/* Copyright (c) 2016 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/framework/parallel_executor.h" #include #include #include #include #include "paddle/fluid/framework/ir/graph_helper.h" #include "paddle/fluid/framework/ir/graph.h" #include "paddle/fluid/framework/details/all_reduce_deps_pass.h" #include "paddle/fluid/framework/details/fast_threaded_ssa_graph_executor.h" #include "paddle/fluid/framework/details/multi_devices_helper.h" #include "paddle/fluid/framework/details/parallel_ssa_graph_executor.h" #include "paddle/fluid/framework/details/reference_count_pass_helper.h" #include "paddle/fluid/framework/details/scope_buffered_ssa_graph_executor.h" #include "paddle/fluid/framework/details/threaded_ssa_graph_executor.h" #include "paddle/fluid/platform/profiler.h" #ifdef WITH_GPERFTOOLS #include "gperftools/profiler.h" #endif DEFINE_string(pe_profile_fname, "", "Profiler filename for PE, which generated by gperftools." "Only valid when compiled `WITH_PRIFILER=ON`. Empty if disable."); DEFINE_bool(enable_parallel_graph, false, "Force disable parallel graph execution mode if set false."); namespace paddle { namespace framework { static std::once_flag gProfileOnce; #ifdef WITH_GPERFTOOLS static bool gProfileStarted = false; #endif class ParallelExecutorPrivate { public: explicit ParallelExecutorPrivate(const std::vector &places) : places_(places) { if (!FLAGS_pe_profile_fname.empty()) { std::call_once(gProfileOnce, [] { #ifdef WITH_GPERFTOOLS ProfilerStart(FLAGS_pe_profile_fname.c_str()); gProfileStarted = true; #else LOG(WARNING) << "Paddle is not compiled with gperftools. " "FLAGS_pe_profile_fname will be ignored"; #endif }); } } ~ParallelExecutorPrivate() { if (own_local_scope_) { for (size_t i = 1; i < local_scopes_.size(); ++i) { // Skip the first scope, since it is the global scope. Scope *local_scope = local_scopes_[i]; if (global_scope_->HasKid(local_scope)) { global_scope_->DeleteScope(local_scope); } } } } std::unique_ptr PrepareGCAndRefCnts( std::unique_ptr graph, size_t max_memory_size); inline bool HasGarbageCollectors() const { return !gcs_.empty(); } void ResetRuntimeReferenceCount(const std::vector &fetch_tensors, const std::string &fetched_var_name) { for (size_t i = 0; i < runtime_ref_cnts_.size(); ++i) { for (auto &pair : global_ref_cnts_[i]) { runtime_ref_cnts_[i][pair.first] = pair.second; } for (auto &fetch_name : fetch_tensors) { runtime_ref_cnts_[i].erase(fetch_name); } runtime_ref_cnts_[i].erase(fetched_var_name); } } BuildStrategy build_strategy_; std::vector places_; std::vector local_scopes_; Scope *global_scope_; // not owned std::unique_ptr executor_; #if defined(PADDLE_WITH_CUDA) && !defined(_WIN32) std::unique_ptr nccl_ctxs_; #endif bool own_local_scope_; bool use_cuda_; bool use_all_reduce_; size_t nranks_; // global_ref_cnts_ is only initialized when ParallelExecutor constructs, and // then keeps unchanged // Before each iteration, runtime_ref_cnts_ is reset to global_ref_cnts_ std::vector global_ref_cnts_; std::vector runtime_ref_cnts_; details::GarbageCollectorMap gcs_; }; std::unique_ptr ParallelExecutorPrivate::PrepareGCAndRefCnts( std::unique_ptr graph, size_t max_memory_size) { for (size_t i = 0; i < places_.size(); ++i) { auto &place = places_[i]; if (gcs_.count(place) > 0) { continue; } std::unique_ptr gc; #ifdef PADDLE_WITH_CUDA if (platform::is_gpu_place(place)) { if (IsFastEagerDeletionModeEnabled()) { gc.reset(new UnsafeFastGPUGarbageCollector( boost::get(place), max_memory_size)); } else { gc.reset(new StreamGarbageCollector( boost::get(place), max_memory_size)); } VLOG(10) << "Created " << i << "-th GarbageCollector at " << place; } else { #endif if (platform::is_cpu_place(place)) { gc.reset(new CPUGarbageCollector(boost::get(place), max_memory_size)); VLOG(10) << "Created GarbageCollector at " << place; } else { PADDLE_THROW("Unsupported