// 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. // Author: kenton@google.com (Kenton Varda) // Based on original Protocol Buffers design by // Sanjay Ghemawat, Jeff Dean, and others. // // This header is logically internal, but is made public because it is used // from protocol-compiler-generated code, which may reside in other components. #ifndef GOOGLE_PROTOBUF_GENERATED_MESSAGE_REFLECTION_H__ #define GOOGLE_PROTOBUF_GENERATED_MESSAGE_REFLECTION_H__ #include #include #include #include #include #include #include #include #include #include #ifdef SWIG #error "You cannot SWIG proto headers" #endif namespace google { namespace protobuf { class MapKey; class MapValueRef; class MessageLayoutInspector; class Message; struct Metadata; } // namespace protobuf } // namespace google namespace google { namespace protobuf { namespace internal { class DefaultEmptyOneof; // Defined in other files. class ExtensionSet; // extension_set.h class WeakFieldMap; // weak_field_map.h // This struct describes the internal layout of the message, hence this is // used to act on the message reflectively. // default_instance: The default instance of the message. This is only // used to obtain pointers to default instances of embedded // messages, which GetMessage() will return if the particular // sub-message has not been initialized yet. (Thus, all // embedded message fields *must* have non-null pointers // in the default instance.) // offsets: An array of ints giving the byte offsets. // For each oneof or weak field, the offset is relative to the // default_instance. These can be computed at compile time // using the // PROTO2_GENERATED_DEFAULT_ONEOF_FIELD_OFFSET() // macro. For each none oneof field, the offset is related to // the start of the message object. These can be computed at // compile time using the // PROTO2_GENERATED_MESSAGE_FIELD_OFFSET() macro. // Besides offsets for all fields, this array also contains // offsets for oneof unions. The offset of the i-th oneof union // is offsets[descriptor->field_count() + i]. // has_bit_indices: Mapping from field indexes to their index in the has // bit array. // has_bits_offset: Offset in the message of an array of uint32s of size // descriptor->field_count()/32, rounded up. This is a // bitfield where each bit indicates whether or not the // corresponding field of the message has been initialized. // The bit for field index i is obtained by the expression: // has_bits[i / 32] & (1 << (i % 32)) // unknown_fields_offset: Offset in the message of the UnknownFieldSet for // the message. // extensions_offset: Offset in the message of the ExtensionSet for the // message, or -1 if the message type has no extension // ranges. // oneof_case_offset: Offset in the message of an array of uint32s of // size descriptor->oneof_decl_count(). Each uint32 // indicates what field is set for each oneof. // object_size: The size of a message object of this type, as measured // by sizeof(). // arena_offset: If a message doesn't have a unknown_field_set that stores // the arena, it must have a direct pointer to the arena. // weak_field_map_offset: If the message proto has weak fields, this is the // offset of _weak_field_map_ in the generated proto. Otherwise // -1. struct ReflectionSchema { public: // Size of a google::protobuf::Message object of this type. uint32 GetObjectSize() const { return static_cast(object_size_); } bool InRealOneof(const FieldDescriptor* field) const { return field->containing_oneof() && !field->containing_oneof()->is_synthetic(); } // Offset of a non-oneof field. Getting a field offset is slightly more // efficient when we know statically that it is not a oneof field. uint32 GetFieldOffsetNonOneof(const FieldDescriptor* field) const { GOOGLE_DCHECK(!InRealOneof(field)); return OffsetValue(offsets_[field->index()], field->type()); } // Offset of any field. uint32 GetFieldOffset(const FieldDescriptor* field) const { if (InRealOneof(field)) { size_t offset = static_cast(field->containing_type()->field_count() + field->containing_oneof()->index()); return OffsetValue(offsets_[offset], field->type()); } else { return GetFieldOffsetNonOneof(field); } } uint32 GetOneofCaseOffset(const OneofDescriptor* oneof_descriptor) const { return static_cast(oneof_case_offset_) + static_cast(static_cast(oneof_descriptor->index()) * sizeof(uint32)); } bool HasHasbits() const { return has_bits_offset_ != -1; } // Bit index within the bit array of hasbits. Bit order is low-to-high. uint32 HasBitIndex(const FieldDescriptor* field) const { if (has_bits_offset_ == -1) return static_cast(-1); GOOGLE_DCHECK(HasHasbits()); return has_bit_indices_[field->index()]; } // Byte offset of the hasbits array. uint32 HasBitsOffset() const { GOOGLE_DCHECK(HasHasbits()); return static_cast(has_bits_offset_); } // The offset of the InternalMetadataWithArena member. // For Lite this will actually be an InternalMetadataWithArenaLite. // The