/* 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 #include #include #include #include #include #include #include #include "paddle/fluid/framework/block_desc.h" #include "paddle/fluid/framework/ddim.h" #include "paddle/fluid/framework/feed_fetch_type.h" #include "paddle/fluid/framework/framework.pb.h" #include "paddle/fluid/framework/lod_tensor.h" #include "paddle/fluid/framework/op_desc.h" #include "paddle/fluid/framework/op_registry.h" #include "paddle/fluid/framework/var_type.h" #include "paddle/fluid/operators/ngraph/ngraph_bridge.h" #include "paddle/fluid/operators/ngraph/ngraph_engine.h" namespace paddle { namespace operators { static ngraph::Shape Ddim2Shape(const framework::DDim& dims) { ngraph::Shape sp; for (int i = 0; i < dims.size(); ++i) { int k = dims[i]; k = k == 0 ? 1 : k; sp.emplace_back(k); } return sp; } static framework::DDim Shape2Ddim(const ngraph::Shape& shape) { std::vector dims; for (size_t i = 0; i < shape.size(); ++i) { int64_t k = shape[i]; dims.emplace_back(k); } return framework::make_ddim(dims); } static std::map pd2ng_type_map = { {framework::proto::VarType::FP32, ngraph::element::f32}, {framework::proto::VarType::FP64, ngraph::element::f64}, {framework::proto::VarType::INT32, ngraph::element::i32}, {framework::proto::VarType::INT64, ngraph::element::i64}, {framework::proto::VarType::BOOL, ngraph::element::boolean}}; static std::map ng2pd_type_map = { {ngraph::element::f32, framework::proto::VarType::FP32}, {ngraph::element::f64, framework::proto::VarType::FP64}, {ngraph::element::i32, framework::proto::VarType::INT32}, {ngraph::element::i64, framework::proto::VarType::INT64}, {ngraph::element::boolean, framework::proto::VarType::BOOL}}; std::vector NgraphEngine::feed_vars = {}; std::vector NgraphEngine::fetch_vars = {}; framework::Variable* NgraphEngine::pre_var_ptr = nullptr; const framework::BlockDesc* NgraphEngine::p_bdesc = nullptr; std::unordered_map NgraphEngine::engine_cache = {}; std::unordered_map>> NgraphEngine::t_in_cache_ = {}; std::shared_ptr NgraphEngine::backend_ = ngraph::runtime::Backend::create("CPU"); static std::vector> NgraphOpIntervals( std::vector>* ops) { NgraphEngine::feed_vars.clear(); NgraphEngine::fetch_vars.clear(); std::vector> intervals; int size = ops->size(); int left = 0; while (left < size && ops->at(left)->Type() != framework::kFeedOpType && ops->at(left)->Type() != framework::kFetchOpType) { ++left; } while (left < size && ops->at(left)->Type() == framework::kFeedOpType) { for (auto& var_name_item : ops->at(left)->Outputs()) { for (auto& var_name : var_name_item.second) { NgraphEngine::feed_vars.emplace_back(var_name); } } ++left; } int right = left; while (right < size && ops->at(right)->Type() != framework::kFetchOpType) { ++right; } int index = right; while (index < size && ops->at(index)->Type() == framework::kFetchOpType) { for (auto& var_name_item : ops->at(index)->Inputs()) { for (auto& var_name : var_name_item.second) { NgraphEngine::fetch_vars.emplace_back(var_name); } } ++index; } if (left == size || ops->at(left)->Type() == framework::kFetchOpType) { left = 0; } // (left, right - 1) represents indices between feed and fetch int pivot = left; while (pivot < right) { auto op_type = ops->at(pivot)->Type(); if (NgraphBridge::isRegister(op_type)) { ++pivot; } else { int start = pivot, end = start; while (pivot < right && (!NgraphBridge::isRegister(ops->at(pivot)->Type()))) { ++pivot; ++end; } std::vector