558 lines
20 KiB
C++
558 lines
20 KiB
C++
// Protocol Buffers - Google's data interchange format
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// Copyright 2008 Google Inc. All rights reserved.
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// http://code.google.com/p/protobuf/
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following disclaimer
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// in the documentation and/or other materials provided with the
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// distribution.
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// * Neither the name of Google Inc. nor the names of its
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// contributors may be used to endorse or promote products derived from
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// this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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// Author: kenton@google.com (Kenton Varda)
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// Based on original Protocol Buffers design by
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// Sanjay Ghemawat, Jeff Dean, and others.
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//
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// DynamicMessage is implemented by constructing a data structure which
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// has roughly the same memory layout as a generated message would have.
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// Then, we use GeneratedMessageReflection to implement our reflection
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// interface. All the other operations we need to implement (e.g.
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// parsing, copying, etc.) are already implemented in terms of
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// Reflection, so the rest is easy.
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//
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// The up side of this strategy is that it's very efficient. We don't
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// need to use hash_maps or generic representations of fields. The
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// down side is that this is a low-level memory management hack which
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// can be tricky to get right.
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//
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// As mentioned in the header, we only expose a DynamicMessageFactory
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// publicly, not the DynamicMessage class itself. This is because
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// GenericMessageReflection wants to have a pointer to a "default"
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// copy of the class, with all fields initialized to their default
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// values. We only want to construct one of these per message type,
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// so DynamicMessageFactory stores a cache of default messages for
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// each type it sees (each unique Descriptor pointer). The code
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// refers to the "default" copy of the class as the "prototype".
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//
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// Note on memory allocation: This module often calls "operator new()"
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// to allocate untyped memory, rather than calling something like
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// "new uint8[]". This is because "operator new()" means "Give me some
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// space which I can use as I please." while "new uint8[]" means "Give
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// me an array of 8-bit integers.". In practice, the later may return
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// a pointer that is not aligned correctly for general use. I believe
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// Item 8 of "More Effective C++" discusses this in more detail, though
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// I don't have the book on me right now so I'm not sure.
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#include <algorithm>
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#include <google/protobuf/stubs/hash.h>
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#include <google/protobuf/stubs/common.h>
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#include <google/protobuf/dynamic_message.h>
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#include <google/protobuf/descriptor.h>
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#include <google/protobuf/descriptor.pb.h>
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#include <google/protobuf/generated_message_util.h>
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#include <google/protobuf/generated_message_reflection.h>
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#include <google/protobuf/reflection_ops.h>
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#include <google/protobuf/repeated_field.h>
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#include <google/protobuf/extension_set.h>
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#include <google/protobuf/wire_format.h>
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namespace google {
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namespace protobuf {
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using internal::WireFormat;
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using internal::ExtensionSet;
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using internal::GeneratedMessageReflection;
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// ===================================================================
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// Some helper tables and functions...
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namespace {
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// Compute the byte size of the in-memory representation of the field.
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int FieldSpaceUsed(const FieldDescriptor* field) {
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typedef FieldDescriptor FD; // avoid line wrapping
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if (field->label() == FD::LABEL_REPEATED) {
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switch (field->cpp_type()) {
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case FD::CPPTYPE_INT32 : return sizeof(RepeatedField<int32 >);
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case FD::CPPTYPE_INT64 : return sizeof(RepeatedField<int64 >);
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case FD::CPPTYPE_UINT32 : return sizeof(RepeatedField<uint32 >);
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case FD::CPPTYPE_UINT64 : return sizeof(RepeatedField<uint64 >);
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case FD::CPPTYPE_DOUBLE : return sizeof(RepeatedField<double >);
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case FD::CPPTYPE_FLOAT : return sizeof(RepeatedField<float >);
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case FD::CPPTYPE_BOOL : return sizeof(RepeatedField<bool >);
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case FD::CPPTYPE_ENUM : return sizeof(RepeatedField<int >);
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case FD::CPPTYPE_MESSAGE: return sizeof(RepeatedPtrField<Message>);
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case FD::CPPTYPE_STRING:
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switch (field->options().ctype()) {
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default: // TODO(kenton): Support other string reps.
