dfhack/depends/protobuf/google/protobuf/extension_set.cc

1465 lines
58 KiB
C++

// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// http://code.google.com/p/protobuf/
//
// 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/stubs/hash.h>
#include <google/protobuf/stubs/common.h>
#include <google/protobuf/stubs/once.h>
#include <google/protobuf/extension_set.h>
#include <google/protobuf/message_lite.h>
#include <google/protobuf/io/coded_stream.h>
#include <google/protobuf/io/zero_copy_stream_impl.h>
#include <google/protobuf/wire_format_lite_inl.h>
#include <google/protobuf/repeated_field.h>
#include <google/protobuf/stubs/map-util.h>
namespace google {
namespace protobuf {
namespace internal {
namespace {
inline WireFormatLite::FieldType real_type(FieldType type) {
GOOGLE_DCHECK(type > 0 && type <= WireFormatLite::MAX_FIELD_TYPE);
return static_cast<WireFormatLite::FieldType>(type);
}
inline WireFormatLite::CppType cpp_type(FieldType type) {
return WireFormatLite::FieldTypeToCppType(real_type(type));
}
// Registry stuff.
typedef hash_map<pair<const MessageLite*, int>,
ExtensionInfo> ExtensionRegistry;
ExtensionRegistry* registry_ = NULL;
GOOGLE_PROTOBUF_DECLARE_ONCE(registry_init_);
void DeleteRegistry() {
delete registry_;
registry_ = NULL;
}
void InitRegistry() {
registry_ = new ExtensionRegistry;
internal::OnShutdown(&DeleteRegistry);
}
// This function is only called at startup, so there is no need for thread-
// safety.
void Register(const MessageLite* containing_type,
int number, ExtensionInfo info) {
::google::protobuf::GoogleOnceInit(&registry_init_, &InitRegistry);
if (!InsertIfNotPresent(registry_, make_pair(containing_type, number),
info)) {
GOOGLE_LOG(FATAL) << "Multiple extension registrations for type \""
<< containing_type->GetTypeName()
<< "\", field number " << number << ".";
}
}
const ExtensionInfo* FindRegisteredExtension(
const MessageLite* containing_type, int number) {
return (registry_ == NULL) ? NULL :
FindOrNull(*registry_, make_pair(containing_type, number));
}
} // namespace
ExtensionFinder::~ExtensionFinder() {}
bool GeneratedExtensionFinder::Find(int number, ExtensionInfo* output) {
const ExtensionInfo* extension =
FindRegisteredExtension(containing_type_, number);
if (extension == NULL) {
return false;
} else {
*output = *extension;
return true;
}
}
void ExtensionSet::RegisterExtension(const MessageLite* containing_type,
int number, FieldType type,
bool is_repeated, bool is_packed) {
GOOGLE_CHECK_NE(type, WireFormatLite::TYPE_ENUM);
GOOGLE_CHECK_NE(type, WireFormatLite::TYPE_MESSAGE);
GOOGLE_CHECK_NE(type, WireFormatLite::TYPE_GROUP);
ExtensionInfo info(type, is_repeated, is_packed);
Register(containing_type, number, info);
}
static bool CallNoArgValidityFunc(const void* arg, int number) {
// Note: Must use C-style cast here rather than reinterpret_cast because
// the C++ standard at one point did not allow casts between function and
// data pointers and some compilers enforce this for C++-style casts. No
// compiler enforces it for C-style casts since lots of C-style code has
// relied on these kinds of casts for a long time, despite being
// technically undefined. See:
// http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_defects.html#195
// Also note: Some compilers do not allow function pointers to be "const".
// Which makes sense, I suppose, because it's meaningless.
return ((EnumValidityFunc*)arg)(number);
}
void ExtensionSet::RegisterEnumExtension(const MessageLite* containing_type,
int number, FieldType type,
bool is_repeated, bool is_packed,
EnumValidityFunc* is_valid) {
GOOGLE_CHECK_EQ(type, WireFormatLite::TYPE_ENUM);
ExtensionInfo info(type, is_repeated, is_packed);
info.enum_validity_check.func = CallNoArgValidityFunc;
// See comment in CallNoArgValidityFunc() about why we use a c-style cast.
info.enum_validity_check.arg = (void*)is_valid;
Register(containing_type, number, info);
}
void ExtensionSet::RegisterMessageExtension(const MessageLite* containing_type,
int number, FieldType type,
bool is_repeated, bool is_packed,
const MessageLite* prototype) {
GOOGLE_CHECK(type == WireFormatLite::TYPE_MESSAGE ||
type == WireFormatLite::TYPE_GROUP);
ExtensionInfo info(type, is_repeated, is_packed);
info.message_prototype = prototype;
Register(containing_type, number, info);
}
// ===================================================================
// Constructors and basic methods.
ExtensionSet::ExtensionSet() {}
ExtensionSet::~ExtensionSet() {
for (map<int, Extension>::iterator iter = extensions_.begin();
iter != extensions_.end(); ++iter) {
iter->second.Free();
}
}
// Defined in extension_set_heavy.cc.
