// 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.
#include <google/protobuf/generated_message_util.h>
#include <limits>
// We're only using this as a standard way for getting the thread id.
// We're not using any thread functionality.
#include <thread> // NOLINT
#include <vector>
#include <google/protobuf/io/coded_stream_inl.h>
#include <google/protobuf/io/coded_stream.h>
#include <google/protobuf/arenastring.h>
#include <google/protobuf/extension_set.h>
#include <google/protobuf/message_lite.h>
#include <google/protobuf/metadata_lite.h>
#include <google/protobuf/stubs/mutex.h>
#include <google/protobuf/repeated_field.h>
#include <google/protobuf/wire_format_lite.h>
#include <google/protobuf/wire_format_lite_inl.h>
#include <google/protobuf/port_def.inc>
namespace google {
namespace protobuf {
namespace internal {
void DestroyMessage(const void* message) {
static_cast<const MessageLite*>(message)->~MessageLite();
}
void DestroyString(const void* s) { static_cast<const string*>(s)->~string(); }
ExplicitlyConstructed<::std::string> fixed_address_empty_string;
static bool InitProtobufDefaultsImpl() {
fixed_address_empty_string.DefaultConstruct();
OnShutdownDestroyString(fixed_address_empty_string.get_mutable());
return true;
}
void InitProtobufDefaults() {
static bool is_inited = InitProtobufDefaultsImpl();
(void)is_inited;
}
size_t StringSpaceUsedExcludingSelfLong(const string& str) {
const void* start = &str;
const void* end = &str + 1;
if (start <= str.data() && str.data() < end) {
// The string's data is stored inside the string object itself.
return 0;
} else {
return str.capacity();
}
}
template <typename T>
const T& Get(const void* ptr) {
return *static_cast<const T*>(ptr);
}
// PrimitiveTypeHelper is a wrapper around the interface of WireFormatLite.
// WireFormatLite has a very inconvenient interface with respect to template
// meta-programming. This class wraps the different named functions into
// a single Serialize / SerializeToArray interface.
template <int type>
struct PrimitiveTypeHelper;
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_BOOL> {
typedef bool Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteBoolNoTag(Get<bool>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteBoolNoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_INT32> {
typedef int32 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteInt32NoTag(Get<int32>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteInt32NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_SINT32> {
typedef int32 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteSInt32NoTag(Get<int32>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteSInt32NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_UINT32> {
typedef uint32 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteUInt32NoTag(Get<uint32>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteUInt32NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_INT64> {
typedef int64 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteInt64NoTag(Get<int64>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteInt64NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_SINT64> {
typedef int64 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteSInt64NoTag(Get<int64>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteSInt64NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_UINT64> {
typedef uint64 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteUInt64NoTag(Get<uint64>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteUInt64NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED32> {
typedef uint32 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteFixed32NoTag(Get<uint32>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteFixed32NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED64> {
typedef uint64 Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
WireFormatLite::WriteFixed64NoTag(Get<uint64>(ptr), output);
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
return WireFormatLite::WriteFixed64NoTagToArray(Get<Type>(ptr), buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_ENUM>
: PrimitiveTypeHelper<WireFormatLite::TYPE_INT32> {};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_SFIXED32>
: PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED32> {
typedef int32 Type;
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_SFIXED64>
: PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED64> {
typedef int64 Type;
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_FLOAT>
: PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED32> {
typedef float Type;
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_DOUBLE>
: PrimitiveTypeHelper<WireFormatLite::TYPE_FIXED64> {
typedef double Type;
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_STRING> {
typedef string Type;
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
const Type& value = *static_cast<const Type*>(ptr);
output->WriteVarint32(value.size());
output->WriteRawMaybeAliased(value.data(), value.size());
}
static uint8* SerializeToArray(const void* ptr, uint8* buffer) {
const Type& value = *static_cast<const Type*>(ptr);
return io::CodedOutputStream::WriteStringWithSizeToArray(value, buffer);
}
};
template <>
struct PrimitiveTypeHelper<WireFormatLite::TYPE_BYTES>
: PrimitiveTypeHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct PrimitiveTypeHelper<FieldMetadata::kInlinedType>
: PrimitiveTypeHelper<WireFormatLite::TYPE_STRING> {};
// We want to serialize to both CodedOutputStream and directly into byte arrays
// without duplicating the code. In fact we might want extra output channels in
// the future.
