//===-- llvm/CodeGen/GlobalISel/CombinerHelper.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 contains common combine transformations that may be used in a combine /// pass,or by the target elsewhere. /// Targets can pick individual opcode transformations from the helper or use /// tryCombine which invokes all transformations. All of the transformations /// return true if the MachineInstruction changed and false otherwise. /// //===--------------------------------------------------------------------===// #ifndef LLVM_CODEGEN_GLOBALISEL_COMBINERHELPER_H #define LLVM_CODEGEN_GLOBALISEL_COMBINERHELPER_H #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/SmallVector.h" #include "llvm/CodeGen/GlobalISel/GenericMachineInstrs.h" #include "llvm/CodeGen/LowLevelType.h" #include "llvm/CodeGen/Register.h" #include "llvm/IR/InstrTypes.h" #include namespace llvm { class GISelChangeObserver; class APInt; class ConstantFP; class GPtrAdd; class GZExtLoad; class MachineIRBuilder; class MachineInstrBuilder; class MachineRegisterInfo; class MachineInstr; class MachineOperand; class GISelKnownBits; class MachineDominatorTree; class LegalizerInfo; struct LegalityQuery; class RegisterBank; class RegisterBankInfo; class TargetLowering; class TargetRegisterInfo; struct PreferredTuple { LLT Ty; // The result type of the extend. unsigned ExtendOpcode; // G_ANYEXT/G_SEXT/G_ZEXT MachineInstr *MI; }; struct IndexedLoadStoreMatchInfo { Register Addr; Register Base; Register Offset; bool RematOffset; // True if Offset is a constant that needs to be // rematerialized before the new load/store. bool IsPre; }; struct PtrAddChain { int64_t Imm; Register Base; const RegisterBank *Bank; }; struct RegisterImmPair { Register Reg; int64_t Imm; }; struct ShiftOfShiftedLogic { MachineInstr *Logic; MachineInstr *Shift2; Register LogicNonShiftReg; uint64_t ValSum; }; using BuildFnTy = std::function; using OperandBuildSteps = SmallVector, 4>; struct InstructionBuildSteps { unsigned Opcode = 0; /// The opcode for the produced instruction. OperandBuildSteps OperandFns; /// Operands to be added to the instruction. InstructionBuildSteps() = default; InstructionBuildSteps(unsigned Opcode, const OperandBuildSteps &OperandFns) : Opcode(Opcode), OperandFns(OperandFns) {} }; struct InstructionStepsMatchInfo { /// Describes instructions to be built during a combine. SmallVector InstrsToBuild; InstructionStepsMatchInfo() = default; InstructionStepsMatchInfo( std::initializer_list InstrsToBuild) : InstrsToBuild(InstrsToBuild) {} }; class CombinerHelper { protected: MachineIRBuilder &Builder; MachineRegisterInfo &MRI; GISelChangeObserver &Observer; GISelKnownBits *KB; MachineDominatorTree *MDT; bool IsPreLegalize; const LegalizerInfo *LI; const RegisterBankInfo *RBI; const TargetRegisterInfo *TRI; public: CombinerHelper(GISelChangeObserver &Observer, MachineIRBuilder &B, bool IsPreLegalize, GISelKnownBits *KB = nullptr, MachineDominatorTree *MDT = nullptr, const LegalizerInfo *LI = nullptr); GISelKnownBits *getKnownBits() const { return KB; } MachineIRBuilder &getBuilder() const { return Builder; } const TargetLowering &getTargetLowering() const; /// \returns true if the combiner is running pre-legalization. bool isPreLegalize() const; /// \returns true if \p Query is legal on the target. bool isLegal(const LegalityQuery &Query) const; /// \return true if the combine is running prior to legalization, or if \p /// Query is legal on the target. bool isLegalOrBeforeLegalizer(const LegalityQuery &Query) const; /// \return true if the combine is running prior to legalization, or if \p Ty /// is a legal integer constant type on the target. bool isConstantLegalOrBeforeLegalizer(const LLT Ty) const; /// MachineRegisterInfo::replaceRegWith() and inform the observer of the changes void replaceRegWith(MachineRegisterInfo &MRI, Register FromReg, Register ToReg) const; /// Replace a single register operand with a new register and inform the /// observer of the changes. void replaceRegOpWith(MachineRegisterInfo &MRI, MachineOperand &FromRegOp, Register ToReg) const; /// Replace the opcode in instruction with a new opcode and inform the /// observer of the changes. void replaceOpcodeWith(MachineInstr &FromMI, unsigned