//===- TargetTransformInfo.h ------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// \file /// This pass exposes codegen information to IR-level passes. Every /// transformation that uses codegen information is broken into three parts: /// 1. The IR-level analysis pass. /// 2. The IR-level transformation interface which provides the needed /// information. /// 3. Codegen-level implementation which uses target-specific hooks. /// /// This file defines #2, which is the interface that IR-level transformations /// use for querying the codegen. /// //===----------------------------------------------------------------------===// #ifndef LLVM_ANALYSIS_TARGETTRANSFORMINFO_H #define LLVM_ANALYSIS_TARGETTRANSFORMINFO_H #include "llvm/ADT/Optional.h" #include "llvm/IR/Operator.h" #include "llvm/IR/PassManager.h" #include "llvm/Pass.h" #include "llvm/Support/AtomicOrdering.h" #include "llvm/Support/DataTypes.h" #include <functional> namespace llvm { namespace Intrinsic { enum ID : unsigned; } class Function; class GlobalValue; class IntrinsicInst; class LoadInst; class Loop; class SCEV; class ScalarEvolution; class StoreInst; class SwitchInst; class Type; class User; class Value; /// Information about a load/store intrinsic defined by the target. struct MemIntrinsicInfo { /// This is the pointer that the intrinsic is loading from or storing to. /// If this is non-null, then analysis/optimization passes can assume that /// this intrinsic is functionally equivalent to a load/store from this /// pointer. Value *PtrVal = nullptr; // Ordering for atomic operations. AtomicOrdering Ordering = AtomicOrdering::NotAtomic; // Same Id is set by the target for corresponding load/store intrinsics. unsigned short MatchingId = 0; bool ReadMem = false; bool WriteMem = false; bool IsVolatile = false; bool isUnordered() const { return (Ordering == AtomicOrdering::NotAtomic || Ordering == AtomicOrdering::Unordered) && !IsVolatile; } }; /// This pass provides access to the codegen interfaces that are needed /// for IR-level transformations. class TargetTransformInfo { public: /// Construct a TTI object using a type implementing the \c Concept /// API below. /// /// This is used by targets to construct a TTI wrapping their target-specific /// implementaion that encodes appropriate costs for their target. template <typename T> TargetTransformInfo(T Impl); /// Construct a baseline TTI object using a minimal implementation of /// the \c Concept API below. /// /// The TTI implementation will reflect the information in the DataLayout /// provided if non-null. explicit TargetTransformInfo(const DataLayout &DL); // Provide move semantics. TargetTransformInfo(TargetTransformInfo &&Arg); TargetTransformInfo &operator=(TargetTransformInfo &&RHS); // We need to define the destructor out-of-line to define our sub-classes // out-of-line. ~TargetTransformInfo(); /// Handle the invalidation of this information. /// /// When used as a result of \c TargetIRAnalysis this method will be called /// when the function this was computed for changes. When it returns false, /// the information is preserved across those changes. bool invalidate(Function &, const PreservedAnalyses &, FunctionAnalysisManager::Invalidator &) { // FIXME: We should probably in some way ensure that the subtarget // information for a function hasn't changed. return false; } /// \name Generic Target Information /// @{ /// The kind of cost model. /// /// There are several different cost models that can be customized by the /// target. The normalization of each cost model may be target specific. enum TargetCostKind { TCK_RecipThroughput, ///< Reciprocal throughput. TCK_Latency, ///< The latency of instruction. TCK_CodeSize ///< Instruction code size. }; /// Query the cost of a specified instruction. /// /// Clients should use this interface to query the cost of an existing /// instruction. The instruction must have a valid parent (basic block). /// /// Note, this method does not cache the cost calculation and it /// can be expensive in some cases. int getInstructionCost(const Instruction *I, enum TargetCostKind kind) const { switch (kind){ case TCK_RecipThroughput: return getInstructionThroughput(I); case TCK_Latency: return getInstructionLatency(I); case TCK_CodeSize: return getUserCost(I); } llvm_unreachable("Unknown instruction cost kind"); } /// Underlying constants for 'cost' values in this interface. /// /// Many APIs in this interface return a cost. This enum defines the /// fundamental values that should be used to interpret (and produce) those /// costs. The costs are returned as an int rather than a member of this /// enumeration because it is expected that the cost of one IR instruction /// may have a multiplicative factor to it or otherwise won't fit directly /// into the enum. Moreover, it is common