//===- llvm/CodeGen/GlobalISel/InstructionSelector.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 declares the API for the instruction selector. /// This class is responsible for selecting machine instructions. /// It's implemented by the target. It's used by the InstructionSelect pass. // //===----------------------------------------------------------------------===// #ifndef LLVM_CODEGEN_GLOBALISEL_INSTRUCTIONSELECTOR_H #define LLVM_CODEGEN_GLOBALISEL_INSTRUCTIONSELECTOR_H #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Support/CodeGenCoverage.h" #include "llvm/Support/LowLevelTypeImpl.h" #include #include #include #include #include #include namespace llvm { class APInt; class APFloat; class GISelKnownBits; class MachineInstr; class MachineInstrBuilder; class MachineFunction; class MachineOperand; class MachineRegisterInfo; class RegisterBankInfo; class TargetInstrInfo; class TargetRegisterClass; class TargetRegisterInfo; /// Container class for CodeGen predicate results. /// This is convenient because std::bitset does not have a constructor /// with an initializer list of set bits. /// /// Each InstructionSelector subclass should define a PredicateBitset class /// with: /// const unsigned MAX_SUBTARGET_PREDICATES = 192; /// using PredicateBitset = PredicateBitsetImpl; /// and updating the constant to suit the target. Tablegen provides a suitable /// definition for the predicates in use in GenGlobalISel.inc when /// GET_GLOBALISEL_PREDICATE_BITSET is defined. template class PredicateBitsetImpl : public std::bitset { public: // Cannot inherit constructors because it's not supported by VC++.. PredicateBitsetImpl() = default; PredicateBitsetImpl(const std::bitset &B) : std::bitset(B) {} PredicateBitsetImpl(std::initializer_list Init) { for (auto I : Init) std::bitset::set(I); } }; enum { /// Begin a try-block to attempt a match and jump to OnFail if it is /// unsuccessful. /// - OnFail - The MatchTable entry at which to resume if the match fails. /// /// FIXME: This ought to take an argument indicating the number of try-blocks /// to exit on failure. It's usually one but the last match attempt of /// a block will need more. The (implemented) alternative is to tack a /// GIM_Reject on the end of each try-block which is simpler but /// requires an extra opcode and iteration in the interpreter on each /// failed match. GIM_Try, /// Switch over the opcode on the specified instruction /// - InsnID - Instruction ID /// - LowerBound - numerically minimum opcode supported /// - UpperBound - numerically maximum + 1 opcode supported /// - Default - failure jump target /// - JumpTable... - (UpperBound - LowerBound) (at least 2) jump targets GIM_SwitchOpcode, /// Switch over the LLT on the specified instruction operand /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - LowerBound - numerically minimum Type ID supported /// - UpperBound - numerically maximum + 1 Type ID supported /// - Default - failure jump target /// - JumpTable... - (UpperBound - LowerBound) (at least 2) jump targets GIM_SwitchType, /// Record the specified instruction /// - NewInsnID - Instruction ID to define /// - InsnID - Instruction ID /// - OpIdx - Operand index GIM_RecordInsn, /// Check the feature bits /// - Expected features GIM_CheckFeatures, /// Check the opcode on the specified instruction /// - InsnID - Instruction ID /// - Expected opcode GIM_CheckOpcode, /// Check the opcode on the specified instruction, checking 2 acceptable /// alternatives. /// - InsnID - Instruction ID /// - Expected opcode /// - Alternative expected opcode GIM_CheckOpcodeIsEither, /// Check the instruction has the right number of operands /// - InsnID - Instruction ID /// - Expected number of operands GIM_CheckNumOperands, /// Check an immediate predicate on the specified instruction /// - InsnID - Instruction ID /// - The predicate to test GIM_CheckI64ImmPredicate, /// Check an immediate predicate on the specified instruction via an APInt. /// - InsnID - Instruction ID /// - The predicate to test GIM_CheckAPIntImmPredicate, /// Check a floating point immediate predicate on the specified instruction. /// - InsnID - Instruction ID /// - The predicate to test GIM_CheckAPFloatImmPredicate, /// Check a memory operation has the specified atomic ordering. /// - InsnID - Instruction ID /// - Ordering - The AtomicOrdering