ToOpcode) const; /// Get the register bank of \p Reg. /// If Reg has not been assigned a register, a register class, /// or a register bank, then this returns nullptr. /// /// \pre Reg.isValid() const RegisterBank *getRegBank(Register Reg) const; /// Set the register bank of \p Reg. /// Does nothing if the RegBank is null. /// This is the counterpart to getRegBank. void setRegBank(Register Reg, const RegisterBank *RegBank); /// If \p MI is COPY, try to combine it. /// Returns true if MI changed. bool tryCombineCopy(MachineInstr &MI); bool matchCombineCopy(MachineInstr &MI); void applyCombineCopy(MachineInstr &MI); /// Returns true if \p DefMI precedes \p UseMI or they are the same /// instruction. Both must be in the same basic block. bool isPredecessor(const MachineInstr &DefMI, const MachineInstr &UseMI); /// Returns true if \p DefMI dominates \p UseMI. By definition an /// instruction dominates itself. /// /// If we haven't been provided with a MachineDominatorTree during /// construction, this function returns a conservative result that tracks just /// a single basic block. bool dominates(const MachineInstr &DefMI, const MachineInstr &UseMI); /// If \p MI is extend that consumes the result of a load, try to combine it. /// Returns true if MI changed. bool tryCombineExtendingLoads(MachineInstr &MI); bool matchCombineExtendingLoads(MachineInstr &MI, PreferredTuple &MatchInfo); void applyCombineExtendingLoads(MachineInstr &MI, PreferredTuple &MatchInfo); /// Match (and (load x), mask) -> zextload x bool matchCombineLoadWithAndMask(MachineInstr &MI, BuildFnTy &MatchInfo); /// Combine a G_EXTRACT_VECTOR_ELT of a load into a narrowed /// load. bool matchCombineExtractedVectorLoad(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchCombineIndexedLoadStore(MachineInstr &MI, IndexedLoadStoreMatchInfo &MatchInfo); void applyCombineIndexedLoadStore(MachineInstr &MI, IndexedLoadStoreMatchInfo &MatchInfo); bool matchSextTruncSextLoad(MachineInstr &MI); void applySextTruncSextLoad(MachineInstr &MI); /// Match sext_inreg(load p), imm -> sextload p bool matchSextInRegOfLoad(MachineInstr &MI, std::tuple &MatchInfo); void applySextInRegOfLoad(MachineInstr &MI, std::tuple &MatchInfo); /// Try to combine G_[SU]DIV and G_[SU]REM into a single G_[SU]DIVREM /// when their source operands are identical. bool matchCombineDivRem(MachineInstr &MI, MachineInstr *&OtherMI); void applyCombineDivRem(MachineInstr &MI, MachineInstr *&OtherMI); /// If a brcond's true block is not the fallthrough, make it so by inverting /// the condition and swapping operands. bool matchOptBrCondByInvertingCond(MachineInstr &MI, MachineInstr *&BrCond); void applyOptBrCondByInvertingCond(MachineInstr &MI, MachineInstr *&BrCond); /// If \p MI is G_CONCAT_VECTORS, try to combine it. /// Returns true if MI changed. /// Right now, we support: /// - concat_vector(undef, undef) => undef /// - concat_vector(build_vector(A, B), build_vector(C, D)) => /// build_vector(A, B, C, D) /// /// \pre MI.getOpcode() == G_CONCAT_VECTORS. bool tryCombineConcatVectors(MachineInstr &MI); /// Check if the G_CONCAT_VECTORS \p MI is undef or if it /// can be flattened into a build_vector. /// In the first case \p IsUndef will be true. /// In the second case \p Ops will contain the operands needed /// to produce the flattened build_vector. /// /// \pre MI.getOpcode() == G_CONCAT_VECTORS. bool matchCombineConcatVectors(MachineInstr &MI, bool &IsUndef, SmallVectorImpl &Ops); /// Replace \p MI with a flattened build_vector with \p Ops or an /// implicit_def if IsUndef is true. void applyCombineConcatVectors(MachineInstr &MI, bool IsUndef, const ArrayRef Ops); /// Try to combine G_SHUFFLE_VECTOR into G_CONCAT_VECTORS. /// Returns true if MI changed. /// /// \pre MI.getOpcode() == G_SHUFFLE_VECTOR. bool tryCombineShuffleVector(MachineInstr &MI); /// Check if the G_SHUFFLE_VECTOR \p MI can be replaced by a /// concat_vectors. /// \p Ops will contain the operands needed to produce the flattened /// concat_vectors. /// /// \pre MI.getOpcode() == G_SHUFFLE_VECTOR. bool matchCombineShuffleVector(MachineInstr &MI, SmallVectorImpl &Ops); /// Replace \p MI with a concat_vectors with \p Ops. void applyCombineShuffleVector(MachineInstr &MI, const ArrayRef Ops); bool matchShuffleToExtract(MachineInstr &MI); void applyShuffleToExtract(MachineInstr &MI); /// Optimize memcpy intrinsics et al, e.g. constant len calls. /// /p MaxLen if non-zero specifies the max length of a mem libcall to inline. /// /// For example (pre-indexed): /// /// $addr = G_PTR_ADD $base, $offset /// [...] /// $val = G_LOAD $addr /// [...] /// $whatever = COPY $addr /// /// --> /// /// $val, $addr = G_INDEXED_LOAD $base, $offset, 1 (IsPre) /// [...] /// $whatever = COPY $addr /// /// or (post-indexed): /// /// G_STORE $val, $base /// [...] /// $addr = G_PTR_ADD $base, $offset /// [...] /// $whatever = COPY $addr /// /// --> /// /// $addr = G_INDEXED_STORE $val, $base, $offset /// [...] /// $whatever = COPY $addr bool tryCombineMemCpyFamily(MachineInstr &MI, unsigned MaxLen = 0); bool matchPtrAddImmedChain(MachineInstr &MI, PtrAddChain &MatchInfo); void applyPtrAddImmedChain(MachineInstr &MI, PtrAddChain &MatchInfo); /// Fold (shift (shift base, x), y) -> (shift base (x+y)) bool matchShiftImmedChain(MachineInstr &MI, RegisterImmPair &MatchInfo); void applyShiftImmedChain(MachineInstr &MI, RegisterImmPair &MatchInfo); /// If we have a shift-by-constant of a bitwise logic op that itself has a /// shift-by-constant operand with identical opcode, we may be able to convert /// that into 2 independent shifts followed by the logic op. bool matchShiftOfShiftedLogic(MachineInstr &MI, ShiftOfShiftedLogic &MatchInfo); void applyShiftOfShiftedLogic(MachineInstr &MI, ShiftOfShiftedLogic &MatchInfo); bool matchCommuteShift(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform a multiply by a power-of-2 value to a left shift. bool matchCombineMulToShl(MachineInstr &MI, unsigned &ShiftVal); void applyCombineMulToShl(MachineInstr &MI, unsigned &ShiftVal); // Transform a G_SHL with an extended source into a narrower shift if // possible. bool matchCombineShlOfExtend(MachineInstr &MI, RegisterImmPair &MatchData); void applyCombineShlOfExtend(MachineInstr &MI, const RegisterImmPair &MatchData); /// Fold away a merge of an unmerge of the corresponding values. bool matchCombineMergeUnmerge(MachineInstr &MI, Register &MatchInfo); /// Reduce a shift by a constant to an unmerge and a shift on a half sized /// type. This will not produce a shift smaller than \p TargetShiftSize. bool matchCombineShiftToUnmerge(MachineInstr &MI, unsigned TargetShiftSize, unsigned &ShiftVal); void applyCombineShiftToUnmerge(MachineInstr &MI, const unsigned &ShiftVal); bool tryCombineShiftToUnmerge(MachineInstr &MI, unsigned TargetShiftAmount); /// Transform G_UNMERGE(G_MERGE ty X, Y, Z) -> ty X, Y, Z. bool matchCombineUnmergeMergeToPlainValues(MachineInstr &MI, SmallVectorImpl &Operands); void applyCombineUnmergeMergeToPlainValues(MachineInstr &MI, SmallVectorImpl &Operands); /// Transform G_UNMERGE Constant -> Constant1, Constant2, ... bool matchCombineUnmergeConstant(MachineInstr &MI, SmallVectorImpl &Csts); void applyCombineUnmergeConstant(MachineInstr &MI, SmallVectorImpl &Csts); /// Transform G_UNMERGE G_IMPLICIT_DEF -> G_IMPLICIT_DEF, G_IMPLICIT_DEF, ... bool matchCombineUnmergeUndef(MachineInstr &MI, std::function &MatchInfo); /// Transform X, Y = G_UNMERGE Z -> X = G_TRUNC Z. bool matchCombineUnmergeWithDeadLanesToTrunc(MachineInstr &MI); void applyCombineUnmergeWithDeadLanesToTrunc(MachineInstr &MI); /// Transform X, Y = G_UNMERGE(G_ZEXT(Z)) -> X = G_ZEXT(Z); Y = G_CONSTANT 0 bool matchCombineUnmergeZExtToZExt(MachineInstr &MI); void applyCombineUnmergeZExtToZExt(MachineInstr &MI); /// Transform fp_instr(cst) to constant result of the fp operation. void applyCombineConstantFoldFpUnary(MachineInstr &MI, const ConstantFP *Cst); /// Transform IntToPtr(PtrToInt(x)) to x if cast is in the same address space. bool matchCombineI2PToP2I(MachineInstr &MI, Register &Reg); void applyCombineI2PToP2I(MachineInstr &MI, Register &Reg); /// Transform PtrToInt(IntToPtr(x)) to x. void applyCombineP2IToI2P(MachineInstr &MI, Register &Reg); /// Transform G_ADD (G_PTRTOINT x), y -> G_PTRTOINT (G_PTR_ADD x, y) /// Transform G_ADD y, (G_PTRTOINT x) -> G_PTRTOINT (G_PTR_ADD x, y) bool matchCombineAddP2IToPtrAdd(MachineInstr &MI, std::pair &PtrRegAndCommute); void