place for garbage collection"); } #ifdef PADDLE_WITH_CUDA } #endif gcs_.emplace(place, std::move(gc)); } if (!gcs_.empty()) { std::vector last_live_ops_of_vars; auto ref_cnt_pass = ir::PassRegistry::Instance().Get("reference_count_pass"); ref_cnt_pass->SetNotOwned(details::kGlobalReferenceCount, &global_ref_cnts_); ref_cnt_pass->SetNotOwned(details::kLastLiveOpsOfVars, &last_live_ops_of_vars); graph = ref_cnt_pass->Apply(std::move(graph)); VLOG(10) << "ReferenceCountPass Applied"; auto eager_deletion_pass = ir::PassRegistry::Instance().Get("eager_deletion_pass"); eager_deletion_pass->SetNotOwned(details::kRuntimeReferenceCount, &runtime_ref_cnts_); eager_deletion_pass->SetNotOwned(details::kGarbageCollector, &gcs_); eager_deletion_pass->SetNotOwned(details::kLastLiveOpsOfVars, &last_live_ops_of_vars); eager_deletion_pass->SetNotOwned(details::kAllPlaces, &places_); graph = eager_deletion_pass->Apply(std::move(graph)); VLOG(10) << "EagerDeletionPass Applied"; } return graph; } std::vector &ParallelExecutor::GetLocalScopes() { return member_->local_scopes_; } ParallelExecutor::ParallelExecutor( const std::vector &places, const std::unordered_set &bcast_vars, const ProgramDesc &main_program, const std::string &loss_var_name, Scope *scope, const std::vector &local_scopes, const ExecutionStrategy &exec_strategy, const BuildStrategy &build_strategy) : member_(new ParallelExecutorPrivate(places)) { member_->global_scope_ = scope; member_->use_cuda_ = exec_strategy.use_cuda_; member_->build_strategy_ = build_strategy; member_->use_all_reduce_ = build_strategy.reduce_ == BuildStrategy::ReduceStrategy::kAllReduce; member_->nranks_ = build_strategy.num_trainers_ * places.size(); if (!member_->use_all_reduce_) { PADDLE_ENFORCE(places.size() > 1, "If you set build_strategy.reduce with 'Reduce'," "the number of places must be greater than 1."); } // Step 1. Bcast the bcast_vars to devs. // Create local scopes if (local_scopes.empty()) { member_->own_local_scope_ = true; member_->local_scopes_.emplace_back(member_->global_scope_); for (size_t i = 1; i < member_->places_.size(); ++i) { member_->local_scopes_.emplace_back(&scope->NewScope()); } } else { member_->own_local_scope_ = false; PADDLE_ENFORCE_EQ(member_->places_.size(), local_scopes.size()); for (size_t i = 0; i < member_->places_.size(); ++i) { member_->local_scopes_.emplace_back(&local_scopes[i]->NewScope()); } } // FIXME(Yancey1989): parallel graph mode get better performance // in GPU allreduce distributed training. Need an elegant way to // choice the execution strategy. build_strategy.enable_parallel_graph_ = EnableParallelGraphExecution(main_program, exec_strategy, build_strategy); if (build_strategy.enable_parallel_graph_) VLOG(0) << "The Executor would execute the graph by ParallelGraph " "Execution which can get better performance," << "you can force it off by env FLAGS_enable_parallel_graph=0"; if (member_->use_cuda_) { // Bcast Parameters to all GPUs #if defined(PADDLE_WITH_CUDA) && !defined(_WIN32) ncclUniqueId *nccl_id = nullptr; // gen_nccl_id operator can broadcast the ncclUniqueId for nccl2 collective // distributed training auto *nccl_id_var = scope->FindVar(NCCL_ID_VARNAME); if (nccl_id_var != nullptr) { nccl_id = nccl_id_var->GetMutable(); } if (build_strategy.enable_parallel_graph_ && member_->nranks_ > 1UL) { if (nccl_id == nullptr) { local_nccl_id_.reset(new ncclUniqueId()); platform::dynload::ncclGetUniqueId(local_nccl_id_.get()); nccl_id = local_nccl_id_.get(); } } member_->nccl_ctxs_.reset(new platform::NCCLContextMap( member_->places_, nccl_id, build_strategy.num_trainers_, build_strategy.trainer_id_)); #else PADDLE_THROW("Not compiled with CUDA"); #endif } if (member_->local_scopes_.size() != 1 && local_scopes.empty()) { BCastParamsToDevices(bcast_vars); } // Startup Program has been run. All local scopes has correct