// Copyright (c) 2023 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/ir/core/value.h" #include "paddle/ir/core/value_impl.h" namespace ir { // Operand OpOperand::OpOperand(const detail::OpOperandImpl *impl) : impl_(const_cast(impl)) {} OpOperand &OpOperand::operator=(const OpOperand &rhs) { if (this == &rhs) return *this; impl_ = rhs.impl_; return *this; } OpOperand &OpOperand::operator=(const detail::OpOperandImpl *impl) { if (this->impl_ == impl) return *this; impl_ = const_cast(impl); return *this; } OpOperand OpOperand::next_use() const { return impl_->next_use(); } Value OpOperand::source() const { return impl_->source(); } Operation *OpOperand::owner() const { return impl_->owner(); } // detail::OpOperandImpl *OpOperand::impl() const { return impl_; } // Value Value::Value(const detail::ValueImpl *impl) : impl_(const_cast(impl)) {} bool Value::operator==(const Value &other) const { return impl_ == other.impl_; } bool Value::operator!=(const Value &other) const { return impl_ != other.impl_; } bool Value::operator!() const { return impl_ == nullptr; } Value::operator bool() const { return impl_; } detail::ValueImpl *Value::impl() const { return impl_; } ir::Type Value::type() const { return impl_->type(); } void Value::SetType(ir::Type type) { impl_->SetType(type); } Operation *Value::GetDefiningOp() const { if (auto result = dyn_cast()) return result.owner(); return nullptr; } std::string Value::print_ud_chain() { return impl_->print_ud_chain(); } Value::use_iterator Value::begin() const { return ir::OpOperand(impl_->first_use()); } Value::use_iterator Value::end() const { return Value::use_iterator(); } OpOperand Value::first_use() const { return impl()->first_use(); } // OpResult bool OpResult::classof(Value value) { return ir::isa(value.impl()); } Operation *OpResult::owner() const { return impl()->owner(); } uint32_t OpResult::GetResultIndex() const { return impl()->GetResultIndex(); } detail::OpResultImpl *OpResult::impl() const { return reinterpret_cast(impl_); } uint32_t OpResult::GetValidInlineIndex(uint32_t index) { uint32_t max_inline_index = ir::detail::OpResultImpl::GetMaxInlineResultIndex(); return index <= max_inline_index ? index : max_inline_index; } // details namespace detail { ir::Operation *OpOperandImpl::owner() const { return owner_; } ir::detail::OpOperandImpl *OpOperandImpl::next_use() { return next_use_; } ir::Value OpOperandImpl::source() const { return source_; } void OpOperandImpl::release_source() { source_ = nullptr; } OpOperandImpl::OpOperandImpl(ir::Value source, ir::Operation *owner) : source_(source), owner_(owner) { prev_use_addr_ = source.impl()->first_use_addr(); next_use_ = source.impl()->first_use(); if (next_use_) { next_use_->prev_use_addr_ = &next_use_; } source.impl()->SetFirstUse(this); } void OpOperandImpl::remove_from_ud_chain() { if (!prev_use_addr_) return; if (prev_use_addr_ == source_.impl()->first_use_addr()) { /// NOTE: In ValueImpl, first_use_offseted_by_index_ use lower three bits /// storage index information, so need to be updated using the SetFirstUse /// method here. source_.impl()->SetFirstUse(next_use_); } else { *prev_use_addr_ = next_use_; } if (next_use_) { next_use_->prev_use_addr_ = prev_use_addr_; } next_use_ = nullptr; prev_use_addr_ = nullptr; release_source(); } OpOperandImpl::~OpOperandImpl() { remove_from_ud_chain(); } uint32_t ValueImpl::index() const { uint32_t index = reinterpret_cast(first_use_offseted_by_index_) & 0x07; if (index < 6) return index; return reinterpret_cast(const_cast(this)) ->GetResultIndex(); } std::string ValueImpl::print_ud_chain() { std::stringstream result; result << "Value[" << this << "] -> "; OpOperandImpl *tmp = first_use(); if (tmp) { result << "OpOperand[" << reinterpret_cast(tmp) << "] -> "; while (tmp->next_use() != nullptr) { result << "OpOperand[" << reinterpret_cast(tmp->next_use()) << "] -> "; tmp = tmp->next_use(); } } result << "nullptr"; return result.str(); } uint32_t OpResultImpl::GetResultIndex() const { if (const auto *outline_result = ir::dyn_cast(this)) { return outline_result->GetResultIndex(); } return ir::dyn_cast(this)->GetResultIndex(); } ir::Operation *OpResultImpl::owner() const { // For inline result, pointer offset index to obtain the address of op. if (const auto *result = ir::dyn_cast(this)) { result += result->GetResultIndex() + 1; return reinterpret_cast( const_cast(result)); } // For outline result, pointer offset outline_index to obtain the address of // maximum inline result. const OpOutlineResultImpl *outline_result = (const OpOutlineResultImpl *)(this); outline_result += (outline_result->outline_index_ - GetMaxInlineResultIndex()); // The offset of the maximum inline result distance op is // GetMaxInlineResultIndex. const auto *inline_result = reinterpret_cast(outline_result); inline_result += (GetMaxInlineResultIndex() + 1); return reinterpret_cast( const_cast(inline_result)); } } // namespace detail } // namespace ir