value GIM_CheckAtomicOrdering, GIM_CheckAtomicOrderingOrStrongerThan, GIM_CheckAtomicOrderingWeakerThan, /// Check the size of the memory access for the given machine memory operand. /// - InsnID - Instruction ID /// - MMOIdx - MMO index /// - Size - The size in bytes of the memory access GIM_CheckMemorySizeEqualTo, /// Check the address space of the memory access for the given machine memory /// operand. /// - InsnID - Instruction ID /// - MMOIdx - MMO index /// - NumAddrSpace - Number of valid address spaces /// - AddrSpaceN - An allowed space of the memory access /// - AddrSpaceN+1 ... GIM_CheckMemoryAddressSpace, /// Check the minimum alignment of the memory access for the given machine /// memory operand. /// - InsnID - Instruction ID /// - MMOIdx - MMO index /// - MinAlign - Minimum acceptable alignment GIM_CheckMemoryAlignment, /// Check the size of the memory access for the given machine memory operand /// against the size of an operand. /// - InsnID - Instruction ID /// - MMOIdx - MMO index /// - OpIdx - The operand index to compare the MMO against GIM_CheckMemorySizeEqualToLLT, GIM_CheckMemorySizeLessThanLLT, GIM_CheckMemorySizeGreaterThanLLT, /// Check if this is a vector that can be treated as a vector splat /// constant. This is valid for both G_BUILD_VECTOR as well as /// G_BUILD_VECTOR_TRUNC. For AllOnes refers to individual bits, so a -1 /// element. /// - InsnID - Instruction ID GIM_CheckIsBuildVectorAllOnes, GIM_CheckIsBuildVectorAllZeros, /// Check a generic C++ instruction predicate /// - InsnID - Instruction ID /// - PredicateID - The ID of the predicate function to call GIM_CheckCxxInsnPredicate, /// Check the type for the specified operand /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected type GIM_CheckType, /// Check the type of a pointer to any address space. /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - SizeInBits - The size of the pointer value in bits. GIM_CheckPointerToAny, /// Check the register bank for the specified operand /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected register bank (specified as a register class) GIM_CheckRegBankForClass, /// Check the operand matches a complex predicate /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - RendererID - The renderer to hold the result /// - Complex predicate ID GIM_CheckComplexPattern, /// Check the operand is a specific integer /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected integer GIM_CheckConstantInt, /// Check the operand is a specific literal integer (i.e. MO.isImm() or /// MO.isCImm() is true). /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected integer GIM_CheckLiteralInt, /// Check the operand is a specific intrinsic ID /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected Intrinsic ID GIM_CheckIntrinsicID, /// Check the operand is a specific predicate /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - Expected predicate GIM_CheckCmpPredicate, /// Check the specified operand is an MBB /// - InsnID - Instruction ID /// - OpIdx - Operand index GIM_CheckIsMBB, /// Check the specified operand is an Imm /// - InsnID - Instruction ID /// - OpIdx - Operand index GIM_CheckIsImm, /// Check if the specified operand is safe to fold into the current /// instruction. /// - InsnID - Instruction ID GIM_CheckIsSafeToFold, /// Check the specified operands are identical. /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - OtherInsnID - Other instruction ID /// - OtherOpIdx - Other operand index GIM_CheckIsSameOperand, /// Predicates with 'let PredicateCodeUsesOperands = 1' need to examine some /// named operands that will be recorded in RecordedOperands. Names of these /// operands are referenced in predicate argument list. Emitter determines /// StoreIdx(corresponds to the order in which names appear in argument list). /// - InsnID - Instruction ID /// - OpIdx - Operand index /// - StoreIdx - Store location in RecordedOperands. GIM_RecordNamedOperand, /// Fail the current try-block, or completely fail to match if there is no /// current try-block. GIM_Reject, //=== Renderers === /// Mutate an instruction /// - NewInsnID - Instruction ID to define /// - OldInsnID - Instruction ID to mutate /// - NewOpcode - The new opcode to use GIR_MutateOpcode, /// Build a new instruction /// - InsnID - Instruction ID to define /// - Opcode - The new opcode to use GIR_BuildMI, /// Copy an operand to the specified instruction /// - NewInsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to copy from /// - OpIdx - The operand to copy GIR_Copy, /// Copy an operand to the specified instruction or add a zero register if the /// operand is a zero immediate. /// - NewInsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to copy from /// - OpIdx - The operand to copy /// - ZeroReg - The zero register to use GIR_CopyOrAddZeroReg, /// Copy an operand to the specified instruction /// - NewInsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to copy from /// - OpIdx - The operand to copy /// - SubRegIdx - The subregister to copy GIR_CopySubReg, /// Add an implicit register def to the specified instruction /// - InsnID - Instruction ID to modify /// - RegNum - The register to add GIR_AddImplicitDef, /// Add an implicit register use to the specified instruction /// - InsnID - Instruction ID to modify /// - RegNum - The register to add GIR_AddImplicitUse, /// Add an register to the specified instruction /// - InsnID - Instruction ID to modify /// - RegNum - The register to add GIR_AddRegister, /// Add a temporary register to the specified instruction /// - InsnID - Instruction ID to modify /// - TempRegID - The temporary register ID to add /// - TempRegFlags - The register flags to set GIR_AddTempRegister, /// Add a temporary register to the specified instruction /// - InsnID - Instruction ID to modify /// - TempRegID - The temporary register ID to add /// - TempRegFlags - The register flags to set /// - SubRegIndex - The subregister index to set GIR_AddTempSubRegister, /// Add an immediate to the specified instruction /// - InsnID - Instruction ID to modify /// - Imm - The immediate to add GIR_AddImm, /// Render complex operands to the specified instruction /// - InsnID - Instruction ID to modify /// - RendererID - The renderer to call GIR_ComplexRenderer, /// Render sub-operands of complex operands to the specified instruction /// - InsnID - Instruction ID to modify /// - RendererID - The renderer to call /// - RenderOpID - The suboperand to render. GIR_ComplexSubOperandRenderer, /// Render operands to the specified instruction using a custom function /// - InsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to get the matched operand from /// - RendererFnID - Custom renderer function to call GIR_CustomRenderer, /// Render operands to the specified instruction using a custom function, /// reading from a specific operand. /// - InsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to get the matched operand from /// - OpIdx - Operand index in OldInsnID the render function should read from.. /// - RendererFnID - Custom renderer function to call GIR_CustomOperandRenderer, /// Render a G_CONSTANT operator as a sign-extended immediate. /// - NewInsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to copy from /// The operand index is implicitly 1. GIR_CopyConstantAsSImm, /// Render a G_FCONSTANT operator as a sign-extended immediate. /// - NewInsnID - Instruction ID to modify /// - OldInsnID - Instruction ID to copy from /// The operand index is implicitly 1. GIR_CopyFConstantAsFPImm, /// Constrain an instruction operand to a register class. /// - InsnID - Instruction ID to modify /// - OpIdx - Operand index /// - RCEnum - Register class enumeration value GIR_ConstrainOperandRC, /// Constrain an instructions operands according to the instruction /// description. /// - InsnID - Instruction ID to modify GIR_ConstrainSelectedInstOperands, /// Merge all memory operands into instruction. /// - InsnID - Instruction ID to modify /// - MergeInsnID... - One or more Instruction ID to merge into the result. /// - GIU_MergeMemOperands_EndOfList - Terminates the list of instructions to /// merge. GIR_MergeMemOperands, /// Erase from parent. /// - InsnID - Instruction ID to erase GIR_EraseFromParent, /// Create a new temporary register that's not constrained. /// - TempRegID - The temporary register ID to initialize. /// - Expected type GIR_MakeTempReg, /// A successful emission GIR_Done, /// Increment the rule coverage counter. /// - RuleID - The ID of the rule that was covered. GIR_Coverage, /// Keeping track of the number of the GI opcodes. Must be the last entry. GIU_NumOpcodes, }; enum { /// Indicates the end