// 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 #include #include #include #include #include #include #include #include #include #include #include namespace google { namespace protobuf { namespace internal { #if !defined(_MSC_VER) || (_MSC_VER >= 1900 && _MSC_VER < 1912) // Old version of MSVC doesn't like definitions of inline constants, GCC // requires them. const int WireFormatLite::kMessageSetItemStartTag; const int WireFormatLite::kMessageSetItemEndTag; const int WireFormatLite::kMessageSetTypeIdTag; const int WireFormatLite::kMessageSetMessageTag; #endif // IBM xlC requires prefixing constants with WireFormatLite:: const size_t WireFormatLite::kMessageSetItemTagsSize = io::CodedOutputStream::StaticVarintSize32< WireFormatLite::kMessageSetItemStartTag>::value + io::CodedOutputStream::StaticVarintSize32< WireFormatLite::kMessageSetItemEndTag>::value + io::CodedOutputStream::StaticVarintSize32< WireFormatLite::kMessageSetTypeIdTag>::value + io::CodedOutputStream::StaticVarintSize32< WireFormatLite::kMessageSetMessageTag>::value; const WireFormatLite::CppType WireFormatLite::kFieldTypeToCppTypeMap[MAX_FIELD_TYPE + 1] = { static_cast(0), // 0 is reserved for errors CPPTYPE_DOUBLE, // TYPE_DOUBLE CPPTYPE_FLOAT, // TYPE_FLOAT CPPTYPE_INT64, // TYPE_INT64 CPPTYPE_UINT64, // TYPE_UINT64 CPPTYPE_INT32, // TYPE_INT32 CPPTYPE_UINT64, // TYPE_FIXED64 CPPTYPE_UINT32, // TYPE_FIXED32 CPPTYPE_BOOL, // TYPE_BOOL CPPTYPE_STRING, // TYPE_STRING CPPTYPE_MESSAGE, // TYPE_GROUP CPPTYPE_MESSAGE, // TYPE_MESSAGE CPPTYPE_STRING, // TYPE_BYTES CPPTYPE_UINT32, // TYPE_UINT32 CPPTYPE_ENUM, // TYPE_ENUM CPPTYPE_INT32, // TYPE_SFIXED32 CPPTYPE_INT64, // TYPE_SFIXED64 CPPTYPE_INT32, // TYPE_SINT32 CPPTYPE_INT64, // TYPE_SINT64 }; const WireFormatLite::WireType WireFormatLite::kWireTypeForFieldType[MAX_FIELD_TYPE + 1] = { static_cast(-1), // invalid WireFormatLite::WIRETYPE_FIXED64, // TYPE_DOUBLE WireFormatLite::WIRETYPE_FIXED32, // TYPE_FLOAT WireFormatLite::WIRETYPE_VARINT, // TYPE_INT64 WireFormatLite::WIRETYPE_VARINT, // TYPE_UINT64 WireFormatLite::WIRETYPE_VARINT, // TYPE_INT32 WireFormatLite::WIRETYPE_FIXED64, // TYPE_FIXED64 WireFormatLite::WIRETYPE_FIXED32, // TYPE_FIXED32 WireFormatLite::WIRETYPE_VARINT, // TYPE_BOOL WireFormatLite::WIRETYPE_LENGTH_DELIMITED, // TYPE_STRING WireFormatLite::WIRETYPE_START_GROUP, // TYPE_GROUP WireFormatLite::WIRETYPE_LENGTH_DELIMITED, // TYPE_MESSAGE WireFormatLite::WIRETYPE_LENGTH_DELIMITED, // TYPE_BYTES WireFormatLite::WIRETYPE_VARINT, // TYPE_UINT32 WireFormatLite::WIRETYPE_VARINT, // TYPE_ENUM WireFormatLite::WIRETYPE_FIXED32, // TYPE_SFIXED32 WireFormatLite::WIRETYPE_FIXED64, // TYPE_SFIXED64 WireFormatLite::WIRETYPE_VARINT, // TYPE_SINT32 WireFormatLite::WIRETYPE_VARINT, // TYPE_SINT64 }; bool WireFormatLite::SkipField(io::CodedInputStream* input, uint32_t tag) { // Field number 0 is illegal. if (WireFormatLite::GetTagFieldNumber(tag) == 0) return false; switch (WireFormatLite::GetTagWireType(tag)) { case WireFormatLite::WIRETYPE_VARINT: { uint64_t value; if (!input->ReadVarint64(&value)) return false; return true; } case WireFormatLite::WIRETYPE_FIXED64: { uint64_t value; if (!input->ReadLittleEndian64(&value)) return false; return true; } case WireFormatLite::WIRETYPE_LENGTH_DELIMITED: { uint32_t length; if (!input->ReadVarint32(&length)) return false; if (!input->Skip(length)) return false; return true; } case WireFormatLite::WIRETYPE_START_GROUP: { if (!input->IncrementRecursionDepth()) return false; if (!SkipMessage(input)) return false; input->DecrementRecursionDepth(); // Check that the ending tag matched the starting tag. if (!input->LastTagWas( WireFormatLite::MakeTag(WireFormatLite::GetTagFieldNumber(tag), WireFormatLite::WIRETYPE_END_GROUP))) { return false; } return true; } case WireFormatLite::WIRETYPE_END_GROUP: { return false; } case WireFormatLite::WIRETYPE_FIXED32: { uint32_t value; if (!input->ReadLittleEndian32(&value)) return false; return true; } default: { return false; } } } bool WireFormatLite::SkipField(io::CodedInputStream* input, uint32_t tag, io::CodedOutputStream* output) { // Field number 0 is illegal. if (WireFormatLite::GetTagFieldNumber(tag) == 0) return false; switch (WireFormatLite::GetTagWireType(tag)) { case WireFormatLite::WIRETYPE_VARINT: { uint64_t value; if (!input->ReadVarint64(&value)) return false; output->WriteVarint32(tag); output->WriteVarint64(value); return true; } case WireFormatLite::WIRETYPE_FIXED64: { uint64_t value; if (!input->ReadLittleEndian64(&value)) return false; output->WriteVarint32(tag); output->WriteLittleEndian64(value); return true; } case WireFormatLite::WIRETYPE_LENGTH_DELIMITED: { uint32_t length; if (!input->ReadVarint32(&length)) return false; output->WriteVarint32(tag); output->WriteVarint32(length); // TODO(mkilavuz): Provide API to prevent extra string copying. std::string temp; if (!input->ReadString(&temp, length)) return false; output->WriteString(temp); return true; } case WireFormatLite::WIRETYPE_START_GROUP: { output->WriteVarint32(tag); if (!input->IncrementRecursionDepth()) return false; if (!SkipMessage(input, output)) return false; input->DecrementRecursionDepth(); // Check that the ending tag matched the starting tag. if (!input->LastTagWas( WireFormatLite::MakeTag(WireFormatLite::GetTagFieldNumber(tag), WireFormatLite::WIRETYPE_END_GROUP))) { return false; } return true; } case WireFormatLite::WIRETYPE_END_GROUP: { return false; } case WireFormatLite::WIRETYPE_FIXED32: { uint32_t value; if (!input->ReadLittleEndian32(&value)) return false; output->WriteVarint32(tag); output->WriteLittleEndian32(value); return true; } default: { return false; } } } bool WireFormatLite::SkipMessage(io::CodedInputStream* input) { while (true) { uint32_t tag = input->ReadTag(); if (tag == 0) { // End of input. This is a valid place to end, so return true. return true; } WireFormatLite::WireType wire_type = WireFormatLite::GetTagWireType(tag); if (wire_type == WireFormatLite::WIRETYPE_END_GROUP) { // Must be the end of the message. return true; } if (!SkipField(input, tag)) return false; } } bool WireFormatLite::SkipMessage(io::CodedInputStream* input, io::CodedOutputStream* output) { while (true) { uint32_t tag = input->ReadTag(); if (tag == 0) { // End of input. This is a valid place to end, so return true. return true; } WireFormatLite::WireType wire_type = WireFormatLite::GetTagWireType(tag); if (wire_type == WireFormatLite::WIRETYPE_END_GROUP) { output->WriteVarint32(tag); // Must be the end of the message. return true; } if (!SkipField(input, tag, output)) return false; } } bool FieldSkipper::SkipField(io::CodedInputStream* input, uint32_t tag) { return WireFormatLite::SkipField(input, tag); } bool FieldSkipper::SkipMessage(io::CodedInputStream* input) { return WireFormatLite::SkipMessage(input); } void FieldSkipper::SkipUnknownEnum(int /* field_number */, int /* value */) { // Nothing. } bool CodedOutputStreamFieldSkipper::SkipField(io::CodedInputStream* input, uint32_t tag) { return WireFormatLite::SkipField(input, tag, unknown_fields_); } bool CodedOutputStreamFieldSkipper::SkipMessage(io::CodedInputStream* input) { return WireFormatLite::SkipMessage(input, unknown_fields_); } void CodedOutputStreamFieldSkipper::SkipUnknownEnum(int field_number, int value) { unknown_fields_->WriteVarint32(field_number); unknown_fields_->WriteVarint64(value); } bool WireFormatLite::ReadPackedEnumPreserveUnknowns( io::CodedInputStream* input, int field_number, bool (*is_valid)(int), io::CodedOutputStream* unknown_fields_stream, RepeatedField* values) { uint32_t length; if (!input->ReadVarint32(&length)) return false; io::CodedInputStream::Limit limit = input->PushLimit(length); while (input->BytesUntilLimit() > 0) { int value; if (!ReadPrimitive(input, &value)) { return false; } if (is_valid == nullptr || is_valid(value)) { values->Add(value); } else { uint32_t tag = WireFormatLite::MakeTag(field_number, WireFormatLite::WIRETYPE_VARINT); unknown_fields_stream->WriteVarint32(tag); unknown_fields_stream->WriteVarint32(value); } } input->PopLimit(limit); return true; } #if !defined(PROTOBUF_LITTLE_ENDIAN) namespace { void EncodeFixedSizeValue(float v, uint8_t* dest) { WireFormatLite::WriteFloatNoTagToArray(v, dest); } void EncodeFixedSizeValue(double