out().slice(indices, sizes).device(context->device()) = context->in1().convolve(context->kernel1d(), dims); +} + +template <typename Context> +static void test_2d_convolution(Context* context) +{ + Eigen::DSizes<int, 3> indices(0,0,0); + Eigen::DSizes<int, 3> sizes(40,49,69); + + Eigen::array<int, 2> dims(1,2); + context->out().slice(indices, sizes).device(context->device()) = context->in1().convolve(context->kernel2d(), dims); +} + +template <typename Context> +static void test_3d_convolution(Context* context) +{ + Eigen::DSizes<int, 3> indices(0,0,0); + Eigen::DSizes<int, 3> sizes(39,49,69); + + Eigen::array<int, 3> dims(0,1,2); + context->out().slice(indices, sizes).device(context->device()) = context->in1().convolve(context->kernel3d(), dims); +} + + +static void test_cpu() { + Eigen::Tensor<float, 3> in1(40,50,70); + Eigen::Tensor<float, 3> in2(40,50,70); + Eigen::Tensor<float, 3> out(40,50,70); + + in1 = in1.random() + in1.constant(10.0f); + in2 = in2.random() + in2.constant(10.0f); + + CPUContext context(in1, in2, out); + test_contextual_eval(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f + 2.718f); + } + } + } + + test_forced_contextual_eval(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), (in1(i,j,k) + in2(i,j,k)) * 3.14f + 2.718f); + } + } + } + + test_compound_assignment(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f + 2.718f); + } + } + } + + test_contraction(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 40; ++j) { + const float result = out(i,j,0); + float expected = 0; + for (int k = 0; k < 50; ++k) { + for (int l = 0; l < 70; ++l) { + expected += in1(i, k, l) * in2(j, k, l); + } + } + VERIFY_IS_APPROX(expected, result); + } + } + + test_1d_convolution(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f)); + } + } + } + + test_2d_convolution(&context); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 69; ++k) { + const float result = out(i,j,k); + const float expected = (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f) + + (in1(i,j,k+1) * 0.2f + in1(i,j+1,k+1) * 7.0f); + if (fabs(expected) < 1e-4 && fabs(result) < 1e-4) { + continue; + } + VERIFY_IS_APPROX(expected, result); + } + } + } + + test_3d_convolution(&context); + for (int i = 0; i < 39; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 69; ++k) { + const float result = out(i,j,k); + const float expected = (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f + + in1(i,j,k+1) * 0.2f + in1(i,j+1,k+1) * 7.0f) + + (in1(i+1,j,k) * -1.0f + in1(i+1,j+1,k) * -0.3f + + in1(i+1,j,k+1) * -0.7f + in1(i+1,j+1,k+1) * -0.5f); + if (fabs(expected) < 1e-4 && fabs(result) < 1e-4) { + continue; + } + VERIFY_IS_APPROX(expected, result); + } + } + } +} + +static void test_gpu() { + Eigen::Tensor<float, 3> in1(40,50,70); + Eigen::Tensor<float, 3> in2(40,50,70); + Eigen::Tensor<float, 3> out(40,50,70); + in1 = in1.random() + in1.constant(10.0f); + in2 = in2.random() + in2.constant(10.0f); + + std::size_t in1_bytes = in1.size() * sizeof(float); + std::size_t in2_bytes = in2.size() * sizeof(float); + std::size_t out_bytes = out.size() * sizeof(float); + + float* d_in1; + float* d_in2; + float* d_out; + cudaMalloc((void**)(&d_in1), in1_bytes); + cudaMalloc((void**)(&d_in2), in2_bytes); + cudaMalloc((void**)(&d_out), out_bytes); + + cudaMemcpy(d_in1, in1.data(), in1_bytes, cudaMemcpyHostToDevice); + cudaMemcpy(d_in2, in2.data(), in2_bytes, cudaMemcpyHostToDevice); + + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_in1(d_in1, 40,50,70); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_in2(d_in2, 40,50,70); + Eigen::TensorMap<Eigen::Tensor<float, 3> > gpu_out(d_out, 40,50,70); + + GPUContext context(gpu_in1, gpu_in2, gpu_out); + test_contextual_eval(&context); + assert(cudaMemcpy(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f + 2.718f); + } + } + } + + test_forced_contextual_eval(&context); + assert(cudaMemcpy(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), (in1(i,j,k) + in2(i,j,k)) * 3.14f + 2.718f); + } + } + } + + test_compound_assignment(&context); + assert(cudaMemcpy(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 50; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f + 2.718f); + } + } + } + + test_contraction(&context); + assert(cudaMemcpy(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 40; ++j) { + const float result = out(i,j,0); + float expected = 0; + for (int k = 0; k < 50; ++k) { + for (int l = 0; l < 70; ++l) { + expected += in1(i, k, l) * in2(j, k, l); + } + } + VERIFY_IS_APPROX(expected, result); + } + } + + test_1d_convolution(&context); + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, context.device().stream()) == cudaSuccess); + assert(cudaStreamSynchronize(context.device().stream()) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 70; ++k) { + VERIFY_IS_APPROX(out(i,j,k), (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f)); + } + } + } + + test_2d_convolution(&context); + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, context.device().stream()) == cudaSuccess); + assert(cudaStreamSynchronize(context.device().stream()) == cudaSuccess); + for (int i = 0; i < 40; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 69; ++k) { + const float result = out(i,j,k); + const float expected = (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f + + in1(i,j,k+1) * 0.2f + in1(i,j+1,k+1) * 7.0f); + VERIFY_IS_APPROX(expected, result); + } + } + } + + test_3d_convolution(&context); + assert(cudaMemcpyAsync(out.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, context.device().stream()) == cudaSuccess); + assert(cudaStreamSynchronize(context.device().stream()) == cudaSuccess); + for (int i = 0; i < 39; ++i) { + for (int j = 0; j < 49; ++j) { + for (int k = 0; k < 69; ++k) { + const float result = out(i,j,k); + const float expected = (in1(i,j,k) * 3.14f + in1(i,j+1,k) * 2.7f + + in1(i,j,k+1) * 0.2f + in1(i,j+1,k+1) * 7.0f + + in1(i+1,j,k) * -1.0f + in1(i+1,j+1,k) * -0.3f + + in1(i+1,j,k+1) * -0.7f + in1(i+1,j+1,k+1) * -0.5f); + VERIFY_IS_APPROX(expected, result); + } + } + } +} + + +void test_cxx11_tensor_device() +{ + CALL_SUBTEST(test_cpu()); + CALL_SUBTEST(test_gpu()); +} diff --git a/unsupported/test/cxx11_tensor_dimension.cpp b/unsupported/test/cxx11_tensor_dimension.cpp new file mode 100644 index 000000000..0cc4e86f7 --- /dev/null +++ b/unsupported/test/cxx11_tensor_dimension.cpp @@ -0,0 +1,54 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + + +static void test_dynamic_size() +{ + Eigen::DSizes<int, 3> dimensions(2,3,7); + + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<0>(dimensions), 2); + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<1>(dimensions), 3); + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<2>(dimensions), 7); + VERIFY_IS_EQUAL(dimensions.TotalSize(), (size_t)2*3*7); + VERIFY_IS_EQUAL((int)dimensions[0], 2); + VERIFY_IS_EQUAL((int)dimensions[1], 3); + VERIFY_IS_EQUAL((int)dimensions[2], 7); +} + +static void test_fixed_size() +{ + Eigen::Sizes<2,3,7> dimensions; + + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<0>(dimensions), 2); + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<1>(dimensions), 3); + VERIFY_IS_EQUAL((int)Eigen::internal::array_get<2>(dimensions), 7); + VERIFY_IS_EQUAL(dimensions.TotalSize(), (size_t)2*3*7); +} + + +static void test_match() +{ + Eigen::DSizes<int, 3> dyn(2,3,7); + Eigen::Sizes<2,3,7> stat; + VERIFY_IS_EQUAL(Eigen::dimensions_match(dyn, stat), true); +} + + +void test_cxx11_tensor_dimension() +{ + CALL_SUBTEST(test_dynamic_size()); + CALL_SUBTEST(test_fixed_size()); + CALL_SUBTEST(test_match()); +} diff --git a/unsupported/test/cxx11_tensor_expr.cpp b/unsupported/test/cxx11_tensor_expr.cpp new file mode 100644 index 000000000..695565e9b --- /dev/null +++ b/unsupported/test/cxx11_tensor_expr.cpp @@ -0,0 +1,314 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_1d() +{ + Tensor<float, 1> vec1({6}); + Tensor<float, 1, RowMajor> vec2({6}); + + vec1(0) = 4.0; vec2(0) = 0.0; + vec1(1) = 8.0; vec2(1) = 1.0; + vec1(2) = 15.0; vec2(2) = 2.0; + vec1(3) = 16.0; vec2(3) = 3.0; + vec1(4) = 23.0; vec2(4) = 4.0; + vec1(5) = 42.0; vec2(5) = 5.0; + + float data3[6]; + TensorMap<Tensor<float, 1>> vec3(data3, 6); + vec3 = vec1.sqrt(); + float data4[6]; + TensorMap<Tensor<float, 1, RowMajor>> vec4(data4, 6); + vec4 = vec2.square(); + float data5[6]; + TensorMap<Tensor<float, 1, RowMajor>> vec5(data5, 6); + vec5 = vec2.cube(); + + VERIFY_IS_APPROX(vec3(0), sqrtf(4.0)); + VERIFY_IS_APPROX(vec3(1), sqrtf(8.0)); + VERIFY_IS_APPROX(vec3(2), sqrtf(15.0)); + VERIFY_IS_APPROX(vec3(3), sqrtf(16.0)); + VERIFY_IS_APPROX(vec3(4), sqrtf(23.0)); + VERIFY_IS_APPROX(vec3(5), sqrtf(42.0)); + + VERIFY_IS_APPROX(vec4(0), 0.0f); + VERIFY_IS_APPROX(vec4(1), 1.0f); + VERIFY_IS_APPROX(vec4(2), 2.0f * 2.0f); + VERIFY_IS_APPROX(vec4(3), 3.0f * 3.0f); + VERIFY_IS_APPROX(vec4(4), 4.0f * 4.0f); + VERIFY_IS_APPROX(vec4(5), 5.0f * 5.0f); + + VERIFY_IS_APPROX(vec5(0), 0.0f); + VERIFY_IS_APPROX(vec5(1), 1.0f); + VERIFY_IS_APPROX(vec5(2), 2.0f * 2.0f * 2.0f); + VERIFY_IS_APPROX(vec5(3), 3.0f * 3.0f * 3.0f); + VERIFY_IS_APPROX(vec5(4), 4.0f * 4.0f * 4.0f); + VERIFY_IS_APPROX(vec5(5), 5.0f * 5.0f * 5.0f); + + vec3 = vec1 + vec2; + VERIFY_IS_APPROX(vec3(0), 4.0f + 0.0f); + VERIFY_IS_APPROX(vec3(1), 8.0f + 1.0f); + VERIFY_IS_APPROX(vec3(2), 15.0f + 2.0f); + VERIFY_IS_APPROX(vec3(3), 16.0f + 3.0f); + VERIFY_IS_APPROX(vec3(4), 23.0f + 4.0f); + VERIFY_IS_APPROX(vec3(5), 42.0f + 5.0f); +} + +static void test_2d() +{ + float data1[6]; + TensorMap<Tensor<float, 2>> mat1(data1, 2, 3); + float data2[6]; + TensorMap<Tensor<float, 2, RowMajor>> mat2(data2, 2, 3); + + mat1(0,0) = 0.0; + mat1(0,1) = 1.0; + mat1(0,2) = 2.0; + mat1(1,0) = 3.0; + mat1(1,1) = 4.0; + mat1(1,2) = 5.0; + + mat2(0,0) = -0.0; + mat2(0,1) = -1.0; + mat2(0,2) = -2.0; + mat2(1,0) = -3.0; + mat2(1,1) = -4.0; + mat2(1,2) = -5.0; + + Tensor<float, 2> mat3(2,3); + Tensor<float, 2, RowMajor> mat4(2,3); + mat3 = mat1.abs(); + mat4 = mat2.abs(); + + VERIFY_IS_APPROX(mat3(0,0), 0.0f); + VERIFY_IS_APPROX(mat3(0,1), 1.0f); + VERIFY_IS_APPROX(mat3(0,2), 2.0f); + VERIFY_IS_APPROX(mat3(1,0), 3.0f); + VERIFY_IS_APPROX(mat3(1,1), 4.0f); + VERIFY_IS_APPROX(mat3(1,2), 5.0f); + + VERIFY_IS_APPROX(mat4(0,0), 0.0f); + VERIFY_IS_APPROX(mat4(0,1), 1.0f); + VERIFY_IS_APPROX(mat4(0,2), 2.0f); + VERIFY_IS_APPROX(mat4(1,0), 3.0f); + VERIFY_IS_APPROX(mat4(1,1), 4.0f); + VERIFY_IS_APPROX(mat4(1,2), 5.0f); +} + +static void test_3d() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3, RowMajor> mat2(2,3,7); + + float val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + mat2(i,j,k) = val; + val += 1.0; + } + } + } + + Tensor<float, 3> mat3(2,3,7); + mat3 = mat1 + mat1; + Tensor<float, 3, RowMajor> mat4(2,3,7); + mat4 = mat2 * 3.14f; + Tensor<float, 3> mat5(2,3,7); + mat5 = mat1.inverse().log(); + Tensor<float, 3, RowMajor> mat6(2,3,7); + mat6 = mat2.pow(0.5f) * 3.14f; + Tensor<float, 3> mat7(2,3,7); + mat7 = mat1.cwiseMax(mat5 * 2.0f).exp(); + Tensor<float, 3, RowMajor> mat8(2,3,7); + mat8 = (-mat2).exp() * 3.14f; + Tensor<float, 3, RowMajor> mat9(2,3,7); + mat9 = mat2 + 3.14f; + Tensor<float, 3, RowMajor> mat10(2,3,7); + mat10 = mat2 - 3.14f; + Tensor<float, 3, RowMajor> mat11(2,3,7); + mat11 = mat2 / 3.14f; + + val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), val + val); + VERIFY_IS_APPROX(mat4(i,j,k), val * 3.14f); + VERIFY_IS_APPROX(mat5(i,j,k), logf(1.0f/val)); + VERIFY_IS_APPROX(mat6(i,j,k), sqrtf(val) * 3.14f); + VERIFY_IS_APPROX(mat7(i,j,k), expf((std::max)(val, mat5(i,j,k) * 2.0f))); + VERIFY_IS_APPROX(mat8(i,j,k), expf(-val) * 3.14f); + VERIFY_IS_APPROX(mat9(i,j,k), val + 3.14f); + VERIFY_IS_APPROX(mat10(i,j,k), val - 3.14f); + VERIFY_IS_APPROX(mat11(i,j,k), val / 3.14f); + val += 1.0; + } + } + } +} + +static void test_constants() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<float, 3> mat3(2,3,7); + + float val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + val += 1.0; + } + } + } + mat2 = mat1.constant(3.14f); + mat3 = mat1.cwiseMax(7.3f).exp(); + + val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat2(i,j,k), 3.14f); + VERIFY_IS_APPROX(mat3(i,j,k), expf((std::max)(val, 7.3f))); + val += 1.0; + } + } + } +} + +static void test_boolean() +{ + Tensor<int, 1> vec(6); + std::copy_n(std::begin({0, 1, 2, 3, 4, 5}), 6, vec.data()); + + // Test ||. + Tensor<bool, 1> bool1 = vec < vec.constant(1) || vec > vec.constant(4); + VERIFY_IS_EQUAL(bool1[0], true); + VERIFY_IS_EQUAL(bool1[1], false); + VERIFY_IS_EQUAL(bool1[2], false); + VERIFY_IS_EQUAL(bool1[3], false); + VERIFY_IS_EQUAL(bool1[4], false); + VERIFY_IS_EQUAL(bool1[5], true); + + // Test &&, including cast of operand vec. + Tensor<bool, 1> bool2 = vec.cast<bool>() && vec < vec.constant(4); + VERIFY_IS_EQUAL(bool2[0], false); + VERIFY_IS_EQUAL(bool2[1], true); + VERIFY_IS_EQUAL(bool2[2], true); + VERIFY_IS_EQUAL(bool2[3], true); + VERIFY_IS_EQUAL(bool2[4], false); + VERIFY_IS_EQUAL(bool2[5], false); + + // Compilation tests: + // Test Tensor<bool> against results of cast or comparison; verifies that + // CoeffReturnType is set to match Op return type of bool for Unary and Binary + // Ops. + Tensor<bool, 1> bool3 = vec.cast<bool>() && bool2; + bool3 = vec < vec.constant(4) && bool2; +} + +static void test_functors() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<float, 3> mat3(2,3,7); + + float val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + val += 1.0; + } + } + } + mat2 = mat1.inverse().unaryExpr(&asinf); + mat3 = mat1.unaryExpr(&tanhf); + + val = 1.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat2(i,j,k), asinf(1.0f / mat1(i,j,k))); + VERIFY_IS_APPROX(mat3(i,j,k), tanhf(mat1(i,j,k))); + val += 1.0; + } + } + } +} + +static void test_type_casting() +{ + Tensor<bool, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<double, 3> mat3(2,3,7); + mat1.setRandom(); + mat2.setRandom(); + + mat3 = mat1.template cast<double>(); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), mat1(i,j,k) ? 