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case FieldOptions::STRING:
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return sizeof(RepeatedPtrField<string>);
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}
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break;
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}
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} else {
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switch (field->cpp_type()) {
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case FD::CPPTYPE_INT32 : return sizeof(int32 );
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case FD::CPPTYPE_INT64 : return sizeof(int64 );
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case FD::CPPTYPE_UINT32 : return sizeof(uint32 );
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case FD::CPPTYPE_UINT64 : return sizeof(uint64 );
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case FD::CPPTYPE_DOUBLE : return sizeof(double );
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case FD::CPPTYPE_FLOAT : return sizeof(float );
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case FD::CPPTYPE_BOOL : return sizeof(bool );
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case FD::CPPTYPE_ENUM : return sizeof(int );
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case FD::CPPTYPE_MESSAGE: return sizeof(Message*);
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case FD::CPPTYPE_STRING:
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switch (field->options().ctype()) {
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default: // TODO(kenton): Support other string reps.
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case FieldOptions::STRING:
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return sizeof(string*);
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}
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break;
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}
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}
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GOOGLE_LOG(DFATAL) << "Can't get here.";
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return 0;
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}
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inline int DivideRoundingUp(int i, int j) {
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return (i + (j - 1)) / j;
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}
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static const int kSafeAlignment = sizeof(uint64);
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inline int AlignTo(int offset, int alignment) {
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return DivideRoundingUp(offset, alignment) * alignment;
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}
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// Rounds the given byte offset up to the next offset aligned such that any
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// type may be stored at it.
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inline int AlignOffset(int offset) {
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return AlignTo(offset, kSafeAlignment);
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}
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#define bitsizeof(T) (sizeof(T) * 8)
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} // namespace
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// ===================================================================
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class DynamicMessage : public Message {
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public:
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struct TypeInfo {
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int size;
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int has_bits_offset;
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int unknown_fields_offset;
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int extensions_offset;
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// Not owned by the TypeInfo.
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DynamicMessageFactory* factory; // The factory that created this object.
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const DescriptorPool* pool; // The factory's DescriptorPool.
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const Descriptor* type; // Type of this DynamicMessage.
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// Warning: The order in which the following pointers are defined is
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// important (the prototype must be deleted *before* the offsets).
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scoped_array<int> offsets;
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scoped_ptr<const GeneratedMessageReflection> reflection;
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scoped_ptr<const DynamicMessage> prototype;
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};
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DynamicMessage(const TypeInfo* type_info);
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~DynamicMessage();
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// Called on the prototype after construction to initialize message fields.
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void CrossLinkPrototypes();
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// implements Message ----------------------------------------------
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Message* New() const;
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int GetCachedSize() const;
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void SetCachedSize(int size) const;
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Metadata GetMetadata() const;
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private:
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GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(DynamicMessage);
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inline bool is_prototype() const {
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return type_info_->prototype == this ||
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// If type_info_->prototype is NULL, then we must be constructing
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// the prototype now, which means we must be the prototype.
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type_info_->prototype == NULL;
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}
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inline void* OffsetToPointer(int offset) {
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return reinterpret_cast<uint8*>(this) + offset;
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}
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inline const void* OffsetToPointer(int offset) const {
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return reinterpret_cast<const uint8*>(this) + offset;
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}
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const TypeInfo* type_info_;
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// TODO(kenton): Make this an atomic<int> when C++ supports it.
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mutable int cached_byte_size_;
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};
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DynamicMessage::DynamicMessage(const TypeInfo* type_info)
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: type_info_(type_info),
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cached_byte_size_(0) {
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// We need to call constructors for various fields manually and set
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// default values where appropriate. We use placement new to call
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// constructors. If you haven't heard of placement new, I suggest Googling
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// it now. We use placement new even for primitive types that don't have
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// constructors for consistency. (In theory, placement new should be used
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// any time you are trying to convert untyped memory to typed memory, though
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// in practice that's not strictly necessary for types that don't have a
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// constructor.)
