/* Copyright 2018 The TensorFlow Authors. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. ==============================================================================*/ #include "tensorflow/compiler/xla/service/gpu/stream_executor_util.h" #include "tensorflow/compiler/xla/layout_util.h" #include "tensorflow/compiler/xla/service/hlo_instruction.h" #include "tensorflow/compiler/xla/util.h" namespace xla { namespace gpu { using se::dnn::DataLayout; using se::dnn::DataLayoutString; using se::dnn::FilterLayout; using se::dnn::FilterLayoutString; bool IsVoltaOrLater(const se::StreamExecutor& stream_executor) { int major, minor; CHECK(stream_executor.GetDeviceDescription().cuda_compute_capability(&major, &minor)); return major >= 7; } StatusOr> StreamExecutorConvLayoutsToXlaLayouts(const ConvolutionDimensionNumbers& dnums, DataLayout input, FilterLayout filter, DataLayout output) { std::vector input_layout; switch (input) { case DataLayout::kBatchDepthYX: input_layout.push_back(dnums.input_batch_dimension()); input_layout.push_back(dnums.input_feature_dimension()); input_layout.insert(input_layout.end(), dnums.input_spatial_dimensions().begin(), dnums.input_spatial_dimensions().end()); break; case DataLayout::kBatchYXDepth: input_layout.push_back(dnums.input_batch_dimension()); input_layout.insert(input_layout.end(), dnums.input_spatial_dimensions().begin(), dnums.input_spatial_dimensions().end()); input_layout.push_back(dnums.input_feature_dimension()); break; default: return InternalError("Invalid input layout %s for conv with dnums %s", DataLayoutString(input), ConvolutionDimensionNumbersToString(dnums)); } std::vector filter_layout; switch (filter) { case FilterLayout::kOutputInputYX: filter_layout.push_back(dnums.kernel_output_feature_dimension()); filter_layout.push_back(dnums.kernel_input_feature_dimension()); filter_layout.insert(filter_layout.end(), dnums.kernel_spatial_dimensions().begin(), dnums.kernel_spatial_dimensions().end()); break; case FilterLayout::kOutputYXInput: filter_layout.push_back(dnums.kernel_output_feature_dimension()); filter_layout.insert(filter_layout.end(), dnums.kernel_spatial_dimensions().begin(), dnums.kernel_spatial_dimensions().end()); filter_layout.push_back(dnums.kernel_input_feature_dimension()); break; default: return InternalError("Invalid filter layout %s for conv with dnums %s", FilterLayoutString(filter), ConvolutionDimensionNumbersToString(dnums)); } std::vector output_layout; switch (output) { case DataLayout::kBatchDepthYX: output_layout.push_back(dnums.output_batch_dimension()); output_layout.push_back(dnums.output_feature_dimension()); output_layout.insert(output_layout.end(), dnums.output_spatial_dimensions().begin(), dnums.output_spatial_dimensions().end()); break; case DataLayout::kBatchYXDepth: output_layout.push_back(dnums.output_batch_dimension()); output_layout.insert(output_layout.end(), dnums.output_spatial_dimensions().begin(), dnums.output_spatial_dimensions().end()); output_layout.push_back(dnums.output_feature_dimension()); break; default: return InternalError("Invalid output layout %s for conv with dnums %s", DataLayoutString(output), ConvolutionDimensionNumbersToString(dnums)); } return std::make_tuple(LayoutUtil::MakeLayoutFromMajorToMinor(input_layout), LayoutUtil::MakeLayoutFromMajorToMinor(filter_layout), LayoutUtil::MakeLayoutFromMajorToMinor(output_layout)); } StatusOr> XlaConvLayoutsToStreamExecutorLayouts(const ConvolutionDimensionNumbers& dnums, const Layout& input, const Layout& filter, const Layout& output) { Layout nchw_input, nchw_filter, nchw_output; std::tie(nchw_input, nchw_filter, nchw_output) = StreamExecutorConvLayoutsToXlaLayouts(dnums, DataLayout::kBatchDepthYX, FilterLayout::kOutputInputYX, DataLayout::kBatchDepthYX) .ConsumeValueOrDie(); Layout nhwc_input, nhwc_filter, nhwc_output; std::tie(nhwc_input, nhwc_filter, nhwc_output) = StreamExecutorConvLayoutsToXlaLayouts(dnums, DataLayout::kBatchYXDepth, FilterLayout::kOutputYXInput, DataLayout::kBatchYXDepth) .ConsumeValueOrDie(); DataLayout input_layout; if (LayoutUtil::Equal(input, nchw_input)) { input_layout = DataLayout::kBatchDepthYX; } else if (LayoutUtil::Equal(input, nhwc_input)) { input_layout = DataLayout::kBatchYXDepth; } else { return InternalError("Invalid input layout %s for conv with dnums %s", LayoutUtil::HumanString(input), ConvolutionDimensionNumbersToString(dnums)); } FilterLayout filter_layout; if (LayoutUtil::Equal(filter, nchw_filter)) { filter_layout = FilterLayout::kOutputInputYX; } else if (LayoutUtil::Equal(filter, nhwc_filter)) { filter_layout = FilterLayout::kOutputYXInput; } else { return InternalError("Invalid filter layout %s for conv with dnums %s", LayoutUtil::HumanString(filter), ConvolutionDimensionNumbersToString(dnums)); } DataLayout output_layout; if (LayoutUtil::Equal(output, nchw_output)) { output_layout = DataLayout::kBatchDepthYX; } else if (LayoutUtil::Equal(output, nhwc_output)) { output_layout = DataLayout::kBatchYXDepth; } else { return InternalError("Invalid output layout %s for conv with dnums %s", LayoutUtil::HumanString(output), ConvolutionDimensionNumbersToString(dnums)); } return std::make_tuple(input_layout, filter_layout, output_layout); } } // namespace gpu } // namespace xla