// Protocol Buffers - Google's data interchange format // Copyright 2008 Google Inc. All rights reserved. // https://developers.google.com/protocol-buffers/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // This header file is protobuf internal. Users should not include this // file directly. #ifndef GOOGLE_PROTOBUF_REPEATED_FIELD_REFLECTION_H__ #define GOOGLE_PROTOBUF_REPEATED_FIELD_REFLECTION_H__ #include #ifndef _SHARED_PTR_H #include #endif #include namespace google { namespace protobuf { namespace internal { // Interfaces used to implement reflection RepeatedFieldRef API. // Reflection::GetRepeatedAccessor() should return a pointer to an singleton // object that implements the below interface. // // This interface passes/returns values using void pointers. The actual type // of the value depends on the field's cpp_type. Following is a mapping from // cpp_type to the type that should be used in this interface: // // field->cpp_type() T Actual type of void* // CPPTYPE_INT32 int32 int32 // CPPTYPE_UINT32 uint32 uint32 // CPPTYPE_INT64 int64 int64 // CPPTYPE_UINT64 uint64 uint64 // CPPTYPE_DOUBLE double double // CPPTYPE_FLOAT float float // CPPTYPE_BOOL bool bool // CPPTYPE_ENUM generated enum type int32 // CPPTYPE_STRING string string // CPPTYPE_MESSAGE generated message type google::protobuf::Message // or google::protobuf::Message // // Note that for enums we use int32 in the interface. // // You can map from T to the actual type using RefTypeTraits: // typedef RefTypeTraits::AccessorValueType ActualType; class LIBPROTOBUF_EXPORT RepeatedFieldAccessor { public: // Typedefs for clarity. typedef void Field; typedef void Value; typedef void Iterator; virtual ~RepeatedFieldAccessor(); virtual bool IsEmpty(const Field* data) const = 0; virtual int Size(const Field* data) const = 0; // Depends on the underlying representation of the repeated field, this // method can return a pointer to the underlying object if such an object // exists, or fill the data into scratch_space and return scratch_space. // Callers of this method must ensure scratch_space is a valid pointer // to a mutable object of the correct type. virtual const Value* Get( const Field* data, int index, Value* scratch_space) const = 0; virtual void Clear(Field* data) const = 0; virtual void Set(Field* data, int index, const Value* value) const = 0; virtual void Add(Field* data, const Value* value) const = 0; virtual void RemoveLast(Field* data) const = 0; virtual void SwapElements(Field* data, int index1, int index2) const = 0; virtual void Swap(Field* data, const RepeatedFieldAccessor* other_mutator, Field* other_data) const = 0; // Create an iterator that points at the begining of the repeated field. virtual Iterator* BeginIterator(const Field* data) const = 0; // Create an iterator that points at the end of the repeated field. virtual Iterator* EndIterator(const Field* data) const = 0; // Make a copy of an iterator and return the new copy. virtual Iterator* CopyIterator(const Field* data, const Iterator* iterator) const = 0; // Move an iterator to point to the next element. virtual Iterator* AdvanceIterator(const Field* data, Iterator* iterator) const = 0; // Compare whether two iterators point to the same element. virtual bool EqualsIterator(const Field* data, const Iterator* a, const Iterator* b) const = 0; // Delete an iterator created by BeginIterator(), EndIterator() and // CopyIterator(). virtual void DeleteIterator(const Field* data, Iterator* iterator) const = 0; // Like Get() but for iterators. virtual const Value* GetIteratorValue(const Field* data, const Iterator* iterator, Value* scratch_space) const = 0; // Templated methods that make using this interface easier for non-message // types. template T Get(const Field* data, int index) const { typedef typename RefTypeTraits::AccessorValueType ActualType; ActualType scratch_space; return static_cast( *reinterpret_cast( Get(data, index, static_cast(&scratch_space)))); } template void Set(Field* data, int index, const ValueType& value) const { typedef typename RefTypeTraits::AccessorValueType ActualType; // In this RepeatedFieldAccessor interface we pass/return data using // raw pointers. Type of the data these raw pointers point to should // be ActualType. Here we have a ValueType object and want a ActualType // pointer. We can't cast a ValueType pointer to an ActualType pointer // directly because their type might be different (for enums ValueType // may be a generated enum type while ActualType is int32). To be safe // we make a copy to get a temporary ActualType object and use it. ActualType tmp = static_cast(value); Set(data, index, static_cast(&tmp)); } template void Add(Field* data, const ValueType& value) const { typedef typename RefTypeTraits::AccessorValueType ActualType; // In this RepeatedFieldAccessor interface we pass/return data using // raw pointers. Type of the data these raw pointers point to should // be ActualType. Here we have a ValueType object and want a ActualType // pointer. We can't cast a ValueType pointer to an ActualType pointer // directly because their type might be different (for enums ValueType // may be a generated enum type while ActualType is int32). To be safe // we make a copy to get a temporary ActualType object and use it. ActualType tmp = static_cast(value); Add(data, static_cast(&tmp)); } }; // Implement (Mutable)RepeatedFieldRef::iterator template class RepeatedFieldRefIterator : public std::iterator { typedef typename RefTypeTraits::AccessorValueType AccessorValueType; typedef typename RefTypeTraits::IteratorValueType IteratorValueType; typedef typename RefTypeTraits::IteratorPointerType IteratorPointerType; public: // Constructor for non-message fields. RepeatedFieldRefIterator(const void* data, const RepeatedFieldAccessor* accessor, bool begin) : data_(data), accessor_(accessor), iterator_(begin ? accessor->BeginIterator(data) : accessor->EndIterator(data)), scratch_space_(new AccessorValueType) { } // Constructor for message fields. RepeatedFieldRefIterator(const void* data, const RepeatedFieldAccessor* accessor, bool begin, AccessorValueType* scratch_space) : data_(data), accessor_(accessor), iterator_(begin ? accessor->BeginIterator(data) : accessor->EndIterator(data)), scratch_space_(scratch_space) { } ~RepeatedFieldRefIterator() { accessor_->DeleteIterator(data_, iterator_); } RepeatedFieldRefIterator operator++(int) { RepeatedFieldRefIterator tmp(*this); iterator_ = accessor_->AdvanceIterator(data_, iterator_); return tmp; } RepeatedFieldRefIterator& operator++() { iterator_ = accessor_->AdvanceIterator(data_, iterator_); return *this; } IteratorValueType operator*() const { return static_cast( *static_cast( accessor_->GetIteratorValue( data_, iterator_, scratch_space_.get()))); } IteratorPointerType operator->() const { return static_cast( accessor_->GetIteratorValue( data_, iterator_, scratch_space_.get())); } bool operator!=(const RepeatedFieldRefIterator& other) const { assert(data_ == other.data_); assert(accessor_ == other.accessor_); return !accessor_->EqualsIterator(data_, iterator_, other.iterator_); } bool operator==(const RepeatedFieldRefIterator& other) const { return !this->operator!=(other); } RepeatedFieldRefIterator(const RepeatedFieldRefIterator& other) : data_(other.data_), accessor_(other.accessor_), iterator_(accessor_->CopyIterator(data_, other.iterator_)) { } RepeatedFieldRefIterator& operator=(const RepeatedFieldRefIterator& other) { if (this != &other) { accessor_->DeleteIterator(data_, iterator_); data_ = other.data_; accessor_ = other.accessor_; iterator_ = accessor_->CopyIterator(data_, other.iterator_); } return *this; } protected: const void* data_; const RepeatedFieldAccessor* accessor_; void* iterator_; google::protobuf::scoped_ptr scratch_space_; }; // TypeTraits that maps the type parameter T of RepeatedFieldRef or // MutableRepeatedFieldRef to corresponding iterator type, // RepeatedFieldAccessor type, etc. template struct PrimitiveTraits { static const bool is_primitive = false; }; #define DEFINE_PRIMITIVE(TYPE, type) \ template<> struct PrimitiveTraits { \ static const bool is_primitive = true; \ static const FieldDescriptor::CppType cpp_type = \ FieldDescriptor::CPPTYPE_ ## TYPE; \ }; DEFINE_PRIMITIVE(INT32, int32) DEFINE_PRIMITIVE(UINT32, uint32) DEFINE_PRIMITIVE(INT64, int64) DEFINE_PRIMITIVE(UINT64, uint64) DEFINE_PRIMITIVE(FLOAT, float) DEFINE_PRIMITIVE(DOUBLE, double) DEFINE_PRIMITIVE(BOOL, bool) #undef DEFINE_PRIMITIVE template struct RefTypeTraits< T, typename internal::enable_if::is_primitive>::type> { typedef RepeatedFieldRefIterator iterator; typedef RepeatedFieldAccessor AccessorType; typedef T AccessorValueType; typedef T IteratorValueType; typedef T* IteratorPointerType; static const FieldDescriptor::CppType cpp_type = PrimitiveTraits::cpp_type; static const Descriptor* GetMessageFieldDescriptor() { return NULL; } }; template struct RefTypeTraits< T, typename internal::enable_if::value>::type> { typedef RepeatedFieldRefIterator iterator; typedef RepeatedFieldAccessor AccessorType; // We use int32 for repeated enums in RepeatedFieldAccessor. typedef int32 AccessorValueType; typedef T IteratorValueType; typedef int32* IteratorPointerType; static const FieldDescriptor::CppType cpp_type = FieldDescriptor::CPPTYPE_ENUM; static const Descriptor* GetMessageFieldDescriptor() { return NULL; } }; template struct RefTypeTraits< T, typename internal::enable_if::value>::type> { typedef RepeatedFieldRefIterator iterator; typedef RepeatedFieldAccessor AccessorType; typedef string AccessorValueType; typedef string IteratorValueType; typedef string* IteratorPointerType; static const FieldDescriptor::CppType cpp_type = FieldDescriptor::CPPTYPE_STRING; static const Descriptor* GetMessageFieldDescriptor() { return NULL; } }; template struct MessageDescriptorGetter { static const Descriptor* get() { return T::default_instance().GetDescriptor(); } }; template<> struct MessageDescriptorGetter { static const Descriptor* get() { return NULL; } }; template struct RefTypeTraits< T, typename internal::enable_if::value>::type> { typedef RepeatedFieldRefIterator iterator; typedef RepeatedFieldAccessor AccessorType; typedef Message AccessorValueType; typedef const T& IteratorValueType; typedef const T* IteratorPointerType; static const FieldDescriptor::CppType cpp_type = FieldDescriptor::CPPTYPE_MESSAGE; static const Descriptor* GetMessageFieldDescriptor() { return MessageDescriptorGetter::get(); } }; } // namespace internal } // namespace protobuf } // namespace google #endif // GOOGLE_PROTOBUF_REPEATED_FIELD_REFLECTION_H__