template <typename O, int type>
struct OutputHelper;
template <int type, typename O>
void SerializeTo(const void* ptr, O* output) {
OutputHelper<O, type>::Serialize(ptr, output);
}
template <typename O>
void WriteTagTo(uint32 tag, O* output) {
SerializeTo<WireFormatLite::TYPE_UINT32>(&tag, output);
}
template <typename O>
void WriteLengthTo(uint32 length, O* output) {
SerializeTo<WireFormatLite::TYPE_UINT32>(&length, output);
}
// Specialization for coded output stream
template <int type>
struct OutputHelper<io::CodedOutputStream, type> {
static void Serialize(const void* ptr, io::CodedOutputStream* output) {
PrimitiveTypeHelper<type>::Serialize(ptr, output);
}
};
// Specialization for writing into a plain array
struct ArrayOutput {
uint8* ptr;
bool is_deterministic;
};
template <int type>
struct OutputHelper<ArrayOutput, type> {
static void Serialize(const void* ptr, ArrayOutput* output) {
output->ptr = PrimitiveTypeHelper<type>::SerializeToArray(ptr, output->ptr);
}
};
void SerializeMessageNoTable(const MessageLite* msg,
io::CodedOutputStream* output) {
msg->SerializeWithCachedSizes(output);
}
void SerializeMessageNoTable(const MessageLite* msg, ArrayOutput* output) {
output->ptr = msg->InternalSerializeWithCachedSizesToArray(
output->is_deterministic, output->ptr);
}
// Helper to branch to fast path if possible
void SerializeMessageDispatch(const MessageLite& msg,
const FieldMetadata* field_table, int num_fields,
int32 cached_size,
io::CodedOutputStream* output) {
const uint8* base = reinterpret_cast<const uint8*>(&msg);
// Try the fast path
uint8* ptr = output->GetDirectBufferForNBytesAndAdvance(cached_size);
if (ptr) {
// We use virtual dispatch to enable dedicated generated code for the
// fast path.
msg.InternalSerializeWithCachedSizesToArray(
output->IsSerializationDeterministic(), ptr);
return;
}
SerializeInternal(base, field_table, num_fields, output);
}
// Helper to branch to fast path if possible
void SerializeMessageDispatch(const MessageLite& msg,
const FieldMetadata* field_table, int num_fields,
int32 cached_size, ArrayOutput* output) {
const uint8* base = reinterpret_cast<const uint8*>(&msg);
output->ptr = SerializeInternalToArray(base, field_table, num_fields,
output->is_deterministic, output->ptr);
}
// Serializing messages is special as it's not a primitive type and needs an
// explicit overload for each output type.
template <typename O>
void SerializeMessageTo(const MessageLite* msg, const void* table_ptr,
O* output) {
const SerializationTable* table =
static_cast<const SerializationTable*>(table_ptr);
if (!table) {
// Proto1
WriteLengthTo(msg->GetCachedSize(), output);
SerializeMessageNoTable(msg, output);
return;
}
const FieldMetadata* field_table = table->field_table;
const uint8* base = reinterpret_cast<const uint8*>(msg);
int cached_size = *reinterpret_cast<const int32*>(base + field_table->offset);
WriteLengthTo(cached_size, output);
int num_fields = table->num_fields - 1;
SerializeMessageDispatch(*msg, field_table + 1, num_fields, cached_size,
output);
}
// Almost the same as above only it doesn't output the length field.