// void ExtensionSet::AppendToList(const Descriptor* containing_type,
// const DescriptorPool* pool,
// vector<const FieldDescriptor*>* output) const
bool ExtensionSet::Has(int number) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end()) return false;
GOOGLE_DCHECK(!iter->second.is_repeated);
return !iter->second.is_cleared;
}
int ExtensionSet::ExtensionSize(int number) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end()) return false;
return iter->second.GetSize();
}
FieldType ExtensionSet::ExtensionType(int number) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end()) {
GOOGLE_LOG(DFATAL) << "Don't lookup extension types if they aren't present (1). ";
return 0;
}
if (iter->second.is_cleared) {
GOOGLE_LOG(DFATAL) << "Don't lookup extension types if they aren't present (2). ";
}
return iter->second.type;
}
void ExtensionSet::ClearExtension(int number) {
map<int, Extension>::iterator iter = extensions_.find(number);
if (iter == extensions_.end()) return;
iter->second.Clear();
}
// ===================================================================
// Field accessors
namespace {
enum Cardinality {
REPEATED,
OPTIONAL
};
} // namespace
#define GOOGLE_DCHECK_TYPE(EXTENSION, LABEL, CPPTYPE) \
GOOGLE_DCHECK_EQ((EXTENSION).is_repeated ? REPEATED : OPTIONAL, LABEL); \
GOOGLE_DCHECK_EQ(cpp_type((EXTENSION).type), WireFormatLite::CPPTYPE_##CPPTYPE)
// -------------------------------------------------------------------
// Primitives
#define PRIMITIVE_ACCESSORS(UPPERCASE, LOWERCASE, CAMELCASE) \
\
LOWERCASE ExtensionSet::Get##CAMELCASE(int number, \
LOWERCASE default_value) const { \
map<int, Extension>::const_iterator iter = extensions_.find(number); \
if (iter == extensions_.end() || iter->second.is_cleared) { \
return default_value; \
} else { \
GOOGLE_DCHECK_TYPE(iter->second, OPTIONAL, UPPERCASE); \
return iter->second.LOWERCASE##_value; \
} \
} \
\
void ExtensionSet::Set##CAMELCASE(int number, FieldType type, \
LOWERCASE value, \
const FieldDescriptor* descriptor) { \
Extension* extension; \
if (MaybeNewExtension(number, descriptor, &extension)) { \
extension->type = type; \
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_##UPPERCASE); \
extension->is_repeated = false; \
} else { \
GOOGLE_DCHECK_TYPE(*extension, OPTIONAL, UPPERCASE); \
} \
extension->is_cleared = false; \
extension->LOWERCASE##_value = value; \
} \
\
LOWERCASE ExtensionSet::GetRepeated##CAMELCASE(int number, int index) const { \
map<int, Extension>::const_iterator iter = extensions_.find(number); \
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty)."; \
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, UPPERCASE); \
return iter->second.repeated_##LOWERCASE##_value->Get(index); \
} \
\
void ExtensionSet::SetRepeated##CAMELCASE( \
int number, int index, LOWERCASE value) { \
map<int, Extension>::iterator iter = extensions_.find(number); \
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty)."; \
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, UPPERCASE); \
iter->second.repeated_##LOWERCASE##_value->Set(index, value); \
} \
\
void ExtensionSet::Add##CAMELCASE(int number, FieldType type, \
bool packed, LOWERCASE value, \
const FieldDescriptor* descriptor) { \
Extension* extension; \
if (MaybeNewExtension(number, descriptor, &extension)) { \
extension->type = type; \
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_##UPPERCASE); \
extension->is_repeated = true; \
extension->is_packed = packed; \
extension->repeated_##LOWERCASE##_value = new RepeatedField<LOWERCASE>(); \
} else { \
GOOGLE_DCHECK_TYPE(*extension, REPEATED, UPPERCASE); \
GOOGLE_DCHECK_EQ(extension->is_packed, packed); \
} \
extension->repeated_##LOWERCASE##_value->Add(value); \
}
PRIMITIVE_ACCESSORS( INT32, int32, Int32)
PRIMITIVE_ACCESSORS( INT64, int64, Int64)
PRIMITIVE_ACCESSORS(UINT32, uint32, UInt32)
PRIMITIVE_ACCESSORS(UINT64, uint64, UInt64)
PRIMITIVE_ACCESSORS( FLOAT, float, Float)
PRIMITIVE_ACCESSORS(DOUBLE, double, Double)
PRIMITIVE_ACCESSORS( BOOL, bool, Bool)
#undef PRIMITIVE_ACCESSORS
// -------------------------------------------------------------------
// Enums
int ExtensionSet::GetEnum(int number, int default_value) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end() || iter->second.is_cleared) {
// Not present. Return the default value.
return default_value;
} else {
GOOGLE_DCHECK_TYPE(iter->second, OPTIONAL, ENUM);
return iter->second.enum_value;
}
}
void ExtensionSet::SetEnum(int number, FieldType type, int value,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_ENUM);
extension->is_repeated = false;
} else {
GOOGLE_DCHECK_TYPE(*extension, OPTIONAL, ENUM);
}
extension->is_cleared = false;
extension->enum_value = value;
}
int ExtensionSet::GetRepeatedEnum(int number, int index) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, ENUM);
return iter->second.repeated_enum_value->Get(index);
}
void ExtensionSet::SetRepeatedEnum(int number, int index, int value) {
map<int, Extension>::iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, ENUM);
iter->second.repeated_enum_value->Set(index, value);
}
void ExtensionSet::AddEnum(int number, FieldType type,
bool packed, int value,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_ENUM);
extension->is_repeated = true;
extension->is_packed = packed;
extension->repeated_enum_value = new RepeatedField<int>();
} else {
GOOGLE_DCHECK_TYPE(*extension, REPEATED, ENUM);
GOOGLE_DCHECK_EQ(extension->is_packed, packed);
}
extension->repeated_enum_value->Add(value);
}
// -------------------------------------------------------------------
// Strings
const string& ExtensionSet::GetString(int number,
const string& default_value) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end() || iter->second.is_cleared) {
// Not present. Return the default value.