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const Descriptor* descriptor = type_info_->type;
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new(OffsetToPointer(type_info_->unknown_fields_offset)) UnknownFieldSet;
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if (type_info_->extensions_offset != -1) {
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new(OffsetToPointer(type_info_->extensions_offset)) ExtensionSet;
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}
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for (int i = 0; i < descriptor->field_count(); i++) {
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const FieldDescriptor* field = descriptor->field(i);
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void* field_ptr = OffsetToPointer(type_info_->offsets[i]);
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switch (field->cpp_type()) {
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#define HANDLE_TYPE(CPPTYPE, TYPE) \
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case FieldDescriptor::CPPTYPE_##CPPTYPE: \
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if (!field->is_repeated()) { \
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new(field_ptr) TYPE(field->default_value_##TYPE()); \
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} else { \
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new(field_ptr) RepeatedField<TYPE>(); \
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} \
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break;
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HANDLE_TYPE(INT32 , int32 );
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HANDLE_TYPE(INT64 , int64 );
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HANDLE_TYPE(UINT32, uint32);
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HANDLE_TYPE(UINT64, uint64);
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HANDLE_TYPE(DOUBLE, double);
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HANDLE_TYPE(FLOAT , float );
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HANDLE_TYPE(BOOL , bool );
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#undef HANDLE_TYPE
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case FieldDescriptor::CPPTYPE_ENUM:
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if (!field->is_repeated()) {
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new(field_ptr) int(field->default_value_enum()->number());
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} else {
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new(field_ptr) RepeatedField<int>();
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}
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break;
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case FieldDescriptor::CPPTYPE_STRING:
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switch (field->options().ctype()) {
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default: // TODO(kenton): Support other string reps.
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case FieldOptions::STRING:
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if (!field->is_repeated()) {
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if (is_prototype()) {
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new(field_ptr) const string*(&field->default_value_string());
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} else {
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string* default_value =
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*reinterpret_cast<string* const*>(
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type_info_->prototype->OffsetToPointer(
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type_info_->offsets[i]));
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new(field_ptr) string*(default_value);
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}
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} else {
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new(field_ptr) RepeatedPtrField<string>();
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}
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break;
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}
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break;
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case FieldDescriptor::CPPTYPE_MESSAGE: {
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if (!field->is_repeated()) {
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new(field_ptr) Message*(NULL);
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} else {
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new(field_ptr) RepeatedPtrField<Message>();
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}
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break;
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}
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}
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}
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}
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DynamicMessage::~DynamicMessage() {
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const Descriptor* descriptor = type_info_->type;
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reinterpret_cast<UnknownFieldSet*>(
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OffsetToPointer(type_info_->unknown_fields_offset))->~UnknownFieldSet();
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if (type_info_->extensions_offset != -1) {
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reinterpret_cast<ExtensionSet*>(
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OffsetToPointer(type_info_->extensions_offset))->~ExtensionSet();
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}
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// We need to manually run the destructors for repeated fields and strings,
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// just as we ran their constructors in the the DynamicMessage constructor.
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// Additionally, if any singular embedded messages have been allocated, we
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// need to delete them, UNLESS we are the prototype message of this type,
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// in which case any embedded messages are other prototypes and shouldn't
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// be touched.
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for (int i = 0; i < descriptor->field_count(); i++) {
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const FieldDescriptor* field = descriptor->field(i);
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void* field_ptr = OffsetToPointer(type_info_->offsets[i]);
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if (field->is_repeated()) {
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switch (field->cpp_type()) {
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#define HANDLE_TYPE(UPPERCASE, LOWERCASE) \
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case FieldDescriptor::CPPTYPE_##UPPERCASE : \
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reinterpret_cast<RepeatedField<LOWERCASE>*>(field_ptr) \
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->~RepeatedField<LOWERCASE>(); \
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break
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HANDLE_TYPE( INT32, int32);
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HANDLE_TYPE( INT64, int64);
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HANDLE_TYPE(UINT32, uint32);
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HANDLE_TYPE(UINT64, uint64);
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HANDLE_TYPE(DOUBLE, double);
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HANDLE_TYPE( FLOAT, float);
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HANDLE_TYPE( BOOL, bool);
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HANDLE_TYPE( ENUM, int);
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#undef HANDLE_TYPE
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case FieldDescriptor::CPPTYPE_STRING:
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switch (field->options().ctype()) {
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default: // TODO(kenton): Support other string reps.