applyCombineAddP2IToPtrAdd(MachineInstr &MI, std::pair &PtrRegAndCommute); // Transform G_PTR_ADD (G_PTRTOINT C1), C2 -> C1 + C2 bool matchCombineConstPtrAddToI2P(MachineInstr &MI, APInt &NewCst); void applyCombineConstPtrAddToI2P(MachineInstr &MI, APInt &NewCst); /// Transform anyext(trunc(x)) to x. bool matchCombineAnyExtTrunc(MachineInstr &MI, Register &Reg); /// Transform zext(trunc(x)) to x. bool matchCombineZextTrunc(MachineInstr &MI, Register &Reg); /// Transform [asz]ext([asz]ext(x)) to [asz]ext x. bool matchCombineExtOfExt(MachineInstr &MI, std::tuple &MatchInfo); void applyCombineExtOfExt(MachineInstr &MI, std::tuple &MatchInfo); /// Transform trunc ([asz]ext x) to x or ([asz]ext x) or (trunc x). bool matchCombineTruncOfExt(MachineInstr &MI, std::pair &MatchInfo); void applyCombineTruncOfExt(MachineInstr &MI, std::pair &MatchInfo); /// Transform trunc (shl x, K) to shl (trunc x), K /// if K < VT.getScalarSizeInBits(). /// /// Transforms trunc ([al]shr x, K) to (trunc ([al]shr (MidVT (trunc x)), K)) /// if K <= (MidVT.getScalarSizeInBits() - VT.getScalarSizeInBits()) /// MidVT is obtained by finding a legal type between the trunc's src and dst /// types. bool matchCombineTruncOfShift(MachineInstr &MI, std::pair &MatchInfo); void applyCombineTruncOfShift(MachineInstr &MI, std::pair &MatchInfo); /// Return true if any explicit use operand on \p MI is defined by a /// G_IMPLICIT_DEF. bool matchAnyExplicitUseIsUndef(MachineInstr &MI); /// Return true if all register explicit use operands on \p MI are defined by /// a G_IMPLICIT_DEF. bool matchAllExplicitUsesAreUndef(MachineInstr &MI); /// Return true if a G_SHUFFLE_VECTOR instruction \p MI has an undef mask. bool matchUndefShuffleVectorMask(MachineInstr &MI); /// Return true if a G_STORE instruction \p MI is storing an undef value. bool matchUndefStore(MachineInstr &MI); /// Return true if a G_SELECT instruction \p MI has an undef comparison. bool matchUndefSelectCmp(MachineInstr &MI); /// Return true if a G_{EXTRACT,INSERT}_VECTOR_ELT has an out of range index. bool matchInsertExtractVecEltOutOfBounds(MachineInstr &MI); /// Return true if a G_SELECT instruction \p MI has a constant comparison. If /// true, \p OpIdx will store the operand index of the known selected value. bool matchConstantSelectCmp(MachineInstr &MI, unsigned &OpIdx); /// Replace an instruction with a G_FCONSTANT with value \p C. void replaceInstWithFConstant(MachineInstr &MI, double C); /// Replace an instruction with an G_FCONSTANT with value \p CFP. void replaceInstWithFConstant(MachineInstr &MI, ConstantFP *CFP); /// Replace an instruction with a G_CONSTANT with value \p C. void replaceInstWithConstant(MachineInstr &MI, int64_t C); /// Replace an instruction with a G_CONSTANT with value \p C. void replaceInstWithConstant(MachineInstr &MI, APInt C); /// Replace an instruction with a G_IMPLICIT_DEF. void replaceInstWithUndef(MachineInstr &MI); /// Delete \p MI and replace all of its uses with its \p OpIdx-th operand. void replaceSingleDefInstWithOperand(MachineInstr &MI, unsigned OpIdx); /// Delete \p MI and replace all of its uses with \p Replacement. void replaceSingleDefInstWithReg(MachineInstr &MI, Register Replacement); /// @brief Replaces the shift amount in \p MI with ShiftAmt % BW /// @param MI void applyFunnelShiftConstantModulo(MachineInstr &MI); /// Return true if \p MOP1 and \p MOP2 are register operands are defined by /// equivalent instructions. bool matchEqualDefs(const MachineOperand &MOP1, const MachineOperand &MOP2); /// Return true if \p MOP is defined by a G_CONSTANT or splat with a value equal to /// \p C. bool matchConstantOp(const MachineOperand &MOP, int64_t C); /// Return true if \p MOP is defined by a G_FCONSTANT or splat with a value exactly /// equal to \p C. bool matchConstantFPOp(const MachineOperand &MOP, double C); /// @brief Checks if constant at \p ConstIdx is larger than \p MI 's bitwidth /// @param ConstIdx Index of the constant bool matchConstantLargerBitWidth(MachineInstr &MI, unsigned ConstIdx); /// Optimize (cond ? x : x) -> x bool matchSelectSameVal(MachineInstr &MI); /// Optimize (x op x) -> x bool matchBinOpSameVal(MachineInstr &MI); /// Check if operand \p OpIdx is zero. bool