return default_value;
} else {
GOOGLE_DCHECK_TYPE(iter->second, OPTIONAL, STRING);
return *iter->second.string_value;
}
}
string* ExtensionSet::MutableString(int number, FieldType type,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_STRING);
extension->is_repeated = false;
extension->string_value = new string;
} else {
GOOGLE_DCHECK_TYPE(*extension, OPTIONAL, STRING);
}
extension->is_cleared = false;
return extension->string_value;
}
const string& ExtensionSet::GetRepeatedString(int number, int index) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, STRING);
return iter->second.repeated_string_value->Get(index);
}
string* ExtensionSet::MutableRepeatedString(int number, int index) {
map<int, Extension>::iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, STRING);
return iter->second.repeated_string_value->Mutable(index);
}
string* ExtensionSet::AddString(int number, FieldType type,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_STRING);
extension->is_repeated = true;
extension->is_packed = false;
extension->repeated_string_value = new RepeatedPtrField<string>();
} else {
GOOGLE_DCHECK_TYPE(*extension, REPEATED, STRING);
}
return extension->repeated_string_value->Add();
}
// -------------------------------------------------------------------
// Messages
const MessageLite& ExtensionSet::GetMessage(
int number, const MessageLite& default_value) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
if (iter == extensions_.end()) {
// Not present. Return the default value.
return default_value;
} else {
GOOGLE_DCHECK_TYPE(iter->second, OPTIONAL, MESSAGE);
return *iter->second.message_value;
}
}
// Defined in extension_set_heavy.cc.
// const MessageLite& ExtensionSet::GetMessage(int number,
// const Descriptor* message_type,
// MessageFactory* factory) const
MessageLite* ExtensionSet::MutableMessage(int number, FieldType type,
const MessageLite& prototype,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_MESSAGE);
extension->is_repeated = false;
extension->message_value = prototype.New();
} else {
GOOGLE_DCHECK_TYPE(*extension, OPTIONAL, MESSAGE);
}
extension->is_cleared = false;
return extension->message_value;
}
// Defined in extension_set_heavy.cc.
// MessageLite* ExtensionSet::MutableMessage(int number, FieldType type,
// const Descriptor* message_type,
// MessageFactory* factory)
const MessageLite& ExtensionSet::GetRepeatedMessage(
int number, int index) const {
map<int, Extension>::const_iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, MESSAGE);
return iter->second.repeated_message_value->Get(index);
}
MessageLite* ExtensionSet::MutableRepeatedMessage(int number, int index) {
map<int, Extension>::iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
GOOGLE_DCHECK_TYPE(iter->second, REPEATED, MESSAGE);
return iter->second.repeated_message_value->Mutable(index);
}
MessageLite* ExtensionSet::AddMessage(int number, FieldType type,
const MessageLite& prototype,
const FieldDescriptor* descriptor) {
Extension* extension;
if (MaybeNewExtension(number, descriptor, &extension)) {
extension->type = type;
GOOGLE_DCHECK_EQ(cpp_type(extension->type), WireFormatLite::CPPTYPE_MESSAGE);
extension->is_repeated = true;
extension->repeated_message_value =
new RepeatedPtrField<MessageLite>();
} else {
GOOGLE_DCHECK_TYPE(*extension, REPEATED, MESSAGE);
}
// RepeatedPtrField<MessageLite> does not know how to Add() since it cannot
// allocate an abstract object, so we have to be tricky.
MessageLite* result = extension->repeated_message_value
->AddFromCleared<internal::GenericTypeHandler<MessageLite> >();
if (result == NULL) {
result = prototype.New();
extension->repeated_message_value->AddAllocated(result);
}
return result;
}
// Defined in extension_set_heavy.cc.
// MessageLite* ExtensionSet::AddMessage(int number, FieldType type,
// const Descriptor* message_type,
// MessageFactory* factory)
#undef GOOGLE_DCHECK_TYPE
void ExtensionSet::RemoveLast(int number) {
map<int, Extension>::iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
Extension* extension = &iter->second;
GOOGLE_DCHECK(extension->is_repeated);
switch(cpp_type(extension->type)) {
case WireFormatLite::CPPTYPE_INT32:
extension->repeated_int32_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_INT64:
extension->repeated_int64_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_UINT32:
extension->repeated_uint32_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_UINT64:
extension->repeated_uint64_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_FLOAT:
extension->repeated_float_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_DOUBLE:
extension->repeated_double_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_BOOL:
extension->repeated_bool_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_ENUM:
extension->repeated_enum_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_STRING:
extension->repeated_string_value->RemoveLast();
break;
case WireFormatLite::CPPTYPE_MESSAGE:
extension->repeated_message_value->RemoveLast();
break;
}
}
void ExtensionSet::SwapElements(int number, int index1, int index2) {
map<int, Extension>::iterator iter = extensions_.find(number);
GOOGLE_CHECK(iter != extensions_.end()) << "Index out-of-bounds (field is empty).";
Extension* extension = &iter->second;
GOOGLE_DCHECK(extension->is_repeated);
switch(cpp_type(extension->type)) {
case WireFormatLite::CPPTYPE_INT32:
extension->repeated_int32_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_INT64:
extension->repeated_int64_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_UINT32:
extension->repeated_uint32_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_UINT64:
extension->repeated_uint64_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_FLOAT:
extension->repeated_float_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_DOUBLE:
extension->repeated_double_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_BOOL:
extension->repeated_bool_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_ENUM:
extension->repeated_enum_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_STRING:
extension->repeated_string_value->SwapElements(index1, index2);
break;
case WireFormatLite::CPPTYPE_MESSAGE:
extension->repeated_message_value->SwapElements(index1, index2);
break;
}
}
// ===================================================================
void ExtensionSet::Clear() {
for (map<int, Extension>::iterator iter = extensions_.begin();
iter != extensions_.end(); ++iter) {
iter->second.Clear();
}
}
void ExtensionSet::MergeFrom(const ExtensionSet& other) {
for (map<int, Extension>::const_iterator iter = other.extensions_.begin();
iter != other.extensions_.end(); ++iter) {
const Extension& other_extension = iter->second;
if (other_extension.is_repeated) {
Extension* extension;
bool is_new = MaybeNewExtension(iter->first, other_extension.descriptor,
&extension);
if (is_new) {
// Extension did not already exist in set.