to sum or average costs which works /// better as simple integral values. Thus this enum only provides constants. /// Also note that the returned costs are signed integers to make it natural /// to add, subtract, and test with zero (a common boundary condition). It is /// not expected that 2^32 is a realistic cost to be modeling at any point. /// /// Note that these costs should usually reflect the intersection of code-size /// cost and execution cost. A free instruction is typically one that folds /// into another instruction. For example, reg-to-reg moves can often be /// skipped by renaming the registers in the CPU, but they still are encoded /// and thus wouldn't be considered 'free' here. enum TargetCostConstants { TCC_Free = 0, ///< Expected to fold away in lowering. TCC_Basic = 1, ///< The cost of a typical 'add' instruction. TCC_Expensive = 4 ///< The cost of a 'div' instruction on x86. }; /// Estimate the cost of a specific operation when lowered. /// /// Note that this is designed to work on an arbitrary synthetic opcode, and /// thus work for hypothetical queries before an instruction has even been /// formed. However, this does *not* work for GEPs, and must not be called /// for a GEP instruction. Instead, use the dedicated getGEPCost interface as /// analyzing a GEP's cost required more information. /// /// Typically only the result type is required, and the operand type can be /// omitted. However, if the opcode is one of the cast instructions, the /// operand type is required. /// /// The returned cost is defined in terms of \c TargetCostConstants, see its /// comments for a detailed explanation of the cost values. int getOperationCost(unsigned Opcode, Type *Ty, Type *OpTy = nullptr) const; /// Estimate the cost of a GEP operation when lowered. /// /// The contract for this function is the same as \c getOperationCost except /// that it supports an interface that provides extra information specific to /// the GEP operation. int getGEPCost(Type *PointeeType, const Value *Ptr, ArrayRef<const Value *> Operands) const; /// Estimate the cost of a EXT operation when lowered. /// /// The contract for this function is the same as \c getOperationCost except /// that it supports an interface that provides extra information specific to /// the EXT operation. int getExtCost(const Instruction *I, const Value *Src) const; /// Estimate the cost of a function call when lowered. /// /// The contract for this is the same as \c getOperationCost except that it /// supports an interface that provides extra information specific to call /// instructions. /// /// This is the most basic query for estimating call cost: it only knows the /// function type and (potentially) the number of arguments at the call site. /// The latter is only interesting for varargs function types. int getCallCost(FunctionType *FTy, int NumArgs = -1) const; /// Estimate the cost of calling a specific function when lowered. /// /// This overload adds the ability to reason about the particular function /// being called in the event it is a library call with special lowering. int getCallCost(const Function *F, int NumArgs = -1) const; /// Estimate the cost of calling a specific function when lowered. /// /// This overload allows specifying a set of candidate argument values. int getCallCost(const Function *F, ArrayRef<const Value *> Arguments) const; /// \returns A value by which our inlining threshold should be multiplied. /// This is primarily used to bump up the inlining threshold wholesale on /// targets where calls are unusually expensive. /// /// TODO: This is a rather blunt instrument. Perhaps altering the costs of /// individual classes of instructions would be better. unsigned getInliningThresholdMultiplier() const; /// Estimate the cost of an intrinsic when lowered. /// /// Mirrors the \c getCallCost method but uses an intrinsic identifier. int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<Type *> ParamTys) const; /// Estimate the cost of an intrinsic when lowered. /// /// Mirrors the \c getCallCost method but uses an intrinsic identifier. int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<const Value *> Arguments) const; /// \return The estimated number of case clusters when lowering \p 'SI'. /// \p JTSize Set a jump table size only when \p SI is suitable for a jump /// table. unsigned getEstimatedNumberOfCaseClusters(const SwitchInst &SI, unsigned &JTSize) const; /// Estimate the cost of a given IR user when lowered. /// /// This can estimate the cost of either a ConstantExpr or Instruction when /// lowered. It has two primary advantages over the \c getOperationCost and /// \c getGEPCost above, and one significant disadvantage: it can only be /// used when the IR construct has already been formed. /// /// The advantages are that it can inspect