/* 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. */ #pragma once #include #include #include #include #include #include "paddle/fluid/framework/framework.pb.h" #include "paddle/fluid/framework/type_defs.h" #include "paddle/fluid/platform/enforce.h" namespace paddle { namespace framework { template struct ExtractAttribute { explicit ExtractAttribute(const std::string& attr_name) : attr_name_(attr_name) {} T* operator()(Attribute& attr) const { T* attr_value = nullptr; try { attr_value = &boost::get(attr); } catch (boost::bad_get& bad_get) { PADDLE_THROW("Cannot get attribute %s by type %s, its type is %s", attr_name_, paddle::platform::demangle(typeid(T).name()), paddle::platform::demangle(attr.type().name())); } return attr_value; } const std::string& attr_name_; }; // special handle bool // FIXME(yuyang18): Currently we cast bool into int in python binding. It is // hard to change the logic there. In another way, we should correct handle // if the user set `some_flag=1`. // // FIX ME anytime if there is a better solution. template <> struct ExtractAttribute { explicit ExtractAttribute(const std::string& attr_name) : attr_name_(attr_name) {} bool* operator()(Attribute& attr) const { if (attr.type() == typeid(int)) { // NOLINT int val = boost::get(attr); attr = static_cast(val); } else if (attr.type() == typeid(float)) { // NOLINT float val = boost::get(attr); attr = static_cast(val); } bool* attr_value = nullptr; try { attr_value = &boost::get(attr); } catch (boost::bad_get& bad_get) { PADDLE_THROW("Cannot get attribute %s by type bool, its type is %s", attr_name_, paddle::platform::demangle(attr.type().name())); } return attr_value; } const std::string& attr_name_; }; template <> struct ExtractAttribute { explicit ExtractAttribute(const std::string& attr_name) : attr_name_(attr_name) {} int64_t* operator()(Attribute& attr) const { if (attr.type() == typeid(int)) { // NOLINT int val = boost::get(attr); attr = static_cast(val); } else if (attr.type() == typeid(float)) { // NOLINT int val = boost::get(attr); attr = static_cast(val); } int64_t* attr_value = nullptr; try { attr_value = &boost::get(attr); } catch (boost::bad_get& bad_get) { PADDLE_THROW("Cannot get attribute %s by type int64_t, its type is %s", attr_name_, paddle::platform::demangle(attr.type().name())); } return attr_value; } const std::string& attr_name_; }; template <> struct ExtractAttribute> { explicit ExtractAttribute(const std::string& attr_name) : attr_name_(attr_name) {} std::vector* operator()(Attribute& attr) const { if (attr.type() == typeid(std::vector)) { // NOLINT std::vector val = boost::get>(attr); std::vector vec(val.begin(), val.end()); attr = vec; } else if (attr.type() == typeid(std::vector)) { // NOLINT std::vector val = boost::get>(attr); std::vector vec(val.begin(), val.end()); attr = vec; } std::vector* attr_value = nullptr; try { attr_value = &boost::get>(attr); } catch (boost::bad_get& bad_get) { PADDLE_THROW("Cannot get attribute %s by type int64_t, its type is %s", attr_name_, paddle::platform::demangle(attr.type().name())); } return attr_value; } const std::string& attr_name_; }; template inline proto::AttrType AttrTypeID() { Attribute tmp = T(); return static_cast(tmp.which() - 1); } Attribute GetAttrValue(const proto::OpDesc::Attr& attr_desc); class AttrReader { public: explicit AttrReader(const AttributeMap& attrs) : attrs_(attrs) {} template inline const T& Get(const std::string& name) const { PADDLE_ENFORCE(attrs_.count(name) != 0, "%s should be in AttributeMap", name); Attribute& attr = const_cast(attrs_.at(name)); ExtractAttribute extract_attr(name); T* attr_value = extract_attr(attr); return *attr_value; } private: const AttributeMap& attrs_; }; // check whether a value(attribute) fit a certain limit template class GreaterThanChecker { public: explicit GreaterThanChecker(T lower_bound) : lower_bound_(lower_bound) {} void operator()(const T& value) const { PADDLE_ENFORCE(value > lower_bound_, "larger_than check fails."); } private: T lower_bound_; }; template class EqualGreaterThanChecker { public: explicit EqualGreaterThanChecker(T lower_bound) : lower_bound_(lower_bound) {} void operator()(const T& value) const { PADDLE_ENFORCE_GE(value, lower_bound_, "equal_larger_than check fails."); } private: T lower_bound_; }; // we can provide users more common Checker, like 'LessThanChecker', // 'BetweenChecker'... template class DefaultValueSetter { public: explicit DefaultValueSetter(T default_value) : default_value_(default_value) {} void operator()(T* value) const { *value = default_value_; } private: T default_value_; }; template class EnumInContainer { public: explicit EnumInContainer(const std::unordered_set& c) : container_(c) {} void operator()(const T& val) const { PADDLE_ENFORCE(container_.find(val) != container_.end(), "Value %s is not in enum container %s", val, ContainerDebugString()); } private: std::string ContainerDebugString() const { std::ostringstream sout; sout << "["; size_t cnt = 0; for (auto& v : container_) { sout << v; ++cnt; if (cnt != container_.size()) { sout << " ,"; } } sout << "]"; return sout.str(); } std::unordered_set container_; }; // check whether a certain attribute fit its limits // an attribute can have more than one limits template class TypedAttrChecker { typedef std::function DefaultValueChecker; typedef std::function ValueChecker; public: explicit TypedAttrChecker(const std::string& attr_name) : attr_name_(attr_name) {} TypedAttrChecker& InEnum(const std::unordered_set& range) { value_checkers_.push_back(EnumInContainer(range)); return *this; } TypedAttrChecker& GreaterThan(const T& lower_bound) { value_checkers_.push_back(GreaterThanChecker(lower_bound)); return *this; } TypedAttrChecker& EqualGreaterThan(const T& lower_bound) { value_checkers_.push_back(EqualGreaterThanChecker(lower_bound)); return *this; } // we can add more common limits, like LessThan(), Between()... TypedAttrChecker& SetDefault(const T& default_value) { PADDLE_ENFORCE(default_value_setter_.empty(), "%s can't have more than one default value!", attr_name_); default_value_setter_.push_back(DefaultValueSetter(default_value)); return *this; } // allow users provide their own checker TypedAttrChecker& AddCustomChecker(const ValueChecker& checker) { value_checkers_.push_back(checker); return *this; } void operator()(AttributeMap* attr_map) const { if (!attr_map->count(attr_name_)) { // user do not set this attr PADDLE_ENFORCE(!default_value_setter_.empty(), "Attribute '%s' is required!", attr_name_); // default_value_setter_ has no more than one element T val; (default_value_setter_[0])(&val); (*attr_map)[attr_name_] = val; } Attribute& attr = attr_map->at(attr_name_); ExtractAttribute extract_attr(attr_name_); T* attr_value = extract_attr(attr); for (const auto& checker : value_checkers_) { checker(*attr_value); } } private: std::string attr_name_; std::vector value_checkers_; std::vector default_value_setter_; }; // check whether op's all attributes fit their own limits class OpAttrChecker { typedef std::function AttrChecker; public: template TypedAttrChecker& AddAttrChecker(const std::string& attr_name) { attr_checkers_.push_back(TypedAttrChecker(attr_name)); AttrChecker& checker = attr_checkers_.back(); return *(checker.target>()); } void Check(AttributeMap* attr_map) const { for (const auto& checker : attr_checkers_) { checker(attr_map); } } private: std::vector attr_checkers_; }; } // namespace framework } // namespace paddle