matchOperandIsZero(MachineInstr &MI, unsigned OpIdx); /// Check if operand \p OpIdx is undef. bool matchOperandIsUndef(MachineInstr &MI, unsigned OpIdx); /// Check if operand \p OpIdx is known to be a power of 2. bool matchOperandIsKnownToBeAPowerOfTwo(MachineInstr &MI, unsigned OpIdx); /// Erase \p MI void eraseInst(MachineInstr &MI); /// Return true if MI is a G_ADD which can be simplified to a G_SUB. bool matchSimplifyAddToSub(MachineInstr &MI, std::tuple &MatchInfo); void applySimplifyAddToSub(MachineInstr &MI, std::tuple &MatchInfo); /// Match (logic_op (op x...), (op y...)) -> (op (logic_op x, y)) bool matchHoistLogicOpWithSameOpcodeHands(MachineInstr &MI, InstructionStepsMatchInfo &MatchInfo); /// Replace \p MI with a series of instructions described in \p MatchInfo. void applyBuildInstructionSteps(MachineInstr &MI, InstructionStepsMatchInfo &MatchInfo); /// Match ashr (shl x, C), C -> sext_inreg (C) bool matchAshrShlToSextInreg(MachineInstr &MI, std::tuple &MatchInfo); void applyAshShlToSextInreg(MachineInstr &MI, std::tuple &MatchInfo); /// Fold and(and(x, C1), C2) -> C1&C2 ? and(x, C1&C2) : 0 bool matchOverlappingAnd(MachineInstr &MI, BuildFnTy &MatchInfo); /// \return true if \p MI is a G_AND instruction whose operands are x and y /// where x & y == x or x & y == y. (E.g., one of operands is all-ones value.) /// /// \param [in] MI - The G_AND instruction. /// \param [out] Replacement - A register the G_AND should be replaced with on /// success. bool matchRedundantAnd(MachineInstr &MI, Register &Replacement); /// \return true if \p MI is a G_OR instruction whose operands are x and y /// where x | y == x or x | y == y. (E.g., one of operands is all-zeros /// value.) /// /// \param [in] MI - The G_OR instruction. /// \param [out] Replacement - A register the G_OR should be replaced with on /// success. bool matchRedundantOr(MachineInstr &MI, Register &Replacement); /// \return true if \p MI is a G_SEXT_INREG that can be erased. bool matchRedundantSExtInReg(MachineInstr &MI); /// Combine inverting a result of a compare into the opposite cond code. bool matchNotCmp(MachineInstr &MI, SmallVectorImpl &RegsToNegate); void applyNotCmp(MachineInstr &MI, SmallVectorImpl &RegsToNegate); /// Fold (xor (and x, y), y) -> (and (not x), y) ///{ bool matchXorOfAndWithSameReg(MachineInstr &MI, std::pair &MatchInfo); void applyXorOfAndWithSameReg(MachineInstr &MI, std::pair &MatchInfo); ///} /// Combine G_PTR_ADD with nullptr to G_INTTOPTR bool matchPtrAddZero(MachineInstr &MI); void applyPtrAddZero(MachineInstr &MI); /// Combine G_UREM x, (known power of 2) to an add and bitmasking. void applySimplifyURemByPow2(MachineInstr &MI); /// Push a binary operator through a select on constants. /// /// binop (select cond, K0, K1), K2 -> /// select cond, (binop K0, K2), (binop K1, K2) bool matchFoldBinOpIntoSelect(MachineInstr &MI, unsigned &SelectOpNo); void applyFoldBinOpIntoSelect(MachineInstr &MI, const unsigned &SelectOpNo); bool matchCombineInsertVecElts(MachineInstr &MI, SmallVectorImpl &MatchInfo); void applyCombineInsertVecElts(MachineInstr &MI, SmallVectorImpl &MatchInfo); /// Match expression trees of the form /// /// \code /// sN *a = ... /// sM val = a[0] | (a[1] << N) | (a[2] << 2N) | (a[3] << 3N) ... /// \endcode /// /// And check if the tree can be replaced with a M-bit load + possibly a /// bswap. bool matchLoadOrCombine(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchExtendThroughPhis(MachineInstr &MI, MachineInstr *&ExtMI); void applyExtendThroughPhis(MachineInstr &MI, MachineInstr *&ExtMI); bool matchExtractVecEltBuildVec(MachineInstr &MI, Register &Reg); void applyExtractVecEltBuildVec(MachineInstr &MI, Register &Reg); bool matchExtractAllEltsFromBuildVector( MachineInstr &MI, SmallVectorImpl> &MatchInfo); void applyExtractAllEltsFromBuildVector( MachineInstr &MI, SmallVectorImpl> &MatchInfo); /// Use a function which takes in a MachineIRBuilder to perform a combine. /// By default, it erases the instruction \p MI from the function. void applyBuildFn(MachineInstr &MI, BuildFnTy &MatchInfo); /// Use a function which takes in a MachineIRBuilder to perform a combine. /// This variant does not erase \p MI after calling the build function. void