// Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "paddle/fluid/operators/detail/variable_response.h" #include #include "paddle/fluid/operators/detail/send_recv.pb.h" #include "paddle/fluid/operators/detail/sendrecvop_utils.h" namespace paddle { namespace operators { namespace detail { enum WireType { WIRETYPE_VARINT = 0, WIRETYPE_LENGTH_DELIMITED = 2, }; inline int GetTagFieldNumber(uint32_t tag) { return tag >> 3; } inline WireType GetTagWireType(uint32_t tag) { return static_cast(tag & 0x7); } bool ReadVarintSizeAsInt(::google::protobuf::io::CodedInputStream* input, int* result) { uint64_t v; if (input->ReadVarint64(&v) && v <= static_cast(INT_MAX)) { *result = static_cast(v); return true; } else { return false; } } bool ReadRaw(::google::protobuf::io::CodedInputStream* input, const platform::DeviceContext& dev_ctx, platform::Place place, void* dest, int size) { const void* data = NULL; int size_to_write = 0; int length = size; int total_written = 0; if (platform::is_gpu_place(place)) { #ifdef PADDLE_WITH_CUDA auto& gpu_dev_ctx = static_cast(dev_ctx); platform::CPUPlace cpu; char* p = reinterpret_cast(dest); while (total_written < length) { if (!input->GetDirectBufferPointer(&data, &size_to_write)) { return false; } // NOTE: if raw buffer is large and have two neighbor fields of raw // buffers GetDirectBufferPointer can get all of them, use length to // truncate it. if (total_written + size_to_write > length) { size_to_write = length - total_written; } memory::Copy(boost::get(place), reinterpret_cast(p), cpu, data, size_to_write, gpu_dev_ctx.stream()); p += size_to_write; total_written += size_to_write; input->Skip(size_to_write); } gpu_dev_ctx.Wait(); #else PADDLE_THROW("Unexpected branch"); #endif return true; } char* p = reinterpret_cast(dest); while (total_written < length) { if (!input->GetDirectBufferPointer(&data, &size_to_write)) { return false; } // NOTE: if raw buffer is large and have two neighbor fields of raw buffers // GetDirectBufferPointer can get all of them, use length to truncate it. if (total_written + size_to_write > length) { size_to_write = length - total_written; } // TODO(gongwb): can we avoid copy? platform::CPUPlace cpu; memory::Copy(cpu, reinterpret_cast(p), cpu, data, size_to_write); p += size_to_write; total_written += size_to_write; input->Skip(size_to_write); } return true; } bool VariableResponse::CopyLodTensorData( ::google::protobuf::io::CodedInputStream* input, const platform::DeviceContext& ctx, framework::DDim& dims, int length) { auto var = scope_->FindVar(meta_.varname()); auto* tensor = var->GetMutable(); tensor->Resize(dims); framework::LoD lod; for (int i = 0; i < meta_.lod_level(); ++i) { framework::Vector v; for (int j = 0; j < meta_.lod(i).lod_data_size(); ++j) { v.push_back(meta_.lod(i).lod_data(j)); } lod.push_back(v); } tensor->set_lod(lod); void* tensor_data = tensor->mutable_data(ctx.GetPlace(), ToTypeIndex(meta_.data_type())); if (!ReadRaw(input, ctx, tensor->place(), tensor_data, length)) { return false; } return true; } inline framework::DDim GetDims( const ::google::protobuf::RepeatedField<::google::protobuf::int64>& dims) { std::vector vecdims; for (auto& d : dims) { vecdims.push_back(d); } return framework::make_ddim(vecdims); } bool VariableResponse::CopySelectRowsTensorData( ::google::protobuf::io::CodedInputStream* input, const platform::DeviceContext& ctx, framework::DDim& dims, int length) { auto var = scope_->FindVar(meta_.varname()); auto* slr = var->GetMutable(); auto* tensor = slr->mutable_value(); tensor->Resize(dims); void* tensor_data = tensor->mutable_data( ctx.GetPlace(), paddle::operators::detail::ToTypeIndex(meta_.data_type())); if (!ReadRaw(input, ctx, tensor->place(), tensor_data, length)) { return false; } return true; } bool VariableResponse::CopySelectRowsData( ::google::protobuf::io::CodedInputStream* input, const platform::DeviceContext& ctx, int length) { auto var = scope_->FindVar(meta_.varname()); auto* slr = var->GetMutable(); slr->mutable_rows()->resize(length / 8); // int64 int64_t* rows_data = slr->mutable_rows()->data(); // copy rows CPU data, GPU data will be copied lazily. platform::CPUPlace cpu; if (!ReadRaw(input, ctx, cpu, rows_data, length)) { return false; } return true; } bool ParseLodData(::google::protobuf::io::CodedInputStream* input, std::vector* lod) { while (true) { auto p = input->ReadTagWithCutoff(127); int tag = GetTagFieldNumber(p.first); WireType wt = GetTagWireType(p.first); if (!p.second) { return (tag == 0); } switch (tag) { case sendrecv::VariableMessage_LodData::kLodDataFieldNumber: { uint64_t v; if (wt == WIRETYPE_VARINT) { if (!input->ReadVarint64(&v)) { return false; } lod->push_back(v); break; } if (wt == WIRETYPE_LENGTH_DELIMITED) { int length = 0; if (!input->ReadVarintSizeAsInt(&length)) { return tag; } for (int i = 0; i < length; i++) { uint64_t v; if (!input->ReadVarint64(&v)) { return false; } lod->push_back(v); } break; } return false; } default: { return false; } } } return true; } int VariableResponse::Parse(const ::grpc::ByteBuffer& byte_buffer) { GrpcByteBufferSource source; source.Init(byte_buffer); GrpcByteBufferSourceWrapper r(&source); return Parse(&r); } int VariableResponse::Parse(Source* source) { ::google::protobuf::io::ZeroCopyInputStream* input_stream = source->contents(); ::google::protobuf::io::CodedInputStream input(input_stream); input.SetTotalBytesLimit(INT_MAX, INT_MAX); while (true) { auto p = input.ReadTagWithCutoff(127); int tag = GetTagFieldNumber(p.first); WireType wt = GetTagWireType(p.first); if (!p.second) { if (tag != 0) { return -1; } return 0; } switch (tag) { case sendrecv::VariableMessage::kVarnameFieldNumber: { uint32_t length; if ((wt != WIRETYPE_LENGTH_DELIMITED) || !input.ReadVarint32(&length)) { return tag; } std::string temp; if (!input.ReadString(&temp, length)) { return tag; } meta_.set_varname(temp); break; } case sendrecv::VariableMessage::kTypeFieldNumber: { uint64_t v; if ((wt != WIRETYPE_VARINT) || !input.ReadVarint64(&v)) { return tag; } meta_.set_type(static_cast<::sendrecv::VarType>(v)); break; } case sendrecv::VariableMessage::kDataTypeFieldNumber: { uint64_t v = 0; if ((wt != WIRETYPE_VARINT) || !input.ReadVarint64(&v)) { return tag; } meta_.set_data_type(static_cast<::sendrecv::VariableMessage_Type>(v)); break; } case sendrecv::VariableMessage::kDimsFieldNumber: { // not packed if (wt == WIRETYPE_VARINT) { uint64_t v; if (!input.ReadVarint64(&v)) { return tag; } meta_.add_dims(v); break; } // packed if (wt == WIRETYPE_LENGTH_DELIMITED) { int length = 0; if (!input.ReadVarintSizeAsInt(&length)) { return tag; } for (int i = 0; i < length; i++) { uint64_t v; if (!input.ReadVarint64(&v)) { return tag; } meta_.add_dims(v); } break; } return tag; } case sendrecv::VariableMessage::kLodLevelFieldNumber: { uint64_t v = 0; if ((wt != WIRETYPE_VARINT) || !input.ReadVarint64(&v)) { return tag; } meta_.set_lod_level(static_cast(v)); break; } case sendrecv::VariableMessage::kLodFieldNumber: { int length = 0; if (wt != WIRETYPE_LENGTH_DELIMITED || !ReadVarintSizeAsInt(&input, &length)) { return tag; } std::pair<::google::protobuf::io::CodedInputStream::Limit, int> p = input.IncrementRecursionDepthAndPushLimit(length); std::vector lod_data; if (p.second < 0 || !ParseLodData(&input, &lod_data)) { return tag; } if (!input.DecrementRecursionDepthAndPopLimit(p.first)) { return false; } if (lod_data.size() == 0) { break; } auto lod = meta_.add_lod(); for (uint32_t i = 0; i < lod_data.size(); i++) { lod->add_lod_data(lod_data[i]); } break; } case sendrecv::VariableMessage::kSerializedFieldNumber: { PADDLE_ENFORCE((meta_.type() == sendrecv::SELECTED_ROWS || meta_.type() == sendrecv::LOD_TENSOR) && meta_.varname() != "", "meta info should be got first!"); int length = 0; if (wt != WIRETYPE_LENGTH_DELIMITED || !ReadVarintSizeAsInt(&input, &length)) { return tag; } framework::DDim dims = GetDims(meta_.dims()); if (meta_.type() == sendrecv::LOD_TENSOR) { PADDLE_ENFORCE(meta_.lod_size() >= 0, "lod info should be got first!"); if (!CopyLodTensorData(&input, *dev_ctx_, dims, length)) { return tag; } break; } if (meta_.type() == sendrecv::SELECTED_ROWS) { if (!CopySelectRowsTensorData(&input, *dev_ctx_, dims, length)) { return tag; } break; } return tag; } case sendrecv::VariableMessage::kRowsFieldNumber: { PADDLE_ENFORCE((meta_.type() == sendrecv::SELECTED_ROWS || meta_.type() == sendrecv::LOD_TENSOR) && meta_.varname() != "", "meta info should be got first!"); int length = 0; if (wt != WIRETYPE_LENGTH_DELIMITED || !ReadVarintSizeAsInt(&input, &length)) { return tag; } if (!CopySelectRowsData(&input, *dev_ctx_, length)) { return tag; } break; } default: { // Unknown tag, return unknown error. return -1; } } } return 0; } }; // namespace detail }; // namespace operators }; // namespace paddle