template <typename O>
void SerializeGroupTo(const MessageLite* msg, const void* table_ptr,
O* output) {
const SerializationTable* table =
static_cast<const SerializationTable*>(table_ptr);
if (!table) {
// Proto1
SerializeMessageNoTable(msg, output);
return;
}
const FieldMetadata* field_table = table->field_table;
const uint8* base = reinterpret_cast<const uint8*>(msg);
int cached_size = *reinterpret_cast<const int32*>(base + field_table->offset);
int num_fields = table->num_fields - 1;
SerializeMessageDispatch(*msg, field_table + 1, num_fields, cached_size,
output);
}
template <int type>
struct SingularFieldHelper {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
WriteTagTo(md.tag, output);
SerializeTo<type>(field, output);
}
};
template <>
struct SingularFieldHelper<WireFormatLite::TYPE_STRING> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
WriteTagTo(md.tag, output);
SerializeTo<WireFormatLite::TYPE_STRING>(&Get<ArenaStringPtr>(field).Get(),
output);
}
};
template <>
struct SingularFieldHelper<WireFormatLite::TYPE_BYTES>
: SingularFieldHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct SingularFieldHelper<WireFormatLite::TYPE_GROUP> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
WriteTagTo(md.tag, output);
SerializeGroupTo(Get<const MessageLite*>(field),
static_cast<const SerializationTable*>(md.ptr), output);
WriteTagTo(md.tag + 1, output);
}
};
template <>
struct SingularFieldHelper<WireFormatLite::TYPE_MESSAGE> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
WriteTagTo(md.tag, output);
SerializeMessageTo(Get<const MessageLite*>(field),
static_cast<const SerializationTable*>(md.ptr), output);
}
};
template <>
struct SingularFieldHelper<FieldMetadata::kInlinedType> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
WriteTagTo(md.tag, output);
SerializeTo<FieldMetadata::kInlinedType>(&Get<::std::string>(field), output);
}
};
template <int type>
struct RepeatedFieldHelper {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
typedef typename PrimitiveTypeHelper<type>::Type T;
const RepeatedField<T>& array = Get<RepeatedField<T> >(field);
for (int i = 0; i < array.size(); i++) {
WriteTagTo(md.tag, output);
SerializeTo<type>(&array[i], output);
}
}
};
// We need to use a helper class to get access to the private members
class AccessorHelper {
public:
static int Size(const RepeatedPtrFieldBase& x) { return x.size(); }
static void const* Get(const RepeatedPtrFieldBase& x, int idx) {
return x.raw_data()[idx];
}
};
template <>
struct RepeatedFieldHelper<WireFormatLite::TYPE_STRING> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
const internal::RepeatedPtrFieldBase& array =
Get<internal::RepeatedPtrFieldBase>(field);
for (int i = 0; i < AccessorHelper::Size(array); i++) {
WriteTagTo(md.tag, output);
SerializeTo<WireFormatLite::TYPE_STRING>(AccessorHelper::Get(array, i),
output);
}
}
};
template <>
struct RepeatedFieldHelper<WireFormatLite::TYPE_BYTES>
: RepeatedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct RepeatedFieldHelper<WireFormatLite::TYPE_GROUP> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
const internal::RepeatedPtrFieldBase& array =
Get<internal::RepeatedPtrFieldBase>(field);
for (int i = 0; i < AccessorHelper::Size(array); i++) {
WriteTagTo(md.tag, output);
SerializeGroupTo(
static_cast<const MessageLite*>(AccessorHelper::Get(array, i)),
static_cast<const SerializationTable*>(md.ptr), output);
WriteTagTo(md.tag + 1, output);
}
}
};
template <>
struct RepeatedFieldHelper<WireFormatLite::TYPE_MESSAGE> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
const internal::RepeatedPtrFieldBase& array =
Get<internal::RepeatedPtrFieldBase>(field);
for (int i = 0; i < AccessorHelper::Size(array); i++) {
WriteTagTo(md.tag, output);
SerializeMessageTo(
static_cast<const MessageLite*>(AccessorHelper::Get(array, i)), md.ptr,
output);
}
}
};
template <>
struct RepeatedFieldHelper<FieldMetadata::kInlinedType>
: RepeatedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <int type>
struct PackedFieldHelper {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
typedef typename PrimitiveTypeHelper<type>::Type T;
const RepeatedField<T>& array = Get<RepeatedField<T> >(field);
if (array.empty()) return;
WriteTagTo(md.tag, output);
int cached_size =
Get<int>(static_cast<const uint8*>(field) + sizeof(RepeatedField<T>));
WriteLengthTo(cached_size, output);
for (int i = 0; i < array.size(); i++) {
SerializeTo<type>(&array[i], output);
}
}
};
template <>
struct PackedFieldHelper<WireFormatLite::TYPE_STRING> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
GOOGLE_LOG(FATAL) << "Not implemented field number " << md.tag << " with type "
<< md.type;
}
};
template <>
struct PackedFieldHelper<WireFormatLite::TYPE_BYTES>
: PackedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct PackedFieldHelper<WireFormatLite::TYPE_GROUP>
: PackedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct PackedFieldHelper<WireFormatLite::TYPE_MESSAGE>
: PackedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <>
struct PackedFieldHelper<FieldMetadata::kInlinedType>
: PackedFieldHelper<WireFormatLite::TYPE_STRING> {};
template <int type>
struct OneOfFieldHelper {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
SingularFieldHelper<type>::Serialize(field, md, output);
}
};
template <>
struct OneOfFieldHelper<FieldMetadata::kInlinedType> {
template <typename O>
static void Serialize(const void* field, const FieldMetadata& md, O* output) {
SingularFieldHelper<FieldMetadata::kInlinedType>::Serialize(
Get<const ::std::string*>(field), md, output);
}
};
void SerializeNotImplemented(int field) {
GOOGLE_LOG(FATAL) << "Not implemented field number " << field;
}
// When switching to c++11 we should make these constexpr functions
#define SERIALIZE_TABLE_OP(type, type_class) \
((type - 1) + static_cast<int>(type_class) * FieldMetadata::kNumTypes)
int FieldMetadata::CalculateType(int type,
FieldMetadata::FieldTypeClass type_class) {
return SERIALIZE_TABLE_OP(type, type_class);
}
template <int type>
bool IsNull(const void* ptr) {
return *static_cast<const typename PrimitiveTypeHelper<type>::Type*>(ptr) ==
0;
}
template <>
bool IsNull<WireFormatLite::TYPE_STRING>(const void* ptr) {
return static_cast<const ArenaStringPtr*>(ptr)->Get().size() == 0;
}
template <>
bool IsNull<WireFormatLite::TYPE_BYTES>(const void* ptr) {
return static_cast<const ArenaStringPtr*>(ptr)->Get().size() == 0;
}
template <>
bool IsNull<WireFormatLite::TYPE_GROUP>(const void* ptr) {
return Get<const MessageLite*>(ptr) == NULL;
}
template <>
bool IsNull<WireFormatLite::TYPE_MESSAGE>(const void* ptr) {
return Get<const MessageLite*>(ptr) == NULL;
}
template <>
bool IsNull<FieldMetadata::kInlinedType>(const void* ptr) {
return static_cast<const ::std::string*>(ptr)->empty();
}
#define SERIALIZERS_FOR_TYPE(type) \
case SERIALIZE_TABLE_OP(type, FieldMetadata::kPresence): \
if (!IsPresent(base, field_metadata.has_offset)) continue; \
SingularFieldHelper<type>::Serialize(ptr, field_metadata, output); \
break; \
case SERIALIZE_TABLE_OP(type, FieldMetadata::kNoPresence): \
if (IsNull<type>(ptr)) continue; \
SingularFieldHelper<type>::Serialize(ptr, field_metadata, output); \
break; \
case SERIALIZE_TABLE_OP(type, FieldMetadata::kRepeated): \
RepeatedFieldHelper<type>::Serialize(ptr, field_metadata, output); \
break; \
case SERIALIZE_TABLE_OP(type, FieldMetadata::kPacked): \
PackedFieldHelper<type>::Serialize(ptr, field_metadata, output); \
break; \
case SERIALIZE_TABLE_OP(type, FieldMetadata::kOneOf): \
if (!IsOneofPresent(base, field_metadata.has_offset, field_metadata.tag)) \
continue; \
OneOfFieldHelper<type>::Serialize(ptr, field_metadata, output); \
break
void SerializeInternal(const uint8* base,
const FieldMetadata* field_metadata_table,
int32 num_fields, io::CodedOutputStream* output) {
for (int i = 0; i < num_fields; i++) {
const FieldMetadata& field_metadata = field_metadata_table[i];
const uint8* ptr = base + field_metadata.offset;
switch (field_metadata.type) {
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_DOUBLE);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FLOAT);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_INT64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_UINT64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_INT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FIXED64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FIXED32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_BOOL);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_STRING);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_GROUP);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_MESSAGE);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_BYTES);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_UINT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_ENUM);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SFIXED32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SFIXED64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SINT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SINT64);
SERIALIZERS_FOR_TYPE(FieldMetadata::kInlinedType);
// Special cases
case FieldMetadata::kSpecial:
reinterpret_cast<SpecialSerializer>(
const_cast<void*>(field_metadata.ptr))(
base, field_metadata.offset, field_metadata.tag,
field_metadata.has_offset, output);
break;
default:
// __builtin_unreachable()
SerializeNotImplemented(field_metadata.type);
}
}
}
uint8* SerializeInternalToArray(const uint8* base,
const FieldMetadata* field_metadata_table,
int32 num_fields, bool is_deterministic,
uint8* buffer) {