applyBuildFnNoErase(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchOrShiftToFunnelShift(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchFunnelShiftToRotate(MachineInstr &MI); void applyFunnelShiftToRotate(MachineInstr &MI); bool matchRotateOutOfRange(MachineInstr &MI); void applyRotateOutOfRange(MachineInstr &MI); /// \returns true if a G_ICMP instruction \p MI can be replaced with a true /// or false constant based off of KnownBits information. bool matchICmpToTrueFalseKnownBits(MachineInstr &MI, int64_t &MatchInfo); /// \returns true if a G_ICMP \p MI can be replaced with its LHS based off of /// KnownBits information. bool matchICmpToLHSKnownBits(MachineInstr &MI, BuildFnTy &MatchInfo); /// \returns true if (and (or x, c1), c2) can be replaced with (and x, c2) bool matchAndOrDisjointMask(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchBitfieldExtractFromSExtInReg(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: and (lshr x, cst), mask -> ubfx x, cst, width bool matchBitfieldExtractFromAnd(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: shr (shl x, n), k -> sbfx/ubfx x, pos, width bool matchBitfieldExtractFromShr(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: shr (and x, n), k -> ubfx x, pos, width bool matchBitfieldExtractFromShrAnd(MachineInstr &MI, BuildFnTy &MatchInfo); // Helpers for reassociation: bool matchReassocConstantInnerRHS(GPtrAdd &MI, MachineInstr *RHS, BuildFnTy &MatchInfo); bool matchReassocFoldConstantsInSubTree(GPtrAdd &MI, MachineInstr *LHS, MachineInstr *RHS, BuildFnTy &MatchInfo); bool matchReassocConstantInnerLHS(GPtrAdd &MI, MachineInstr *LHS, MachineInstr *RHS, BuildFnTy &MatchInfo); /// Reassociate pointer calculations with G_ADD involved, to allow better /// addressing mode usage. bool matchReassocPtrAdd(MachineInstr &MI, BuildFnTy &MatchInfo); /// Try to reassociate to reassociate operands of a commutative binop. bool tryReassocBinOp(unsigned Opc, Register DstReg, Register Op0, Register Op1, BuildFnTy &MatchInfo); /// Reassociate commutative binary operations like G_ADD. bool matchReassocCommBinOp(MachineInstr &MI, BuildFnTy &MatchInfo); /// Do constant folding when opportunities are exposed after MIR building. bool matchConstantFoldCastOp(MachineInstr &MI, APInt &MatchInfo); /// Do constant folding when opportunities are exposed after MIR building. bool matchConstantFoldBinOp(MachineInstr &MI, APInt &MatchInfo); /// Do constant FP folding when opportunities are exposed after MIR building. bool matchConstantFoldFPBinOp(MachineInstr &MI, ConstantFP* &MatchInfo); /// Constant fold G_FMA/G_FMAD. bool matchConstantFoldFMA(MachineInstr &MI, ConstantFP *&MatchInfo); /// \returns true if it is possible to narrow the width of a scalar binop /// feeding a G_AND instruction \p MI. bool matchNarrowBinopFeedingAnd(MachineInstr &MI, BuildFnTy &MatchInfo); /// Given an G_UDIV \p MI expressing a divide by constant, return an /// expression that implements it by multiplying by a magic number. /// Ref: "Hacker's Delight" or "The PowerPC Compiler Writer's Guide". MachineInstr *buildUDivUsingMul(MachineInstr &MI); /// Combine G_UDIV by constant into a multiply by magic constant. bool matchUDivByConst(MachineInstr &MI); void applyUDivByConst(MachineInstr &MI); /// Given an G_SDIV \p MI expressing a signed divide by constant, return an /// expression that implements it by multiplying by a magic number. /// Ref: "Hacker's Delight" or "The PowerPC Compiler Writer's Guide". MachineInstr *buildSDivUsingMul(MachineInstr &MI); bool matchSDivByConst(MachineInstr &MI); void applySDivByConst(MachineInstr &MI); // G_UMULH x, (1 << c)) -> x >> (bitwidth - c) bool matchUMulHToLShr(MachineInstr &MI); void applyUMulHToLShr(MachineInstr &MI); /// Try to transform \p MI by using all of the above /// combine functions. Returns true if changed. bool tryCombine(MachineInstr &MI); /// Emit loads and stores that perform the given memcpy. /// Assumes \p MI is a G_MEMCPY_INLINE /// TODO: implement dynamically sized inline memcpy, /// and rename: s/bool tryEmit/void emit/ bool tryEmitMemcpyInline(MachineInstr &MI); /// Match: /// (G_UMULO x, 2) -> (G_UADDO x, x) /// (G_SMULO x, 2) -> (G_SADDO x, x) bool