extension->type = other_extension.type;
extension->is_repeated = true;
} else {
GOOGLE_DCHECK_EQ(extension->type, other_extension.type);
GOOGLE_DCHECK(extension->is_repeated);
}
switch (cpp_type(other_extension.type)) {
#define HANDLE_TYPE(UPPERCASE, LOWERCASE, REPEATED_TYPE) \
case WireFormatLite::CPPTYPE_##UPPERCASE: \
if (is_new) { \
extension->repeated_##LOWERCASE##_value = \
new REPEATED_TYPE; \
} \
extension->repeated_##LOWERCASE##_value->MergeFrom( \
*other_extension.repeated_##LOWERCASE##_value); \
break;
HANDLE_TYPE( INT32, int32, RepeatedField < int32>);
HANDLE_TYPE( INT64, int64, RepeatedField < int64>);
HANDLE_TYPE( UINT32, uint32, RepeatedField < uint32>);
HANDLE_TYPE( UINT64, uint64, RepeatedField < uint64>);
HANDLE_TYPE( FLOAT, float, RepeatedField < float>);
HANDLE_TYPE( DOUBLE, double, RepeatedField < double>);
HANDLE_TYPE( BOOL, bool, RepeatedField < bool>);
HANDLE_TYPE( ENUM, enum, RepeatedField < int>);
HANDLE_TYPE( STRING, string, RepeatedPtrField< string>);
#undef HANDLE_TYPE
case WireFormatLite::CPPTYPE_MESSAGE:
if (is_new) {
extension->repeated_message_value =
new RepeatedPtrField<MessageLite>();
}
// We can't call RepeatedPtrField<MessageLite>::MergeFrom() because
// it would attempt to allocate new objects.
RepeatedPtrField<MessageLite>* other_repeated_message =
other_extension.repeated_message_value;
for (int i = 0; i < other_repeated_message->size(); i++) {
const MessageLite& other_message = other_repeated_message->Get(i);
MessageLite* target = extension->repeated_message_value
->AddFromCleared<GenericTypeHandler<MessageLite> >();
if (target == NULL) {
target = other_message.New();
extension->repeated_message_value->AddAllocated(target);
}
target->CheckTypeAndMergeFrom(other_message);
}
break;
}
} else {
if (!other_extension.is_cleared) {
switch (cpp_type(other_extension.type)) {
#define HANDLE_TYPE(UPPERCASE, LOWERCASE, CAMELCASE) \
case WireFormatLite::CPPTYPE_##UPPERCASE: \
Set##CAMELCASE(iter->first, other_extension.type, \
other_extension.LOWERCASE##_value, \
other_extension.descriptor); \
break;
HANDLE_TYPE( INT32, int32, Int32);
HANDLE_TYPE( INT64, int64, Int64);
HANDLE_TYPE(UINT32, uint32, UInt32);
HANDLE_TYPE(UINT64, uint64, UInt64);
HANDLE_TYPE( FLOAT, float, Float);
HANDLE_TYPE(DOUBLE, double, Double);
HANDLE_TYPE( BOOL, bool, Bool);
HANDLE_TYPE( ENUM, enum, Enum);
#undef HANDLE_TYPE
case WireFormatLite::CPPTYPE_STRING:
SetString(iter->first, other_extension.type,
*other_extension.string_value,
other_extension.descriptor);
break;
case WireFormatLite::CPPTYPE_MESSAGE:
MutableMessage(iter->first, other_extension.type,
*other_extension.message_value,
other_extension.descriptor)
->CheckTypeAndMergeFrom(*other_extension.message_value);
break;
}
}
}
}
}
void ExtensionSet::Swap(ExtensionSet* x) {
extensions_.swap(x->extensions_);
}
bool ExtensionSet::IsInitialized() const {
// Extensions are never required. However, we need to check that all
// embedded messages are initialized.
for (map<int, Extension>::const_iterator iter = extensions_.begin();
iter != extensions_.end(); ++iter) {
const Extension& extension = iter->second;
if (cpp_type(extension.type) == WireFormatLite::CPPTYPE_MESSAGE) {
if (extension.is_repeated) {
for (int i = 0; i < extension.repeated_message_value->size(); i++) {
if (!extension.repeated_message_value->Get(i).IsInitialized()) {
return false;
}
}
} else {
if (!extension.is_cleared) {
if (!extension.message_value->IsInitialized()) return false;
}
}
}
}
return true;
}
bool ExtensionSet::ParseField(uint32 tag, io::CodedInputStream* input,
ExtensionFinder* extension_finder,
FieldSkipper* field_skipper) {
int number = WireFormatLite::GetTagFieldNumber(tag);
WireFormatLite::WireType wire_type = WireFormatLite::GetTagWireType(tag);
ExtensionInfo extension;
bool is_unknown;
if (!extension_finder->Find(number, &extension)) {
is_unknown = true;
} else if (extension.is_packed) {
is_unknown = (wire_type != WireFormatLite::WIRETYPE_LENGTH_DELIMITED);
} else {
WireFormatLite::WireType expected_wire_type =
WireFormatLite::WireTypeForFieldType(real_type(extension.type));
is_unknown = (wire_type != expected_wire_type);
}
if (is_unknown) {
field_skipper->SkipField(input, tag);
} else if (extension.is_packed) {
uint32 size;
if (!input->ReadVarint32(&size)) return false;
io::CodedInputStream::Limit limit = input->PushLimit(size);
switch (extension.type) {
#define HANDLE_TYPE(UPPERCASE, CPP_CAMELCASE, CPP_LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
while (input->BytesUntilLimit() > 0) { \
CPP_LOWERCASE value; \
if (!WireFormatLite::ReadPrimitive< \
CPP_LOWERCASE, WireFormatLite::TYPE_##UPPERCASE>( \
input, &value)) return false; \
Add##CPP_CAMELCASE(number, WireFormatLite::TYPE_##UPPERCASE, \
true, value, extension.descriptor); \
} \
break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, Int32, int32);
HANDLE_TYPE( SINT64, Int64, int64);
HANDLE_TYPE( FIXED32, UInt32, uint32);
HANDLE_TYPE( FIXED64, UInt64, uint64);
HANDLE_TYPE(SFIXED32, Int32, int32);