interval = {start, end}; intervals.emplace_back(interval); } } // end while return intervals; } static void SubstituteNgraphOp( std::vector>* ops, std::string engine_key, std::string block_str, std::vector interval) { framework::OpDesc ng_op_desc(nullptr); ng_op_desc.SetType("ngraph_engine"); ng_op_desc.SetAttr("interval", interval); ng_op_desc.SetAttr("engine_key", engine_key); ng_op_desc.SetAttr("graph", block_str); ops->erase(ops->begin() + interval[0], ops->begin() + interval[1]); ops->insert(ops->begin() + interval[0], framework::OpRegistry::CreateOp(ng_op_desc)); } std::string SerializedBlock(const std::vector& op_descs) { framework::proto::BlockDesc block_proto; framework::BlockDesc block_desc(nullptr, &block_proto); block_desc.Proto()->set_parent_idx(-1); block_desc.Proto()->set_idx(0); for (auto* op_desc : op_descs) { auto* op = block_desc.AppendOp(); *op->Proto() = *op_desc->Proto(); } return block_desc.Proto()->SerializeAsString(); } std::string GenerateEngineKey(const framework::BlockDesc& bdesc) { framework::proto::BlockDesc block_proto; framework::BlockDesc block_desc(nullptr, &block_proto); block_desc.Proto()->set_parent_idx(-1); block_desc.Proto()->set_idx(0); for (auto& op_desc : bdesc.AllOps()) { auto* op = block_desc.AppendOp(); *op->Proto() = *op_desc->Proto(); } auto engine_key = std::to_string( std::hash()(block_desc.Proto()->SerializeAsString())); return engine_key; } std::string GenerateEngineKey(const std::vector& engine_inputs, const std::vector& engine_outputs, int size) { std::string engine_hash_key = ""; for (auto name : engine_inputs) { engine_hash_key += name; } for (auto name : engine_outputs) { engine_hash_key += name; } engine_hash_key += std::to_string(size); auto engine_key = std::to_string(std::hash()(engine_hash_key)); return engine_key; } void NgraphEngine::FuseNgraphOps( const framework::BlockDesc& block_desc, std::vector>* ops) { NgraphEngine::p_bdesc = &block_desc; auto intervals = NgraphOpIntervals(ops); std::string engine_key = GenerateEngineKey(feed_vars, fetch_vars, ops->size()); for (auto it = intervals.rbegin(); it != intervals.rend(); ++it) { SubstituteNgraphOp(ops, engine_key, "", *it); } } NgraphEngine::NgraphEngine(const framework::Scope& scope, const platform::Place& place, const framework::ExecutionContext& ctx) : scope_(scope), place_(place) { std::string serialized_graph = ctx.Attr("graph"); auto interval = ctx.Attr>("interval"); std::string engine_key = ctx.Attr("engine_key"); var_in_node_map_ = std::make_shared< std::unordered_map>>(); var_node_map_ = std::make_shared< std::unordered_map>>(); GetNgFunction(engine_key, interval); } void NgraphEngine::Prepare(const std::vector& interval) { bool has_fetch = false, is_full = false; for (auto& var : p_bdesc->AllVars()) { if (!(var->GetType() == framework::proto::VarType::SELECTED_ROWS || var->GetType() == framework::proto::VarType::LOD_TENSOR || var->GetType() == framework::proto::VarType::LOD_TENSOR_ARRAY)) { continue; } auto var_name = var->Name(); if (var->Name() == framework::kEmptyVarName) { continue; } if (var_name != framework::kFeedOpType && var_name != framework::kFetchOpType) { auto pd_type = var->GetDataType(); if (pd2ng_type_map.find(pd_type) == pd2ng_type_map.end()) { PADDLE_THROW("Data type of var %s not found in pd2ng_type_map", var_name); } var_type_map_[var_name] = pd2ng_type_map[pd_type]; } if (var->Persistable()) { persistables_.insert(var->Name()); } } std::vector ops_desc; for (auto op_desc : p_bdesc->AllOps()) { ops_desc.emplace_back(op_desc); if (op_desc->Type() == framework::kFetchOpType) { has_fetch = true; } } for (auto op_desc : ops_desc) { if (op_desc->Type().find("_grad") != std::string::npos) { this->is_test_ = false; break; } } if (interval[0] > 0 && ops_desc.at(interval[0] - 1)->Type() == framework::kFeedOpType && interval[1] < static_cast(ops_desc.size()) && ops_desc.at(interval[1])->Type() == framework::kFetchOpType) { is_full = true; } if (is_full) { this->op_state_ = this->is_test_ ? OpState::FULL_TEST : OpState::FULL_TRAIN; } else { this->op_state_ = this->is_test_ ? OpState::PARTIAL_TEST : OpState::PARTIAL_TRAIN; } int idx = interval[0]; while (idx < interval[1]) { this->fused_ops_.emplace_back( framework::OpRegistry::CreateOp(*(ops_desc[idx]))); ++idx; } while (idx < static_cast(ops_desc.size()) && ops_desc.at(idx)->Type() != framework::kFetchOpType) { auto op_desc = ops_desc.at(idx); for (auto& var_name_item : op_desc->Inputs()) { for (auto& var_name : var_name_item.second) { this->post_op_inputs_.insert(var_name); } } ++idx; } if (!has_fetch) { op_state_ = OpState::UNKNOWN; } BuildNgIO(ops_desc, interval); } void NgraphEngine::BuildNgIO(const std::vector& ops_desc, const std::vector& interval) { std::unordered_set inputs; std::unordered_set outputs; for (int i = interval[0]; i < interval[1]; ++i) { auto op = ops_desc[i]; for (auto& var_name_item : op->Inputs()) { for (auto& var_name : var_name_item.second) { inputs.insert(var_name); const bool is_output = outputs.find(var_name) != outputs.end(); if (!is_output && std::find(var_in_.begin(), var_in_.end(), var_name) == var_in_.end() && scope_.FindVar(var_name)) { // fill var_in here to keep lhs and rhs order this->var_in_.emplace_back(var_name); } } } for (auto& var_name_item : op->Outputs()) { PADDLE_ENFORCE_LE(var_name_item.second.size(), 1, "op %s has more than 1 output - Not handling yet", op->Type()); for (auto& var_name : var_name_item.second) { outputs.insert(var_name); } } } // var_out.clear(); for (int i = interval[0]; i < interval[1]; ++i) { auto op = ops_desc[i]; for (auto& var_name_item : op->Outputs()) { PADDLE_ENFORCE_LE(var_name_item.second.size(), 1, "op %s has more than 1 output - Not handling yet", op->Type()); for (auto& var_name : var_name_item.second) { switch (this->op_state_) { case OpState::PARTIAL_TEST: if (post_op_inputs_.find(var_name) != post_op_inputs_.end() || find(fetch_vars.begin(), fetch_vars.end(), var_name) != fetch_vars.end()) { this->var_out_.emplace_back(var_name); } break; case OpState::FULL_TEST: if (find(fetch_vars.begin(), fetch_vars.end(), var_name) != fetch_vars.end()) { this->var_out_.emplace_back(var_name); } break; case OpState::PARTIAL_TRAIN: if (find(fetch_vars.begin(), fetch_vars.end(), var_name) != fetch_vars.end() || post_op_inputs_.find(var_name) != post_op_inputs_.end() || persistables_.find(var_name) != persistables_.end()) { this->var_out_.emplace_back(var_name); } break; case OpState::FULL_TRAIN: if (find(fetch_vars.begin(), fetch_vars.end(), var_name) != fetch_vars.end() || persistables_.find(var_name) != persistables_.end()) { this->var_out_.emplace_back(var_name); } break; default: this->var_out_.emplace_back(var_name); } } } } for (size_t i = 0; i < var_in_.size(); ++i) { auto var_name = var_in_[i]; if (persistables_.find(var_name) == persistables_.end()) { var_in_updates_.emplace_back(i); } } } void NgraphEngine::GetNgInputShape() { for (auto& var_name : var_in_) { auto* var = scope_.FindVar(var_name); if (var && var->IsType()) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto sp = Ddim2Shape(tensor_pd->dims()); auto ng_type = var_type_map_[var_name]; auto prm = std::make_shared(ng_type, sp, true); (*var_node_map_)[var_name] = prm; (*var_in_node_map_)[var_name] = prm; } } } void NgraphEngine::BuildNgNodes() { for (auto& op : fused_ops_) { for (auto& var_name_item : op->Outputs()) { for (auto& var_name : var_name_item.second) { if (var_node_map_->find(var_name) == var_node_map_->end()) { auto* var = scope_.FindVar(var_name); if (var && var->IsType()) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto& ddim = tensor_pd->dims(); auto ng_shape = Ddim2Shape(ddim); auto ng_type = var_type_map_[var_name]; auto prm = std::make_shared(ng_type, ng_shape, true); (*var_node_map_)[var_name] = prm; } } } } } NgraphBridge ngb(var_node_map_); for (auto& op : fused_ops_) { ngb.BuildNgNode(op); } } void NgraphEngine::RunInferShape() { for (auto& op : fused_ops_) { framework::RuntimeContext ctx(op->Inputs(), op->Outputs(), scope_); op->RuntimeInferShape(scope_, place_, ctx); } } void NgraphEngine::BuildNgFunction(const std::vector& interval) { Prepare(interval); RunInferShape(); GetNgInputShape(); BuildNgNodes(); ngraph_function_ = nullptr; ngraph::NodeVector func_outputs; ngraph::ParameterVector func_inputs; for (auto& vo : var_out_) { func_outputs.emplace_back(var_node_map_->at(vo)); } for (auto& vi : var_in_) { std::shared_ptr prm = std::dynamic_pointer_cast( var_in_node_map_->at(vi)); func_inputs.emplace_back(prm); } ngraph_function_ = std::make_shared(func_outputs, func_inputs); } void NgraphEngine::GetNgFunction(std::string engine_key, const std::vector& interval) { bool use_cache = true; if (use_cache) { this->func_cache_key_ = ""; for (int i = 0; i < std::min(static_cast(feed_vars.size()), 10); ++i) { auto* var = scope_.FindVar(feed_vars[i]); if (var && var->IsType()) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto dims = tensor_pd->dims(); for (int j = 0; j < dims.size(); ++j) { func_cache_key_ += std::to_string(dims[j]); } } } func_cache_key_ += std::to_string(interval[0]) + "_" + std::to_string(interval[1]) + engine_key; func_cache_key_ = std::to_string(std::hash()(func_cache_key_)); if (engine_cache.find(func_cache_key_) != engine_cache.end()) { if (engine_cache[func_cache_key_].persistables.size() == 0) { engine_cache.clear(); t_in_cache_.clear(); } else { auto var_name = engine_cache[func_cache_key_].persistables.begin(); framework::Variable* var = scope_.FindVar(*var_name); if (var != pre_var_ptr) { engine_cache.clear(); t_in_cache_.clear(); } pre_var_ptr = var; } } if (engine_cache.find(func_cache_key_) == engine_cache.end()) { BuildNgFunction(interval); engine_cache[func_cache_key_].ngraph_function = this->ngraph_function_; engine_cache[func_cache_key_].persistables = this->persistables_; engine_cache[func_cache_key_].var_in_updates = this->var_in_updates_; engine_cache[func_cache_key_].var_in = this->var_in_; engine_cache[func_cache_key_].var_out = this->var_out_; engine_cache[func_cache_key_].is_test = this->is_test_; } } else { BuildNgFunction(interval); } } void NgraphEngine::Run(const framework::Scope& scope, const platform::Place& place) const { std::shared_ptr ng_func; const std::set* p_persistables; const std::vector* p_var_in_updates; const std::vector* p_var_in; const std::vector* p_var_out; bool is_test; bool use_cache = true; if (use_cache) { PADDLE_ENFORCE(engine_cache.find(func_cache_key_) != engine_cache.end(), "Cannot find cached data to run ngraph function"); ng_func = engine_cache[func_cache_key_].ngraph_function; p_persistables = &(engine_cache[func_cache_key_].persistables); p_var_in_updates = &(engine_cache[func_cache_key_].var_in_updates); p_var_in = &(engine_cache[func_cache_key_].var_in); p_var_out = &(engine_cache[func_cache_key_].var_out); is_test = engine_cache[func_cache_key_].is_test; } else { ng_func = ngraph_function_; p_persistables = &this->persistables_; p_var_in_updates = &this->var_in_updates_; p_var_in = &this->var_in_; p_var_out = &this->var_out_; is_test = this->is_test_; } std::vector>* p_t_in; std::vector> t_in = {}; auto m_parameters = ng_func->get_parameters(); auto m_results = ng_func->get_results(); if (is_test && use_cache && t_in_cache_.find(func_cache_key_) != t_in_cache_.end()) { p_t_in = &(t_in_cache_[func_cache_key_]); for (size_t i = 0; i < p_var_in_updates->size(); ++i) { int index = p_var_in_updates->at(i); auto vi = p_var_in->at(index); auto sp = m_parameters[index]->get_shape(); auto ng_type = m_parameters[index]->get_element_type(); std::shared_ptr ti; auto* var = scope.FindVar(vi); if (var && var->IsType()) { auto* tensor_pd = GetMutableLoDTensorOrSelectedRowsValueFromVar(var); void* pd_arr = tensor_pd->mutable_data(place, ng2pd_type_map[ng_type]); ti = backend_->create_tensor(ng_type, sp, pd_arr); (*p_t_in)[index] = ti; } else { PADDLE_THROW("Cannot find var or tensor with var name %s", vi); } } } else { if (is_test && use_cache) { p_t_in = &(t_in_cache_[func_cache_key_]); } else { p_t_in = &t_in; } for (size_t i = 0; i < p_var_in->size(); ++i) { auto vi = p_var_in->at(i); auto sp = m_parameters[i]->get_shape(); auto ng_type = m_parameters[i]->get_element_type(); std::shared_ptr ti; auto* var = scope.FindVar(vi); if (var && var->IsType()) { auto* tensor_pd = GetMutableLoDTensorOrSelectedRowsValueFromVar(var); void* pd_arr = tensor_pd->mutable_data(place, ng2pd_type_map[ng_type]); PADDLE_ENFORCE(sp == Ddim2Shape(tensor_pd->dims()), "Ensure ngraph tensor layout align with paddle tensor"); ti = backend_->create_tensor(ng_type, sp, pd_arr); } else { PADDLE_THROW("Cannot find var or tensor with var name %s", vi); } bool is_persistable = (p_persistables->find(vi) != p_persistables->end()) ? true : false; if (is_test && is_persistable) { ti->set_stale(false); } (*p_t_in).emplace_back(ti); } } std::vector> t_out = {}; for (size_t i = 0; i < p_var_out->size(); ++i) { auto vo = p_var_out->at(i); auto* var = scope.FindVar(vo); if (var && var->IsType()) { auto sp = m_results[i]->get_shape(); var->GetMutable()->Resize(Shape2Ddim(sp)); auto* tensor_pd = GetMutableLoDTensorOrSelectedRowsValueFromVar(var); auto ng_type = m_results[i]->get_element_type(); void* pd_arr = tensor_pd->mutable_data(place, ng2pd_type_map[ng_type]); std::shared_ptr to = backend_->create_tensor(ng_type, sp, pd_arr); t_out.emplace_back(to); } else { PADDLE_THROW("Cannot find var or tensor with var name %s", vo); } } auto handle = backend_->compile(ng_func); handle->call_with_validate(t_out, *p_t_in); } // NgraphEngine::Run } // namespace operators } // namespace paddle