/* 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. */ #ifdef PADDLE_WITH_NGRAPH #include #include #include #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/ngraph_bridge.h" #include "paddle/fluid/framework/ngraph_operator.h" #include "paddle/fluid/framework/tensor.h" #include "paddle/fluid/framework/var_desc.h" #include "paddle/fluid/framework/var_type.h" #include "ngraph/ngraph.hpp" namespace paddle { namespace framework { static ngraph::Shape Ddim2Shape(const DDim& dims) { ngraph::Shape sp; for (int i = 0; i < dims.size(); ++i) { int k = dims[i]; k = k == 0 ? 1 : k; sp.push_back(k); } return sp; } static std::map pd2ng_type_map = { {proto::VarType::FP32, ngraph::element::f32}, {proto::VarType::FP64, ngraph::element::f64}, {proto::VarType::INT32, ngraph::element::i32}, {proto::VarType::INT64, ngraph::element::i64}, {proto::VarType::BOOL, ngraph::element::boolean}, }; typedef enum { /* nGraph support state on ops */ FULL_TRAIN, /* Support full ops for train */ PARTIAL_TRAIN, /* Support partial ops for train */ FULL_TEST, /* Support full list of ops for test */ PARTIAL_TEST /* Support partial list of ops for test */ } op_state; // perform graph build through bridge and execute computation class NgraphOperator { public: explicit NgraphOperator(const Scope& scope, const platform::Place& place, const std::vector>& ops, const std::unordered_map< std::string, ngraph::element::Type>& var_type_map, const std::unordered_set& persist, const std::unordered_set& fetches, const std::unordered_set& post_op_inputs, op_state ng_op_state) : scope_(scope), place_(place), fused_ops_(ops), var_type_map_(var_type_map), persistables_(persist), fetches_(fetches), post_op_inputs_(post_op_inputs), ng_op_state_(ng_op_state) { var_in_node_map_ = std::make_shared< std::unordered_map>>(); var_node_map_ = std::make_shared< std::unordered_map>>(); BuildNgIO(); GetNgFunction(); } void Run(const Scope& scope, const platform::Place& place) const; private: static std::unordered_map> func_cache_; const Scope& scope_; const platform::Place& place_; std::vector> fused_ops_; std::unordered_map var_type_map_; std::unordered_set persistables_; std::unordered_set fetches_; std::unordered_set post_op_inputs_; op_state ng_op_state_; // ngraph backend eg. CPU static std::shared_ptr backend_; // ngraph function to call and execute std::shared_ptr ngraph_function_; // var_name of inputs std::vector var_in_; // var_name of outputs from fetch in order std::vector var_out_; // map input vars to nodes std::shared_ptr< std::unordered_map>> var_in_node_map_; // map each var name with a ngraph node std::shared_ptr< std::unordered_map>> var_node_map_; // cache key to check if function is cached std::shared_ptr GetCacheKey(); // get ngraph input and define ngraph input parameters void GetNgInputShape(std::shared_ptr op); // Call ngraph bridge to map ops void BuildNgNode(); // get the ngraph input and output var list void BuildNgIO(); // build ngraph function call void BuildNgFunction(); // Check cache for ngraph function or otherwise build the function void GetNgFunction(); }; std::vector>::iterator>> FusedOperator::FusedOpIntervals( std::vector>* ops) { std::vector>::iterator>> intervals; if (ops->empty()) { return intervals; } size_t size = ops->size(); size_t left = 0; while (left < size && ops->at(left)->Type() != kFeedOpType) { ++left; } if (left == size) { return intervals; } while (left < size && ops->at(left)->Type() == kFeedOpType) { ++left; } size_t right = left; while (right < size && ops->at(right)->Type() != kFetchOpType) { ++right; } if (right == size) { return intervals; } if (left >= right) return intervals; // (left, right - 1) represents indices between feed and fetch size_t pivot = left; while (pivot < right) { auto op_type = ops->at(pivot)->Type(); if (paddle::framework::NgraphBridge::NG_NODE_MAP.find(op_type) == paddle::framework::NgraphBridge::NG_NODE_MAP.end()) { ++pivot; } else { size_t start = pivot, end = start; while (pivot < right && (paddle::framework::NgraphBridge::NG_NODE_MAP.find( ops->at(pivot)->Type()) != paddle::framework::NgraphBridge::NG_NODE_MAP.end())) { ++pivot; ++end; } std::vector>::iterator> interval = {ops->begin() + start, ops->begin() + end}; intervals.push_back(interval); } } // end while return intervals; } FusedOperator::FusedOperator( const ProgramDesc& prog, size_t block_id, std::vector>::iterator