schema doesn't contain enough information to distinguish between // these two cases. uint32 GetMetadataOffset() const { return static_cast(metadata_offset_); } // Whether this message has an ExtensionSet. bool HasExtensionSet() const { return extensions_offset_ != -1; } // The offset of the ExtensionSet in this message. uint32 GetExtensionSetOffset() const { GOOGLE_DCHECK(HasExtensionSet()); return static_cast(extensions_offset_); } // The off set of WeakFieldMap when the message contains weak fields. // The default is 0 for now. int GetWeakFieldMapOffset() const { return weak_field_map_offset_; } bool IsDefaultInstance(const Message& message) const { return &message == default_instance_; } // Returns a pointer to the default value for this field. The size and type // of the underlying data depends on the field's type. const void* GetFieldDefault(const FieldDescriptor* field) const { return reinterpret_cast(default_instance_) + OffsetValue(offsets_[field->index()], field->type()); } // Returns true if the field is implicitly backed by LazyField. bool IsEagerlyVerifiedLazyField(const FieldDescriptor* field) const { GOOGLE_DCHECK_EQ(field->type(), FieldDescriptor::TYPE_MESSAGE); (void)field; return false; } // Returns true if the field's accessor is called by any external code (aka, // non proto library code). bool IsFieldUsed(const FieldDescriptor* field) const { (void)field; return true; } bool IsFieldStripped(const FieldDescriptor* field) const { (void)field; return false; } bool IsMessageStripped(const Descriptor* descriptor) const { (void)descriptor; return false; } bool HasWeakFields() const { return weak_field_map_offset_ > 0; } // These members are intended to be private, but we cannot actually make them // private because this prevents us from using aggregate initialization of // them, ie. // // ReflectionSchema schema = {a, b, c, d, e, ...}; // private: const Message* default_instance_; const uint32* offsets_; const uint32* has_bit_indices_; int has_bits_offset_; int metadata_offset_; int extensions_offset_; int oneof_case_offset_; int object_size_; int weak_field_map_offset_; // We tag offset values to provide additional data about fields (such as // "unused" or "lazy"). static uint32 OffsetValue(uint32 v, FieldDescriptor::Type type) { if (type == FieldDescriptor::TYPE_MESSAGE) { return v & 0x7FFFFFFEu; } return v & 0x7FFFFFFFu; } }; // Structs that the code generator emits directly to describe a message. // These should never used directly except to build a ReflectionSchema // object. // // EXPERIMENTAL: these are changing rapidly, and may completely disappear // or merge with ReflectionSchema. struct MigrationSchema { int32 offsets_index; int32 has_bit_indices_index; int object_size; }; // This struct tries to reduce unnecessary padding. // The num_xxx might not be close to their respective pointer, but this saves // padding. struct PROTOBUF_EXPORT DescriptorTable { mutable bool is_initialized; bool is_eager; int size; // of serialized descriptor const char* descriptor; const char* filename; once_flag* once; const DescriptorTable* const* deps; int num_deps; int num_messages; const MigrationSchema* schemas; const Message* const* default_instances; const uint32* offsets; // update the following descriptor arrays. Metadata* file_level_metadata; const EnumDescriptor** file_level_enum_descriptors; const ServiceDescriptor** file_level_service_descriptors; }; enum { // Tag used on offsets for fields that don't have a real offset. // For example, weak message fields go into the WeakFieldMap and not in an // actual field. kInvalidFieldOffsetTag = 0x40000000u, }; // AssignDescriptors() pulls the compiled FileDescriptor from the DescriptorPool // and uses it to populate all of the global variables which store pointers to // the descriptor objects. It also constructs the reflection objects. It is // called the first time anyone calls descriptor() or GetReflection() on one of // the types defined in the file. AssignDescriptors() is thread-safe. void PROTOBUF_EXPORT AssignDescriptors(const DescriptorTable* table, bool eager = false); // Overload used to implement GetMetadataStatic in the generated code. // See comments in compiler/cpp/internal/file.cc as to why. // It takes a `Metadata` and returns it to allow for tail calls and reduce // binary size. Metadata PROTOBUF_EXPORT AssignDescriptors(const DescriptorTable* (*table)(), internal::once_flag* once, const Metadata& metadata); // These cannot be in lite so we put them in the reflection. PROTOBUF_EXPORT void UnknownFieldSetSerializer(const uint8* base, uint32 offset, uint32 tag, uint32 has_offset, io::CodedOutputStream* output); struct PROTOBUF_EXPORT AddDescriptorsRunner { explicit AddDescriptorsRunner(const DescriptorTable* table); }; } // namespace internal } // namespace protobuf } // namespace google #include #endif // GOOGLE_PROTOBUF_GENERATED_MESSAGE_REFLECTION_H__