matchMulOBy2(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: /// (G_*MULO x, 0) -> 0 + no carry out bool matchMulOBy0(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: /// (G_*ADDO x, 0) -> x + no carry out bool matchAddOBy0(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match: /// (G_*ADDE x, y, 0) -> (G_*ADDO x, y) /// (G_*SUBE x, y, 0) -> (G_*SUBO x, y) bool matchAddEToAddO(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fadd x, fneg(y)) -> (fsub x, y) /// (fadd fneg(x), y) -> (fsub y, x) /// (fsub x, fneg(y)) -> (fadd x, y) /// (fmul fneg(x), fneg(y)) -> (fmul x, y) /// (fdiv fneg(x), fneg(y)) -> (fdiv x, y) /// (fmad fneg(x), fneg(y), z) -> (fmad x, y, z) /// (fma fneg(x), fneg(y), z) -> (fma x, y, z) bool matchRedundantNegOperands(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchFsubToFneg(MachineInstr &MI, Register &MatchInfo); void applyFsubToFneg(MachineInstr &MI, Register &MatchInfo); bool canCombineFMadOrFMA(MachineInstr &MI, bool &AllowFusionGlobally, bool &HasFMAD, bool &Aggressive, bool CanReassociate = false); /// Transform (fadd (fmul x, y), z) -> (fma x, y, z) /// (fadd (fmul x, y), z) -> (fmad x, y, z) bool matchCombineFAddFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fadd (fpext (fmul x, y)), z) -> (fma (fpext x), (fpext y), z) /// (fadd (fpext (fmul x, y)), z) -> (fmad (fpext x), (fpext y), z) bool matchCombineFAddFpExtFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fadd (fma x, y, (fmul u, v)), z) -> (fma x, y, (fma u, v, z)) /// (fadd (fmad x, y, (fmul u, v)), z) -> (fmad x, y, (fmad u, v, z)) bool matchCombineFAddFMAFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); // Transform (fadd (fma x, y, (fpext (fmul u, v))), z) // -> (fma x, y, (fma (fpext u), (fpext v), z)) // (fadd (fmad x, y, (fpext (fmul u, v))), z) // -> (fmad x, y, (fmad (fpext u), (fpext v), z)) bool matchCombineFAddFpExtFMulToFMadOrFMAAggressive(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fsub (fmul x, y), z) -> (fma x, y, -z) /// (fsub (fmul x, y), z) -> (fmad x, y, -z) bool matchCombineFSubFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fsub (fneg (fmul, x, y)), z) -> (fma (fneg x), y, (fneg z)) /// (fsub (fneg (fmul, x, y)), z) -> (fmad (fneg x), y, (fneg z)) bool matchCombineFSubFNegFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fsub (fpext (fmul x, y)), z) /// -> (fma (fpext x), (fpext y), (fneg z)) /// (fsub (fpext (fmul x, y)), z) /// -> (fmad (fpext x), (fpext y), (fneg z)) bool matchCombineFSubFpExtFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform (fsub (fpext (fneg (fmul x, y))), z) /// -> (fneg (fma (fpext x), (fpext y), z)) /// (fsub (fpext (fneg (fmul x, y))), z) /// -> (fneg (fmad (fpext x), (fpext y), z)) bool matchCombineFSubFpExtFNegFMulToFMadOrFMA(MachineInstr &MI, BuildFnTy &MatchInfo); bool matchCombineFMinMaxNaN(MachineInstr &MI, unsigned &Info); /// Transform G_ADD(x, G_SUB(y, x)) to y. /// Transform G_ADD(G_SUB(y, x), x) to y. bool matchAddSubSameReg(MachineInstr &MI, Register &Src); bool matchBuildVectorIdentityFold(MachineInstr &MI, Register &MatchInfo); bool matchTruncBuildVectorFold(MachineInstr &MI, Register &MatchInfo); bool matchTruncLshrBuildVectorFold(MachineInstr &MI, Register &MatchInfo); /// Transform: /// (x + y) - y -> x /// (x + y) - x -> y /// x - (y + x) -> 0 - y /// x - (x + z) -> 0 - z bool matchSubAddSameReg(MachineInstr &MI, BuildFnTy &MatchInfo); /// \returns true if it is possible to simplify a select instruction \p MI /// to a min/max instruction of some sort. bool matchSimplifySelectToMinMax(MachineInstr &MI, BuildFnTy &MatchInfo); /// Transform: /// (X + Y) == X -> Y == 0 /// (X - Y) == X -> Y == 0 /// (X ^ Y) == X -> Y == 0 /// (X + Y) != X -> Y != 0 /// (X - Y) != X -> Y != 0 /// (X ^ Y) != X -> Y != 0 bool matchRedundantBinOpInEquality(MachineInstr &MI, BuildFnTy &MatchInfo); /// Match shifts greater or equal to the bitwidth of the operation. bool matchShiftsTooBig(MachineInstr &MI); /// Match constant LHS ops that should be commuted. bool matchCommuteConstantToRHS(MachineInstr &MI); /// Match constant LHS FP ops that should be commuted. bool matchCommuteFPConstantToRHS(MachineInstr &MI); // Given a binop \p MI, commute operands 1 and 2. void