1.0 : 0.0); + } + } + } + + mat3 = mat2.template cast<double>(); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), static_cast<double>(mat2(i,j,k))); + } + } + } +} + +static void test_select() +{ + Tensor<float, 3> selector(2,3,7); + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<float, 3> result(2,3,7); + + selector.setRandom(); + mat1.setRandom(); + mat2.setRandom(); + result = (selector > selector.constant(0.5f)).select(mat1, mat2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(result(i,j,k), (selector(i,j,k) > 0.5f) ? mat1(i,j,k) : mat2(i,j,k)); + } + } + } +} + + +void test_cxx11_tensor_expr() +{ + CALL_SUBTEST(test_1d()); + CALL_SUBTEST(test_2d()); + CALL_SUBTEST(test_3d()); + CALL_SUBTEST(test_constants()); + CALL_SUBTEST(test_boolean()); + CALL_SUBTEST(test_functors()); + CALL_SUBTEST(test_type_casting()); + CALL_SUBTEST(test_select()); +} diff --git a/unsupported/test/cxx11_tensor_fixed_size.cpp b/unsupported/test/cxx11_tensor_fixed_size.cpp new file mode 100644 index 000000000..8a27f5ad8 --- /dev/null +++ b/unsupported/test/cxx11_tensor_fixed_size.cpp @@ -0,0 +1,198 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + + +static void test_1d() +{ + TensorFixedSize<float, Sizes<6> > vec1; + TensorFixedSize<float, Sizes<6>, RowMajor> vec2; + + VERIFY_IS_EQUAL((vec1.size()), 6); + // VERIFY_IS_EQUAL((vec1.dimensions()[0]), 6); + // VERIFY_IS_EQUAL((vec1.dimension(0)), 6); + + vec1(0) = 4.0; vec2(0) = 0.0; + vec1(1) = 8.0; vec2(1) = 1.0; + vec1(2) = 15.0; vec2(2) = 2.0; + vec1(3) = 16.0; vec2(3) = 3.0; + vec1(4) = 23.0; vec2(4) = 4.0; + vec1(5) = 42.0; vec2(5) = 5.0; + + float data3[6]; + TensorMap<TensorFixedSize<float, Sizes<6> > > vec3(data3, 6); + vec3 = vec1.sqrt(); + float data4[6]; + TensorMap<TensorFixedSize<float, Sizes<6>, RowMajor> > vec4(data4, 6); + vec4 = vec2.sqrt(); + + VERIFY_IS_EQUAL((vec3.size()), 6); + VERIFY_IS_EQUAL(vec3.rank(), 1); + // VERIFY_IS_EQUAL((vec3.dimensions()[0]), 6); + // VERIFY_IS_EQUAL((vec3.dimension(0)), 6); + + VERIFY_IS_APPROX(vec3(0), sqrtf(4.0)); + VERIFY_IS_APPROX(vec3(1), sqrtf(8.0)); + VERIFY_IS_APPROX(vec3(2), sqrtf(15.0)); + VERIFY_IS_APPROX(vec3(3), sqrtf(16.0)); + VERIFY_IS_APPROX(vec3(4), sqrtf(23.0)); + VERIFY_IS_APPROX(vec3(5), sqrtf(42.0)); + + VERIFY_IS_APPROX(vec4(0), sqrtf(0.0)); + VERIFY_IS_APPROX(vec4(1), sqrtf(1.0)); + VERIFY_IS_APPROX(vec4(2), sqrtf(2.0)); + VERIFY_IS_APPROX(vec4(3), sqrtf(3.0)); + VERIFY_IS_APPROX(vec4(4), sqrtf(4.0)); + VERIFY_IS_APPROX(vec4(5), sqrtf(5.0)); + + vec3 = vec1 + vec2; + VERIFY_IS_APPROX(vec3(0), 4.0f + 0.0f); + VERIFY_IS_APPROX(vec3(1), 8.0f + 1.0f); + VERIFY_IS_APPROX(vec3(2), 15.0f + 2.0f); + VERIFY_IS_APPROX(vec3(3), 16.0f + 3.0f); + VERIFY_IS_APPROX(vec3(4), 23.0f + 4.0f); + VERIFY_IS_APPROX(vec3(5), 42.0f + 5.0f); +} + +static void test_2d() +{ + float data1[6]; + TensorMap<TensorFixedSize<float, Sizes<2, 3> >> mat1(data1,2,3); + float data2[6]; + TensorMap<TensorFixedSize<float, Sizes<2, 3>, RowMajor>> mat2(data2,2,3); + + VERIFY_IS_EQUAL((mat1.size()), 2*3); + VERIFY_IS_EQUAL(mat1.rank(), 2); + // VERIFY_IS_EQUAL((mat1.dimension(0)), 2); + // VERIFY_IS_EQUAL((mat1.dimension(1)), 3); + + mat1(0,0) = 0.0; + mat1(0,1) = 1.0; + mat1(0,2) = 2.0; + mat1(1,0) = 3.0; + mat1(1,1) = 4.0; + mat1(1,2) = 5.0; + + mat2(0,0) = -0.0; + mat2(0,1) = -1.0; + mat2(0,2) = -2.0; + mat2(1,0) = -3.0; + mat2(1,1) = -4.0; + mat2(1,2) = -5.0; + + TensorFixedSize<float, Sizes<2, 3>> mat3; + TensorFixedSize<float, Sizes<2, 3>, RowMajor> mat4; + mat3 = mat1.abs(); + mat4 = mat2.abs(); + + VERIFY_IS_EQUAL((mat3.size()), 2*3); + // VERIFY_IS_EQUAL((mat3.dimension(0)), 2); + // VERIFY_IS_EQUAL((mat3.dimension(1)), 3); + + VERIFY_IS_APPROX(mat3(0,0), 0.0f); + VERIFY_IS_APPROX(mat3(0,1), 1.0f); + VERIFY_IS_APPROX(mat3(0,2), 2.0f); + VERIFY_IS_APPROX(mat3(1,0), 3.0f); + VERIFY_IS_APPROX(mat3(1,1), 4.0f); + VERIFY_IS_APPROX(mat3(1,2), 5.0f); + + VERIFY_IS_APPROX(mat4(0,0), 0.0f); + VERIFY_IS_APPROX(mat4(0,1), 1.0f); + VERIFY_IS_APPROX(mat4(0,2), 2.0f); + VERIFY_IS_APPROX(mat4(1,0), 3.0f); + VERIFY_IS_APPROX(mat4(1,1), 4.0f); + VERIFY_IS_APPROX(mat4(1,2), 5.0f); +} + +static void test_3d() +{ + TensorFixedSize<float, Sizes<2, 3, 7> > mat1; + TensorFixedSize<float, Sizes<2, 3, 7>, RowMajor> mat2; + + VERIFY_IS_EQUAL((mat1.size()), 2*3*7); + VERIFY_IS_EQUAL(mat1.rank(), 3); + // VERIFY_IS_EQUAL((mat1.dimension(0)), 2); + // VERIFY_IS_EQUAL((mat1.dimension(1)), 3); + // VERIFY_IS_EQUAL((mat1.dimension(2)), 7); + + float val = 0.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + mat2(i,j,k) = val; + val += 1.0; + } + } + } + + TensorFixedSize<float, Sizes<2, 3, 7> > mat3; + mat3 = mat1.sqrt(); + TensorFixedSize<float, Sizes<2, 3, 7>, RowMajor> mat4; + mat4 = mat2.sqrt(); + + VERIFY_IS_EQUAL((mat3.size()), 2*3*7); + // VERIFY_IS_EQUAL((mat3.dimension(0)), 2); + // VERIFY_IS_EQUAL((mat3.dimension(1)), 3); + // VERIFY_IS_EQUAL((mat3.dimension(2)), 7); + + + val = 0.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), sqrtf(val)); + VERIFY_IS_APPROX(mat4(i,j,k), sqrtf(val)); + val += 1.0; + } + } + } +} + + +static void test_array() +{ + TensorFixedSize<float, Sizes<2, 3, 7> > mat1; + float val = 0.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + val += 1.0; + } + } + } + + TensorFixedSize<float, Sizes<2, 3, 7> > mat3; + mat3 = mat1.pow(3.5f); + + val = 0.0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), powf(val, 3.5f)); + val += 1.0; + } + } + } +} + +void test_cxx11_tensor_fixed_size() +{ + CALL_SUBTEST(test_1d()); + CALL_SUBTEST(test_2d()); + CALL_SUBTEST(test_3d()); + CALL_SUBTEST(test_array()); +} diff --git a/unsupported/test/cxx11_tensor_forced_eval.cpp b/unsupported/test/cxx11_tensor_forced_eval.cpp new file mode 100644 index 000000000..ad9de867d --- /dev/null +++ b/unsupported/test/cxx11_tensor_forced_eval.cpp @@ -0,0 +1,78 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/Core> +#include <Eigen/CXX11/Tensor> + +using Eigen::MatrixXf; +using Eigen::Tensor; + +static void test_simple() +{ + MatrixXf m1(3,3); + MatrixXf m2(3,3); + m1.setRandom(); + m2.setRandom(); + + TensorMap<Tensor<float, 2>> mat1(m1.data(), 3,3); + TensorMap<Tensor<float, 2>> mat2(m2.data(), 3,3); + + Tensor<float, 2> mat3(3,3); + mat3 = mat1; + + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 1> dims({{DimPair(1, 0)}}); + + mat3 = mat3.contract(mat2, dims).eval(); + + VERIFY_IS_APPROX(mat3(0, 0), (m1*m2).eval()(0,0)); + VERIFY_IS_APPROX(mat3(0, 1), (m1*m2).eval()(0,1)); + VERIFY_IS_APPROX(mat3(0, 2), (m1*m2).eval()(0,2)); + VERIFY_IS_APPROX(mat3(1, 0), (m1*m2).eval()(1,0)); + VERIFY_IS_APPROX(mat3(1, 1), (m1*m2).eval()(1,1)); + VERIFY_IS_APPROX(mat3(1, 2), (m1*m2).eval()(1,2)); + VERIFY_IS_APPROX(mat3(2, 0), (m1*m2).eval()(2,0)); + VERIFY_IS_APPROX(mat3(2, 1), (m1*m2).eval()(2,1)); + VERIFY_IS_APPROX(mat3(2, 2), (m1*m2).eval()(2,2)); +} + + +static void test_const() +{ + MatrixXf input(3,3); + input.setRandom(); + MatrixXf output = input; + output.rowwise() -= input.colwise().maxCoeff(); + + Eigen::array<int, 1> depth_dim; + depth_dim[0] = 0; + Tensor<float, 2>::Dimensions dims2d; + dims2d[0] = 1; + dims2d[1] = 3; + Eigen::array<int, 2> bcast; + bcast[0] = 3; + bcast[1] = 1; + const TensorMap<Tensor<const float, 2>> input_tensor(input.data(), 3, 3); + Tensor<float, 2> output_tensor= (input_tensor - input_tensor.maximum(depth_dim).eval().reshape(dims2d).broadcast(bcast)); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_APPROX(output(i, j), output_tensor(i, j)); + } + } +} + + +void test_cxx11_tensor_forced_eval() +{ + CALL_SUBTEST(test_simple()); + CALL_SUBTEST(test_const()); +} diff --git a/unsupported/test/cxx11_tensor_image_patch.cpp b/unsupported/test/cxx11_tensor_image_patch.cpp new file mode 100644 index 000000000..26854f5a4 --- /dev/null +++ b/unsupported/test/cxx11_tensor_image_patch.cpp @@ -0,0 +1,476 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +static void test_simple_patch() +{ + Tensor<float, 4> tensor(2,3,5,7); + tensor.setRandom(); + + Tensor<float, 5> single_pixel_patch; + single_pixel_patch = tensor.extract_image_patches<1, 1>(); + + VERIFY_IS_EQUAL(single_pixel_patch.dimension(0), 2); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(1), 1); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(2), 1); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(3), 3*5); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(4), 7); + + for (int i = 0; i < tensor.size(); ++i) { + if (tensor.data()[i] != single_pixel_patch.data()[i]) { + std::cout << "Mismatch detected at index " << i << " : " << tensor.data()[i] << " vs " << single_pixel_patch.data()[i] << std::endl; + } + VERIFY_IS_EQUAL(single_pixel_patch.data()[i], tensor.data()[i]); + } + + Tensor<float, 5> entire_image_patch; + entire_image_patch = tensor.extract_image_patches<3, 5>(); + + VERIFY_IS_EQUAL(entire_image_patch.dimension(0), 2); + VERIFY_IS_EQUAL(entire_image_patch.dimension(1), 3); + VERIFY_IS_EQUAL(entire_image_patch.dimension(2), 5); + VERIFY_IS_EQUAL(entire_image_patch.dimension(3), 3*5); + VERIFY_IS_EQUAL(entire_image_patch.dimension(4), 7); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + int patchId = i+3*j; + for (int r = 0; r < 3; ++r) { + for (int c = 0; c < 5; ++c) { + for (int d = 0; d < 2; ++d) { + for (int b = 0; b < 7; ++b) { + float expected = 0.0f; + if (r-1+i >= 0 && c-2+j >= 0 && r-1+i < 3 && c-2+j < 5) { + expected = tensor(d, r-1+i, c-2+j, b); + } + if (entire_image_patch(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(entire_image_patch(d, r, c, patchId, b), expected); + } + } + } + } + } + } + + Tensor<float, 5> twod_patch; + twod_patch = tensor.extract_image_patches<2, 2>(); + + VERIFY_IS_EQUAL(twod_patch.dimension(0), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(1), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(2), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(3), 3*5); + VERIFY_IS_EQUAL(twod_patch.dimension(4), 7); + + // Based on the calculation described in TensorTraits.h, padding happens to be 0. + int row_padding = 0; + int col_padding = 0; + int stride = 1; + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + int patchId = i+3*j; + for (int r = 0; r < 2; ++r) { + for (int c = 0; c < 2; ++c) { + for (int d = 0; d < 2; ++d) { + for (int b = 0; b < 7; ++b) { + float expected = 0.0f; + int row_offset = r*stride + i - row_padding; + int col_offset = c*stride + j - col_padding; + if (row_offset >= 0 && col_offset >= 0 && row_offset < tensor.dimension(1) && col_offset < tensor.dimension(2)) { + expected = tensor(d, row_offset, col_offset, b); + } + if (twod_patch(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(twod_patch(d, r, c, patchId, b), expected); + } + } + } + } + } + } +} + +// Verifies VALID padding (no padding) with incrementing values. +static void test_patch_padding_valid() +{ + int input_depth = 3; + int input_rows = 3; + int input_cols = 3; + int input_batches = 1; + int ksize = 2; // Corresponds to the Rows and Cols for tensor.extract_image_patches<>. + int stride = 2; // Only same stride is supported. + Tensor<float, 4> tensor(input_depth, input_rows, input_cols, input_batches); + // Initializes tensor with incrementing numbers. + for (int i = 0; i < tensor.size(); ++i) { + tensor.data()[i] = i + 1; + } + Tensor<float, 5> result = tensor.extract_image_patches(ksize, ksize, stride, stride, PADDING_VALID); + + VERIFY_IS_EQUAL(result.dimension(0), input_depth); // depth + VERIFY_IS_EQUAL(result.dimension(1), ksize); // kernel rows + VERIFY_IS_EQUAL(result.dimension(2), ksize); // kernel cols + VERIFY_IS_EQUAL(result.dimension(3), 1); // number of patches + VERIFY_IS_EQUAL(result.dimension(4), input_batches); // number of batches + + // No padding is carried out. + int row_padding = 0; + int col_padding = 0; + + for (int i = 0; (i+stride+ksize-1) < input_rows; i += stride) { // input rows + for (int j = 0; (j+stride+ksize-1) < input_cols; j += stride) { // input cols + int patchId = i+input_rows*j; + for (int r = 0; r < ksize; ++r) { // patch rows + for (int c = 0; c < ksize; ++c) { // patch cols + for (int d = 0; d < input_depth; ++d) { // depth + for (int b = 0; b < input_batches; ++b) { // batch + float expected = 0.0f; + int row_offset = r + i - row_padding; + int col_offset = c + j - col_padding; + if (row_offset >= 0 && col_offset >= 0 && row_offset < input_rows && col_offset < input_cols) { + expected = tensor(d, row_offset, col_offset, b); + } + if (result(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(result(d, r, c, patchId, b), expected); + } + } + } + } + } + } +} + +// Verifies VALID padding (no padding) with the same value. +static void test_patch_padding_valid_same_value() +{ + int input_depth = 1; + int input_rows = 5; + int input_cols = 5; + int input_batches = 2; + int ksize = 3; // Corresponds to the Rows and Cols for tensor.extract_image_patches<>. + int stride = 2; // Only same stride is supported. + Tensor<float, 4> tensor(input_depth, input_rows, input_cols, input_batches); + tensor = tensor.constant(11.0f); + Tensor<float, 5> result = tensor.extract_image_patches(ksize, ksize, stride, stride, PADDING_VALID); + + VERIFY_IS_EQUAL(result.dimension(0), input_depth); // depth + VERIFY_IS_EQUAL(result.dimension(1), ksize); // kernel rows + VERIFY_IS_EQUAL(result.dimension(2), ksize); // kernel cols + VERIFY_IS_EQUAL(result.dimension(3), 4); // number of patches + VERIFY_IS_EQUAL(result.dimension(4), input_batches); // number of batches + + // No padding is carried out. + int row_padding = 0; + int col_padding = 0; + + for (int i = 0; (i+stride+ksize-1) <= input_rows; i += stride) { // input rows + for (int j = 0; (j+stride+ksize-1) <= input_cols; j += stride) { // input cols + int patchId = i+input_rows*j; + for (int r = 0; r < ksize; ++r) { // patch rows + for (int c = 0; c < ksize; ++c) { // patch cols + for (int d = 0; d < input_depth; ++d) { // depth + for (int b = 0; b < input_batches; ++b) { // batch + float expected = 0.0f; + int row_offset = r + i - row_padding; + int col_offset = c + j - col_padding; + if (row_offset >= 0 && col_offset >= 0 && row_offset < input_rows && col_offset < input_cols) { + expected = tensor(d, row_offset, col_offset, b); + } + if (result(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(result(d, r, c, patchId, b), expected); + } + } + } + } + } + } +} + +// Verifies SAME padding. +static void test_patch_padding_same() +{ + int input_depth = 3; + int input_rows = 4; + int input_cols = 2; + int input_batches = 1; + int ksize = 2; // Corresponds to the Rows and Cols for tensor.extract_image_patches<>. + int stride = 2; // Only same stride is supported. + Tensor<float, 4> tensor(input_depth, input_rows, input_cols, input_batches); + // Initializes tensor with incrementing numbers. + for (int i = 0; i < tensor.size(); ++i) { + tensor.data()[i] = i + 1; + } + Tensor<float, 5> result = tensor.extract_image_patches(ksize, ksize, stride, stride, PADDING_SAME); + + VERIFY_IS_EQUAL(result.dimension(0), input_depth); // depth + VERIFY_IS_EQUAL(result.dimension(1), ksize); // kernel rows + VERIFY_IS_EQUAL(result.dimension(2), ksize); // kernel cols + VERIFY_IS_EQUAL(result.dimension(3), 2); // number of patches + VERIFY_IS_EQUAL(result.dimension(4), input_batches); // number of batches + + // Based on the calculation described in TensorTraits.h, padding happens to be + // 0. + int row_padding = 0; + int col_padding = 0; + + for (int i = 0; (i+stride+ksize-1) <= input_rows; i += stride) { // input rows + for (int j = 0; (j+stride+ksize-1) <= input_cols; j += stride) { // input cols + int patchId = i+input_rows*j; + for (int r = 0; r < ksize; ++r) { // patch rows + for (int c = 0; c < ksize; ++c) { // patch cols + for (int d = 0; d < input_depth; ++d) { // depth + for (int b = 0; b < input_batches; ++b) { // batch + float expected = 0.0f; + int row_offset = r*stride + i - row_padding; + int col_offset = c*stride + j - col_padding; + if (row_offset >= 0 && col_offset >= 0 && row_offset < input_rows && col_offset < input_cols) { + expected = tensor(d, row_offset, col_offset, b); + } + if (result(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(result(d, r, c, patchId, b), expected); + } + } + } + } + } + } +} + +static void test_patch_no_extra_dim() +{ + Tensor<float, 3> tensor(2,3,5); + tensor.setRandom(); + + Tensor<float, 4> single_pixel_patch; + single_pixel_patch = tensor.extract_image_patches<1, 1>(); + + VERIFY_IS_EQUAL(single_pixel_patch.dimension(0), 2); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(1), 1); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(2), 1); + VERIFY_IS_EQUAL(single_pixel_patch.dimension(3), 3*5); + + for (int i = 0; i < tensor.size(); ++i) { + if (tensor.data()[i] != single_pixel_patch.data()[i]) { + std::cout << "Mismatch detected at index " << i << " : " << tensor.data()[i] << " vs " << single_pixel_patch.data()[i] << std::endl; + } + VERIFY_IS_EQUAL(single_pixel_patch.data()[i], tensor.data()[i]); + } + + Tensor<float, 4> entire_image_patch; + entire_image_patch = tensor.extract_image_patches<3, 5>(); + + VERIFY_IS_EQUAL(entire_image_patch.dimension(0), 2); + VERIFY_IS_EQUAL(entire_image_patch.dimension(1), 3); + VERIFY_IS_EQUAL(entire_image_patch.dimension(2), 5); + VERIFY_IS_EQUAL(entire_image_patch.dimension(3), 3*5); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + int patchId = i+3*j; + for (int r = 0; r < 3; ++r) { + for (int c = 0; c < 5; ++c) { + for (int d = 0; d < 2; ++d) { + float expected = 0.0f; + if (r-1+i >= 0 && c-2+j >= 0 && r-1+i < 3 && c-2+j < 5) { + expected = tensor(d, r-1+i, c-2+j); + } + if (entire_image_patch(d, r, c, patchId) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << std::endl; + } + VERIFY_IS_EQUAL(entire_image_patch(d, r, c, patchId), expected); + } + } + } + } + } + + Tensor<float, 4> twod_patch; + twod_patch = tensor.extract_image_patches<2, 2>(); + + VERIFY_IS_EQUAL(twod_patch.dimension(0), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(1), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(2), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(3), 3*5); + + // Based on the calculation described in TensorTraits.h, padding happens to be 0. + int row_padding = 0; + int col_padding = 0; + int stride = 1; + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + int patchId = i+3*j; + for (int r = 0; r < 2; ++r) { + for (int c = 0; c < 2; ++c) { + for (int d = 0; d < 2; ++d) { + float expected = 0.0f; + int row_offset = r*stride + i - row_padding; + int col_offset = c*stride + j - col_padding; + if (row_offset >= 0 && col_offset >= 0 && row_offset < tensor.dimension(1) && col_offset < tensor.dimension(2)) { + expected = tensor(d, row_offset, col_offset); + } + if (twod_patch(d, r, c, patchId) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << std::endl; + } + VERIFY_IS_EQUAL(twod_patch(d, r, c, patchId), expected); + } + } + } + } + } +} + + +static void test_imagenet_patches() +{ + // Test the code on typical configurations used by the 'imagenet' benchmarks at + // https://github.com/soumith/convnet-benchmarks + Tensor<float, 4> l_in(3, 128, 128, 128); + l_in.setRandom(); + Tensor<float, 5> l_out = l_in.extract_image_patches(11, 11); + VERIFY_IS_EQUAL(l_out.dimension(0), 3); + VERIFY_IS_EQUAL(l_out.dimension(1), 11); + VERIFY_IS_EQUAL(l_out.dimension(2), 11); + VERIFY_IS_EQUAL(l_out.dimension(3), 128*128); + VERIFY_IS_EQUAL(l_out.dimension(4), 128); + for (int b = 0; b < 128; ++b) { + for (int i = 0; i < 128; ++i) { + for (int j = 0; j < 128; ++j) { + int patchId = i+128*j; + for (int c = 0; c < 11; ++c) { + for (int r = 0; r < 11; ++r) { + for (int d = 0; d < 3; ++d) { + float expected = 0.0f; + if (r-5+i >= 0 && c-5+j >= 0 && r-5+i < 128 && c-5+j < 128) { + expected = l_in(d, r-5+i, c-5+j, b); + } + if (l_out(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(l_out(d, r, c, patchId, b), expected); + } + } + } + } + } + } + + l_in.resize(64, 64, 64, 128); + l_in.setRandom(); + l_out = l_in.extract_image_patches(9, 9); + VERIFY_IS_EQUAL(l_out.dimension(0), 64); + VERIFY_IS_EQUAL(l_out.dimension(1), 9); + VERIFY_IS_EQUAL(l_out.dimension(2), 9); + VERIFY_IS_EQUAL(l_out.dimension(3), 64*64); + VERIFY_IS_EQUAL(l_out.dimension(4), 128); + for (int b = 0; b < 128; ++b) { + for (int i = 0; i < 64; ++i) { + for (int j = 0; j < 64; ++j) { + int patchId = i+64*j; + for (int c = 0; c < 9; ++c) { + for (int r = 0; r < 9; ++r) { + for (int d = 0; d < 64; ++d) { + float expected = 0.0f; + if (r-4+i >= 0 && c-4+j >= 0 && r-4+i < 64 && c-4+j < 64) { + expected = l_in(d, r-4+i, c-4+j, b); + } + if (l_out(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(l_out(d, r, c, patchId, b), expected); + } + } + } + } + } + } + + l_in.resize(128, 16, 16, 128); + l_in.setRandom(); + l_out = l_in.extract_image_patches(7, 7); + VERIFY_IS_EQUAL(l_out.dimension(0), 128); + VERIFY_IS_EQUAL(l_out.dimension(1), 7); + VERIFY_IS_EQUAL(l_out.dimension(2), 7); + VERIFY_IS_EQUAL(l_out.dimension(3), 16*16); + VERIFY_IS_EQUAL(l_out.dimension(4), 128); + for (int b = 0; b < 128; ++b) { + for (int i = 0; i < 16; ++i) { + for (int j = 0; j < 16; ++j) { + int patchId = i+16*j; + for (int c = 0; c < 7; ++c) { + for (int r = 0; r < 7; ++r) { + for (int d = 0; d < 128; ++d) { + float expected = 0.0f; + if (r-3+i >= 0 && c-3+j >= 0 && r-3+i < 16 && c-3+j < 16) { + expected = l_in(d, r-3+i, c-3+j, b); + } + if (l_out(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(l_out(d, r, c, patchId, b), expected); + } + } + } + } + } + } + + l_in.resize(384, 13, 13, 128); + l_in.setRandom(); + l_out = l_in.extract_image_patches(3, 3); + VERIFY_IS_EQUAL(l_out.dimension(0), 384); + VERIFY_IS_EQUAL(l_out.dimension(1), 3); + VERIFY_IS_EQUAL(l_out.dimension(2), 3); + VERIFY_IS_EQUAL(l_out.dimension(3), 13*13); + VERIFY_IS_EQUAL(l_out.dimension(4), 128); + for (int b = 0; b < 128; ++b) { + for (int i = 0; i < 13; ++i) { + for (int j = 0; j < 13; ++j) { + int patchId = i+13*j; + for (int c = 0; c < 3; ++c) { + for (int r = 0; r < 3; ++r) { + for (int d = 0; d < 384; ++d) { + float expected = 0.0f; + if (r-1+i >= 0 && c-1+j >= 0 && r-1+i < 13 && c-1+j < 13) { + expected = l_in(d, r-1+i, c-1+j, b); + } + if (l_out(d, r, c, patchId, b) != expected) { + std::cout << "Mismatch detected at index i=" << i << " j=" << j << " r=" << r << " c=" << c << " d=" << d << " b=" << b << std::endl; + } + VERIFY_IS_EQUAL(l_out(d, r, c, patchId, b), expected); + } + } + } + } + } + } +} + +void test_cxx11_tensor_image_patch() +{ + CALL_SUBTEST(test_simple_patch()); + CALL_SUBTEST(test_patch_no_extra_dim()); + CALL_SUBTEST(test_patch_padding_valid()); + CALL_SUBTEST(test_patch_padding_valid_same_value()); + CALL_SUBTEST(test_patch_padding_same()); + CALL_SUBTEST(test_imagenet_patches()); +} diff --git a/unsupported/test/cxx11_tensor_index_list.cpp b/unsupported/test/cxx11_tensor_index_list.cpp new file mode 100644 index 000000000..c4d4f244f --- /dev/null +++ b/unsupported/test/cxx11_tensor_index_list.cpp @@ -0,0 +1,268 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +#ifdef EIGEN_HAS_CONSTEXPR + +static void test_static_index_list() +{ + Tensor<float, 4> tensor(2,3,5,7); + tensor.setRandom(); + + constexpr auto reduction_axis = make_index_list(0, 1, 2); + VERIFY_IS_EQUAL(internal::array_get<0>(reduction_axis), 0); + VERIFY_IS_EQUAL(internal::array_get<1>(reduction_axis), 1); + VERIFY_IS_EQUAL(internal::array_get<2>(reduction_axis), 2); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[0]), 0); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[1]), 1); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[2]), 2); + + EIGEN_STATIC_ASSERT((internal::array_get<0>(reduction_axis) == 0), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::array_get<1>(reduction_axis) == 1), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::array_get<2>(reduction_axis) == 2), YOU_MADE_A_PROGRAMMING_MISTAKE); + + Tensor<float, 1> result = tensor.sum(reduction_axis); + for (int i = 0; i < result.size(); ++i) { + float expected = 0.0f; + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 5; ++l) { + expected += tensor(j,k,l,i); + } + } + } + VERIFY_IS_APPROX(result(i), expected); + } +} + + +static void test_type2index_list() +{ + Tensor<float, 5> tensor(2,3,5,7,11); + tensor.setRandom(); + tensor += tensor.constant(10.0f); + + typedef Eigen::IndexList<Eigen::type2index<0>> Dims0; + typedef Eigen::IndexList<Eigen::type2index<0>, Eigen::type2index<1>> Dims1; + typedef Eigen::IndexList<Eigen::type2index<0>, Eigen::type2index<1>, Eigen::type2index<2>> Dims2; + typedef Eigen::IndexList<Eigen::type2index<0>, Eigen::type2index<1>, Eigen::type2index<2>, Eigen::type2index<3>> Dims3; + typedef Eigen::IndexList<Eigen::type2index<0>, Eigen::type2index<1>, Eigen::type2index<2>, Eigen::type2index<3>, Eigen::type2index<4>> Dims4; + +#if 0 + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<Dims0>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<Dims1>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<Dims2>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<Dims3>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<Dims4>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); +#endif + + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims0, 1, ColMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims1, 2, ColMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims2, 3, ColMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims3, 4, ColMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims4, 5, ColMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims0, 1, RowMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims1, 2, RowMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims2, 3, RowMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims3, 4, RowMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::are_inner_most_dims<Dims4, 5, RowMajor>::value == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + + const Dims0 reduction_axis0; + Tensor<float, 4> result0 = tensor.sum(reduction_axis0); + for (int m = 0; m < 11; ++m) { + for (int l = 0; l < 7; ++l) { + for (int k = 0; k < 5; ++k) { + for (int j = 0; j < 3; ++j) { + float expected = 0.0f; + for (int i = 0; i < 2; ++i) { + expected += tensor(i,j,k,l,m); + } + VERIFY_IS_APPROX(result0(j,k,l,m), expected); + } + } + } + } + + const Dims1 reduction_axis1; + Tensor<float, 3> result1 = tensor.sum(reduction_axis1); + for (int m = 0; m < 11; ++m) { + for (int l = 0; l < 7; ++l) { + for (int k = 0; k < 5; ++k) { + float expected = 0.0f; + for (int j = 0; j < 3; ++j) { + for (int i = 0; i < 2; ++i) { + expected += tensor(i,j,k,l,m); + } + } + VERIFY_IS_APPROX(result1(k,l,m), expected); + } + } + } + + const Dims2 reduction_axis2; + Tensor<float, 2> result2 = tensor.sum(reduction_axis2); + for (int m = 0; m < 11; ++m) { + for (int l = 0; l < 7; ++l) { + float expected = 0.0f; + for (int k = 0; k < 5; ++k) { + for (int j = 0; j < 3; ++j) { + for (int i = 0; i < 2; ++i) { + expected += tensor(i,j,k,l,m); + } + } + } + VERIFY_IS_APPROX(result2(l,m), expected); + } + } + + const Dims3 reduction_axis3; + Tensor<float, 1> result3 = tensor.sum(reduction_axis3); + for (int m = 0; m < 11; ++m) { + float expected = 0.0f; + for (int l = 0; l < 7; ++l) { + for (int k = 0; k < 5; ++k) { + for (int j = 0; j < 3; ++j) { + for (int i = 0; i < 2; ++i) { + expected += tensor(i,j,k,l,m); + } + } + } + } + VERIFY_IS_APPROX(result3(m), expected); + } + + const Dims4 reduction_axis4; + Tensor<float, 1> result4 = tensor.sum(reduction_axis4); + float expected = 0.0f; + for (int m = 0; m < 11; ++m) { + for (int l = 0; l < 7; ++l) { + for (int k = 0; k < 5; ++k) { + for (int j = 0; j < 3; ++j) { + for (int i = 0; i < 2; ++i) { + expected += tensor(i,j,k,l,m); + } + } + } + } + } + VERIFY_IS_APPROX(result4(0), expected); +} + + +static void test_dynamic_index_list() +{ + Tensor<float, 4> tensor(2,3,5,7); + tensor.setRandom(); + + int dim1 = 2; + int dim2 = 1; + int dim3 = 0; + + auto reduction_axis = make_index_list(dim1, dim2, dim3); + + VERIFY_IS_EQUAL(internal::array_get<0>(reduction_axis), 2); + VERIFY_IS_EQUAL(internal::array_get<1>(reduction_axis), 1); + VERIFY_IS_EQUAL(internal::array_get<2>(reduction_axis), 0); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[0]), 2); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[1]), 1); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[2]), 0); + + Tensor<float, 1> result = tensor.sum(reduction_axis); + for (int i = 0; i < result.size(); ++i) { + float expected = 0.0f; + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 5; ++l) { + expected += tensor(j,k,l,i); + } + } + } + VERIFY_IS_APPROX(result(i), expected); + } +} + +static void test_mixed_index_list() +{ + Tensor<float, 4> tensor(2,3,5,7); + tensor.setRandom(); + + int dim2 = 1; + int dim4 = 3; + + auto reduction_axis = make_index_list(0, dim2, 2, dim4); + + VERIFY_IS_EQUAL(internal::array_get<0>(reduction_axis), 0); + VERIFY_IS_EQUAL(internal::array_get<1>(reduction_axis), 1); + VERIFY_IS_EQUAL(internal::array_get<2>(reduction_axis), 2); + VERIFY_IS_EQUAL(internal::array_get<3>(reduction_axis), 3); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[0]), 0); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[1]), 1); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[2]), 2); + VERIFY_IS_EQUAL(static_cast<DenseIndex>(reduction_axis[3]), 3); + + typedef IndexList<type2index<0>, int, type2index<2>, int> ReductionIndices; + ReductionIndices reduction_indices; + reduction_indices.set(1, 1); + reduction_indices.set(3, 3); + EIGEN_STATIC_ASSERT((internal::array_get<0>(reduction_indices) == 0), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::array_get<2>(reduction_indices) == 2), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_known_statically<ReductionIndices>()(0) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_known_statically<ReductionIndices>()(2) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionIndices>()(0, 0) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionIndices>()(2, 2) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); +#if 0 + EIGEN_STATIC_ASSERT((internal::all_indices_known_statically<ReductionIndices>()() == false), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<ReductionIndices>()() == false), YOU_MADE_A_PROGRAMMING_MISTAKE); +#endif + + typedef IndexList<type2index<0>, type2index<1>, type2index<2>, type2index<3>> ReductionList; + ReductionList reduction_list; + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionList>()(0, 0) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionList>()(1, 1) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionList>()(2, 2) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::index_statically_eq<ReductionList>()(3, 3) == true), YOU_MADE_A_PROGRAMMING_MISTAKE); +#if 0 + EIGEN_STATIC_ASSERT((internal::all_indices_known_statically<ReductionList>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); + EIGEN_STATIC_ASSERT((internal::indices_statically_known_to_increase<ReductionList>()() == true), YOU_MADE_A_PROGRAMMING_MISTAKE); +#endif + + Tensor<float, 1> result1 = tensor.sum(reduction_axis); + Tensor<float, 1> result2 = tensor.sum(reduction_indices); + Tensor<float, 1> result3 = tensor.sum(reduction_list); + + float expected = 0.0f; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + expected += tensor(i,j,k,l); + } + } + } + } + VERIFY_IS_APPROX(result1(0), expected); + VERIFY_IS_APPROX(result2(0), expected); + VERIFY_IS_APPROX(result3(0), expected); +} + +#endif + +void test_cxx11_tensor_index_list() +{ +#ifdef EIGEN_HAS_CONSTEXPR + CALL_SUBTEST(test_static_index_list()); + CALL_SUBTEST(test_type2index_list()); + CALL_SUBTEST(test_dynamic_index_list()); + CALL_SUBTEST(test_mixed_index_list()); +#endif +} diff --git a/unsupported/test/cxx11_tensor_intdiv.cpp b/unsupported/test/cxx11_tensor_intdiv.cpp new file mode 100644 index 000000000..a510dc695 --- /dev/null +++ b/unsupported/test/cxx11_tensor_intdiv.cpp @@ -0,0 +1,77 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + + +static void test_signed_32bit() +{ + for (int32_t i = 1; i < 25000; ++i) { + const Eigen::internal::TensorIntDivisor<int32_t> div(i); + + for (int32_t j = 0; j < 25000; ++j) { + const int32_t fast_div = j / div; + const int32_t slow_div = j / i; + VERIFY_IS_EQUAL(fast_div, slow_div); + } + } +} + + +static void test_unsigned_32bit() +{ + for (uint32_t i = 1; i < 25000; ++i) { + const Eigen::internal::TensorIntDivisor<uint32_t> div(i); + + for (uint32_t j = 0; j < 25000; ++j) { + const uint32_t fast_div = j / div; + const uint32_t slow_div = j / i; + VERIFY_IS_EQUAL(fast_div, slow_div); + } + } +} + + +static void test_signed_64bit() +{ + for (int64_t i = 2; i < 25000; ++i) { + const Eigen::internal::TensorIntDivisor<int64_t> div(i); + + for (int64_t j = 0; j < 25000; ++j) { + const int64_t fast_div = j / div; + const int64_t slow_div = j / i; + VERIFY_IS_EQUAL(fast_div, slow_div); + } + } +} + + +static void test_unsigned_64bit() +{ + for (uint64_t i = 2; i < 25000; ++i) { + const Eigen::internal::TensorIntDivisor<uint64_t> div(i); + + for (uint64_t j = 0; j < 25000; ++j) { + const uint64_t fast_div = j / div; + const uint64_t slow_div = j / i; + VERIFY_IS_EQUAL(fast_div, slow_div); + } + } +} + + +void test_cxx11_tensor_intdiv() +{ + CALL_SUBTEST(test_signed_32bit()); + CALL_SUBTEST(test_unsigned_32bit()); + CALL_SUBTEST(test_signed_64bit()); + CALL_SUBTEST(test_unsigned_64bit()); +} diff --git a/unsupported/test/cxx11_tensor_io.cpp b/unsupported/test/cxx11_tensor_io.cpp new file mode 100644 index 000000000..8bbcf7089 --- /dev/null +++ b/unsupported/test/cxx11_tensor_io.cpp @@ -0,0 +1,114 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" +#include <sstream> +#include <string> +#include <Eigen/CXX11/Tensor> + + +template<int DataLayout> +static void test_output_1d() +{ + Tensor<int, 1, DataLayout> tensor(5); + for (int i = 0; i < 5; ++i) { + tensor(i) = i; + } + + std::stringstream os; + os << tensor; + + std::string expected("0\n1\n2\n3\n4"); + VERIFY_IS_EQUAL(std::string(os.str()), expected); +} + + +template<int DataLayout> +static void test_output_2d() +{ + Tensor<int, 2, DataLayout> tensor(5, 3); + for (int i = 0; i < 5; ++i) { + for (int j = 0; j < 3; ++j) { + tensor(i, j) = i*j; + } + } + + std::stringstream os; + os << tensor; + + std::string expected("0 0 0\n0 1 2\n0 2 4\n0 3 6\n0 4 8"); + VERIFY_IS_EQUAL(std::string(os.str()), expected); +} + + +template<int DataLayout> +static void test_output_expr() +{ + Tensor<int, 1, DataLayout> tensor1(5); + Tensor<int, 1, DataLayout> tensor2(5); + for (int i = 0; i < 5; ++i) { + tensor1(i) = i; + tensor2(i) = 7; + } + + std::stringstream os; + os << tensor1 + tensor2; + + std::string expected(" 7\n 8\n 9\n10\n11"); + VERIFY_IS_EQUAL(std::string(os.str()), expected); +} + + +template<int DataLayout> +static void test_output_string() +{ + Tensor<std::string, 2, DataLayout> tensor(5, 3); + tensor.setConstant(std::string("foo")); + + std::cout << tensor << std::endl; + + std::stringstream os; + os << tensor; + + std::string expected("foo foo foo\nfoo foo foo\nfoo foo foo\nfoo foo foo\nfoo foo foo"); + VERIFY_IS_EQUAL(std::string(os.str()), expected); +} + + +template<int DataLayout> +static void test_output_const() +{ + Tensor<int, 1, DataLayout> tensor(5); + for (int i = 0; i < 5; ++i) { + tensor(i) = i; + } + + TensorMap<Tensor<const int, 1, DataLayout> > tensor_map(tensor.data(), 5); + + std::stringstream os; + os << tensor_map; + + std::string expected("0\n1\n2\n3\n4"); + VERIFY_IS_EQUAL(std::string(os.str()), expected); +} + + +void test_cxx11_tensor_io() +{ + CALL_SUBTEST(test_output_1d<ColMajor>()); + CALL_SUBTEST(test_output_1d<RowMajor>()); + CALL_SUBTEST(test_output_2d<ColMajor>()); + CALL_SUBTEST(test_output_2d<RowMajor>()); + CALL_SUBTEST(test_output_expr<ColMajor>()); + CALL_SUBTEST(test_output_expr<RowMajor>()); + CALL_SUBTEST(test_output_string<ColMajor>()); + CALL_SUBTEST(test_output_string<RowMajor>()); + CALL_SUBTEST(test_output_const<ColMajor>()); + CALL_SUBTEST(test_output_const<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_layout_swap.cpp b/unsupported/test/cxx11_tensor_layout_swap.cpp new file mode 100644 index 000000000..ae297a9da --- /dev/null +++ b/unsupported/test/cxx11_tensor_layout_swap.cpp @@ -0,0 +1,61 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +static void test_simple_swap() +{ + Tensor<float, 3, ColMajor> tensor(2,3,7); + tensor.setRandom(); + + Tensor<float, 3, RowMajor> tensor2 = tensor.swap_layout(); + VERIFY_IS_EQUAL(tensor.dimension(0), tensor2.dimension(2)); + VERIFY_IS_EQUAL(tensor.dimension(1), tensor2.dimension(1)); + VERIFY_IS_EQUAL(tensor.dimension(2), tensor2.dimension(0)); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(tensor(i,j,k), tensor2(k,j,i)); + } + } + } +} + + +static void test_swap_as_lvalue() +{ + Tensor<float, 3, ColMajor> tensor(2,3,7); + tensor.setRandom(); + + Tensor<float, 3, RowMajor> tensor2(7,3,2); + tensor2.swap_layout() = tensor; + VERIFY_IS_EQUAL(tensor.dimension(0), tensor2.dimension(2)); + VERIFY_IS_EQUAL(tensor.dimension(1), tensor2.dimension(1)); + VERIFY_IS_EQUAL(tensor.dimension(2), tensor2.dimension(0)); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(tensor(i,j,k), tensor2(k,j,i)); + } + } + } +} + + +void test_cxx11_tensor_layout_swap() +{ + CALL_SUBTEST(test_simple_swap()); + CALL_SUBTEST(test_swap_as_lvalue()); +} diff --git a/unsupported/test/cxx11_tensor_lvalue.cpp b/unsupported/test/cxx11_tensor_lvalue.cpp new file mode 100644 index 000000000..071f5b406 --- /dev/null +++ b/unsupported/test/cxx11_tensor_lvalue.cpp @@ -0,0 +1,42 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + + +static void test_compound_assignment() +{ + Tensor<float, 3> mat1(2,3,7); + Tensor<float, 3> mat2(2,3,7); + Tensor<float, 3> mat3(2,3,7); + + mat1.setRandom(); + mat2.setRandom(); + mat3 = mat1; + mat3 += mat2; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(mat3(i,j,k), mat1(i,j,k) + mat2(i,j,k)); + } + } + } +} + + +void test_cxx11_tensor_lvalue() +{ + CALL_SUBTEST(test_compound_assignment()); +} diff --git a/unsupported/test/cxx11_tensor_map.cpp b/unsupported/test/cxx11_tensor_map.cpp new file mode 100644 index 000000000..9cf2eb150 --- /dev/null +++ b/unsupported/test/cxx11_tensor_map.cpp @@ -0,0 +1,147 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_1d() +{ + Tensor<int, 1> vec1(6); + Tensor<int, 1, RowMajor> vec2(6); + + TensorMap<Tensor<const int, 1>> vec3(vec1.data(), 6); + TensorMap<Tensor<const int, 1, RowMajor>> vec4(vec2.data(), 6); + + vec1(0) = 4; vec2(0) = 0; + vec1(1) = 8; vec2(1) = 1; + vec1(2) = 15; vec2(2) = 2; + vec1(3) = 16; vec2(3) = 3; + vec1(4) = 23; vec2(4) = 4; + vec1(5) = 42; vec2(5) = 5; + + VERIFY_IS_EQUAL(vec1.rank(), 1); + VERIFY_IS_EQUAL(vec1.size(), 6); + VERIFY_IS_EQUAL(vec1.dimension(0), 6); + + VERIFY_IS_EQUAL(vec3(0), 4); + VERIFY_IS_EQUAL(vec3(1), 8); + VERIFY_IS_EQUAL(vec3(2), 15); + VERIFY_IS_EQUAL(vec3(3), 16); + VERIFY_IS_EQUAL(vec3(4), 23); + VERIFY_IS_EQUAL(vec3(5), 42); + + VERIFY_IS_EQUAL(vec4(0), 0); + VERIFY_IS_EQUAL(vec4(1), 1); + VERIFY_IS_EQUAL(vec4(2), 2); + VERIFY_IS_EQUAL(vec4(3), 3); + VERIFY_IS_EQUAL(vec4(4), 4); + VERIFY_IS_EQUAL(vec4(5), 5); +} + +static void test_2d() +{ + Tensor<int, 2> mat1(2,3); + Tensor<int, 2, RowMajor> mat2(2,3); + + mat1(0,0) = 0; + mat1(0,1) = 1; + mat1(0,2) = 2; + mat1(1,0) = 3; + mat1(1,1) = 4; + mat1(1,2) = 5; + + mat2(0,0) = 0; + mat2(0,1) = 1; + mat2(0,2) = 2; + mat2(1,0) = 3; + mat2(1,1) = 4; + mat2(1,2) = 5; + + TensorMap<Tensor<const int, 2>> mat3(mat1.data(), 2, 3); + TensorMap<Tensor<const int, 2, RowMajor>> mat4(mat2.data(), 2, 3); + + VERIFY_IS_EQUAL(mat3.rank(), 2); + VERIFY_IS_EQUAL(mat3.size(), 6); + VERIFY_IS_EQUAL(mat3.dimension(0), 2); + VERIFY_IS_EQUAL(mat3.dimension(1), 3); + + VERIFY_IS_EQUAL(mat4.rank(), 2); + VERIFY_IS_EQUAL(mat4.size(), 6); + VERIFY_IS_EQUAL(mat4.dimension(0), 2); + VERIFY_IS_EQUAL(mat4.dimension(1), 3); + + VERIFY_IS_EQUAL(mat3(0,0), 0); + VERIFY_IS_EQUAL(mat3(0,1), 1); + VERIFY_IS_EQUAL(mat3(0,2), 2); + VERIFY_IS_EQUAL(mat3(1,0), 3); + VERIFY_IS_EQUAL(mat3(1,1), 4); + VERIFY_IS_EQUAL(mat3(1,2), 5); + + VERIFY_IS_EQUAL(mat4(0,0), 0); + VERIFY_IS_EQUAL(mat4(0,1), 1); + VERIFY_IS_EQUAL(mat4(0,2), 2); + VERIFY_IS_EQUAL(mat4(1,0), 3); + VERIFY_IS_EQUAL(mat4(1,1), 4); + VERIFY_IS_EQUAL(mat4(1,2), 5); +} + +static void test_3d() +{ + Tensor<int, 3> mat1(2,3,7); + Tensor<int, 3, RowMajor> mat2(2,3,7); + + int val = 0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + mat1(i,j,k) = val; + mat2(i,j,k) = val; + val++; + } + } + } + + TensorMap<Tensor<const int, 3>> mat3(mat1.data(), 2, 3, 7); + TensorMap<Tensor<const int, 3, RowMajor>> mat4(mat2.data(), array<DenseIndex, 3>{{2, 3, 7}}); + + VERIFY_IS_EQUAL(mat3.rank(), 3); + VERIFY_IS_EQUAL(mat3.size(), 2*3*7); + VERIFY_IS_EQUAL(mat3.dimension(0), 2); + VERIFY_IS_EQUAL(mat3.dimension(1), 3); + VERIFY_IS_EQUAL(mat3.dimension(2), 7); + + VERIFY_IS_EQUAL(mat4.rank(), 3); + VERIFY_IS_EQUAL(mat4.size(), 2*3*7); + VERIFY_IS_EQUAL(mat4.dimension(0), 2); + VERIFY_IS_EQUAL(mat4.dimension(1), 3); + VERIFY_IS_EQUAL(mat4.dimension(2), 7); + + val = 0; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(mat3(i,j,k), val); + VERIFY_IS_EQUAL(mat4(i,j,k), val); + val++; + } + } + } +} + + +void test_cxx11_tensor_map() +{ + CALL_SUBTEST(test_1d()); + CALL_SUBTEST(test_2d()); + CALL_SUBTEST(test_3d()); +} diff --git a/unsupported/test/cxx11_tensor_morphing.cpp b/unsupported/test/cxx11_tensor_morphing.cpp new file mode 100644 index 000000000..7fd7a283a --- /dev/null +++ b/unsupported/test/cxx11_tensor_morphing.cpp @@ -0,0 +1,342 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +static void test_simple_reshape() +{ + Tensor<float, 5> tensor1(2,3,1,7,1); + tensor1.setRandom(); + + Tensor<float, 3> tensor2(2,3,7); + Tensor<float, 2> tensor3(6,7); + Tensor<float, 2> tensor4(2,21); + + Tensor<float, 3>::Dimensions dim1{{2,3,7}}; + tensor2 = tensor1.reshape(dim1); + Tensor<float, 2>::Dimensions dim2{{6,7}}; + tensor3 = tensor1.reshape(dim2); + Tensor<float, 2>::Dimensions dim3{{2,21}}; + tensor4 = tensor1.reshape(dim1).reshape(dim3); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(tensor1(i,j,0,k,0), tensor2(i,j,k)); + VERIFY_IS_EQUAL(tensor1(i,j,0,k,0), tensor3(i+2*j,k)); + VERIFY_IS_EQUAL(tensor1(i,j,0,k,0), tensor4(i,j+3*k)); + } + } + } +} + + +static void test_reshape_in_expr() { + MatrixXf m1(2,3*5*7*11); + MatrixXf m2(3*5*7*11,13); + m1.setRandom(); + m2.setRandom(); + MatrixXf m3 = m1 * m2; + + TensorMap<Tensor<float, 5>> tensor1(m1.data(), 2,3,5,7,11); + TensorMap<Tensor<float, 5>> tensor2(m2.data(), 3,5,7,11,13); + Tensor<float, 2>::Dimensions newDims1{{2,3*5*7*11}}; + Tensor<float, 2>::Dimensions newDims2{{3*5*7*11,13}}; + typedef Tensor<float, 1>::DimensionPair DimPair; + array<DimPair, 1> contract_along{{DimPair(1, 0)}}; + Tensor<float, 2> tensor3(2,13); + tensor3 = tensor1.reshape(newDims1).contract(tensor2.reshape(newDims2), contract_along); + + Map<MatrixXf> res(tensor3.data(), 2, 13); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 13; ++j) { + VERIFY_IS_APPROX(res(i,j), m3(i,j)); + } + } +} + + +static void test_reshape_as_lvalue() +{ + Tensor<float, 3> tensor(2,3,7); + tensor.setRandom(); + + Tensor<float, 2> tensor2d(6,7); + Tensor<float, 3>::Dimensions dim{{2,3,7}}; + tensor2d.reshape(dim) = tensor; + + float scratch[2*3*1*7*1]; + TensorMap<Tensor<float, 5>> tensor5d(scratch, 2,3,1,7,1); + tensor5d.reshape(dim).device(Eigen::DefaultDevice()) = tensor; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(tensor2d(i+2*j,k), tensor(i,j,k)); + VERIFY_IS_EQUAL(tensor5d(i,j,0,k,0), tensor(i,j,k)); + } + } + } +} + +template<int DataLayout> +static void test_simple_slice() +{ + Tensor<float, 5, DataLayout> tensor(2,3,5,7,11); + tensor.setRandom(); + + Tensor<float, 5, DataLayout> slice1(1,1,1,1,1); + Eigen::DSizes<ptrdiff_t, 5> indices(1,2,3,4,5); + Eigen::DSizes<ptrdiff_t, 5> sizes(1,1,1,1,1); + slice1 = tensor.slice(indices, sizes); + VERIFY_IS_EQUAL(slice1(0,0,0,0,0), tensor(1,2,3,4,5)); + + Tensor<float, 5, DataLayout> slice2(1,1,2,2,3); + Eigen::DSizes<ptrdiff_t, 5> indices2(1,1,3,4,5); + Eigen::DSizes<ptrdiff_t, 5> sizes2(1,1,2,2,3); + slice2 = tensor.slice(indices2, sizes2); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 3; ++k) { + VERIFY_IS_EQUAL(slice2(0,0,i,j,k), tensor(1,1,3+i,4+j,5+k)); + } + } + } +} + +// TODO(andydavis) Add RowMajor support when TensorContract supports RowMajor. +static void test_slice_in_expr() { + MatrixXf m1(7,7); + MatrixXf m2(3,3); + m1.setRandom(); + m2.setRandom(); + + MatrixXf m3 = m1.block(1, 2, 3, 3) * m2.block(0, 2, 3, 1); + + TensorMap<Tensor<float, 2>> tensor1(m1.data(), 7, 7); + TensorMap<Tensor<float, 2>> tensor2(m2.data(), 3, 3); + Tensor<float, 2> tensor3(3,1); + typedef Tensor<float, 1>::DimensionPair DimPair; + array<DimPair, 1> contract_along{{DimPair(1, 0)}}; + + Eigen::DSizes<ptrdiff_t, 2> indices1(1,2); + Eigen::DSizes<ptrdiff_t, 2> sizes1(3,3); + Eigen::DSizes<ptrdiff_t, 2> indices2(0,2); + Eigen::DSizes<ptrdiff_t, 2> sizes2(3,1); + tensor3 = tensor1.slice(indices1, sizes1).contract(tensor2.slice(indices2, sizes2), contract_along); + + Map<MatrixXf> res(tensor3.data(), 3, 1); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 1; ++j) { + VERIFY_IS_APPROX(res(i,j), m3(i,j)); + } + } + + // Take an arbitrary slice of an arbitrarily sized tensor. + TensorMap<Tensor<const float, 2>> tensor4(m1.data(), 7, 7); + Tensor<float, 1> tensor6 = tensor4.reshape(DSizes<ptrdiff_t, 1>(7*7)).exp().slice(DSizes<ptrdiff_t, 1>(0), DSizes<ptrdiff_t, 1>(35)); + for (int i = 0; i < 35; ++i) { + VERIFY_IS_APPROX(tensor6(i), expf(tensor4.data()[i])); + } +} + +template<int DataLayout> +static void test_slice_as_lvalue() +{ + Tensor<float, 3, DataLayout> tensor1(2,2,7); + tensor1.setRandom(); + Tensor<float, 3, DataLayout> tensor2(2,2,7); + tensor2.setRandom(); + Tensor<float, 3, DataLayout> tensor3(4,3,5); + tensor3.setRandom(); + Tensor<float, 3, DataLayout> tensor4(4,3,2); + tensor4.setRandom(); + Tensor<float, 