ArrayOutput array_output = {buffer, is_deterministic};
ArrayOutput* output = &array_output;
for (int i = 0; i < num_fields; i++) {
const FieldMetadata& field_metadata = field_metadata_table[i];
const uint8* ptr = base + field_metadata.offset;
switch (field_metadata.type) {
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_DOUBLE);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FLOAT);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_INT64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_UINT64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_INT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FIXED64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_FIXED32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_BOOL);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_STRING);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_GROUP);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_MESSAGE);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_BYTES);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_UINT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_ENUM);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SFIXED32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SFIXED64);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SINT32);
SERIALIZERS_FOR_TYPE(WireFormatLite::TYPE_SINT64);
SERIALIZERS_FOR_TYPE(FieldMetadata::kInlinedType);
// Special cases
case FieldMetadata::kSpecial: {
io::ArrayOutputStream array_stream(array_output.ptr, INT_MAX);
io::CodedOutputStream output(&array_stream);
output.SetSerializationDeterministic(is_deterministic);
reinterpret_cast<SpecialSerializer>(
const_cast<void*>(field_metadata.ptr))(
base, field_metadata.offset, field_metadata.tag,
field_metadata.has_offset, &output);
array_output.ptr += output.ByteCount();
} break;
default:
// __builtin_unreachable()
SerializeNotImplemented(field_metadata.type);
}
}
return array_output.ptr;
}
#undef SERIALIZERS_FOR_TYPE
void ExtensionSerializer(const uint8* ptr, uint32 offset, uint32 tag,
uint32 has_offset, io::CodedOutputStream* output) {
reinterpret_cast<const ExtensionSet*>(ptr + offset)
->SerializeWithCachedSizes(tag, has_offset, output);
}
void UnknownFieldSerializerLite(const uint8* ptr, uint32 offset, uint32 tag,
uint32 has_offset,
io::CodedOutputStream* output) {
output->WriteString(
reinterpret_cast<const InternalMetadataWithArenaLite*>(ptr + offset)
->unknown_fields());
}
MessageLite* DuplicateIfNonNullInternal(MessageLite* message) {
if (message) {
MessageLite* ret = message->New();
ret->CheckTypeAndMergeFrom(*message);
return ret;
} else {
return NULL;
}
}
// Returns a message owned by this Arena. This may require Own()ing or
// duplicating the message.
MessageLite* GetOwnedMessageInternal(Arena* message_arena,
MessageLite* submessage,
Arena* submessage_arena) {
GOOGLE_DCHECK(submessage->GetArena() == submessage_arena);
GOOGLE_DCHECK(message_arena != submessage_arena);
if (message_arena != NULL && submessage_arena == NULL) {
message_arena->Own(submessage);
return submessage;
} else {
MessageLite* ret = submessage->New(message_arena);
ret->CheckTypeAndMergeFrom(*submessage);
return ret;
}
}
namespace {
void InitSCC_DFS(SCCInfoBase* scc) {
if (scc->visit_status.load(std::memory_order_relaxed) !=
SCCInfoBase::kUninitialized) return;
scc->visit_status.store(SCCInfoBase::kRunning, std::memory_order_relaxed);
// Each base is followed by an array of pointers to deps
auto deps = reinterpret_cast<SCCInfoBase* const*>(scc + 1);
for (int i = 0; i < scc->num_deps; i++) {
if (deps[i]) InitSCC_DFS(deps[i]);
}
scc->init_func();
// Mark done (note we use memory order release here), other threads could
// now see this as initialized and thus the initialization must have happened
// before.
scc->visit_status.store(SCCInfoBase::kInitialized, std::memory_order_release);
}
} // namespace
void InitSCCImpl(SCCInfoBase* scc) {
static WrappedMutex mu{GOOGLE_PROTOBUF_LINKER_INITIALIZED};
// Either the default in case no initialization is running or the id of the
// thread that is currently initializing.
static std::atomic<std::thread::id> runner;
auto me = std::this_thread::get_id();
// This will only happen because the constructor will call InitSCC while
// constructing the default instance.
if (runner.load(std::memory_order_relaxed) == me) {
// Because we're in the process of constructing the default instance.
// We can be assured that we're already exploring this SCC.
GOOGLE_CHECK_EQ(scc->visit_status.load(std::memory_order_relaxed),
SCCInfoBase::kRunning);
return;
}
InitProtobufDefaults();
mu.Lock();
runner.store(me, std::memory_order_relaxed);
InitSCC_DFS(scc);
runner.store(std::thread::id{}, std::memory_order_relaxed);
mu.Unlock();
}
} // namespace internal
} // namespace protobuf
} // namespace google