applyCommuteBinOpOperands(MachineInstr &MI); /// Combine selects. bool matchSelect(MachineInstr &MI, BuildFnTy &MatchInfo); private: /// Checks for legality of an indexed variant of \p LdSt. bool isIndexedLoadStoreLegal(GLoadStore &LdSt) const; /// Given a non-indexed load or store instruction \p MI, find an offset that /// can be usefully and legally folded into it as a post-indexing operation. /// /// \returns true if a candidate is found. bool findPostIndexCandidate(GLoadStore &MI, Register &Addr, Register &Base, Register &Offset, bool &RematOffset); /// Given a non-indexed load or store instruction \p MI, find an offset that /// can be usefully and legally folded into it as a pre-indexing operation. /// /// \returns true if a candidate is found. bool findPreIndexCandidate(GLoadStore &MI, Register &Addr, Register &Base, Register &Offset); /// Helper function for matchLoadOrCombine. Searches for Registers /// which may have been produced by a load instruction + some arithmetic. /// /// \param [in] Root - The search root. /// /// \returns The Registers found during the search. std::optional> findCandidatesForLoadOrCombine(const MachineInstr *Root) const; /// Helper function for matchLoadOrCombine. /// /// Checks if every register in \p RegsToVisit is defined by a load /// instruction + some arithmetic. /// /// \param [out] MemOffset2Idx - Maps the byte positions each load ends up /// at to the index of the load. /// \param [in] MemSizeInBits - The number of bits each load should produce. /// /// \returns On success, a 3-tuple containing lowest-index load found, the /// lowest index, and the last load in the sequence. std::optional> findLoadOffsetsForLoadOrCombine( SmallDenseMap &MemOffset2Idx, const SmallVector &RegsToVisit, const unsigned MemSizeInBits); /// Examines the G_PTR_ADD instruction \p PtrAdd and determines if performing /// a re-association of its operands would break an existing legal addressing /// mode that the address computation currently represents. bool reassociationCanBreakAddressingModePattern(MachineInstr &PtrAdd); /// Behavior when a floating point min/max is given one NaN and one /// non-NaN as input. enum class SelectPatternNaNBehaviour { NOT_APPLICABLE = 0, /// NaN behavior not applicable. RETURNS_NAN, /// Given one NaN input, returns the NaN. RETURNS_OTHER, /// Given one NaN input, returns the non-NaN. RETURNS_ANY /// Given one NaN input, can return either (or both operands are /// known non-NaN.) }; /// \returns which of \p LHS and \p RHS would be the result of a non-equality /// floating point comparison where one of \p LHS and \p RHS may be NaN. /// /// If both \p LHS and \p RHS may be NaN, returns /// SelectPatternNaNBehaviour::NOT_APPLICABLE. SelectPatternNaNBehaviour computeRetValAgainstNaN(Register LHS, Register RHS, bool IsOrderedComparison) const; /// Determines the floating point min/max opcode which should be used for /// a G_SELECT fed by a G_FCMP with predicate \p Pred. /// /// \returns 0 if this G_SELECT should not be combined to a floating point /// min or max. If it should be combined, returns one of /// /// * G_FMAXNUM /// * G_FMAXIMUM /// * G_FMINNUM /// * G_FMINIMUM /// /// Helper function for matchFPSelectToMinMax. unsigned getFPMinMaxOpcForSelect(CmpInst::Predicate Pred, LLT DstTy, SelectPatternNaNBehaviour VsNaNRetVal) const; /// Handle floating point cases for matchSimplifySelectToMinMax. /// /// E.g. /// /// select (fcmp uge x, 1.0) x, 1.0 -> fmax x, 1.0 /// select (fcmp uge x, 1.0) 1.0, x -> fminnm x, 1.0 bool matchFPSelectToMinMax(Register Dst, Register Cond, Register TrueVal, Register FalseVal, BuildFnTy &MatchInfo); /// Try to fold selects to logical operations. bool tryFoldBoolSelectToLogic(GSelect *Select, BuildFnTy &MatchInfo); bool tryFoldSelectOfConstants(GSelect *Select, BuildFnTy &MatchInfo); /// Try to fold (icmp X, Y) ? X : Y -> integer minmax. bool tryFoldSelectToIntMinMax(GSelect *Select, BuildFnTy &MatchInfo); bool isOneOrOneSplat(Register Src, bool AllowUndefs); bool isZeroOrZeroSplat(Register Src, bool AllowUndefs); bool isConstantSplatVector(Register Src, int64_t SplatValue, bool AllowUndefs); std::optional getConstantOrConstantSplatVector(Register Src); }; } // namespace llvm #endif