3, DataLayout> tensor5(10,13,12); + tensor5.setRandom(); + + Tensor<float, 3, DataLayout> result(4,5,7); + Eigen::DSizes<ptrdiff_t, 3> sizes12(2,2,7); + Eigen::DSizes<ptrdiff_t, 3> first_slice(0,0,0); + result.slice(first_slice, sizes12) = tensor1; + Eigen::DSizes<ptrdiff_t, 3> second_slice(2,0,0); + result.slice(second_slice, sizes12).device(Eigen::DefaultDevice()) = tensor2; + + Eigen::DSizes<ptrdiff_t, 3> sizes3(4,3,5); + Eigen::DSizes<ptrdiff_t, 3> third_slice(0,2,0); + result.slice(third_slice, sizes3) = tensor3; + + Eigen::DSizes<ptrdiff_t, 3> sizes4(4,3,2); + Eigen::DSizes<ptrdiff_t, 3> fourth_slice(0,2,5); + result.slice(fourth_slice, sizes4) = tensor4; + + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 7; ++k) { + for (int i = 0; i < 2; ++i) { + VERIFY_IS_EQUAL(result(i,j,k), tensor1(i,j,k)); + VERIFY_IS_EQUAL(result(i+2,j,k), tensor2(i,j,k)); + } + } + } + for (int i = 0; i < 4; ++i) { + for (int j = 2; j < 5; ++j) { + for (int k = 0; k < 5; ++k) { + VERIFY_IS_EQUAL(result(i,j,k), tensor3(i,j-2,k)); + } + for (int k = 5; k < 7; ++k) { + VERIFY_IS_EQUAL(result(i,j,k), tensor4(i,j-2,k-5)); + } + } + } + + Eigen::DSizes<ptrdiff_t, 3> sizes5(4,5,7); + Eigen::DSizes<ptrdiff_t, 3> fifth_slice(0,0,0); + result.slice(fifth_slice, sizes5) = tensor5.slice(fifth_slice, sizes5); + for (int i = 0; i < 4; ++i) { + for (int j = 2; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(result(i,j,k), tensor5(i,j,k)); + } + } + } +} + +template<int DataLayout> +static void test_slice_raw_data() +{ + Tensor<float, 4, DataLayout> tensor(3,5,7,11); + tensor.setRandom(); + + Eigen::DSizes<ptrdiff_t, 4> offsets(1,2,3,4); + Eigen::DSizes<ptrdiff_t, 4> extents(1,1,1,1); + typedef TensorEvaluator<decltype(tensor.slice(offsets, extents)), DefaultDevice> SliceEvaluator; + auto slice1 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice1.dimensions().TotalSize(), 1ul); + VERIFY_IS_EQUAL(slice1.data()[0], tensor(1,2,3,4)); + + if (DataLayout == ColMajor) { + extents = Eigen::DSizes<ptrdiff_t, 4>(2,1,1,1); + auto slice2 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice2.dimensions().TotalSize(), 2ul); + VERIFY_IS_EQUAL(slice2.data()[0], tensor(1,2,3,4)); + VERIFY_IS_EQUAL(slice2.data()[1], tensor(2,2,3,4)); + } else { + extents = Eigen::DSizes<ptrdiff_t, 4>(1,1,1,2); + auto slice2 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice2.dimensions().TotalSize(), 2ul); + VERIFY_IS_EQUAL(slice2.data()[0], tensor(1,2,3,4)); + VERIFY_IS_EQUAL(slice2.data()[1], tensor(1,2,3,5)); + } + + extents = Eigen::DSizes<ptrdiff_t, 4>(1,2,1,1); + auto slice3 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice3.dimensions().TotalSize(), 2ul); + VERIFY_IS_EQUAL(slice3.data(), static_cast<float*>(0)); + + if (DataLayout == ColMajor) { + offsets = Eigen::DSizes<ptrdiff_t, 4>(0,2,3,4); + extents = Eigen::DSizes<ptrdiff_t, 4>(3,2,1,1); + auto slice4 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice4.dimensions().TotalSize(), 6ul); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 2; ++j) { + VERIFY_IS_EQUAL(slice4.data()[i+3*j], tensor(i,2+j,3,4)); + } + } + } else { + offsets = Eigen::DSizes<ptrdiff_t, 4>(1,2,3,0); + extents = Eigen::DSizes<ptrdiff_t, 4>(1,1,2,11); + auto slice4 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice4.dimensions().TotalSize(), 22ul); + for (int l = 0; l < 11; ++l) { + for (int k = 0; k < 2; ++k) { + VERIFY_IS_EQUAL(slice4.data()[l+11*k], tensor(1,2,3+k,l)); + } + } + } + + if (DataLayout == ColMajor) { + offsets = Eigen::DSizes<ptrdiff_t, 4>(0,0,0,4); + extents = Eigen::DSizes<ptrdiff_t, 4>(3,5,7,2); + auto slice5 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice5.dimensions().TotalSize(), 210ul); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + for (int l = 0; l < 2; ++l) { + int slice_index = i + 3 * (j + 5 * (k + 7 * l)); + VERIFY_IS_EQUAL(slice5.data()[slice_index], tensor(i,j,k,l+4)); + } + } + } + } + } else { + offsets = Eigen::DSizes<ptrdiff_t, 4>(1,0,0,0); + extents = Eigen::DSizes<ptrdiff_t, 4>(2,5,7,11); + auto slice5 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice5.dimensions().TotalSize(), 770ul); + for (int l = 0; l < 11; ++l) { + for (int k = 0; k < 7; ++k) { + for (int j = 0; j < 5; ++j) { + for (int i = 0; i < 2; ++i) { + int slice_index = l + 11 * (k + 7 * (j + 5 * i)); + VERIFY_IS_EQUAL(slice5.data()[slice_index], tensor(i+1,j,k,l)); + } + } + } + } + + } + + offsets = Eigen::DSizes<ptrdiff_t, 4>(0,0,0,0); + extents = Eigen::DSizes<ptrdiff_t, 4>(3,5,7,11); + auto slice6 = SliceEvaluator(tensor.slice(offsets, extents), DefaultDevice()); + VERIFY_IS_EQUAL(slice6.dimensions().TotalSize(), 3ul*5*7*11); + VERIFY_IS_EQUAL(slice6.data(), tensor.data()); +} + + +static void test_composition() +{ + Eigen::Tensor<float, 2> matrix(7, 11); + matrix.setRandom(); + + const DSizes<ptrdiff_t, 3> newDims{{1, 1, 11}}; + Eigen::Tensor<float, 3> tensor = + matrix.slice(DSizes<ptrdiff_t, 2>(2, 0), DSizes<ptrdiff_t, 2>(1, 11)).reshape(newDims); + + VERIFY_IS_EQUAL(tensor.dimensions().TotalSize(), 11ul); + VERIFY_IS_EQUAL(tensor.dimension(0), 1); + VERIFY_IS_EQUAL(tensor.dimension(1), 1); + VERIFY_IS_EQUAL(tensor.dimension(2), 11); + for (int i = 0; i < 11; ++i) { + VERIFY_IS_EQUAL(tensor(0,0,i), matrix(2,i)); + } +} + + +void test_cxx11_tensor_morphing() +{ + CALL_SUBTEST(test_simple_reshape()); + CALL_SUBTEST(test_reshape_in_expr()); + CALL_SUBTEST(test_reshape_as_lvalue()); + + CALL_SUBTEST(test_simple_slice<ColMajor>()); + CALL_SUBTEST(test_simple_slice<RowMajor>()); + CALL_SUBTEST(test_slice_in_expr()); + CALL_SUBTEST(test_slice_as_lvalue<ColMajor>()); + CALL_SUBTEST(test_slice_as_lvalue<RowMajor>()); + CALL_SUBTEST(test_slice_raw_data<ColMajor>()); + CALL_SUBTEST(test_slice_raw_data<RowMajor>()); + + CALL_SUBTEST(test_composition()); +} diff --git a/unsupported/test/cxx11_tensor_of_complex.cpp b/unsupported/test/cxx11_tensor_of_complex.cpp new file mode 100644 index 000000000..24b2bcb58 --- /dev/null +++ b/unsupported/test/cxx11_tensor_of_complex.cpp @@ -0,0 +1,81 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::TensorMap; + + + +static void test_additions() +{ + Tensor<std::complex<float>, 1> data1(3); + Tensor<std::complex<float>, 1> data2(3); + for (int i = 0; i < 3; ++i) { + data1(i) = std::complex<float>(i, -i); + data2(i) = std::complex<float>(i, 7 * i); + } + + Tensor<std::complex<float>, 1> sum = data1 + data2; + for (int i = 0; i < 3; ++i) { + VERIFY_IS_EQUAL(sum(i), std::complex<float>(2*i, 6*i)); + } +} + + +static void test_abs() +{ + Tensor<std::complex<float>, 1> data1(3); + Tensor<std::complex<double>, 1> data2(3); + data1.setRandom(); + data2.setRandom(); + + Tensor<float, 1> abs1 = data1.abs(); + Tensor<double, 1> abs2 = data2.abs(); + for (int i = 0; i < 3; ++i) { + VERIFY_IS_APPROX(abs1(i), std::abs(data1(i))); + VERIFY_IS_APPROX(abs2(i), std::abs(data2(i))); + } +} + + +static void test_contractions() +{ + Tensor<std::complex<float>, 4> t_left(30, 50, 8, 31); + Tensor<std::complex<float>, 5> t_right(8, 31, 7, 20, 10); + Tensor<std::complex<float>, 5> t_result(30, 50, 7, 20, 10); + + t_left.setRandom(); + t_right.setRandom(); + + typedef Map<Matrix<std::complex<float>, Dynamic, Dynamic>> MapXcf; + MapXcf m_left(t_left.data(), 1500, 248); + MapXcf m_right(t_right.data(), 248, 1400); + Matrix<std::complex<float>, Dynamic, Dynamic> m_result(1500, 1400); + + // This contraction should be equivalent to a regular matrix multiplication + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 2> dims({{DimPair(2, 0), DimPair(3, 1)}}); + t_result = t_left.contract(t_right, dims); + m_result = m_left * m_right; + for (size_t i = 0; i < t_result.dimensions().TotalSize(); i++) { + VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]); + } +} + + +void test_cxx11_tensor_of_complex() +{ + CALL_SUBTEST(test_additions()); + CALL_SUBTEST(test_abs()); + CALL_SUBTEST(test_contractions()); +} diff --git a/unsupported/test/cxx11_tensor_of_const_values.cpp b/unsupported/test/cxx11_tensor_of_const_values.cpp new file mode 100644 index 000000000..f179a0c21 --- /dev/null +++ b/unsupported/test/cxx11_tensor_of_const_values.cpp @@ -0,0 +1,105 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_assign() +{ + float data1[6]; + TensorMap<Tensor<const float, 2>> mat1(data1, 2, 3); + float data2[6]; + const TensorMap<Tensor<float, 2>> mat2(data2, 2, 3); + + for (int i = 0; i < 6; ++i) { + data1[i] = i; + data2[i] = -i; + } + + Tensor<float, 2> rslt1; + rslt1 = mat1; + Tensor<float, 2> rslt2; + rslt2 = mat2; + + Tensor<float, 2> rslt3 = mat1; + Tensor<float, 2> rslt4 = mat2; + + Tensor<float, 2> rslt5(mat1); + Tensor<float, 2> rslt6(mat2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_APPROX(rslt1(i,j), static_cast<float>(i + 2*j)); + VERIFY_IS_APPROX(rslt2(i,j), static_cast<float>(-i - 2*j)); + VERIFY_IS_APPROX(rslt3(i,j), static_cast<float>(i + 2*j)); + VERIFY_IS_APPROX(rslt4(i,j), static_cast<float>(-i - 2*j)); + VERIFY_IS_APPROX(rslt5(i,j), static_cast<float>(i + 2*j)); + VERIFY_IS_APPROX(rslt6(i,j), static_cast<float>(-i - 2*j)); + } + } +} + + +static void test_plus() +{ + float data1[6]; + TensorMap<Tensor<const float, 2>> mat1(data1, 2, 3); + float data2[6]; + TensorMap<Tensor<float, 2>> mat2(data2, 2, 3); + + for (int i = 0; i < 6; ++i) { + data1[i] = i; + data2[i] = -i; + } + + Tensor<float, 2> sum1; + sum1 = mat1 + mat2; + Tensor<float, 2> sum2; + sum2 = mat2 + mat1; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_APPROX(sum1(i,j), 0.0f); + VERIFY_IS_APPROX(sum2(i,j), 0.0f); + } + } +} + + +static void test_plus_equal() +{ + float data1[6]; + TensorMap<Tensor<const float, 2>> mat1(data1, 2, 3); + float data2[6]; + TensorMap<Tensor<float, 2>> mat2(data2, 2, 3); + + for (int i = 0; i < 6; ++i) { + data1[i] = i; + data2[i] = -i; + } + mat2 += mat1; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_APPROX(mat2(i,j), 0.0f); + } + } +} + + +void test_cxx11_tensor_of_const_values() +{ + CALL_SUBTEST(test_assign()); + CALL_SUBTEST(test_plus()); + CALL_SUBTEST(test_plus_equal()); +} diff --git a/unsupported/test/cxx11_tensor_of_strings.cpp b/unsupported/test/cxx11_tensor_of_strings.cpp new file mode 100644 index 000000000..8d05d154e --- /dev/null +++ b/unsupported/test/cxx11_tensor_of_strings.cpp @@ -0,0 +1,152 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::TensorMap; + +static void test_assign() +{ + std::string data1[6]; + TensorMap<Tensor<std::string, 2>> mat1(data1, 2, 3); + std::string data2[6]; + const TensorMap<Tensor<const std::string, 2>> mat2(data2, 2, 3); + + for (int i = 0; i < 6; ++i) { + std::ostringstream s1; + s1 << "abc" << i*3; + data1[i] = s1.str(); + std::ostringstream s2; + s2 << "def" << i*5; + data2[i] = s2.str(); + } + + Tensor<std::string, 2> rslt1; + rslt1 = mat1; + Tensor<std::string, 2> rslt2; + rslt2 = mat2; + + Tensor<std::string, 2> rslt3 = mat1; + Tensor<std::string, 2> rslt4 = mat2; + + Tensor<std::string, 2> rslt5(mat1); + Tensor<std::string, 2> rslt6(mat2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_EQUAL(rslt1(i,j), data1[i+2*j]); + VERIFY_IS_EQUAL(rslt2(i,j), data2[i+2*j]); + VERIFY_IS_EQUAL(rslt3(i,j), data1[i+2*j]); + VERIFY_IS_EQUAL(rslt4(i,j), data2[i+2*j]); + VERIFY_IS_EQUAL(rslt5(i,j), data1[i+2*j]); + VERIFY_IS_EQUAL(rslt6(i,j), data2[i+2*j]); + } + } +} + + +static void test_concat() +{ + Tensor<std::string, 2> t1(2, 3); + Tensor<std::string, 2> t2(2, 3); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + std::ostringstream s1; + s1 << "abc" << i + j*2; + t1(i, j) = s1.str(); + std::ostringstream s2; + s2 << "def" << i*5 + j*32; + t2(i, j) = s2.str(); + } + } + + Tensor<std::string, 2> result = t1.concatenate(t2, 1); + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_EQUAL(result.dimension(1), 6); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_EQUAL(result(i, j), t1(i, j)); + VERIFY_IS_EQUAL(result(i, j+3), t2(i, j)); + } + } +} + + +static void test_slices() +{ + Tensor<std::string, 2> data(2, 6); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + std::ostringstream s1; + s1 << "abc" << i + j*2; + data(i, j) = s1.str(); + } + } + + const Eigen::DSizes<ptrdiff_t, 2> half_size{{2, 3}}; + const Eigen::DSizes<ptrdiff_t, 2> first_half{{0, 0}}; + const Eigen::DSizes<ptrdiff_t, 2> second_half{{0, 3}}; + + Tensor<std::string, 2> t1 = data.slice(first_half, half_size); + Tensor<std::string, 2> t2 = data.slice(second_half, half_size); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + VERIFY_IS_EQUAL(data(i, j), t1(i, j)); + VERIFY_IS_EQUAL(data(i, j+3), t2(i, j)); + } + } +} + + +static void test_additions() +{ + Tensor<std::string, 1> data1(3); + Tensor<std::string, 1> data2(3); + for (int i = 0; i < 3; ++i) { + data1(i) = "abc"; + std::ostringstream s1; + s1 << i; + data2(i) = s1.str(); + } + + Tensor<std::string, 1> sum = data1 + data2; + for (int i = 0; i < 3; ++i) { + std::ostringstream concat; + concat << "abc" << i; + std::string expected = concat.str(); + VERIFY_IS_EQUAL(sum(i), expected); + } +} + + +static void test_initialization() +{ + Tensor<std::string, 2> a(2, 3); + a.setConstant(std::string("foo")); + for (int i = 0; i < 2*3; ++i) { + VERIFY_IS_EQUAL(a(i), std::string("foo")); + } +} + + +void test_cxx11_tensor_of_strings() +{ + // Beware: none of this is likely to ever work on a GPU. + CALL_SUBTEST(test_assign()); + CALL_SUBTEST(test_concat()); + CALL_SUBTEST(test_slices()); + CALL_SUBTEST(test_additions()); + CALL_SUBTEST(test_initialization()); +} diff --git a/unsupported/test/cxx11_tensor_padding.cpp b/unsupported/test/cxx11_tensor_padding.cpp new file mode 100644 index 000000000..ffa19896e --- /dev/null +++ b/unsupported/test/cxx11_tensor_padding.cpp @@ -0,0 +1,93 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template<int DataLayout> +static void test_simple_padding() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + + array<std::pair<ptrdiff_t, ptrdiff_t>, 4> paddings; + paddings[0] = std::make_pair(0, 0); + paddings[1] = std::make_pair(2, 1); + paddings[2] = std::make_pair(3, 4); + paddings[3] = std::make_pair(0, 0); + + Tensor<float, 4, DataLayout> padded; + padded = tensor.pad(paddings); + + VERIFY_IS_EQUAL(padded.dimension(0), 2+0); + VERIFY_IS_EQUAL(padded.dimension(1), 3+3); + VERIFY_IS_EQUAL(padded.dimension(2), 5+7); + VERIFY_IS_EQUAL(padded.dimension(3), 7+0); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 6; ++j) { + for (int k = 0; k < 12; ++k) { + for (int l = 0; l < 7; ++l) { + if (j >= 2 && j < 5 && k >= 3 && k < 8) { + VERIFY_IS_EQUAL(padded(i,j,k,l), tensor(i,j-2,k-3,l)); + } else { + VERIFY_IS_EQUAL(padded(i,j,k,l), 0.0f); + } + } + } + } + } +} + +template<int DataLayout> +static void test_padded_expr() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + + array<std::pair<ptrdiff_t, ptrdiff_t>, 4> paddings; + paddings[0] = std::make_pair(0, 0); + paddings[1] = std::make_pair(2, 1); + paddings[2] = std::make_pair(3, 4); + paddings[3] = std::make_pair(0, 0); + + Eigen::DSizes<ptrdiff_t, 2> reshape_dims; + reshape_dims[0] = 12; + reshape_dims[1] = 