of the variable-length MergeInsnID list in a /// GIR_MergeMemOperands opcode. GIU_MergeMemOperands_EndOfList = -1, }; /// Provides the logic to select generic machine instructions. class InstructionSelector { public: virtual ~InstructionSelector() = default; /// Select the (possibly generic) instruction \p I to only use target-specific /// opcodes. It is OK to insert multiple instructions, but they cannot be /// generic pre-isel instructions. /// /// \returns whether selection succeeded. /// \pre I.getParent() && I.getParent()->getParent() /// \post /// if returns true: /// for I in all mutated/inserted instructions: /// !isPreISelGenericOpcode(I.getOpcode()) virtual bool select(MachineInstr &I) = 0; CodeGenCoverage *CoverageInfo = nullptr; GISelKnownBits *KnownBits = nullptr; MachineFunction *MF = nullptr; virtual void setupGeneratedPerFunctionState(MachineFunction &MF) { llvm_unreachable("TableGen should have emitted implementation"); } /// Setup per-MF selector state. virtual void setupMF(MachineFunction &mf, GISelKnownBits &KB, CodeGenCoverage &covinfo) { CoverageInfo = &covinfo; KnownBits = &KB; MF = &mf; setupGeneratedPerFunctionState(mf); } protected: using ComplexRendererFns = Optional, 4>>; using RecordedMIVector = SmallVector; using NewMIVector = SmallVector; struct MatcherState { std::vector Renderers; RecordedMIVector MIs; DenseMap TempRegisters; /// Named operands that predicate with 'let PredicateCodeUsesOperands = 1' /// referenced in its argument list. Operands are inserted at index set by /// emitter, it corresponds to the order in which names appear in argument /// list. Currently such predicates don't have more then 3 arguments. std::array RecordedOperands; MatcherState(unsigned MaxRenderers); }; public: template struct ISelInfoTy { ISelInfoTy(const LLT *TypeObjects, size_t NumTypeObjects, const PredicateBitset *FeatureBitsets, const ComplexMatcherMemFn *ComplexPredicates, const CustomRendererFn *CustomRenderers) : TypeObjects(TypeObjects), FeatureBitsets(FeatureBitsets), ComplexPredicates(ComplexPredicates), CustomRenderers(CustomRenderers) { for (size_t I = 0; I < NumTypeObjects; ++I) TypeIDMap[TypeObjects[I]] = I; } const LLT *TypeObjects; const PredicateBitset *FeatureBitsets; const ComplexMatcherMemFn *ComplexPredicates; const CustomRendererFn *CustomRenderers; SmallDenseMap TypeIDMap; }; protected: InstructionSelector(); /// Execute a given matcher table and return true if the match was successful /// and false otherwise. template bool executeMatchTable( TgtInstructionSelector &ISel, NewMIVector &OutMIs, MatcherState &State, const ISelInfoTy &ISelInfo, const int64_t *MatchTable, const TargetInstrInfo &TII, MachineRegisterInfo &MRI, const TargetRegisterInfo &TRI, const RegisterBankInfo &RBI, const PredicateBitset &AvailableFeatures, CodeGenCoverage &CoverageInfo) const; virtual const int64_t *getMatchTable() const { llvm_unreachable("Should have been overridden by tablegen if used"); } virtual bool testImmPredicate_I64(unsigned, int64_t) const { llvm_unreachable( "Subclasses must override this with a tablegen-erated function"); } virtual bool testImmPredicate_APInt(unsigned, const APInt &) const { llvm_unreachable( "Subclasses must override this with a tablegen-erated function"); } virtual bool testImmPredicate_APFloat(unsigned, const APFloat &) const { llvm_unreachable( "Subclasses must override this with a tablegen-erated function"); } virtual bool testMIPredicate_MI( unsigned, const MachineInstr &, const std::array &Operands) const { llvm_unreachable( "Subclasses must override this with a tablegen-erated function"); } bool isOperandImmEqual(const MachineOperand &MO, int64_t Value, const MachineRegisterInfo &MRI) const; /// Return true if the specified operand is a G_PTR_ADD with a G_CONSTANT on the /// right-hand side. GlobalISel's separation of pointer and integer types /// means that we don't need to worry about G_OR with equivalent semantics. bool isBaseWithConstantOffset(const MachineOperand &Root, const MachineRegisterInfo &MRI) const; /// Return true if MI can obviously be folded into IntoMI. /// MI and IntoMI do not need to be in the same basic blocks, but MI must /// preceed IntoMI. bool isObviouslySafeToFold(MachineInstr &MI, MachineInstr &IntoMI) const; }; } // end namespace llvm #endif // LLVM_CODEGEN_GLOBALISEL_INSTRUCTIONSELECTOR_H