v, uint8_t* dest) { WireFormatLite::WriteDoubleNoTagToArray(v, dest); } void EncodeFixedSizeValue(uint32_t v, uint8_t* dest) { WireFormatLite::WriteFixed32NoTagToArray(v, dest); } void EncodeFixedSizeValue(uint64_t v, uint8_t* dest) { WireFormatLite::WriteFixed64NoTagToArray(v, dest); } void EncodeFixedSizeValue(int32_t v, uint8_t* dest) { WireFormatLite::WriteSFixed32NoTagToArray(v, dest); } void EncodeFixedSizeValue(int64_t v, uint8_t* dest) { WireFormatLite::WriteSFixed64NoTagToArray(v, dest); } void EncodeFixedSizeValue(bool v, uint8_t* dest) { WireFormatLite::WriteBoolNoTagToArray(v, dest); } } // anonymous namespace #endif // !defined(PROTOBUF_LITTLE_ENDIAN) template static void WriteArray(const CType* a, int n, io::CodedOutputStream* output) { #if defined(PROTOBUF_LITTLE_ENDIAN) output->WriteRaw(reinterpret_cast(a), n * sizeof(a[0])); #else const int kAtATime = 128; uint8_t buf[sizeof(CType) * kAtATime]; for (int i = 0; i < n; i += kAtATime) { int to_do = std::min(kAtATime, n - i); uint8_t* ptr = buf; for (int j = 0; j < to_do; j++) { EncodeFixedSizeValue(a[i + j], ptr); ptr += sizeof(a[0]); } output->WriteRaw(buf, to_do * sizeof(a[0])); } #endif } void WireFormatLite::WriteFloatArray(const float* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteDoubleArray(const double* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteFixed32Array(const uint32_t* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteFixed64Array(const uint64_t* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteSFixed32Array(const int32_t* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteSFixed64Array(const int64_t* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteBoolArray(const bool* a, int n, io::CodedOutputStream* output) { WriteArray(a, n, output); } void WireFormatLite::WriteInt32(int field_number, int32_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteInt32NoTag(value, output); } void WireFormatLite::WriteInt64(int field_number, int64_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteInt64NoTag(value, output); } void WireFormatLite::WriteUInt32(int field_number, uint32_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteUInt32NoTag(value, output); } void WireFormatLite::WriteUInt64(int field_number, uint64_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteUInt64NoTag(value, output); } void WireFormatLite::WriteSInt32(int field_number, int32_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteSInt32NoTag(value, output); } void WireFormatLite::WriteSInt64(int field_number, int64_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteSInt64NoTag(value, output); } void WireFormatLite::WriteFixed32(int field_number, uint32_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED32, output); WriteFixed32NoTag(value, output); } void WireFormatLite::WriteFixed64(int field_number, uint64_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED64, output); WriteFixed64NoTag(value, output); } void WireFormatLite::WriteSFixed32(int field_number, int32_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED32, output); WriteSFixed32NoTag(value, output); } void WireFormatLite::WriteSFixed64(int field_number, int64_t value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED64, output); WriteSFixed64NoTag(value, output); } void WireFormatLite::WriteFloat(int field_number, float value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED32, output); WriteFloatNoTag(value, output); } void WireFormatLite::WriteDouble(int field_number, double value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_FIXED64, output); WriteDoubleNoTag(value, output); } void WireFormatLite::WriteBool(int field_number, bool value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteBoolNoTag(value, output); } void WireFormatLite::WriteEnum(int field_number, int value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_VARINT, output); WriteEnumNoTag(value, output); } constexpr size_t kInt32MaxSize = std::numeric_limits::max(); void WireFormatLite::WriteString(int field_number, const std::string& value, io::CodedOutputStream* output) { // String is for UTF-8 text only WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); GOOGLE_CHECK_LE(value.size(), kInt32MaxSize); output->WriteVarint32(value.size()); output->WriteString(value); } void WireFormatLite::WriteStringMaybeAliased(int field_number, const std::string& value, io::CodedOutputStream* output) { // String is for UTF-8 text only WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); GOOGLE_CHECK_LE(value.size(), kInt32MaxSize); output->WriteVarint32(value.size()); output->WriteRawMaybeAliased(value.data(), value.size()); } void WireFormatLite::WriteBytes(int field_number, const std::string& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); GOOGLE_CHECK_LE(value.size(), kInt32MaxSize); output->WriteVarint32(value.size()); output->WriteString(value); } void WireFormatLite::WriteBytesMaybeAliased(int field_number, const std::string& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); GOOGLE_CHECK_LE(value.size(), kInt32MaxSize); output->WriteVarint32(value.size()); output->WriteRawMaybeAliased(value.data(), value.size()); } void WireFormatLite::WriteGroup(int field_number, const MessageLite& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_START_GROUP, output); value.SerializeWithCachedSizes(output); WriteTag(field_number, WIRETYPE_END_GROUP, output); } void WireFormatLite::WriteMessage(int field_number, const MessageLite& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); const int size = value.GetCachedSize(); output->WriteVarint32(size); value.SerializeWithCachedSizes(output); } void WireFormatLite::WriteSubMessageMaybeToArray( int /*size*/, const MessageLite& value, io::CodedOutputStream* output) { output->SetCur(value._InternalSerialize(output->Cur(), output->EpsCopy())); } void WireFormatLite::WriteGroupMaybeToArray(int field_number, const MessageLite& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_START_GROUP, output); const int size = value.GetCachedSize(); WriteSubMessageMaybeToArray(size, value, output); WriteTag(field_number, WIRETYPE_END_GROUP, output); } void WireFormatLite::WriteMessageMaybeToArray(int field_number, const MessageLite& value, io::CodedOutputStream* output) { WriteTag(field_number, WIRETYPE_LENGTH_DELIMITED, output); const int size = value.GetCachedSize(); output->WriteVarint32(size); WriteSubMessageMaybeToArray(size, value, output); } PROTOBUF_NDEBUG_INLINE static bool ReadBytesToString( io::CodedInputStream* input, std::string* value); inline static bool ReadBytesToString(io::CodedInputStream* input, std::string* value) { uint32_t length; return input->ReadVarint32(&length) && input->ReadString(value, length); } bool WireFormatLite::ReadBytes(io::CodedInputStream* input, std::string* value) { return ReadBytesToString(input, value); } bool WireFormatLite::ReadBytes(io::CodedInputStream* input, std::string** p) { if (*p == &GetEmptyStringAlreadyInited()) { *p = new std::string(); } return ReadBytesToString(input, *p); } void PrintUTF8ErrorLog(const char* field_name, const char* operation_str, bool emit_stacktrace) { std::string stacktrace; (void)emit_stacktrace; // Parameter is used by Google-internal code. std::string quoted_field_name = ""; if (field_name != nullptr) { quoted_field_name = StringPrintf(" '%s'", field_name); } GOOGLE_LOG(ERROR) << "String field" << quoted_field_name << " contains invalid " << "UTF-8 data when " << operation_str << " a protocol " << "buffer. Use the 'bytes' type if you intend to send raw " << "bytes. " << stacktrace; } bool WireFormatLite::VerifyUtf8String(const char* data, int size, Operation op, const char* field_name) { if (!IsStructurallyValidUTF8(data, size)) { const char* operation_str = nullptr; switch (op) { case PARSE: operation_str = "parsing"; break; case SERIALIZE: operation_str = "serializing"; break; // no default case: have the compiler warn if a case is not covered. } PrintUTF8ErrorLog(field_name, operation_str, false); return false; } return true; } // this code is deliberately written such that clang makes it into really // efficient SSE code. template static size_t VarintSize(const T* data, const int n) { static_assert(sizeof(T) == 4, "This routine only works for 32 bit integers"); // is_unsigned => !ZigZag static_assert( (std::is_unsigned::value ^ ZigZag) || std::is_signed::value, "Cannot ZigZag encode unsigned types"); // is_unsigned => !SignExtended static_assert( (std::is_unsigned::value ^ SignExtended) || std::is_signed::value, "Cannot SignExtended unsigned types"); static_assert(!