/* 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/scope.h" #include // for unique_ptr #include #include #include #include "glog/logging.h" #include "paddle/fluid/framework/threadpool.h" #include "paddle/fluid/string/printf.h" DECLARE_bool(benchmark); DEFINE_bool( eager_delete_scope, true, "Delete local scope eagerly. It will reduce GPU memory usage but " "slow down the destruction of variables.(around 1% performance harm)"); // When in inference scenario, the scopes will not be written by two threads in // a mean time, but a scope may be read by multiple threads concurrently, and // the mutex will cause serious performance issue. // So the mutex is disabled when `ON_INFER`. #ifdef PADDLE_ON_INFERENCE #define SCOPE_KIDS_READER_LOCK #define SCOPE_KIDS_WRITER_LOCK #define SCOPE_VARS_READER_LOCK #define SCOPE_VARS_WRITER_LOCK #else #define SCOPE_KIDS_READER_LOCK AutoRDLock auto_lock(&kids_lock_); #define SCOPE_KIDS_WRITER_LOCK AutoWRLock auto_lock(&kids_lock_); #define SCOPE_VARS_READER_LOCK AutoRDLock auto_lock(&vars_lock_); #define SCOPE_VARS_WRITER_LOCK AutoWRLock auto_lock(&vars_lock_); #endif namespace paddle { namespace framework { Scope::~Scope() { DropKids(); } Scope& Scope::NewScope() const { Scope* child = new Scope(this); { SCOPE_KIDS_WRITER_LOCK kids_.push_back(child); } return *child; } Variable* Scope::Var(const std::string& name) { SCOPE_VARS_WRITER_LOCK return VarInternal(name); } Variable* Scope::Var(std::string* name) { SCOPE_VARS_WRITER_LOCK auto new_name = std::to_string(reinterpret_cast(this)) + "." + std::to_string(vars_.size()); if (name != nullptr) { *name = new_name; } return VarInternal(new_name); } Variable* Scope::FindVar(const std::string& name) const { SCOPE_VARS_READER_LOCK return FindVarInternal(name); } Variable* Scope::FindLocalVar(const std::string& name) const { SCOPE_VARS_READER_LOCK return FindVarLocally(name); } const Scope* Scope::FindScope(const Variable* var) const { SCOPE_VARS_READER_LOCK return FindScopeInternal(var); } void Scope::DropKids() { SCOPE_KIDS_WRITER_LOCK for (Scope* s : kids_) delete s; kids_.clear(); } bool Scope::HasKid(const Scope* scope) const { SCOPE_KIDS_READER_LOCK auto it = std::find(this->kids_.begin(), this->kids_.end(), scope); return it != this->kids_.end(); } std::vector Scope::LocalVarNames() const { std::vector known_vars; { SCOPE_VARS_READER_LOCK known_vars.reserve(this->vars_.size()); for (auto& p : vars_) { known_vars.emplace_back(p.first); } } return known_vars; } void Scope::DeleteScope(Scope* scope) const { SCOPE_KIDS_WRITER_LOCK auto it = std::find(this->kids_.begin(), this->kids_.end(), scope); PADDLE_ENFORCE(it != this->kids_.end(), "%p Cannot find %p as kid scope", this, scope); this->kids_.erase(it); // When making memory benchmark on Fluid, we have to delete scope sync. if (FLAGS_benchmark || FLAGS_eager_delete_scope) { delete scope; } else { Async([scope] { delete scope; }); } } void Scope::EraseVars(const std::vector& var_names) { std::set var_set(var_names.begin(), var_names.end()); SCOPE_VARS_WRITER_LOCK for (auto it = vars_.begin(); it != vars_.end();) { if (var_set.find(it->first) != var_set.end()) { it = vars_.erase(it); } else { ++it; } } } void Scope::Rename(const std::string& origin_name, const std::string& new_name) const { SCOPE_VARS_WRITER_LOCK RenameInternal(origin_name, new_name); } std::string Scope::Rename(const std::string& origin_name) const { SCOPE_VARS_WRITER_LOCK auto new_name = string::Sprintf("%p.%d", this, vars_.size()); RenameInternal(origin_name, new_name); return new_name; } Variable* Scope::VarInternal(const std::string& name) { auto* v = FindVarLocally(name); if (v != nullptr) return v; v = new Variable(); vars_.emplace(name, std::unique_ptr(v)); VLOG(3) << "Create variable " << name; return v; } const Scope* Scope::FindScopeInternal(const Variable* var) const { for (auto& kv : vars_) { if (kv.second.get() == var) { return this; } } return (parent_ == nullptr) ? nullptr : parent_->FindScope(var); } void Scope::RenameInternal(const std::string& origin_name, const std::string& new_name) const { auto origin_it = vars_.find(origin_name); PADDLE_ENFORCE(origin_it != vars_.end(), "Cannot find original variable with name %s", origin_name); auto new_it = vars_.find(new_name); PADDLE_ENFORCE(new_it == vars_.end(), "The variable with name %s is already in the scope", new_name); vars_[new_name].reset(origin_it->second.release()); vars_.erase(origin_it); } Variable* Scope::FindVarInternal(const std::string& name) const { auto var = FindVarLocally(name); if (var != nullptr) { return var; } return (parent_ == nullptr) ? nullptr : parent_->FindVar(name); } Variable* Scope::FindVarLocally(const std::string& name) const { auto it = vars_.find(name); if (it != vars_.end()) return it->second.get(); return nullptr; } std::string GenScopeTreeDebugInfo(Scope* root) { std::stringstream os; if (!root) return ""; // level traversal std::queue queue; queue.push(root); std::vector scopes; while (!queue.empty()) { auto* end = queue.back(); Scope* q = nullptr; while (q != end) { q = queue.front(); queue.pop(); os << q << " "; scopes.push_back(q); for (auto* c : q->kids()) { queue.push(c); } } // end of a level os << "\n------------------------------------------\n"; } os << "\nDetails:\n\n"; for (Scope* q : scopes) { os << "====\n"; os << q << ":\n"; for (auto& var : q->LocalVarNames()) { os << " - " << var << "\n"; } } return os.str(); } } // namespace framework } // namespace paddle