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case FieldOptions::STRING:
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reinterpret_cast<RepeatedPtrField<string>*>(field_ptr)
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->~RepeatedPtrField<string>();
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break;
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}
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break;
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case FieldDescriptor::CPPTYPE_MESSAGE:
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reinterpret_cast<RepeatedPtrField<Message>*>(field_ptr)
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->~RepeatedPtrField<Message>();
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break;
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}
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} else if (field->cpp_type() == FieldDescriptor::CPPTYPE_STRING) {
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switch (field->options().ctype()) {
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default: // TODO(kenton): Support other string reps.
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case FieldOptions::STRING: {
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string* ptr = *reinterpret_cast<string**>(field_ptr);
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if (ptr != &field->default_value_string()) {
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delete ptr;
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}
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break;
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}
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}
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} else if ((field->cpp_type() == FieldDescriptor::CPPTYPE_MESSAGE) &&
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!is_prototype()) {
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Message* message = *reinterpret_cast<Message**>(field_ptr);
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if (message != NULL) {
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delete message;
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}
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}
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}
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}
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void DynamicMessage::CrossLinkPrototypes() {
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// This should only be called on the prototype message.
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GOOGLE_CHECK(is_prototype());
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DynamicMessageFactory* factory = type_info_->factory;
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const Descriptor* descriptor = type_info_->type;
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// Cross-link default messages.
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for (int i = 0; i < descriptor->field_count(); i++) {
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const FieldDescriptor* field = descriptor->field(i);
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void* field_ptr = OffsetToPointer(type_info_->offsets[i]);
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if (field->cpp_type() == FieldDescriptor::CPPTYPE_MESSAGE &&
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!field->is_repeated()) {
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// For fields with message types, we need to cross-link with the
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// prototype for the field's type.
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// For singular fields, the field is just a pointer which should
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// point to the prototype.
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*reinterpret_cast<const Message**>(field_ptr) =
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factory->GetPrototypeNoLock(field->message_type());
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}
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}
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}
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Message* DynamicMessage::New() const {
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void* new_base = reinterpret_cast<uint8*>(operator new(type_info_->size));
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memset(new_base, 0, type_info_->size);
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return new(new_base) DynamicMessage(type_info_);
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}
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int DynamicMessage::GetCachedSize() const {
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return cached_byte_size_;
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}
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void DynamicMessage::SetCachedSize(int size) const {
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// This is theoretically not thread-compatible, but in practice it works
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// because if multiple threads write this simultaneously, they will be
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// writing the exact same value.
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cached_byte_size_ = size;
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}
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Metadata DynamicMessage::GetMetadata() const {
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Metadata metadata;
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metadata.descriptor = type_info_->type;
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metadata.reflection = type_info_->reflection.get();
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return metadata;
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}
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// ===================================================================
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struct DynamicMessageFactory::PrototypeMap {
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typedef hash_map<const Descriptor*, const DynamicMessage::TypeInfo*> Map;
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Map map_;
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};
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DynamicMessageFactory::DynamicMessageFactory()
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: pool_(NULL), delegate_to_generated_factory_(false),
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prototypes_(new PrototypeMap) {
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}
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DynamicMessageFactory::DynamicMessageFactory(const DescriptorPool* pool)
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: pool_(pool), delegate_to_generated_factory_(false),
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prototypes_(new PrototypeMap) {
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}
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DynamicMessageFactory::~DynamicMessageFactory() {
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for (PrototypeMap::Map::iterator iter = prototypes_->map_.begin();
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iter != prototypes_->map_.end(); ++iter) {
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delete iter->second;
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}
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}
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const Message* DynamicMessageFactory::GetPrototype(const Descriptor* type) {
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MutexLock lock(&prototypes_mutex_);
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return GetPrototypeNoLock(type);
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}
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const Message* DynamicMessageFactory::GetPrototypeNoLock(
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const Descriptor* type) {
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if (delegate_to_generated_factory_ &&
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type->file()->pool() == DescriptorPool::generated_pool()) {
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return MessageFactory::generated_factory()->GetPrototype(type);
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}
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const DynamicMessage::TypeInfo** target = &prototypes_->map_[type];
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if (*target != NULL) {
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// Already exists.