HANDLE_TYPE(SFIXED64, Int64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
#undef HANDLE_TYPE
case WireFormatLite::TYPE_ENUM:
while (input->BytesUntilLimit() > 0) {
int value;
if (!WireFormatLite::ReadPrimitive<int, WireFormatLite::TYPE_ENUM>(
input, &value)) return false;
if (extension.enum_validity_check.func(
extension.enum_validity_check.arg, value)) {
AddEnum(number, WireFormatLite::TYPE_ENUM, true, value,
extension.descriptor);
}
}
break;
case WireFormatLite::TYPE_STRING:
case WireFormatLite::TYPE_BYTES:
case WireFormatLite::TYPE_GROUP:
case WireFormatLite::TYPE_MESSAGE:
GOOGLE_LOG(FATAL) << "Non-primitive types can't be packed.";
break;
}
input->PopLimit(limit);
} else {
switch (extension.type) {
#define HANDLE_TYPE(UPPERCASE, CPP_CAMELCASE, CPP_LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: { \
CPP_LOWERCASE value; \
if (!WireFormatLite::ReadPrimitive< \
CPP_LOWERCASE, WireFormatLite::TYPE_##UPPERCASE>( \
input, &value)) return false; \
if (extension.is_repeated) { \
Add##CPP_CAMELCASE(number, WireFormatLite::TYPE_##UPPERCASE, \
false, value, extension.descriptor); \
} else { \
Set##CPP_CAMELCASE(number, WireFormatLite::TYPE_##UPPERCASE, value, \
extension.descriptor); \
} \
} break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, Int32, int32);
HANDLE_TYPE( SINT64, Int64, int64);
HANDLE_TYPE( FIXED32, UInt32, uint32);
HANDLE_TYPE( FIXED64, UInt64, uint64);
HANDLE_TYPE(SFIXED32, Int32, int32);
HANDLE_TYPE(SFIXED64, Int64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
#undef HANDLE_TYPE
case WireFormatLite::TYPE_ENUM: {
int value;
if (!WireFormatLite::ReadPrimitive<int, WireFormatLite::TYPE_ENUM>(
input, &value)) return false;
if (!extension.enum_validity_check.func(
extension.enum_validity_check.arg, value)) {
// Invalid value. Treat as unknown.
field_skipper->SkipUnknownEnum(number, value);
} else if (extension.is_repeated) {
AddEnum(number, WireFormatLite::TYPE_ENUM, false, value,
extension.descriptor);
} else {
SetEnum(number, WireFormatLite::TYPE_ENUM, value,
extension.descriptor);
}
break;
}
case WireFormatLite::TYPE_STRING: {
string* value = extension.is_repeated ?
AddString(number, WireFormatLite::TYPE_STRING, extension.descriptor) :
MutableString(number, WireFormatLite::TYPE_STRING,
extension.descriptor);
if (!WireFormatLite::ReadString(input, value)) return false;
break;
}
case WireFormatLite::TYPE_BYTES: {
string* value = extension.is_repeated ?
AddString(number, WireFormatLite::TYPE_STRING, extension.descriptor) :
MutableString(number, WireFormatLite::TYPE_STRING,
extension.descriptor);
if (!WireFormatLite::ReadBytes(input, value)) return false;
break;
}
case WireFormatLite::TYPE_GROUP: {
MessageLite* value = extension.is_repeated ?
AddMessage(number, WireFormatLite::TYPE_GROUP,
*extension.message_prototype, extension.descriptor) :
MutableMessage(number, WireFormatLite::TYPE_GROUP,
*extension.message_prototype, extension.descriptor);
if (!WireFormatLite::ReadGroup(number, input, value)) return false;
break;
}
case WireFormatLite::TYPE_MESSAGE: {
MessageLite* value = extension.is_repeated ?
AddMessage(number, WireFormatLite::TYPE_MESSAGE,
*extension.message_prototype, extension.descriptor) :
MutableMessage(number, WireFormatLite::TYPE_MESSAGE,
*extension.message_prototype, extension.descriptor);
if (!WireFormatLite::ReadMessage(input, value)) return false;
break;
}
}
}
return true;
}
bool ExtensionSet::ParseField(uint32 tag, io::CodedInputStream* input,
const MessageLite* containing_type) {
FieldSkipper skipper;
GeneratedExtensionFinder finder(containing_type);
return ParseField(tag, input, &finder, &skipper);
}
// Defined in extension_set_heavy.cc.
// bool ExtensionSet::ParseField(uint32 tag, io::CodedInputStream* input,
// const MessageLite* containing_type,
// UnknownFieldSet* unknown_fields)
bool ExtensionSet::ParseMessageSet(io::CodedInputStream* input,
ExtensionFinder* extension_finder,
FieldSkipper* field_skipper) {
while (true) {
uint32 tag = input->ReadTag();
switch (tag) {
case 0:
return true;
case WireFormatLite::kMessageSetItemStartTag:
if (!ParseMessageSetItem(input, extension_finder, field_skipper)) {
return false;
}
break;
default:
if (!ParseField(tag, input, extension_finder, field_skipper)) {
return false;
}
break;
}
}
}
bool ExtensionSet::ParseMessageSet(io::CodedInputStream* input,
const MessageLite* containing_type) {
FieldSkipper skipper;
GeneratedExtensionFinder finder(containing_type);
return ParseMessageSet(input, &finder, &skipper);
}
// Defined in extension_set_heavy.cc.
// bool ExtensionSet::ParseMessageSet(io::CodedInputStream* input,
// const MessageLite* containing_type,
// UnknownFieldSet* unknown_fields);
bool ExtensionSet::ParseMessageSetItem(io::CodedInputStream* input,
ExtensionFinder* extension_finder,
FieldSkipper* field_skipper) {
// TODO(kenton): It would be nice to share code between this and
// WireFormatLite::ParseAndMergeMessageSetItem(), but I think the
// differences would be hard to factor out.