start, std::vector>::iterator end, const std::string& type, const VariableNameMap& inputs, const VariableNameMap& outputs, const AttributeMap& attrs) : OperatorBase(type, inputs, outputs, attrs), pdesc_(prog), block_(block_id) { for (std::vector>::iterator it = start; it != end; ++it) { fused_ops_.push_back(std::move(*it)); } for (std::vector>::iterator it = end; (*it)->Type() != kFetchOpType; ++it) { for (auto& var_name_item : (*it)->Inputs()) { for (auto& var_name : var_name_item.second) { post_op_inputs_.insert(var_name); } } } if ((*(start - 1))->Type() == kFeedOpType && (*end)->Type() == kFetchOpType) { is_full_ = true; } Process(); } void FusedOperator::Process() { auto& bdesc = pdesc_.Block(block_); for (auto& var : bdesc.AllVars()) { if (!(var->GetType() == proto::VarType::SELECTED_ROWS || var->GetType() == proto::VarType::LOD_TENSOR || var->GetType() == proto::VarType::LOD_TENSOR_ARRAY)) { continue; } auto var_name = var->Name(); if (var->Name() == framework::kEmptyVarName) { continue; } if (var_name != "fetch" && var_name != "feed") { 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()); } } for (auto* op : bdesc.AllOps()) { if (op->Type() == kFetchOpType) { std::string fetch_target_name = op->Input("X")[0]; fetches_.insert(fetch_target_name); } } } void FusedOperator::RunImpl(const Scope& scope, const platform::Place& place) const { op_state ng_op_state = PARTIAL_TEST; auto& bdesc = pdesc_.Block(block_); for (auto* op : bdesc.AllOps()) { if (op->Type().find("_grad") != std::string::npos) { ng_op_state = PARTIAL_TRAIN; break; } } if (is_full_) { ng_op_state = ng_op_state == PARTIAL_TEST ? FULL_TEST : FULL_TRAIN; } NgraphOperator ngraph_op(scope, place, fused_ops_, var_type_map_, persistables_, fetches_, post_op_inputs_, ng_op_state); ngraph_op.Run(scope, place); } std::unordered_map> NgraphOperator::func_cache_ = {}; std::shared_ptr NgraphOperator::backend_ = ngraph::runtime::Backend::create("CPU"); void NgraphOperator::GetNgInputShape(std::shared_ptr op) { op->RunInferShape(scope_, place_); for (auto& var_name_item : op->Inputs()) { for (auto& var_name : var_name_item.second) { auto* var = scope_.FindVar(var_name); if (var && VarIsTensor(*var)) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto sp = Ddim2Shape(tensor_pd->dims()); if (std::find(var_in_.begin(), var_in_.end(), var_name) != var_in_.end()) { if (var_node_map_->find(var_name) == var_node_map_->end()) { auto ng_type = var_type_map_.at(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 NgraphOperator::BuildNgNode() { for (auto& var_name : var_out_) { if (var_node_map_->find(var_name) == var_node_map_->end()) { auto* var = scope_.FindVar(var_name); if (var && VarIsTensor(*var)) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto& ddim = tensor_pd->dims(); auto ng_shape = Ddim2Shape(ddim); auto ng_type = var_type_map_.at(var_name); auto prm = std::make_shared(ng_type, ng_shape, true); (*var_node_map_)[var_name] = prm; } } } paddle::framework::NgraphBridge ngb(var_node_map_); for (auto& op : fused_ops_) { ngb.BuildNgGraph(op); } } void NgraphOperator::BuildNgIO() { std::unordered_set inputs; std::unordered_set outputs; for (auto& op : fused_ops_) { 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()) { // fill var_in here to keep lhs and rhs order var_in_.push_back(var_name); } } } if (op->Type() != "fill_constant") { GetNgInputShape(op); } 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 (auto& op : fused_ops_) { 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 (ng_op_state_) { case PARTIAL_TEST: if (post_op_inputs_.find(var_name) != post_op_inputs_.end() || fetches_.find(var_name) != fetches_.end()) { var_out_.push_back(var_name); } break; case FULL_TEST: if (fetches_.find(var_name) != fetches_.end()) { var_out_.push_back(var_name); } break; case PARTIAL_TRAIN: if (fetches_.find(var_name) != fetches_.end() || post_op_inputs_.find(var_name) != post_op_inputs_.end() || persistables_.find(var_name) != persistables_.end()) { var_out_.push_back(var_name); } break; case FULL_TRAIN: if (fetches_.find(var_name) != fetches_.end() || persistables_.find(var_name) != persistables_.end()) { var_out_.push_back(var_name); } break; default: var_out_.push_back(var_name); } } } } } void NgraphOperator::BuildNgFunction() { BuildNgNode(); ngraph_function_ = nullptr; ngraph::NodeVector func_outputs; ngraph::op::ParameterVector func_inputs; for (auto& vo : var_out_) { func_outputs.push_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.push_back(prm); } ngraph_function_ = std::make_shared(func_outputs, func_inputs); } std::shared_ptr NgraphOperator::GetCacheKey() { auto cache_key = std::make_shared(""); *cache_key += std::to_string(fused_ops_.size()); for (auto& op : fused_ops_) { *cache_key += op->Type(); } for (auto& var_name : var_in_) { auto shape = var_node_map_->at(var_name)->get_shape(); *cache_key += var_name; *cache_key += var_type_map_.at(var_name).c_type_string(); for (size_t i = 0; i < shape.size(); ++i) { *cache_key += std::to_string(shape.at(i)); } } for (auto& var_name : var_out_) { auto* var = scope_.FindVar(var_name); if (var && VarIsTensor(*var)) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); auto& ddim = tensor_pd->dims(); for (int i = 0; i < ddim.size(); ++i) { *cache_key += std::to_string(ddim[i]); } } } return cache_key; } void NgraphOperator::GetNgFunction() { bool cache_on = true; if (cache_on) { std::string cache_key_val = *GetCacheKey(); if (func_cache_.find(cache_key_val) != func_cache_.end()) { ngraph_function_ = func_cache_.at(cache_key_val); } else { BuildNgFunction(); func_cache_[cache_key_val] = ngraph_function_; } } else { BuildNgFunction(); } } void NgraphOperator::Run(const Scope& scope, const platform::Place& place) const { std::vector> t_in; std::vector> t_out; for (size_t i = 0; i < var_in_.size(); ++i) { auto vi = var_in_.at(i); auto sp = var_node_map_->at(vi)->get_shape(); std::shared_ptr ti; auto* var = scope.FindVar(vi); if (var && VarIsTensor(*var)) { auto* tensor_pd = GetLoDTensorOrSelectedRowsValueFromVar(*var); PADDLE_ENFORCE(sp == Ddim2Shape(tensor_pd->dims()), "Ensure ngraph tensor layout align with paddle tensor"); if (tensor_pd->type().hash_code() == typeid(float).hash_code()) { // NOLINT const float* arr = tensor_pd->data(); ti = backend_->create_tensor(ngraph::element::f32, sp, const_cast(arr)); } else if (tensor_pd->type().hash_code() == typeid(int).hash_code()) { // NOLINT const int* arr = tensor_pd->data(); ti = backend_->create_tensor(ngraph::element::i32, sp, const_cast(arr)); } else if (tensor_pd->type().hash_code() == typeid(int64_t).hash_code()) { const int64_t* arr = tensor_pd->data(); ti = backend_->create_tensor(ngraph::element::i64, sp, const_cast(arr)); } else if (tensor_pd->type().hash_code() == typeid(double).hash_code()) { // NOLINT const double* arr = tensor_pd->data(); ti = backend_->create_tensor(ngraph::element::f64, sp, const_cast(arr)); } else if (tensor_pd->type().hash_code() == typeid(bool).hash_code()) { // NOLINT const bool* arr = tensor_pd->data(); ti = backend_->create_tensor(ngraph::element::boolean, sp, const_cast(arr)); } else { PADDLE_THROW("Data type not handling for var %s", vi); } } else { PADDLE_THROW("Cannot find var or tensor with var name %s", vi); } bool is_test = (ng_op_state_ == PARTIAL_TEST || ng_op_state_ == FULL_TEST) ? true : false; bool is_persistable = (persistables_.find(vi) != persistables_.end()) ? true : false; if (is_test && is_persistable) { ti->set_stale(false); } t_in.push_back(ti); } for (size_t i = 0; i < var_out_.size(); ++i) { auto var_name = var_out_[i]; auto* var = scope.FindVar(var_name); std::shared_ptr to; if (var && VarIsTensor(*var)) { auto* tensor_pd = GetMutableLoDTensorOrSelectedRowsValueFromVar(var); auto dd = tensor_pd->dims(); ngraph::Shape sp = Ddim2Shape(dd); auto ng_type = var_type_map_.at(var_name); if (ng_type == ngraph::element::f32) { auto pd_arr = tensor_pd->mutable_data(place); to = backend_->create_tensor(ngraph::element::f32, sp, pd_arr); } else if (ng_type == ngraph::element::i64) { auto pd_arr = tensor_pd->mutable_data(place); to = backend_->create_tensor(ngraph::element::i64, sp, pd_arr); } else if (ng_type == ngraph::element::f64) { auto pd_arr = tensor_pd->mutable_data(place); to = backend_->create_tensor(ngraph::element::f64, sp, pd_arr); } else if (ng_type == ngraph::element::boolean) { auto pd_arr = tensor_pd->mutable_data(place); to = backend_->create_tensor(ngraph::element::boolean, sp, pd_arr); } else { PADDLE_THROW("Data type not handled in for var %s", var_name); } t_out.push_back(to); } else { PADDLE_THROW("Cannot find var or tensor with var name %s", var_name); } } backend_->call(ngraph_function_, t_out, t_in); } // NgraphOperator::RunImpl } // namespace framework } // namespace paddle #endif