(SignExtended && ZigZag), "Cannot SignExtended and ZigZag on the same type"); uint32_t sum = n; uint32_t msb_sum = 0; for (int i = 0; i < n; i++) { uint32_t x = data[i]; if (ZigZag) { x = WireFormatLite::ZigZagEncode32(x); } else if (SignExtended) { msb_sum += x >> 31; } // clang is so smart that it produces optimal SSE sequence unrolling // the loop 8 ints at a time. With a sequence of 4 // cmpres = cmpgt x, sizeclass ( -1 or 0) // sum = sum - cmpres if (x > 0x7F) sum++; if (x > 0x3FFF) sum++; if (x > 0x1FFFFF) sum++; if (x > 0xFFFFFFF) sum++; } if (SignExtended) sum += msb_sum * 5; return sum; } template static size_t VarintSize64(const T* data, const int n) { static_assert(sizeof(T) == 8, "This routine only works for 64 bit integers"); // is_unsigned => !ZigZag static_assert(!ZigZag || !std::is_unsigned::value, "Cannot ZigZag encode unsigned types"); uint64_t sum = n; for (int i = 0; i < n; i++) { uint64_t x = data[i]; if (ZigZag) { x = WireFormatLite::ZigZagEncode64(x); } // First step is a binary search, we can't branch in sse so we use the // result of the compare to adjust sum and appropriately. This code is // written to make clang recognize the vectorization. uint64_t tmp = x >= (static_cast(1) << 35) ? -1 : 0; sum += 5 & tmp; x >>= 35 & tmp; if (x > 0x7F) sum++; if (x > 0x3FFF) sum++; if (x > 0x1FFFFF) sum++; if (x > 0xFFFFFFF) sum++; } return sum; } // GCC does not recognize the vectorization opportunity // and other platforms are untested, in those cases using the optimized // varint size routine for each element is faster. // Hence we enable it only for clang #if defined(__SSE__) && defined(__clang__) size_t WireFormatLite::Int32Size(const RepeatedField& value) { return VarintSize(value.data(), value.size()); } size_t WireFormatLite::UInt32Size(const RepeatedField& value) { return VarintSize(value.data(), value.size()); } size_t WireFormatLite::SInt32Size(const RepeatedField& value) { return VarintSize(value.data(), value.size()); } size_t WireFormatLite::EnumSize(const RepeatedField& value) { // On ILP64, sizeof(int) == 8, which would require a different template. return VarintSize(value.data(), value.size()); } #else // !(defined(__SSE4_1__) && defined(__clang__)) size_t WireFormatLite::Int32Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += Int32Size(value.Get(i)); } return out; } size_t WireFormatLite::UInt32Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += UInt32Size(value.Get(i)); } return out; } size_t WireFormatLite::SInt32Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += SInt32Size(value.Get(i)); } return out; } size_t WireFormatLite::EnumSize(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += EnumSize(value.Get(i)); } return out; } #endif // Micro benchmarks show that the SSE improved loop only starts beating // the normal loop on Haswell platforms and then only for >32 ints. We // disable this for now. Some specialized users might find it worthwhile to // enable this. #define USE_SSE_FOR_64_BIT_INTEGER_ARRAYS 0 #if USE_SSE_FOR_64_BIT_INTEGER_ARRAYS size_t WireFormatLite::Int64Size(const RepeatedField& value) { return VarintSize64(value.data(), value.size()); } size_t WireFormatLite::UInt64Size(const RepeatedField& value) { return VarintSize64(value.data(), value.size()); } size_t WireFormatLite::SInt64Size(const RepeatedField& value) { return VarintSize64(value.data(), value.size()); } #else size_t WireFormatLite::Int64Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += Int64Size(value.Get(i)); } return out; } size_t WireFormatLite::UInt64Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += UInt64Size(value.Get(i)); } return out; } size_t WireFormatLite::SInt64Size(const RepeatedField& value) { size_t out = 0; const int n = value.size(); for (int i = 0; i < n; i++) { out += SInt64Size(value.Get(i)); } return out; } #endif } // namespace internal } // namespace protobuf } // namespace google #include