// This method parses a group which should contain two fields:
// required int32 type_id = 2;
// required data message = 3;
// Once we see a type_id, we'll construct a fake tag for this extension
// which is the tag it would have had under the proto2 extensions wire
// format.
uint32 fake_tag = 0;
// If we see message data before the type_id, we'll append it to this so
// we can parse it later. This will probably never happen in practice,
// as no MessageSet encoder I know of writes the message before the type ID.
// But, it's technically valid so we should allow it.
// TODO(kenton): Use a Cord instead? Do I care?
string message_data;
while (true) {
uint32 tag = input->ReadTag();
if (tag == 0) return false;
switch (tag) {
case WireFormatLite::kMessageSetTypeIdTag: {
uint32 type_id;
if (!input->ReadVarint32(&type_id)) return false;
fake_tag = WireFormatLite::MakeTag(type_id,
WireFormatLite::WIRETYPE_LENGTH_DELIMITED);
if (!message_data.empty()) {
// We saw some message data before the type_id. Have to parse it
// now.
io::CodedInputStream sub_input(
reinterpret_cast<const uint8*>(message_data.data()),
message_data.size());
if (!ParseField(fake_tag, &sub_input,
extension_finder, field_skipper)) {
return false;
}
message_data.clear();
}
break;
}
case WireFormatLite::kMessageSetMessageTag: {
if (fake_tag == 0) {
// We haven't seen a type_id yet. Append this data to message_data.
string temp;
uint32 length;
if (!input->ReadVarint32(&length)) return false;
if (!input->ReadString(&temp, length)) return false;
message_data.append(temp);
} else {
// Already saw type_id, so we can parse this directly.
if (!ParseField(fake_tag, input,
extension_finder, field_skipper)) {
return false;
}
}
break;
}
case WireFormatLite::kMessageSetItemEndTag: {
return true;
}
default: {
if (!field_skipper->SkipField(input, tag)) return false;
}
}
}
}
void ExtensionSet::SerializeWithCachedSizes(
int start_field_number, int end_field_number,
io::CodedOutputStream* output) const {
map<int, Extension>::const_iterator iter;
for (iter = extensions_.lower_bound(start_field_number);
iter != extensions_.end() && iter->first < end_field_number;
++iter) {
iter->second.SerializeFieldWithCachedSizes(iter->first, output);
}
}
void ExtensionSet::SerializeMessageSetWithCachedSizes(
io::CodedOutputStream* output) const {
map<int, Extension>::const_iterator iter;
for (iter = extensions_.begin(); iter != extensions_.end(); ++iter) {
iter->second.SerializeMessageSetItemWithCachedSizes(iter->first, output);
}
}
int ExtensionSet::ByteSize() const {
int total_size = 0;
for (map<int, Extension>::const_iterator iter = extensions_.begin();
iter != extensions_.end(); ++iter) {
total_size += iter->second.ByteSize(iter->first);
}
return total_size;
}
int ExtensionSet::MessageSetByteSize() const {
int total_size = 0;
for (map<int, Extension>::const_iterator iter = extensions_.begin();
iter != extensions_.end(); ++iter) {
total_size += iter->second.MessageSetItemByteSize(iter->first);
}
return total_size;
}
// Defined in extension_set_heavy.cc.
// int ExtensionSet::SpaceUsedExcludingSelf() const
bool ExtensionSet::MaybeNewExtension(int number,
const FieldDescriptor* descriptor,
Extension** result) {
pair<map<int, Extension>::iterator, bool> insert_result =
extensions_.insert(make_pair(number, Extension()));
*result = &insert_result.first->second;
(*result)->descriptor = descriptor;
return insert_result.second;
}
// ===================================================================
// Methods of ExtensionSet::Extension
void ExtensionSet::Extension::Clear() {
if (is_repeated) {
switch (cpp_type(type)) {
#define HANDLE_TYPE(UPPERCASE, LOWERCASE) \
case WireFormatLite::CPPTYPE_##UPPERCASE: \
repeated_##LOWERCASE##_value->Clear(); \
break
HANDLE_TYPE( INT32, int32);
HANDLE_TYPE( INT64, int64);
HANDLE_TYPE( UINT32, uint32);
HANDLE_TYPE( UINT64, uint64);
HANDLE_TYPE( FLOAT, float);
HANDLE_TYPE( DOUBLE, double);
HANDLE_TYPE( BOOL, bool);
HANDLE_TYPE( ENUM, enum);
HANDLE_TYPE( STRING, string);
HANDLE_TYPE(MESSAGE, message);
#undef HANDLE_TYPE
}
} else {
if (!is_cleared) {
switch (cpp_type(type)) {
case WireFormatLite::CPPTYPE_STRING:
string_value->clear();
break;
case WireFormatLite::CPPTYPE_MESSAGE:
message_value->Clear();
break;
default:
// No need to do anything. Get*() will return the default value
// as long as is_cleared is true and Set*() will overwrite the
// previous value.