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return (*target)->prototype.get();
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}
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DynamicMessage::TypeInfo* type_info = new DynamicMessage::TypeInfo;
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*target = type_info;
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type_info->type = type;
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type_info->pool = (pool_ == NULL) ? type->file()->pool() : pool_;
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type_info->factory = this;
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// We need to construct all the structures passed to
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// GeneratedMessageReflection's constructor. This includes:
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// - A block of memory that contains space for all the message's fields.
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// - An array of integers indicating the byte offset of each field within
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// this block.
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// - A big bitfield containing a bit for each field indicating whether
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// or not that field is set.
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// Compute size and offsets.
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int* offsets = new int[type->field_count()];
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type_info->offsets.reset(offsets);
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// Decide all field offsets by packing in order.
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// We place the DynamicMessage object itself at the beginning of the allocated
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// space.
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int size = sizeof(DynamicMessage);
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size = AlignOffset(size);
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// Next the has_bits, which is an array of uint32s.
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type_info->has_bits_offset = size;
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int has_bits_array_size =
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DivideRoundingUp(type->field_count(), bitsizeof(uint32));
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size += has_bits_array_size * sizeof(uint32);
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size = AlignOffset(size);
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// The ExtensionSet, if any.
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if (type->extension_range_count() > 0) {
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type_info->extensions_offset = size;
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size += sizeof(ExtensionSet);
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size = AlignOffset(size);
|
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} else {
|
|
// No extensions.
|
|
type_info->extensions_offset = -1;
|
|
}
|
|
|
|
// All the fields.
|
|
for (int i = 0; i < type->field_count(); i++) {
|
|
// Make sure field is aligned to avoid bus errors.
|
|
int field_size = FieldSpaceUsed(type->field(i));
|
|
size = AlignTo(size, min(kSafeAlignment, field_size));
|
|
offsets[i] = size;
|
|
size += field_size;
|
|
}
|
|
|
|
// Add the UnknownFieldSet to the end.
|
|
size = AlignOffset(size);
|
|
type_info->unknown_fields_offset = size;
|
|
size += sizeof(UnknownFieldSet);
|
|
|
|
// Align the final size to make sure no clever allocators think that
|
|
// alignment is not necessary.
|
|
size = AlignOffset(size);
|
|
type_info->size = size;
|
|
|
|
// Allocate the prototype.
|
|
void* base = operator new(size);
|
|
memset(base, 0, size);
|
|
DynamicMessage* prototype = new(base) DynamicMessage(type_info);
|
|
type_info->prototype.reset(prototype);
|
|
|
|
// Construct the reflection object.
|
|
type_info->reflection.reset(
|
|
new GeneratedMessageReflection(
|
|
type_info->type,
|
|
type_info->prototype.get(),
|
|
type_info->offsets.get(),
|
|
type_info->has_bits_offset,
|
|
type_info->unknown_fields_offset,
|
|
type_info->extensions_offset,
|
|
type_info->pool,
|
|
this,
|
|
type_info->size));
|
|
|
|
// Cross link prototypes.
|
|
prototype->CrossLinkPrototypes();
|
|
|
|
return prototype;
|
|
}
|
|
|
|
} // namespace protobuf
|
|
} // namespace google
|