#pragma once #ifdef __GNUC__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-parameter" #endif //===- InstructionCost.h ----------------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// /// \file /// This file defines an InstructionCost class that is used when calculating /// the cost of an instruction, or a group of instructions. In addition to a /// numeric value representing the cost the class also contains a state that /// can be used to encode particular properties, such as a cost being invalid. /// Operations on InstructionCost implement saturation arithmetic, so that /// accumulating costs on large cost-values don't overflow. /// //===----------------------------------------------------------------------===// #ifndef LLVM_SUPPORT_INSTRUCTIONCOST_H #define LLVM_SUPPORT_INSTRUCTIONCOST_H #include "llvm/ADT/Optional.h" #include "llvm/Support/MathExtras.h" #include namespace llvm { class raw_ostream; class InstructionCost { public: using CostType = int64_t; /// CostState describes the state of a cost. enum CostState { Valid, /// < The cost value represents a valid cost, even when the /// cost-value is large. Invalid /// < Invalid indicates there is no way to represent the cost as a /// numeric value. This state exists to represent a possible issue, /// e.g. if the cost-model knows the operation cannot be expanded /// into a valid code-sequence by the code-generator. While some /// passes may assert that the calculated cost must be valid, it is /// up to individual passes how to interpret an Invalid cost. For /// example, a transformation pass could choose not to perform a /// transformation if the resulting cost would end up Invalid. /// Because some passes may assert a cost is Valid, it is not /// recommended to use Invalid costs to model 'Unknown'. /// Note that Invalid is semantically different from a (very) high, /// but valid cost, which intentionally indicates no issue, but /// rather a strong preference not to select a certain operation. }; private: CostType Value = 0; CostState State = Valid; void propagateState(const InstructionCost &RHS) { if (RHS.State == Invalid) State = Invalid; } static CostType getMaxValue() { return std::numeric_limits::max(); } static CostType getMinValue() { return std::numeric_limits::min(); } public: // A default constructed InstructionCost is a valid zero cost InstructionCost() = default; InstructionCost(CostState) = delete; InstructionCost(CostType Val) : Value(Val), State(Valid) {} static InstructionCost getMax() { return getMaxValue(); } static InstructionCost getMin() { return getMinValue(); } static InstructionCost getInvalid(CostType Val = 0) { InstructionCost Tmp(Val); Tmp.setInvalid(); return Tmp; } bool isValid() const { return State == Valid; } void setValid() { State = Valid; } void setInvalid() { State = Invalid; } CostState getState() const { return State; } /// This function is intended to be used as sparingly as possible, since the /// class provides the full range of operator support required for arithmetic /// and comparisons. Optional getValue() const { if (isValid()) return Value; return None; } /// For all of the arithmetic operators provided here any invalid state is /// perpetuated and cannot be removed. Once a cost becomes invalid it stays /// invalid, and it also inherits any invalid state from the RHS. /// Arithmetic work on the actual values is implemented with saturation, /// to avoid overflow when using more extreme cost values. InstructionCost &operator+=(const InstructionCost &RHS) { propagateState(RHS); // Saturating addition. InstructionCost::CostType Result; if (AddOverflow(Value, RHS.Value, Result)) Result = RHS.Value > 0 ? getMaxValue() : getMinValue(); Value = Result; return *this; } InstructionCost &operator+=(const CostType RHS) { InstructionCost RHS2(RHS); *this += RHS2; return *this; } InstructionCost &operator-=(const InstructionCost &RHS) { propagateState(RHS); // Saturating subtract. InstructionCost::CostType Result; if (SubOverflow(Value, RHS.Value, Result)) Result = RHS.Value > 0 ? getMinValue() : getMaxValue(); Value = Result; return *this; } InstructionCost &operator-=(const CostType RHS) { InstructionCost RHS2(RHS); *this -= RHS2; return *this; } InstructionCost &operator*=(const InstructionCost &RHS) { propagateState(RHS); // Saturating multiply. InstructionCost::CostType Result; if (MulOverflow(Value, RHS.Value, Result)) { if ((Value > 0 && RHS.Value > 0) || (Value < 0 && RHS.Value < 0)) Result = getMaxValue(); else Result = getMinValue(); } Value = Result; return *this; } InstructionCost &operator*=(const CostType RHS) { InstructionCost RHS2(RHS); *this *= RHS2; return *this; } InstructionCost &operator/=(const InstructionCost &RHS) { propagateState(RHS); Value /= RHS.Value; return *this; } InstructionCost &operator/=(const CostType RHS) { InstructionCost RHS2(RHS); *this /= RHS2; return *this; } InstructionCost &operator++() { *this += 1; return *this; } InstructionCost operator++(int) { InstructionCost Copy = *this; ++*this; return Copy; } InstructionCost &operator--() { *this -= 1; return *this; } InstructionCost operator--(int) { InstructionCost Copy = *this; --*this; return Copy; } /// For the comparison operators we have chosen to use lexicographical /// ordering where valid costs are always considered to be less than invalid /// costs. This avoids having to add asserts to the comparison operators that /// the states are valid and users can test for validity of the cost /// explicitly. bool operator<(const InstructionCost &RHS) const { if (State != RHS.State) return State < RHS.State; return Value < RHS.Value; } // Implement in terms of operator< to ensure that the two comparisons stay in // sync bool operator==(const InstructionCost &RHS) const { return !(*this < RHS) && !(RHS < *this); } bool operator!=(const InstructionCost &RHS) const { return !(*this == RHS); } bool operator==(const CostType RHS) const { InstructionCost RHS2(RHS); return *this == RHS2; } bool operator!=(const CostType RHS) const { return !(*this == RHS); } bool operator>(const InstructionCost &RHS) const { return RHS < *this; } bool operator<=(const InstructionCost &RHS) const { return !(RHS < *this); } bool operator>=(const InstructionCost &RHS) const { return !(*this < RHS); } bool operator<(const CostType RHS) const { InstructionCost RHS2(RHS); return *this < RHS2; } bool operator>(const CostType RHS) const { InstructionCost RHS2(RHS); return *this > RHS2; } bool operator<=(const CostType RHS) const { InstructionCost RHS2(RHS); return *this <= RHS2; } bool operator>=(const CostType RHS) const { InstructionCost RHS2(RHS); return *this >= RHS2; } void print(raw_ostream &OS) const; template auto map(const Function &F) const -> InstructionCost { if (isValid()) return F(*getValue()); return getInvalid(); } }; inline InstructionCost operator+(const InstructionCost &LHS, const InstructionCost &RHS) { InstructionCost LHS2(LHS); LHS2 += RHS; return LHS2; } inline InstructionCost operator-(const InstructionCost &LHS, const InstructionCost &RHS) { InstructionCost LHS2(LHS); LHS2 -= RHS; return LHS2; } inline InstructionCost operator*(const InstructionCost &LHS, const InstructionCost &RHS) { InstructionCost LHS2(LHS); LHS2 *= RHS; return LHS2; } inline InstructionCost operator/(const InstructionCost &LHS, const InstructionCost &RHS) { InstructionCost LHS2(LHS); LHS2 /= RHS; return LHS2; } inline raw_ostream &operator<<(raw_ostream &OS, const InstructionCost &V) { V.print(OS); return OS; } } // namespace llvm #endif #ifdef __GNUC__ #pragma GCC diagnostic pop #endif