break;
}
is_cleared = true;
}
}
}
void ExtensionSet::Extension::SerializeFieldWithCachedSizes(
int number,
io::CodedOutputStream* output) const {
if (is_repeated) {
if (is_packed) {
if (cached_size == 0) return;
WireFormatLite::WriteTag(number,
WireFormatLite::WIRETYPE_LENGTH_DELIMITED, output);
output->WriteVarint32(cached_size);
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
for (int i = 0; i < repeated_##LOWERCASE##_value->size(); i++) { \
WireFormatLite::Write##CAMELCASE##NoTag( \
repeated_##LOWERCASE##_value->Get(i), output); \
} \
break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, SInt32, int32);
HANDLE_TYPE( SINT64, SInt64, int64);
HANDLE_TYPE( FIXED32, Fixed32, uint32);
HANDLE_TYPE( FIXED64, Fixed64, uint64);
HANDLE_TYPE(SFIXED32, SFixed32, int32);
HANDLE_TYPE(SFIXED64, SFixed64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
HANDLE_TYPE( ENUM, Enum, enum);
#undef HANDLE_TYPE
case WireFormatLite::TYPE_STRING:
case WireFormatLite::TYPE_BYTES:
case WireFormatLite::TYPE_GROUP:
case WireFormatLite::TYPE_MESSAGE:
GOOGLE_LOG(FATAL) << "Non-primitive types can't be packed.";
break;
}
} else {
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
for (int i = 0; i < repeated_##LOWERCASE##_value->size(); i++) { \
WireFormatLite::Write##CAMELCASE(number, \
repeated_##LOWERCASE##_value->Get(i), output); \
} \
break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, SInt32, int32);
HANDLE_TYPE( SINT64, SInt64, int64);
HANDLE_TYPE( FIXED32, Fixed32, uint32);
HANDLE_TYPE( FIXED64, Fixed64, uint64);
HANDLE_TYPE(SFIXED32, SFixed32, int32);
HANDLE_TYPE(SFIXED64, SFixed64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
HANDLE_TYPE( STRING, String, string);
HANDLE_TYPE( BYTES, Bytes, string);
HANDLE_TYPE( ENUM, Enum, enum);
HANDLE_TYPE( GROUP, Group, message);
HANDLE_TYPE( MESSAGE, Message, message);
#undef HANDLE_TYPE
}
}
} else if (!is_cleared) {
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, VALUE) \
case WireFormatLite::TYPE_##UPPERCASE: \
WireFormatLite::Write##CAMELCASE(number, VALUE, output); \
break
HANDLE_TYPE( INT32, Int32, int32_value);
HANDLE_TYPE( INT64, Int64, int64_value);
HANDLE_TYPE( UINT32, UInt32, uint32_value);
HANDLE_TYPE( UINT64, UInt64, uint64_value);
HANDLE_TYPE( SINT32, SInt32, int32_value);
HANDLE_TYPE( SINT64, SInt64, int64_value);
HANDLE_TYPE( FIXED32, Fixed32, uint32_value);
HANDLE_TYPE( FIXED64, Fixed64, uint64_value);
HANDLE_TYPE(SFIXED32, SFixed32, int32_value);
HANDLE_TYPE(SFIXED64, SFixed64, int64_value);
HANDLE_TYPE( FLOAT, Float, float_value);
HANDLE_TYPE( DOUBLE, Double, double_value);
HANDLE_TYPE( BOOL, Bool, bool_value);
HANDLE_TYPE( STRING, String, *string_value);
HANDLE_TYPE( BYTES, Bytes, *string_value);
HANDLE_TYPE( ENUM, Enum, enum_value);
HANDLE_TYPE( GROUP, Group, *message_value);
HANDLE_TYPE( MESSAGE, Message, *message_value);
#undef HANDLE_TYPE
}
}
}
void ExtensionSet::Extension::SerializeMessageSetItemWithCachedSizes(
int number,
io::CodedOutputStream* output) const {
if (type != WireFormatLite::TYPE_MESSAGE || is_repeated) {
// Not a valid MessageSet extension, but serialize it the normal way.
SerializeFieldWithCachedSizes(number, output);
return;
}
if (is_cleared) return;
// Start group.
output->WriteTag(WireFormatLite::kMessageSetItemStartTag);
// Write type ID.
WireFormatLite::WriteUInt32(WireFormatLite::kMessageSetTypeIdNumber,
number,
output);
// Write message.
WireFormatLite::WriteMessageMaybeToArray(
WireFormatLite::kMessageSetMessageNumber,
*message_value,
output);
// End group.
output->WriteTag(WireFormatLite::kMessageSetItemEndTag);
}
int ExtensionSet::Extension::ByteSize(int number) const {
int result = 0;
if (is_repeated) {
if (is_packed) {
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
for (int i = 0; i < repeated_##LOWERCASE##_value->size(); i++) { \
result += WireFormatLite::CAMELCASE##Size( \
repeated_##LOWERCASE##_value->Get(i)); \
} \
break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, SInt32, int32);
HANDLE_TYPE( SINT64, SInt64, int64);
HANDLE_TYPE( ENUM, Enum, enum);
#undef HANDLE_TYPE
// Stuff with fixed size.
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
result += WireFormatLite::k##CAMELCASE##Size * \
repeated_##LOWERCASE##_value->size(); \
break
HANDLE_TYPE( FIXED32, Fixed32, uint32);
HANDLE_TYPE( FIXED64, Fixed64, uint64);
HANDLE_TYPE(SFIXED32, SFixed32, int32);
HANDLE_TYPE(SFIXED64, SFixed64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
#undef HANDLE_TYPE
case WireFormatLite::TYPE_STRING:
case WireFormatLite::TYPE_BYTES:
case WireFormatLite::TYPE_GROUP:
case WireFormatLite::TYPE_MESSAGE:
GOOGLE_LOG(FATAL) << "Non-primitive types can't be packed.";
break;
}
cached_size = result;
if (result > 0) {
result += io::CodedOutputStream::VarintSize32(result);
result += io::CodedOutputStream::VarintSize32(
WireFormatLite::MakeTag(number,
WireFormatLite::WIRETYPE_LENGTH_DELIMITED));
}
} else {
int tag_size = WireFormatLite::TagSize(number, real_type(type));
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
result += tag_size * repeated_##LOWERCASE##_value->size(); \
for (int i = 0; i < repeated_##LOWERCASE##_value->size(); i++) { \
result += WireFormatLite::CAMELCASE##Size( \
repeated_##LOWERCASE##_value->Get(i)); \
} \
break
HANDLE_TYPE( INT32, Int32, int32);
HANDLE_TYPE( INT64, Int64, int64);
HANDLE_TYPE( UINT32, UInt32, uint32);
HANDLE_TYPE( UINT64, UInt64, uint64);
HANDLE_TYPE( SINT32, SInt32, int32);
HANDLE_TYPE( SINT64, SInt64, int64);
HANDLE_TYPE( STRING, String, string);
HANDLE_TYPE( BYTES, Bytes, string);
HANDLE_TYPE( ENUM, Enum, enum);
HANDLE_TYPE( GROUP, Group, message);
HANDLE_TYPE( MESSAGE, Message, message);
#undef HANDLE_TYPE
// Stuff with fixed size.