parameters. // Step 2. Convert main_program to SSA form and dependency graph. Also, insert // ncclOp std::unique_ptr graph; #if defined(PADDLE_WITH_CUDA) && !defined(_WIN32) graph = build_strategy.Apply(main_program, member_->places_, loss_var_name, member_->local_scopes_, member_->nranks_, member_->use_cuda_, member_->nccl_ctxs_.get()); #else graph = build_strategy.Apply(main_program, member_->places_, loss_var_name, member_->local_scopes_, member_->nranks_, member_->use_cuda_); #endif auto max_memory_size = GetEagerDeletionThreshold(); VLOG(10) << "Eager Deletion Threshold " << static_cast(max_memory_size) / (1 << 30); if (max_memory_size >= 0) { graph = member_->PrepareGCAndRefCnts(std::move(graph), static_cast(max_memory_size)); } // Step 3. Create vars in each scope. Passes may also create new vars. // skip control vars and empty vars std::vector var_infos; for (auto &node : graph->Nodes()) { if (node->IsVar() && !node->IsCtrlVar() && node->Var()) { var_infos.emplace_back(); var_infos.back().name_ = node->Var()->Name(); var_infos.back().type_ = node->Var()->GetType(); var_infos.back().persistable_ = node->Var()->Persistable(); } } // If the loss_var_name is given, the number of graph should be only one. if (loss_var_name.size()) { size_t graph_num = ir::GraphNum(*graph); if (graph_num > 1) { LOG(WARNING) << "The number of graph should be only one, " "but the current graph has " << ir::GraphNum(*graph) << " sub_graphs. If you want to see the nodes of the " "sub_graphs, you should use 'FLAGS_print_sub_graph_dir' " "to specify the output dir. NOTES: if you not do training, " "please don't pass loss_var_name."; } } if (build_strategy.enable_parallel_graph_) { #ifdef PADDLE_WITH_CUDA auto parallel_graph = details::SeparateMultiDevicesGraph(member_->places_, std::move(graph)); auto seq_allreduce_pass = ir::PassRegistry::Instance().Get("all_reduce_deps_pass"); seq_allreduce_pass->Erase(details::kAllOpDescs); seq_allreduce_pass->Set>( details::kAllOpDescs, new std::vector(main_program.Block(0).AllOps())); for (size_t i = 0; i < parallel_graph.size(); ++i) { parallel_graph[i] = seq_allreduce_pass->Apply(std::move(parallel_graph[i])); } member_->executor_.reset(new details::ParallelSSAGraphExecutor( exec_strategy, member_->local_scopes_, member_->places_, std::move(parallel_graph))); #else PADDLE_THROW( "Paddle should be compiled with CUDA for ParallelGraph Execution."); #endif } else { if (exec_strategy.type_ == ExecutionStrategy::kDefault) { member_->executor_.reset(new details::ThreadedSSAGraphExecutor( exec_strategy, member_->local_scopes_, member_->places_, std::move(graph))); } else { member_->executor_.reset(new details::FastThreadedSSAGraphExecutor( exec_strategy, member_->local_scopes_, member_->places_, std::move(graph))); } } member_->executor_.reset(new details::ScopeBufferedSSAGraphExecutor( exec_strategy, member_->local_scopes_, std::move(var_infos), member_->places_, std::move(member_->executor_))); } void ParallelExecutor::BCastParamsToDevices( const std::unordered_set &vars) const { // the initializing bcast, all vars would be bcast from device(0). for (auto &var : vars) { framework::Variable *main_var = member_->local_scopes_[0]->FindVar(var); if (main_var == nullptr || !main_var->IsType()) { continue; } auto &main_tensor = main_var->Get(); if (!main_tensor.IsInitialized()) { VLOG(3) << "one in var not inited, return!"; continue; } auto &dims = main_tensor.dims(); if (paddle::platform::is_gpu_place(main_tensor.place())) { #if defined(PADDLE_WITH_CUDA) && !defined(_WIN32) std::vector buffers; buffers.reserve(member_->places_.size()); size_t numel = main_tensor.numel(); ncclDataType_t data_type = platform::ToNCCLDataType(main_tensor.type()); for (size_t i = 0; i < member_->places_.size(); ++i) { auto place = member_->places_[i]; void *buffer; if (i == 0) { buffer = const_cast(main_tensor.data()); } else { auto local_scope = member_->local_scopes_[i]; auto *t = local_scope->Var(var)->GetMutable(); t->Resize(dims); buffer = t->mutable_data(place, main_tensor.type()); } buffers.push_back(buffer); } PADDLE_ENFORCE_EQ(member_->places_.size(), buffers.size(), "variables' buffer size to bcast NOT equal to places"); { platform::NCCLGroupGuard guard; for (size_t i = 0; i < member_->places_.size(); ++i) { auto &nccl_ctx = member_->nccl_ctxs_->at(member_->places_[i]); platform::dynload::ncclBcast(buffers[i], numel, data_type, 0, nccl_ctx.comm_, nccl_ctx.stream()); } member_->nccl_ctxs_->WaitAll(); } #else PADDLE_THROW("Not compiled with CUDA"); #endif } else { platform::CPUPlace cpu; for (size_t i = 1; i < member_->places_.size(); ++i) { auto local_scope = member_->local_scopes_[i]; auto *t = local_scope->Var(var)->GetMutable(); // FIXME(zcd): LR_DECAY_COUNTER should not be shared. This is a hot fix. if (member_->use_all_reduce_ || member_->use_cuda_ || var == "@LR_DECAY_COUNTER@") { t->Resize(dims); t->mutable_data(cpu, main_tensor.type()); paddle::framework::TensorCopy(main_tensor, cpu, t); } else { t->ShareDataWith(main_tensor); } } } } } void ParallelExecutor::Run(const std::vector &fetch_tensors, const std::string &fetched_var_name) { #ifdef WITH_GPERFTOOLS if (gProfileStarted) { ProfilerFlush(); } #endif platform::RecordBlock b(0); if (member_->HasGarbageCollectors()) { member_->ResetRuntimeReferenceCount(fetch_tensors, fetched_var_name); } auto fetch_data = member_->executor_->Run(fetch_tensors); *member_->global_scope_->Var(fetched_var_name)->GetMutable() = fetch_data; } void ParallelExecutor::FeedTensorsIntoLocalScopes( const std::vector> &tensors) { PADDLE_ENFORCE_EQ(member_->local_scopes_.size(), tensors.size()); for (size_t i = 0; i < tensors.size(); ++i) { auto &map = tensors[i]; auto *scope = member_->local_scopes_[i]; for (auto &pair : map) { auto *trg = scope->Var(pair.first)->GetMutable(); trg->ShareDataWith(pair.second); trg->set_lod(pair.second.lod()); } } } void ParallelExecutor::FeedAndSplitTensorIntoLocalScopes( const std::unordered_map &tensors) { for (auto pair : tensors) { auto lod_tensors = pair.second.SplitLoDTensor(member_->places_); PADDLE_ENFORCE_EQ( member_->places_.size(), lod_tensors.size(), "The number of samples of current batch is less than the count of " "devices, currently, it is not allowed. (%d vs %d)", member_->places_.size(), lod_tensors.size()); for (size_t j = 0; j < member_->places_.size(); ++j) { // TODO(panxy0718): Do I need to delete this var? auto t = member_->local_scopes_[j]->Var(pair.first)->GetMutable(); t->ShareDataWith(lod_tensors[j]); t->set_lod(lod_tensors[j].lod()); } } } bool ParallelExecutor::EnableParallelGraphExecution( const ProgramDesc &main_program, const ExecutionStrategy &exec_strategy, const BuildStrategy &build_strategy) const { if (!FLAGS_enable_parallel_graph) return false; bool enable_parallel_graph = true; // TODO(Yancey1989): support sparse update in ParallelGraph mode. for (auto &var_desc : main_program.Block(0).AllVars()) { if (var_desc->GetType() == proto::VarType::SELECTED_ROWS) { enable_parallel_graph = false; } } // TODO(Yancey1989): support pserver mode for (auto &op_desc : main_program.Block(0).AllOps()) { if (op_desc->Type() == "send" || op_desc->Type() == "recv") { enable_parallel_graph = false; break; } } if (!member_->use_all_reduce_ || !member_->use_cuda_) if (build_strategy.enable_sequential_execution_ || exec_strategy.type_ == ExecutionStrategy::ExecutorType::kExperimental) enable_parallel_graph = false; return enable_parallel_graph; } ParallelExecutor::~ParallelExecutor() { for (auto &p : member_->places_) { platform::DeviceContextPool::Instance().Get(p)->Wait(); } delete member_; } } // namespace framework } // namespace paddle USE_PASS(reference_count_pass); USE_PASS(eager_deletion_pass);