84; + + Tensor<float, 2, DataLayout> result; + result = tensor.pad(paddings).reshape(reshape_dims); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 6; ++j) { + for (int k = 0; k < 12; ++k) { + for (int l = 0; l < 7; ++l) { + const float result_value = DataLayout == ColMajor ? + result(i+2*j,k+12*l) : result(j+6*i,l+7*k); + if (j >= 2 && j < 5 && k >= 3 && k < 8) { + VERIFY_IS_EQUAL(result_value, tensor(i,j-2,k-3,l)); + } else { + VERIFY_IS_EQUAL(result_value, 0.0f); + } + } + } + } + } +} + +void test_cxx11_tensor_padding() +{ + CALL_SUBTEST(test_simple_padding<ColMajor>()); + CALL_SUBTEST(test_simple_padding<RowMajor>()); + CALL_SUBTEST(test_padded_expr<ColMajor>()); + CALL_SUBTEST(test_padded_expr<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_patch.cpp b/unsupported/test/cxx11_tensor_patch.cpp new file mode 100644 index 000000000..0ee7b46d4 --- /dev/null +++ b/unsupported/test/cxx11_tensor_patch.cpp @@ -0,0 +1,120 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +static void test_simple_patch() +{ + Tensor<float, 4> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> patch_dims; + patch_dims[0] = 1; + patch_dims[1] = 1; + patch_dims[2] = 1; + patch_dims[3] = 1; + + Tensor<float, 5> no_patch; + no_patch = tensor.extract_patches(patch_dims); + + VERIFY_IS_EQUAL(no_patch.dimension(0), 1); + VERIFY_IS_EQUAL(no_patch.dimension(1), 1); + VERIFY_IS_EQUAL(no_patch.dimension(2), 1); + VERIFY_IS_EQUAL(no_patch.dimension(3), 1); + VERIFY_IS_EQUAL(no_patch.dimension(4), tensor.size()); + + for (int i = 0; i < tensor.size(); ++i) { + VERIFY_IS_EQUAL(tensor.data()[i], no_patch.data()[i]); + } + + patch_dims[0] = 2; + patch_dims[1] = 3; + patch_dims[2] = 5; + patch_dims[3] = 7; + Tensor<float, 5> single_patch; + single_patch = tensor.extract_patches(patch_dims); + + VERIFY_IS_EQUAL(single_patch.dimension(0), 2); + VERIFY_IS_EQUAL(single_patch.dimension(1), 3); + VERIFY_IS_EQUAL(single_patch.dimension(2), 5); + VERIFY_IS_EQUAL(single_patch.dimension(3), 7); + VERIFY_IS_EQUAL(single_patch.dimension(4), 1); + + for (int i = 0; i < tensor.size(); ++i) { + VERIFY_IS_EQUAL(tensor.data()[i], single_patch.data()[i]); + } + + patch_dims[0] = 1; + patch_dims[1] = 2; + patch_dims[2] = 2; + patch_dims[3] = 1; + Tensor<float, 5> twod_patch; + twod_patch = tensor.extract_patches(patch_dims); + + VERIFY_IS_EQUAL(twod_patch.dimension(0), 1); + VERIFY_IS_EQUAL(twod_patch.dimension(1), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(2), 2); + VERIFY_IS_EQUAL(twod_patch.dimension(3), 1); + VERIFY_IS_EQUAL(twod_patch.dimension(4), 2*2*4*7); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 4; ++k) { + for (int l = 0; l < 7; ++l) { + int patch_loc = i + 2 * (j + 2 * (k + 4 * l)); + for (int x = 0; x < 2; ++x) { + for (int y = 0; y < 2; ++y) { + VERIFY_IS_EQUAL(tensor(i,j+x,k+y,l), twod_patch(0,x,y,0,patch_loc)); + } + } + } + } + } + } + + patch_dims[0] = 1; + patch_dims[1] = 2; + patch_dims[2] = 3; + patch_dims[3] = 5; + Tensor<float, 5> threed_patch; + threed_patch = tensor.extract_patches(patch_dims); + + VERIFY_IS_EQUAL(threed_patch.dimension(0), 1); + VERIFY_IS_EQUAL(threed_patch.dimension(1), 2); + VERIFY_IS_EQUAL(threed_patch.dimension(2), 3); + VERIFY_IS_EQUAL(threed_patch.dimension(3), 5); + VERIFY_IS_EQUAL(threed_patch.dimension(4), 2*2*3*3); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 3; ++l) { + int patch_loc = i + 2 * (j + 2 * (k + 3 * l)); + for (int x = 0; x < 2; ++x) { + for (int y = 0; y < 3; ++y) { + for (int z = 0; z < 5; ++z) { + VERIFY_IS_EQUAL(tensor(i,j+x,k+y,l+z), threed_patch(0,x,y,z,patch_loc)); + } + } + } + } + } + } + } +} + + +void test_cxx11_tensor_patch() +{ + CALL_SUBTEST(test_simple_patch()); + // CALL_SUBTEST(test_expr_shuffling()); +} diff --git a/unsupported/test/cxx11_tensor_random.cpp b/unsupported/test/cxx11_tensor_random.cpp new file mode 100644 index 000000000..8276ae822 --- /dev/null +++ b/unsupported/test/cxx11_tensor_random.cpp @@ -0,0 +1,78 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +static void test_default() +{ + Tensor<float, 1> vec(6); + vec.setRandom(); + + // Fixme: we should check that the generated numbers follow a uniform + // distribution instead. + for (int i = 1; i < 6; ++i) { + VERIFY_IS_NOT_EQUAL(vec(i), vec(i-1)); + } +} + +static void test_normal() +{ + Tensor<float, 1> vec(6); + vec.setRandom<Eigen::internal::NormalRandomGenerator<float>>(); + + // Fixme: we should check that the generated numbers follow a gaussian + // distribution instead. + for (int i = 1; i < 6; ++i) { + VERIFY_IS_NOT_EQUAL(vec(i), vec(i-1)); + } +} + + +struct MyGenerator { + MyGenerator() { } + MyGenerator(const MyGenerator&) { } + + // Return a random value to be used. "element_location" is the + // location of the entry to set in the tensor, it can typically + // be ignored. + int operator()(Eigen::DenseIndex element_location, Eigen::DenseIndex /*unused*/ = 0) const { + return 3 * element_location; + } + + // Same as above but generates several numbers at a time. + typename internal::packet_traits<int>::type packetOp( + Eigen::DenseIndex packet_location, Eigen::DenseIndex /*unused*/ = 0) const { + const int packetSize = internal::packet_traits<int>::size; + EIGEN_ALIGN_DEFAULT int values[packetSize]; + for (int i = 0; i < packetSize; ++i) { + values[i] = 3 * (packet_location + i); + } + return internal::pload<typename internal::packet_traits<int>::type>(values); + } +}; + + +static void test_custom() +{ + Tensor<int, 1> vec(6); + vec.setRandom<MyGenerator>(); + + for (int i = 0; i < 6; ++i) { + VERIFY_IS_EQUAL(vec(i), 3*i); + } +} + +void test_cxx11_tensor_random() +{ + CALL_SUBTEST(test_default()); + CALL_SUBTEST(test_normal()); + CALL_SUBTEST(test_custom()); +} diff --git a/unsupported/test/cxx11_tensor_reduction.cpp b/unsupported/test/cxx11_tensor_reduction.cpp new file mode 100644 index 000000000..0269853a9 --- /dev/null +++ b/unsupported/test/cxx11_tensor_reduction.cpp @@ -0,0 +1,420 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" +#include <limits> +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template <int DataLayout> +static void test_simple_reductions() { + Tensor<float, 4, DataLayout> tensor(2, 3, 5, 7); + tensor.setRandom(); + array<ptrdiff_t, 2> reduction_axis; + reduction_axis[0] = 1; + reduction_axis[1] = 3; + + Tensor<float, 2, DataLayout> result = tensor.sum(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_EQUAL(result.dimension(1), 5); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 5; ++j) { + float sum = 0.0f; + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 7; ++l) { + sum += tensor(i, k, j, l); + } + } + VERIFY_IS_APPROX(result(i, j), sum); + } + } + + { + Tensor<float, 1, DataLayout> sum1 = tensor.sum(); + VERIFY_IS_EQUAL(sum1.dimension(0), 1); + + array<ptrdiff_t, 4> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + reduction_axis[2] = 2; + reduction_axis[3] = 3; + Tensor<float, 1, DataLayout> sum2 = tensor.sum(reduction_axis); + VERIFY_IS_EQUAL(sum2.dimension(0), 1); + + VERIFY_IS_APPROX(sum1(0), sum2(0)); + } + + reduction_axis[0] = 0; + reduction_axis[1] = 2; + result = tensor.prod(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 3); + VERIFY_IS_EQUAL(result.dimension(1), 7); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 7; ++j) { + float prod = 1.0f; + for (int k = 0; k < 2; ++k) { + for (int l = 0; l < 5; ++l) { + prod *= tensor(k, i, l, j); + } + } + VERIFY_IS_APPROX(result(i, j), prod); + } + } + + { + Tensor<float, 1, DataLayout> prod1 = tensor.prod(); + VERIFY_IS_EQUAL(prod1.dimension(0), 1); + + array<ptrdiff_t, 4> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + reduction_axis[2] = 2; + reduction_axis[3] = 3; + Tensor<float, 1, DataLayout> prod2 = tensor.prod(reduction_axis); + VERIFY_IS_EQUAL(prod2.dimension(0), 1); + + VERIFY_IS_APPROX(prod1(0), prod2(0)); + } + + reduction_axis[0] = 0; + reduction_axis[1] = 2; + result = tensor.maximum(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 3); + VERIFY_IS_EQUAL(result.dimension(1), 7); + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 7; ++j) { + float max_val = std::numeric_limits<float>::lowest(); + for (int k = 0; k < 2; ++k) { + for (int l = 0; l < 5; ++l) { + max_val = (std::max)(max_val, tensor(k, i, l, j)); + } + } + VERIFY_IS_APPROX(result(i, j), max_val); + } + } + + { + Tensor<float, 1, DataLayout> max1 = tensor.maximum(); + VERIFY_IS_EQUAL(max1.dimension(0), 1); + + array<ptrdiff_t, 4> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + reduction_axis[2] = 2; + reduction_axis[3] = 3; + Tensor<float, 1, DataLayout> max2 = tensor.maximum(reduction_axis); + VERIFY_IS_EQUAL(max2.dimension(0), 1); + + VERIFY_IS_APPROX(max1(0), max2(0)); + } + + reduction_axis[0] = 0; + reduction_axis[1] = 1; + result = tensor.minimum(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 5); + VERIFY_IS_EQUAL(result.dimension(1), 7); + for (int i = 0; i < 5; ++i) { + for (int j = 0; j < 7; ++j) { + float min_val = (std::numeric_limits<float>::max)(); + for (int k = 0; k < 2; ++k) { + for (int l = 0; l < 3; ++l) { + min_val = (std::min)(min_val, tensor(k, l, i, j)); + } + } + VERIFY_IS_APPROX(result(i, j), min_val); + } + } + + { + Tensor<float, 1, DataLayout> min1 = tensor.minimum(); + VERIFY_IS_EQUAL(min1.dimension(0), 1); + + array<ptrdiff_t, 4> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + reduction_axis[2] = 2; + reduction_axis[3] = 3; + Tensor<float, 1, DataLayout> min2 = tensor.minimum(reduction_axis); + VERIFY_IS_EQUAL(min2.dimension(0), 1); + + VERIFY_IS_APPROX(min1(0), min2(0)); + } + + reduction_axis[0] = 0; + reduction_axis[1] = 1; + result = tensor.mean(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 5); + VERIFY_IS_EQUAL(result.dimension(1), 7); + for (int i = 0; i < 5; ++i) { + for (int j = 0; j < 7; ++j) { + float sum = 0.0f; + int count = 0; + for (int k = 0; k < 2; ++k) { + for (int l = 0; l < 3; ++l) { + sum += tensor(k, l, i, j); + ++count; + } + } + VERIFY_IS_APPROX(result(i, j), sum / count); + } + } + + { + Tensor<float, 1, DataLayout> mean1 = tensor.mean(); + VERIFY_IS_EQUAL(mean1.dimension(0), 1); + + array<ptrdiff_t, 4> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + reduction_axis[2] = 2; + reduction_axis[3] = 3; + Tensor<float, 1, DataLayout> mean2 = tensor.mean(reduction_axis); + VERIFY_IS_EQUAL(mean2.dimension(0), 1); + + VERIFY_IS_APPROX(mean1(0), mean2(0)); + } +} + +template <int DataLayout> +static void test_full_reductions() { + Tensor<float, 2, DataLayout> tensor(2, 3); + tensor.setRandom(); + array<ptrdiff_t, 2> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; + + Tensor<float, 1, DataLayout> result = tensor.sum(reduction_axis); + VERIFY_IS_EQUAL(result.dimension(0), 1); + + float sum = 0.0f; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + sum += tensor(i, j); + } + } + VERIFY_IS_APPROX(result(0), sum); + + result = tensor.square().sum(reduction_axis).sqrt(); + VERIFY_IS_EQUAL(result.dimension(0), 1); + + sum = 0.0f; + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + sum += tensor(i, j) * tensor(i, j); + } + } + VERIFY_IS_APPROX(result(0), sqrtf(sum)); +} + +struct UserReducer { + static const bool PacketAccess = false; + UserReducer(float offset) : offset_(offset) {} + void reduce(const float val, float* accum) { *accum += val * val; } + float initialize() const { return 0; } + float finalize(const float accum) const { return 1.0f / (accum + offset_); } + + private: + const float offset_; +}; + +template <int DataLayout> +static void test_user_defined_reductions() { + Tensor<float, 2, DataLayout> tensor(5, 7); + tensor.setRandom(); + array<ptrdiff_t, 1> reduction_axis; + reduction_axis[0] = 1; + + UserReducer reducer(10.0f); + Tensor<float, 1, DataLayout> result = tensor.reduce(reduction_axis, reducer); + VERIFY_IS_EQUAL(result.dimension(0), 5); + for (int i = 0; i < 5; ++i) { + float expected = 10.0f; + for (int j = 0; j < 7; ++j) { + expected += tensor(i, j) * tensor(i, j); + } + expected = 1.0f / expected; + VERIFY_IS_APPROX(result(i), expected); + } +} + +template <int DataLayout> +static void test_tensor_maps() { + int inputs[2 * 3 * 5 * 7]; + TensorMap<Tensor<int, 4, DataLayout> > tensor_map(inputs, 2, 3, 5, 7); + TensorMap<Tensor<const int, 4, DataLayout> > tensor_map_const(inputs, 2, 3, 5, + 7); + const TensorMap<Tensor<const int, 4, DataLayout> > tensor_map_const_const( + inputs, 2, 3, 5, 7); + + tensor_map.setRandom(); + array<ptrdiff_t, 2> reduction_axis; + reduction_axis[0] = 1; + reduction_axis[1] = 3; + + Tensor<int, 2, DataLayout> result = tensor_map.sum(reduction_axis); + Tensor<int, 2, DataLayout> result2 = tensor_map_const.sum(reduction_axis); + Tensor<int, 2, DataLayout> result3 = + tensor_map_const_const.sum(reduction_axis); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 5; ++j) { + int sum = 0; + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 7; ++l) { + sum += tensor_map(i, k, j, l); + } + } + VERIFY_IS_EQUAL(result(i, j), sum); + VERIFY_IS_EQUAL(result2(i, j), sum); + VERIFY_IS_EQUAL(result3(i, j), sum); + } + } +} + +template <int DataLayout> +static void test_static_dims() { + Tensor<float, 4, DataLayout> in(72, 53, 97, 113); + Tensor<float, 2, DataLayout> out(72, 97); + in.setRandom(); + +#ifndef EIGEN_HAS_CONSTEXPR + array<int, 2> reduction_axis; + reduction_axis[0] = 1; + reduction_axis[1] = 3; +#else + Eigen::IndexList<Eigen::type2index<1>, Eigen::type2index<3> > reduction_axis; +#endif + + out = in.maximum(reduction_axis); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 97; ++j) { + float expected = -1e10f; + for (int k = 0; k < 53; ++k) { + for (int l = 0; l < 113; ++l) { + expected = (std::max)(expected, in(i, k, j, l)); + } + } + VERIFY_IS_APPROX(out(i, j), expected); + } + } +} + +template <int DataLayout> +static void test_innermost_last_dims() { + Tensor<float, 4, DataLayout> in(72, 53, 97, 113); + Tensor<float, 2, DataLayout> out(97, 113); + in.setRandom(); + +// Reduce on the innermost dimensions. +#ifndef EIGEN_HAS_CONSTEXPR + array<int, 2> reduction_axis; + reduction_axis[0] = 0; + reduction_axis[1] = 1; +#else + // This triggers the use of packets for ColMajor. + Eigen::IndexList<Eigen::type2index<0>, Eigen::type2index<1> > reduction_axis; +#endif + + out = in.maximum(reduction_axis); + + for (int i = 0; i < 97; ++i) { + for (int j = 0; j < 113; ++j) { + float expected = -1e10f; + for (int k = 0; k < 53; ++k) { + for (int l = 0; l < 72; ++l) { + expected = (std::max)(expected, in(l, k, i, j)); + } + } + VERIFY_IS_APPROX(out(i, j), expected); + } + } +} + +template <int DataLayout> +static void test_innermost_first_dims() { + Tensor<float, 4, DataLayout> in(72, 53, 97, 113); + Tensor<float, 2, DataLayout> out(72, 53); + in.setRandom(); + +// Reduce on the innermost dimensions. +#ifndef EIGEN_HAS_CONSTEXPR + array<int, 2> reduction_axis; + reduction_axis[0] = 2; + reduction_axis[1] = 3; +#else + // This triggers the use of packets for RowMajor. + Eigen::IndexList<Eigen::type2index<2>, Eigen::type2index<3>> reduction_axis; +#endif + + out = in.maximum(reduction_axis); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 53; ++j) { + float expected = -1e10f; + for (int k = 0; k < 97; ++k) { + for (int l = 0; l < 113; ++l) { + expected = (std::max)(expected, in(i, j, k, l)); + } + } + VERIFY_IS_APPROX(out(i, j), expected); + } + } +} + +template <int DataLayout> +static void test_reduce_middle_dims() { + Tensor<float, 4, DataLayout> in(72, 53, 97, 113); + Tensor<float, 2, DataLayout> out(72, 53); + in.setRandom(); + +// Reduce on the innermost dimensions. +#ifndef EIGEN_HAS_CONSTEXPR + array<int, 2> reduction_axis; + reduction_axis[0] = 1; + reduction_axis[1] = 2; +#else + // This triggers the use of packets for RowMajor. + Eigen::IndexList<Eigen::type2index<1>, Eigen::type2index<2>> reduction_axis; +#endif + + out = in.maximum(reduction_axis); + + for (int i = 0; i < 72; ++i) { + for (int j = 0; j < 113; ++j) { + float expected = -1e10f; + for (int k = 0; k < 53; ++k) { + for (int l = 0; l < 97; ++l) { + expected = (std::max)(expected, in(i, k, l, j)); + } + } + VERIFY_IS_APPROX(out(i, j), expected); + } + } +} + +void test_cxx11_tensor_reduction() { + CALL_SUBTEST(test_simple_reductions<ColMajor>()); + CALL_SUBTEST(test_simple_reductions<RowMajor>()); + CALL_SUBTEST(test_full_reductions<ColMajor>()); + CALL_SUBTEST(test_full_reductions<RowMajor>()); + CALL_SUBTEST(test_user_defined_reductions<ColMajor>()); + CALL_SUBTEST(test_user_defined_reductions<RowMajor>()); + CALL_SUBTEST(test_tensor_maps<ColMajor>()); + CALL_SUBTEST(test_tensor_maps<RowMajor>()); + CALL_SUBTEST(test_static_dims<ColMajor>()); + CALL_SUBTEST(test_static_dims<RowMajor>()); + CALL_SUBTEST(test_innermost_last_dims<ColMajor>()); + CALL_SUBTEST(test_innermost_last_dims<RowMajor>()); + CALL_SUBTEST(test_innermost_first_dims<ColMajor>()); + CALL_SUBTEST(test_innermost_first_dims<RowMajor>()); + CALL_SUBTEST(test_reduce_middle_dims<ColMajor>()); + CALL_SUBTEST(test_reduce_middle_dims<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_ref.cpp b/unsupported/test/cxx11_tensor_ref.cpp new file mode 100644 index 000000000..aa369f278 --- /dev/null +++ b/unsupported/test/cxx11_tensor_ref.cpp @@ -0,0 +1,208 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::RowMajor; + +static void test_simple_lvalue_ref() +{ + Tensor<int, 1> input(6); + input.setRandom(); + + TensorRef<Tensor<int, 1>> ref3(input); + TensorRef<Tensor<int, 1>> ref4 = input; + + VERIFY_IS_EQUAL(ref3.data(), input.data()); + VERIFY_IS_EQUAL(ref4.data(), input.data()); + + for (int i = 0; i < 6; ++i) { + VERIFY_IS_EQUAL(ref3(i), input(i)); + VERIFY_IS_EQUAL(ref4(i), input(i)); + } + + for (int i = 0; i < 6; ++i) { + ref3.coeffRef(i) = i; + } + for (int i = 0; i < 6; ++i) { + VERIFY_IS_EQUAL(input(i), i); + } + for (int i = 0; i < 6; ++i) { + ref4.coeffRef(i) = -i * 2; + } + for (int i = 0; i < 6; ++i) { + VERIFY_IS_EQUAL(input(i), -i*2); + } +} + + +static void test_simple_rvalue_ref() +{ + Tensor<int, 1> input1(6); + input1.setRandom(); + Tensor<int, 1> input2(6); + input2.setRandom(); + + TensorRef<Tensor<int, 1>> ref3(input1 + input2); + TensorRef<Tensor<int, 1>> ref4 = input1 + input2; + + VERIFY_IS_NOT_EQUAL(ref3.data(), input1.data()); + VERIFY_IS_NOT_EQUAL(ref4.data(), input1.data()); + VERIFY_IS_NOT_EQUAL(ref3.data(), input2.data()); + VERIFY_IS_NOT_EQUAL(ref4.data(), input2.data()); + + for (int i = 0; i < 6; ++i) { + VERIFY_IS_EQUAL(ref3(i), input1(i) + input2(i)); + VERIFY_IS_EQUAL(ref4(i), input1(i) + input2(i)); + } +} + + +static void test_multiple_dims() +{ + Tensor<float, 3> input(3,5,7); + input.setRandom(); + + TensorRef<Tensor<float, 3>> ref(input); + VERIFY_IS_EQUAL(ref.data(), input.data()); + VERIFY_IS_EQUAL(ref.dimension(0), 3); + VERIFY_IS_EQUAL(ref.dimension(1), 5); + VERIFY_IS_EQUAL(ref.dimension(2), 7); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(ref(i,j,k), input(i,j,k)); + } + } + } +} + + +static void test_slice() +{ + Tensor<float, 5> tensor(2,3,5,7,11); + tensor.setRandom(); + + Eigen::DSizes<ptrdiff_t, 5> indices(1,2,3,4,5); + Eigen::DSizes<ptrdiff_t, 5> sizes(1,1,1,1,1); + TensorRef<Tensor<float, 5>> slice = tensor.slice(indices, sizes); + VERIFY_IS_EQUAL(slice(0,0,0,0,0), tensor(1,2,3,4,5)); + + Eigen::DSizes<ptrdiff_t, 5> indices2(1,1,3,4,5); + Eigen::DSizes<ptrdiff_t, 5> sizes2(1,1,2,2,3); + slice = tensor.slice(indices2, sizes2); + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 2; ++j) { + for (int k = 0; k < 3; ++k) { + VERIFY_IS_EQUAL(slice(0,0,i,j,k), tensor(1,1,3+i,4+j,5+k)); + } + } + } + + Eigen::DSizes<ptrdiff_t, 5> indices3(0,0,0,0,0); + Eigen::DSizes<ptrdiff_t, 5> sizes3(2,3,1,1,1); + slice = tensor.slice(indices3, sizes3); + VERIFY_IS_EQUAL(slice.data(), tensor.data()); +} + + +static void test_ref_of_ref() +{ + Tensor<float, 3> input(3,5,7); + input.setRandom(); + + TensorRef<Tensor<float, 3>> ref(input); + TensorRef<Tensor<float, 3>> ref_of_ref(ref); + TensorRef<Tensor<float, 3>> ref_of_ref2; + ref_of_ref2 = ref; + + VERIFY_IS_EQUAL(ref_of_ref.data(), input.data()); + VERIFY_IS_EQUAL(ref_of_ref.dimension(0), 3); + VERIFY_IS_EQUAL(ref_of_ref.dimension(1), 5); + VERIFY_IS_EQUAL(ref_of_ref.dimension(2), 7); + + VERIFY_IS_EQUAL(ref_of_ref2.data(), input.data()); + VERIFY_IS_EQUAL(ref_of_ref2.dimension(0), 3); + VERIFY_IS_EQUAL(ref_of_ref2.dimension(1), 5); + VERIFY_IS_EQUAL(ref_of_ref2.dimension(2), 7); + + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(ref_of_ref(i,j,k), input(i,j,k)); + VERIFY_IS_EQUAL(ref_of_ref2(i,j,k), input(i,j,k)); + } + } + } +} + + +static void test_ref_in_expr() +{ + Tensor<float, 3> input(3,5,7); + input.setRandom(); + TensorRef<Tensor<float, 3>> input_ref(input); + + Tensor<float, 3> result(3,5,7); + result.setRandom(); + TensorRef<Tensor<float, 3>> result_ref(result); + + Tensor<float, 3> bias(3,5,7); + bias.setRandom(); + + result_ref = input_ref + bias; + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(result_ref(i,j,k), input(i,j,k) + bias(i,j,k)); + VERIFY_IS_NOT_EQUAL(result(i,j,k), input(i,j,k) + bias(i,j,k)); + } + } + } + + result = result_ref; + for (int i = 0; i < 3; ++i) { + for (int j = 0; j < 5; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_EQUAL(result(i,j,k), input(i,j,k) + bias(i,j,k)); + } + } + } +} + + +static void test_coeff_ref() +{ + Tensor<float, 5> tensor(2,3,5,7,11); + tensor.setRandom(); + Tensor<float, 5> original = tensor; + + TensorRef<Tensor<float, 4>> slice = tensor.chip(7, 4); + slice.coeffRef(0, 0, 0, 0) = 1.0f; + slice.coeffRef(1, 0, 0, 0) += 2.0f; + + VERIFY_IS_EQUAL(tensor(0,0,0,0,7), 1.0f); + VERIFY_IS_EQUAL(tensor(1,0,0,0,7), original(1,0,0,0,7) + 2.0f); +} + + +void test_cxx11_tensor_ref() +{ + CALL_SUBTEST(test_simple_lvalue_ref()); + CALL_SUBTEST(test_simple_rvalue_ref()); + CALL_SUBTEST(test_multiple_dims()); + CALL_SUBTEST(test_slice()); + CALL_SUBTEST(test_ref_of_ref()); + CALL_SUBTEST(test_ref_in_expr()); + CALL_SUBTEST(test_coeff_ref()); +} diff --git a/unsupported/test/cxx11_tensor_reverse.cpp b/unsupported/test/cxx11_tensor_reverse.cpp new file mode 100644 index 000000000..4c0be35da --- /dev/null +++ b/unsupported/test/cxx11_tensor_reverse.cpp @@ -0,0 +1,167 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Navdeep Jaitly <ndjaitly@google.com and +// Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::array; + +template <int DataLayout> +static void test_simple_reverse() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + + array<bool, 4> dim_rev; + dim_rev[0] = false; + dim_rev[1] = true; + dim_rev[2] = true; + dim_rev[3] = false; + + Tensor<float, 4, DataLayout> reversed_tensor; + reversed_tensor = tensor.reverse(dim_rev); + + VERIFY_IS_EQUAL(reversed_tensor.dimension(0), 2); + VERIFY_IS_EQUAL(reversed_tensor.dimension(1), 3); + VERIFY_IS_EQUAL(reversed_tensor.dimension(2), 5); + VERIFY_IS_EQUAL(reversed_tensor.dimension(3), 7); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), reversed_tensor(i,2-j,4-k,l)); + } + } + } + } + + dim_rev[0] = true; + dim_rev[1] = false; + dim_rev[2] = false; + dim_rev[3] = false; + + reversed_tensor = tensor.reverse(dim_rev); + + VERIFY_IS_EQUAL(reversed_tensor.dimension(0), 2); + VERIFY_IS_EQUAL(reversed_tensor.dimension(1), 3); + VERIFY_IS_EQUAL(reversed_tensor.dimension(2), 5); + VERIFY_IS_EQUAL(reversed_tensor.dimension(3), 7); + + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), reversed_tensor(1-i,j,k,l)); + } + } + } + } + + dim_rev[0] = true; + dim_rev[1] = false; + dim_rev[2] = false; + dim_rev[3] = true; + + reversed_tensor = tensor.reverse(dim_rev); + + VERIFY_IS_EQUAL(reversed_tensor.dimension(0), 2); + VERIFY_IS_EQUAL(reversed_tensor.dimension(1), 3); + VERIFY_IS_EQUAL(reversed_tensor.dimension(2), 5); + VERIFY_IS_EQUAL(reversed_tensor.dimension(3), 7); + + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), reversed_tensor(1-i,j,k,6-l)); + } + } + } + } +} + + +template <int DataLayout> +static void test_expr_reverse() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + + array<bool, 4> dim_rev; + dim_rev[0] = false; + dim_rev[1] = true; + dim_rev[2] = false; + dim_rev[3] = true; + + + Tensor<float, 4, DataLayout> expected; + expected = tensor.reverse(dim_rev); + + Tensor<float, 4, DataLayout> result(2,3,5,7); + + array<ptrdiff_t, 4> src_slice_dim{{2,3,1,7}}; + array<ptrdiff_t, 4> src_slice_start{{0,0,0,0}}; + array<ptrdiff_t, 4> dst_slice_dim{{2,3,1,7}}; + array<ptrdiff_t, 4> dst_slice_start{{0,0,0,0}}; + + for (int i = 0; i < 5; ++i) { + result.slice(dst_slice_start, dst_slice_dim) = + tensor.slice(src_slice_start, src_slice_dim).reverse(dim_rev); + src_slice_start[2] += 1; + dst_slice_start[2] += 1; + } + + VERIFY_IS_EQUAL(result.dimension(0), 2); + VERIFY_IS_EQUAL(result.dimension(1), 3); + VERIFY_IS_EQUAL(result.dimension(2), 5); + VERIFY_IS_EQUAL(result.dimension(3), 7); + + for (int i = 0; i < expected.dimension(0); ++i) { + for (int j = 0; j < expected.dimension(1); ++j) { + for (int k = 0; k < expected.dimension(2); ++k) { + for (int l = 0; l < expected.dimension(3); ++l) { + VERIFY_IS_EQUAL(result(i,j,k,l), expected(i,j,k,l)); + } + } + } + } + + dst_slice_start[2] = 0; + result.setRandom(); + for (int i = 0; i < 5; ++i) { + result.slice(dst_slice_start, dst_slice_dim) = + tensor.reverse(dim_rev).slice(dst_slice_start, dst_slice_dim); + dst_slice_start[2] += 1; + } + + for (int i = 0; i < expected.dimension(0); ++i) { + for (int j = 0; j < expected.dimension(1); ++j) { + for (int k = 0; k < expected.dimension(2); ++k) { + for (int l = 0; l < expected.dimension(3); ++l) { + VERIFY_IS_EQUAL(result(i,j,k,l), expected(i,j,k,l)); + } + } + } + } +} + + +void test_cxx11_tensor_reverse() +{ + CALL_SUBTEST(test_simple_reverse<ColMajor>()); + CALL_SUBTEST(test_simple_reverse<RowMajor>()); + CALL_SUBTEST(test_expr_reverse<ColMajor>()); + CALL_SUBTEST(test_expr_reverse<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_shuffling.cpp b/unsupported/test/cxx11_tensor_shuffling.cpp new file mode 100644 index 000000000..2f7fd9e50 --- /dev/null +++ b/unsupported/test/cxx11_tensor_shuffling.cpp @@ -0,0 +1,187 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; +using Eigen::array; + +template <int DataLayout> +static void test_simple_shuffling() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> shuffles; + shuffles[0] = 0; + shuffles[1] = 1; + shuffles[2] = 2; + shuffles[3] = 3; + + Tensor<float, 4, DataLayout> no_shuffle; + no_shuffle = tensor.shuffle(shuffles); + + VERIFY_IS_EQUAL(no_shuffle.dimension(0), 2); + VERIFY_IS_EQUAL(no_shuffle.dimension(1), 3); + VERIFY_IS_EQUAL(no_shuffle.dimension(2), 5); + VERIFY_IS_EQUAL(no_shuffle.dimension(3), 7); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), no_shuffle(i,j,k,l)); + } + } + } + } + + shuffles[0] = 2; + shuffles[1] = 3; + shuffles[2] = 1; + shuffles[3] = 0; + Tensor<float, 4, DataLayout> shuffle; + shuffle = tensor.shuffle(shuffles); + + VERIFY_IS_EQUAL(shuffle.dimension(0), 5); + VERIFY_IS_EQUAL(shuffle.dimension(1), 7); + VERIFY_IS_EQUAL(shuffle.dimension(2), 3); + VERIFY_IS_EQUAL(shuffle.dimension(3), 2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), shuffle(k,l,j,i)); + } + } + } + } +} + + +template <int DataLayout> +static void test_expr_shuffling() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + + array<ptrdiff_t, 4> shuffles; + shuffles[0] = 2; + shuffles[1] = 3; + shuffles[2] = 1; + shuffles[3] = 0; + Tensor<float, 4, DataLayout> expected; + expected = tensor.shuffle(shuffles); + + Tensor<float, 4, DataLayout> result(5,7,3,2); + + array<int, 4> src_slice_dim{{2,3,1,7}}; + array<int, 4> src_slice_start{{0,0,0,0}}; + array<int, 4> dst_slice_dim{{1,7,3,2}}; + array<int, 4> dst_slice_start{{0,0,0,0}}; + + for (int i = 0; i < 5; ++i) { + result.slice(dst_slice_start, dst_slice_dim) = + tensor.slice(src_slice_start, src_slice_dim).shuffle(shuffles); + src_slice_start[2] += 1; + dst_slice_start[0] += 1; + } + + VERIFY_IS_EQUAL(result.dimension(0), 5); + VERIFY_IS_EQUAL(result.dimension(1), 7); + VERIFY_IS_EQUAL(result.dimension(2), 3); + VERIFY_IS_EQUAL(result.dimension(3), 2); + + for (int i = 0; i < expected.dimension(0); ++i) { + for (int j = 0; j < expected.dimension(1); ++j) { + for (int k = 0; k < expected.dimension(2); ++k) { + for (int l = 0; l < expected.dimension(3); ++l) { + VERIFY_IS_EQUAL(result(i,j,k,l), expected(i,j,k,l)); + } + } + } + } + + dst_slice_start[0] = 0; + result.setRandom(); + for (int i = 0; i < 5; ++i) { + result.slice(dst_slice_start, dst_slice_dim) = + tensor.shuffle(shuffles).slice(dst_slice_start, dst_slice_dim); + dst_slice_start[0] += 1; + } + + for (int i = 0; i < expected.dimension(0); ++i) { + for (int j = 0; j < expected.dimension(1); ++j) { + for (int k = 0; k < expected.dimension(2); ++k) { + for (int l = 0; l < expected.dimension(3); ++l) { + VERIFY_IS_EQUAL(result(i,j,k,l), expected(i,j,k,l)); + } + } + } + } +} + + +template <int DataLayout> +static void test_shuffling_as_value() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> shuffles; + shuffles[2] = 0; + shuffles[3] = 1; + shuffles[1] = 2; + shuffles[0] = 3; + Tensor<float, 4, DataLayout> shuffle(5,7,3,2); + shuffle.shuffle(shuffles) = tensor; + + VERIFY_IS_EQUAL(shuffle.dimension(0), 5); + VERIFY_IS_EQUAL(shuffle.dimension(1), 7); + VERIFY_IS_EQUAL(shuffle.dimension(2), 3); + VERIFY_IS_EQUAL(shuffle.dimension(3), 2); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), shuffle(k,l,j,i)); + } + } + } + } + + array<ptrdiff_t, 4> no_shuffle; + no_shuffle[0] = 0; + no_shuffle[1] = 1; + no_shuffle[2] = 2; + no_shuffle[3] = 3; + Tensor<float, 4, DataLayout> shuffle2(5,7,3,2); + shuffle2.shuffle(shuffles) = tensor.shuffle(no_shuffle); + for (int i = 0; i < 5; ++i) { + for (int j = 0; j < 7; ++j) { + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 2; ++l) { + VERIFY_IS_EQUAL(shuffle2(i,j,k,l), shuffle(i,j,k,l)); + } + } + } + } +} + +void test_cxx11_tensor_shuffling() +{ + CALL_SUBTEST(test_simple_shuffling<ColMajor>()); + CALL_SUBTEST(test_simple_shuffling<RowMajor>()); + CALL_SUBTEST(test_expr_shuffling<ColMajor>()); + CALL_SUBTEST(test_expr_shuffling<RowMajor>()); + CALL_SUBTEST(test_shuffling_as_value<ColMajor>()); + CALL_SUBTEST(test_shuffling_as_value<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_simple.cpp b/unsupported/test/cxx11_tensor_simple.cpp index ea512c9cc..23855fca0 100644 --- a/unsupported/test/cxx11_tensor_simple.cpp +++ b/unsupported/test/cxx11_tensor_simple.cpp @@ -32,6 +32,7 @@ static void test_1d() vec1(5) = 42; vec2(5) = 5; vec3(5) = 0; vec4.setZero(); + VERIFY_IS_EQUAL((vec1.rank()), 1); VERIFY_IS_EQUAL((vec1.size()), 6); VERIFY_IS_EQUAL((vec1.dimensions()[0]), 6); @@ -99,10 +100,12 @@ static void test_2d() mat2(1,1) = 4; mat2(1,2) = 5; + VERIFY_IS_EQUAL((mat1.rank()), 2); VERIFY_IS_EQUAL((mat1.size()), 6); VERIFY_IS_EQUAL((mat1.dimensions()[0]), 2); VERIFY_IS_EQUAL((mat1.dimensions()[1]), 3); + VERIFY_IS_EQUAL((mat2.rank()), 2); VERIFY_IS_EQUAL((mat2.size()), 6); VERIFY_IS_EQUAL((mat2.dimensions()[0]), 2); VERIFY_IS_EQUAL((mat2.dimensions()[1]), 3); @@ -163,7 +166,7 @@ static void test_3d() VERIFY_IS_EQUAL((epsilon(0,2,1)), -1); VERIFY_IS_EQUAL((epsilon(1,0,2)), -1); - std::array<Eigen::DenseIndex, 3> dims{{2,3,4}}; + array<Eigen::DenseIndex, 3> dims{{2,3,4}}; Tensor<int, 3> t1(dims); Tensor<int, 3, RowMajor> t2(dims); @@ -244,7 +247,7 @@ static void test_simple_assign() epsilon(0,1,2) = epsilon(2,0,1) = epsilon(1,2,0) = 1; epsilon(2,1,0) = epsilon(0,2,1) = epsilon(1,0,2) = -1; - Tensor<int, 3> e2(2,3,1); + Tensor<int, 3> e2(3,3,3); e2.setZero(); VERIFY_IS_EQUAL((e2(1,2,0)), 0); @@ -257,12 +260,38 @@ static void test_simple_assign() VERIFY_IS_EQUAL((e2(1,0,2)), -1); } +static void test_resize() +{ + Tensor<int, 3> epsilon; + epsilon.resize(2,3,7); + VERIFY_IS_EQUAL(epsilon.dimension(0), 2); + VERIFY_IS_EQUAL(epsilon.dimension(1), 3); + VERIFY_IS_EQUAL(epsilon.dimension(2), 7); + VERIFY_IS_EQUAL(epsilon.dimensions().TotalSize(), 2ul*3*7); + + const int* old_data = epsilon.data(); + epsilon.resize(3,2,7); + VERIFY_IS_EQUAL(epsilon.dimension(0), 3); + VERIFY_IS_EQUAL(epsilon.dimension(1), 2); + VERIFY_IS_EQUAL(epsilon.dimension(2), 7); + VERIFY_IS_EQUAL(epsilon.dimensions().TotalSize(), 2ul*3*7); + VERIFY_IS_EQUAL(epsilon.data(), old_data); + + epsilon.resize(3,5,7); + VERIFY_IS_EQUAL(epsilon.dimension(0), 3); + VERIFY_IS_EQUAL(epsilon.dimension(1), 5); + VERIFY_IS_EQUAL(epsilon.dimension(2), 7); + VERIFY_IS_EQUAL(epsilon.dimensions().TotalSize(), 3ul*5*7); + VERIFY_IS_NOT_EQUAL(epsilon.data(), old_data); +} + void test_cxx11_tensor_simple() { CALL_SUBTEST(test_1d()); CALL_SUBTEST(test_2d()); CALL_SUBTEST(test_3d()); CALL_SUBTEST(test_simple_assign()); + CALL_SUBTEST(test_resize()); } /* diff --git a/unsupported/test/cxx11_tensor_striding.cpp b/unsupported/test/cxx11_tensor_striding.cpp new file mode 100644 index 000000000..935b908cc --- /dev/null +++ b/unsupported/test/cxx11_tensor_striding.cpp @@ -0,0 +1,119 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#include "main.h" + +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + +template<int DataLayout> +static void test_simple_striding() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> strides; + strides[0] = 1; + strides[1] = 1; + strides[2] = 1; + strides[3] = 1; + + Tensor<float, 4, DataLayout> no_stride; + no_stride = tensor.stride(strides); + + VERIFY_IS_EQUAL(no_stride.dimension(0), 2); + VERIFY_IS_EQUAL(no_stride.dimension(1), 3); + VERIFY_IS_EQUAL(no_stride.dimension(2), 5); + VERIFY_IS_EQUAL(no_stride.dimension(3), 7); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), no_stride(i,j,k,l)); + } + } + } + } + + strides[0] = 2; + strides[1] = 4; + strides[2] = 2; + strides[3] = 3; + Tensor<float, 4, DataLayout> stride; + stride = tensor.stride(strides); + + VERIFY_IS_EQUAL(stride.dimension(0), 1); + VERIFY_IS_EQUAL(stride.dimension(1), 1); + VERIFY_IS_EQUAL(stride.dimension(2), 3); + VERIFY_IS_EQUAL(stride.dimension(3), 3); + + for (int i = 0; i < 1; ++i) { + for (int j = 0; j < 1; ++j) { + for (int k = 0; k < 3; ++k) { + for (int l = 0; l < 3; ++l) { + VERIFY_IS_EQUAL(tensor(2*i,4*j,2*k,3*l), stride(i,j,k,l)); + } + } + } + } +} + + +template<int DataLayout> +static void test_striding_as_lvalue() +{ + Tensor<float, 4, DataLayout> tensor(2,3,5,7); + tensor.setRandom(); + array<ptrdiff_t, 4> strides; + strides[0] = 2; + strides[1] = 4; + strides[2] = 2; + strides[3] = 3; + + Tensor<float, 4, DataLayout> result(3, 12, 10, 21); + result.stride(strides) = tensor; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), result(2*i,4*j,2*k,3*l)); + } + } + } + } + + array<ptrdiff_t, 4> no_strides; + no_strides[0] = 1; + no_strides[1] = 1; + no_strides[2] = 1; + no_strides[3] = 1; + Tensor<float, 4, DataLayout> result2(3, 12, 10, 21); + result2.stride(strides) = tensor.stride(no_strides); + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 5; ++k) { + for (int l = 0; l < 7; ++l) { + VERIFY_IS_EQUAL(tensor(i,j,k,l), result2(2*i,4*j,2*k,3*l)); + } + } + } + } +} + + +void test_cxx11_tensor_striding() +{ + CALL_SUBTEST(test_simple_striding<ColMajor>()); + CALL_SUBTEST(test_simple_striding<RowMajor>()); + CALL_SUBTEST(test_striding_as_lvalue<ColMajor>()); + CALL_SUBTEST(test_striding_as_lvalue<RowMajor>()); +} diff --git a/unsupported/test/cxx11_tensor_thread_pool.cpp b/unsupported/test/cxx11_tensor_thread_pool.cpp new file mode 100644 index 000000000..6fe65c7f9 --- /dev/null +++ b/unsupported/test/cxx11_tensor_thread_pool.cpp @@ -0,0 +1,270 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> +// +// This Source Code Form is subject to the terms of the Mozilla +// Public License v. 2.0. If a copy of the MPL was not distributed +// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. + +#define EIGEN_USE_THREADS + + +#include "main.h" +#include <iostream> +#include <Eigen/CXX11/Tensor> + +using Eigen::Tensor; + + +static void test_multithread_elementwise() +{ + Tensor<float, 3> in1(2,3,7); + Tensor<float, 3> in2(2,3,7); + Tensor<float, 3> out(2,3,7); + + in1.setRandom(); + in2.setRandom(); + + Eigen::ThreadPoolDevice thread_pool_device(internal::random<int>(3, 11)); + out.device(thread_pool_device) = in1 + in2 * 3.14f; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f); + } + } + } +} + + +static void test_multithread_compound_assignment() +{ + Tensor<float, 3> in1(2,3,7); + Tensor<float, 3> in2(2,3,7); + Tensor<float, 3> out(2,3,7); + + in1.setRandom(); + in2.setRandom(); + + Eigen::ThreadPoolDevice thread_pool_device(internal::random<int>(3, 11)); + out.device(thread_pool_device) = in1; + out.device(thread_pool_device) += in2 * 3.14f; + + for (int i = 0; i < 2; ++i) { + for (int j = 0; j < 3; ++j) { + for (int k = 0; k < 7; ++k) { + VERIFY_IS_APPROX(out(i,j,k), in1(i,j,k) + in2(i,j,k) * 3.14f); + } + } + } +} + +template<int DataLayout> +static void test_multithread_contraction() +{ + Tensor<float, 4, DataLayout> t_left(30, 50, 37, 31); + Tensor<float, 5, DataLayout> t_right(37, 31, 70, 2, 10); + Tensor<float, 5, DataLayout> t_result(30, 50, 70, 2, 10); + + t_left.setRandom(); + t_right.setRandom(); + + // this contraction should be equivalent to a single matrix multiplication + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 2> dims({{DimPair(2, 0), DimPair(3, 1)}}); + + typedef Map<Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf; + MapXf m_left(t_left.data(), 1500, 1147); + MapXf m_right(t_right.data(), 1147, 1400); + Matrix<float, Dynamic, Dynamic, DataLayout> m_result(1500, 1400); + + Eigen::ThreadPoolDevice thread_pool_device(4); + + // compute results by separate methods + t_result.device(thread_pool_device) = t_left.contract(t_right, dims); + m_result = m_left * m_right; + + for (ptrdiff_t i = 0; i < t_result.size(); i++) { + VERIFY(&t_result.data()[i] != &m_result.data()[i]); + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + std::cout << "mismatch detected: " << t_result.data()[i] << " vs " << m_result.data()[i] << std::endl; + assert(false); + } + } +} + +template<int DataLayout> +static void test_contraction_corner_cases() +{ + Tensor<float, 2, DataLayout> t_left(32, 500); + Tensor<float, 2, DataLayout> t_right(32, 28*28); + Tensor<float, 2, DataLayout> t_result(500, 28*28); + + t_left = (t_left.constant(-0.5f) + t_left.random()) * 2.0f; + t_right = (t_right.constant(-0.6f) + t_right.random()) * 2.0f; + t_result = t_result.constant(NAN); + + // this contraction should be equivalent to a single matrix multiplication + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 1> dims{{DimPair(0, 0)}}; + + typedef Map<Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf; + MapXf m_left(t_left.data(), 32, 500); + MapXf m_right(t_right.data(), 32, 28*28); + Matrix<float, Dynamic, Dynamic, DataLayout> m_result(500, 28*28); + + Eigen::ThreadPoolDevice thread_pool_device(12); + + // compute results by separate methods + t_result.device(thread_pool_device) = t_left.contract(t_right, dims); + m_result = m_left.transpose() * m_right; + + for (ptrdiff_t i = 0; i < t_result.size(); i++) { + assert(!std::isnan(t_result.data()[i])); + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + std::cout << "mismatch detected at index " << i << " : " << t_result.data()[i] << " vs " << m_result.data()[i] << std::endl; + assert(false); + } + } + + t_left.resize(32, 1); + t_left = (t_left.constant(-0.5f) + t_left.random()) * 2.0f; + t_result.resize (1, 28*28); + t_result = t_result.constant(NAN); + t_result.device(thread_pool_device) = t_left.contract(t_right, dims); + new(&m_left) MapXf(t_left.data(), 32, 1); + m_result = m_left.transpose() * m_right; + for (ptrdiff_t i = 0; i < t_result.size(); i++) { + assert(!std::isnan(t_result.data()[i])); + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + std::cout << "mismatch detected: " << t_result.data()[i] << " vs " << m_result.data()[i] << std::endl; + assert(false); + } + } + + t_left.resize(32, 500); + t_right.resize(32, 4); + t_left = (t_left.constant(-0.5f) + t_left.random()) * 2.0f; + t_right = (t_right.constant(-0.6f) + t_right.random()) * 2.0f; + t_result.resize (500, 4); + t_result = t_result.constant(NAN); + t_result.device(thread_pool_device) = t_left.contract(t_right, dims); + new(&m_left) MapXf(t_left.data(), 32, 500); + new(&m_right) MapXf(t_right.data(), 32, 4); + m_result = m_left.transpose() * m_right; + for (ptrdiff_t i = 0; i < t_result.size(); i++) { + assert(!std::isnan(t_result.data()[i])); + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + std::cout << "mismatch detected: " << t_result.data()[i] << " vs " << m_result.data()[i] << std::endl; + assert(false); + } + } + + t_left.resize(32, 1); + t_right.resize(32, 4); + t_left = (t_left.constant(-0.5f) + t_left.random()) * 2.0f; + t_right = (t_right.constant(-0.6f) + t_right.random()) * 2.0f; + t_result.resize (1, 4); + t_result = t_result.constant(NAN); + t_result.device(thread_pool_device) = t_left.contract(t_right, dims); + new(&m_left) MapXf(t_left.data(), 32, 1); + new(&m_right) MapXf(t_right.data(), 32, 4); + m_result = m_left.transpose() * m_right; + for (ptrdiff_t i = 0; i < t_result.size(); i++) { + assert(!std::isnan(t_result.data()[i])); + if (fabs(t_result.data()[i] - m_result.data()[i]) >= 1e-4) { + std::cout << "mismatch detected: " << t_result.data()[i] << " vs " << m_result.data()[i] << std::endl; + assert(false); + } + } +} + +template<int DataLayout> +static void test_multithread_contraction_agrees_with_singlethread() { + int contract_size = internal::random<int>(1, 5000); + + Tensor<float, 3, DataLayout> left(internal::random<int>(1, 80), + contract_size, + internal::random<int>(1, 100)); + + Tensor<float, 4, DataLayout> right(internal::random<int>(1, 25), + internal::random<int>(1, 37), + contract_size, + internal::random<int>(1, 51)); + + left.setRandom(); + right.setRandom(); + + // add constants to shift values away from 0 for more precision + left += left.constant(1.5f); + right += right.constant(1.5f); + + typedef Tensor<float, 1>::DimensionPair DimPair; + Eigen::array<DimPair, 1> dims({{DimPair(1, 2)}}); + + Eigen::ThreadPoolDevice thread_pool_device(internal::random<int>(2, 11)); + + Tensor<float, 5, DataLayout> st_result; + st_result = left.contract(right, dims); + + Tensor<float, 5, DataLayout> tp_result(st_result.dimensions()); + tp_result.device(thread_pool_device) = left.contract(right, dims); + + VERIFY(dimensions_match(st_result.dimensions(), tp_result.dimensions())); + for (ptrdiff_t i = 0; i < st_result.size(); i++) { + // if both of the values are very small, then do nothing (because the test will fail + // due to numerical precision issues when values are small) + if (fabs(st_result.data()[i] - tp_result.data()[i]) >= 1e-4) { + VERIFY_IS_APPROX(st_result.data()[i], tp_result.data()[i]); + } + } +} + + +static void test_memcpy() { + + for (int i = 0; i < 5; ++i) { + const int num_threads = internal::random<int>(3, 11); + Eigen::ThreadPoolDevice thread_pool_device(num_threads); + + const int size = internal::random<int>(13, 7632); + Tensor<float, 1> t1(size); + t1.setRandom(); + std::vector<float> result(size); + thread_pool_device.memcpy(&result[0], t1.data(), size*sizeof(float)); + for (int i = 0; i < size; i++) { + VERIFY_IS_EQUAL(t1(i), result[i]); + } + } +} + + +static void test_multithread_random() +{ + Eigen::ThreadPoolDevice device(2); + Tensor<float, 1> t(1 << 20); + t.device(device) = t.random<Eigen::internal::NormalRandomGenerator<float>>(); +} + + +void test_cxx11_tensor_thread_pool() +{ + CALL_SUBTEST(test_multithread_elementwise()); + CALL_SUBTEST(test_multithread_compound_assignment()); + + CALL_SUBTEST(test_multithread_contraction<ColMajor>()); + CALL_SUBTEST(test_multithread_contraction<RowMajor>()); + + CALL_SUBTEST(test_multithread_contraction_agrees_with_singlethread<ColMajor>()); + CALL_SUBTEST(test_multithread_contraction_agrees_with_singlethread<RowMajor>()); + + // Exercise various cases that have been problematic in the past. + CALL_SUBTEST(test_contraction_corner_cases<ColMajor>()); + CALL_SUBTEST(test_contraction_corner_cases<RowMajor>()); + + CALL_SUBTEST(test_memcpy()); + + CALL_SUBTEST(test_multithread_random()); +} diff --git a/unsupported/test/minres.cpp b/unsupported/test/minres.cpp index 81b762c37..8b300b78a 100644 --- a/unsupported/test/minres.cpp +++ b/unsupported/test/minres.cpp @@ -21,6 +21,7 @@ template<typename T> void test_minres_T() // Diagonal preconditioner MINRES<SparseMatrix<T>, Lower, DiagonalPreconditioner<T> > minres_colmajor_lower_diag; MINRES<SparseMatrix<T>, Upper, DiagonalPreconditioner<T> > minres_colmajor_upper_diag; + MINRES<SparseMatrix<T>, Lower|Upper, DiagonalPreconditioner<T> > minres_colmajor_uplo_diag; // call tests for SPD matrix CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_lower_I) ); @@ -28,6 +29,7 @@ template<typename T> void test_minres_T() CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_lower_diag) ); CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_upper_diag) ); + CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_uplo_diag) ); // TO DO: symmetric semi-definite matrix // TO DO: symmetric indefinite matrix |