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
result += (tag_size + WireFormatLite::k##CAMELCASE##Size) * \
repeated_##LOWERCASE##_value->size(); \
break
HANDLE_TYPE( FIXED32, Fixed32, uint32);
HANDLE_TYPE( FIXED64, Fixed64, uint64);
HANDLE_TYPE(SFIXED32, SFixed32, int32);
HANDLE_TYPE(SFIXED64, SFixed64, int64);
HANDLE_TYPE( FLOAT, Float, float);
HANDLE_TYPE( DOUBLE, Double, double);
HANDLE_TYPE( BOOL, Bool, bool);
#undef HANDLE_TYPE
}
}
} else if (!is_cleared) {
result += WireFormatLite::TagSize(number, real_type(type));
switch (real_type(type)) {
#define HANDLE_TYPE(UPPERCASE, CAMELCASE, LOWERCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
result += WireFormatLite::CAMELCASE##Size(LOWERCASE); \
break
HANDLE_TYPE( INT32, Int32, int32_value);
HANDLE_TYPE( INT64, Int64, int64_value);
HANDLE_TYPE( UINT32, UInt32, uint32_value);
HANDLE_TYPE( UINT64, UInt64, uint64_value);
HANDLE_TYPE( SINT32, SInt32, int32_value);
HANDLE_TYPE( SINT64, SInt64, int64_value);
HANDLE_TYPE( STRING, String, *string_value);
HANDLE_TYPE( BYTES, Bytes, *string_value);
HANDLE_TYPE( ENUM, Enum, enum_value);
HANDLE_TYPE( GROUP, Group, *message_value);
HANDLE_TYPE( MESSAGE, Message, *message_value);
#undef HANDLE_TYPE
// Stuff with fixed size.
#define HANDLE_TYPE(UPPERCASE, CAMELCASE) \
case WireFormatLite::TYPE_##UPPERCASE: \
result += WireFormatLite::k##CAMELCASE##Size; \
break
HANDLE_TYPE( FIXED32, Fixed32);
HANDLE_TYPE( FIXED64, Fixed64);
HANDLE_TYPE(SFIXED32, SFixed32);
HANDLE_TYPE(SFIXED64, SFixed64);
HANDLE_TYPE( FLOAT, Float);
HANDLE_TYPE( DOUBLE, Double);
HANDLE_TYPE( BOOL, Bool);
#undef HANDLE_TYPE
}
}
return result;
}
int ExtensionSet::Extension::MessageSetItemByteSize(int number) const {
if (type != WireFormatLite::TYPE_MESSAGE || is_repeated) {
// Not a valid MessageSet extension, but compute the byte size for it the
// normal way.
return ByteSize(number);
}
if (is_cleared) return 0;
int our_size = WireFormatLite::kMessageSetItemTagsSize;
// type_id
our_size += io::CodedOutputStream::VarintSize32(number);
// message
int message_size = message_value->ByteSize();
our_size += io::CodedOutputStream::VarintSize32(message_size);
our_size += message_size;
return our_size;
}
int ExtensionSet::Extension::GetSize() const {
GOOGLE_DCHECK(is_repeated);
switch (cpp_type(type)) {
#define HANDLE_TYPE(UPPERCASE, LOWERCASE) \
case WireFormatLite::CPPTYPE_##UPPERCASE: \
return repeated_##LOWERCASE##_value->size()
HANDLE_TYPE( INT32, int32);
HANDLE_TYPE( INT64, int64);
HANDLE_TYPE( UINT32, uint32);
HANDLE_TYPE( UINT64, uint64);
HANDLE_TYPE( FLOAT, float);
HANDLE_TYPE( DOUBLE, double);
HANDLE_TYPE( BOOL, bool);
HANDLE_TYPE( ENUM, enum);
HANDLE_TYPE( STRING, string);
HANDLE_TYPE(MESSAGE, message);
#undef HANDLE_TYPE
}
GOOGLE_LOG(FATAL) << "Can't get here.";
return 0;
}
void ExtensionSet::Extension::Free() {
if (is_repeated) {
switch (cpp_type(type)) {
#define HANDLE_TYPE(UPPERCASE, LOWERCASE) \
case WireFormatLite::CPPTYPE_##UPPERCASE: \
delete repeated_##LOWERCASE##_value; \
break
HANDLE_TYPE( INT32, int32);
HANDLE_TYPE( INT64, int64);
HANDLE_TYPE( UINT32, uint32);
HANDLE_TYPE( UINT64, uint64);
HANDLE_TYPE( FLOAT, float);
HANDLE_TYPE( DOUBLE, double);
HANDLE_TYPE( BOOL, bool);
HANDLE_TYPE( ENUM, enum);
HANDLE_TYPE( STRING, string);
HANDLE_TYPE(MESSAGE, message);
#undef HANDLE_TYPE
}
} else {
switch (cpp_type(type)) {
case WireFormatLite::CPPTYPE_STRING:
delete string_value;
break;
case WireFormatLite::CPPTYPE_MESSAGE:
delete message_value;
break;
default:
break;
}
}
}
// Defined in extension_set_heavy.cc.
// int ExtensionSet::Extension::SpaceUsedExcludingSelf() const
} // namespace internal
} // namespace protobuf
} // namespace google