the SSA use graph to reason more /// accurately about the cost. For example, all-constant-GEPs can often be /// folded into a load or other instruction, but if they are used in some /// other context they may not be folded. This routine can distinguish such /// cases. /// /// \p Operands is a list of operands which can be a result of transformations /// of the current operands. The number of the operands on the list must equal /// to the number of the current operands the IR user has. Their order on the /// list must be the same as the order of the current operands the IR user /// has. /// /// The returned cost is defined in terms of \c TargetCostConstants, see its /// comments for a detailed explanation of the cost values. int getUserCost(const User *U, ArrayRef<const Value *> Operands) const; /// This is a helper function which calls the two-argument getUserCost /// with \p Operands which are the current operands U has. int getUserCost(const User *U) const { SmallVector<const Value *, 4> Operands(U->value_op_begin(), U->value_op_end()); return getUserCost(U, Operands); } /// Return true if branch divergence exists. /// /// Branch divergence has a significantly negative impact on GPU performance /// when threads in the same wavefront take different paths due to conditional /// branches. bool hasBranchDivergence() const; /// Returns whether V is a source of divergence. /// /// This function provides the target-dependent information for /// the target-independent LegacyDivergenceAnalysis. LegacyDivergenceAnalysis first /// builds the dependency graph, and then runs the reachability algorithm /// starting with the sources of divergence. bool isSourceOfDivergence(const Value *V) const; // Returns true for the target specific // set of operations which produce uniform result // even taking non-unform arguments bool isAlwaysUniform(const Value *V) const; /// Returns the address space ID for a target's 'flat' address space. Note /// this is not necessarily the same as addrspace(0), which LLVM sometimes /// refers to as the generic address space. The flat address space is a /// generic address space that can be used access multiple segments of memory /// with different address spaces. Access of a memory location through a /// pointer with this address space is expected to be legal but slower /// compared to the same memory location accessed through a pointer with a /// different address space. // /// This is for targets with different pointer representations which can /// be converted with the addrspacecast instruction. If a pointer is converted /// to this address space, optimizations should attempt to replace the access /// with the source address space. /// /// \returns ~0u if the target does not have such a flat address space to /// optimize away. unsigned getFlatAddressSpace() const; /// Test whether calls to a function lower to actual program function /// calls. /// /// The idea is to test whether the program is likely to require a 'call' /// instruction or equivalent in order to call the given function. /// /// FIXME: It's not clear that this is a good or useful query API. Client's /// should probably move to simpler cost metrics using the above. /// Alternatively, we could split the cost interface into distinct code-size /// and execution-speed costs. This would allow modelling the core of this /// query more accurately as a call is a single small instruction, but /// incurs significant execution cost. bool isLoweredToCall(const Function *F) const; struct LSRCost { /// TODO: Some of these could be merged. Also, a lexical ordering /// isn't always optimal. unsigned Insns; unsigned NumRegs; unsigned AddRecCost; unsigned NumIVMuls; unsigned NumBaseAdds; unsigned ImmCost; unsigned SetupCost; unsigned ScaleCost; }; /// Parameters that control the generic loop unrolling transformation. struct UnrollingPreferences { /// The cost threshold for the unrolled loop. Should be relative to the /// getUserCost values returned by this API, and the expectation is that /// the unrolled loop's instructions when run through that interface should /// not exceed this cost. However, this is only an estimate. Also, specific /// loops may be unrolled even with a cost above this threshold if deemed /// profitable. Set this to UINT_MAX to disable the loop body cost /// restriction. unsigned Threshold; /// If complete unrolling will reduce the cost of the loop, we will boost /// the Threshold by a certain percent to allow more aggressive complete /// unrolling. This value provides the maximum boost percentage that we /// can apply to Threshold (The value should be no less than 100). /// BoostedThreshold = Threshold * min(RolledCost / UnrolledCost, /// MaxPercentThresholdBoost / 100) /// E.g. if complete unrolling reduces the loop execution time by 50% /// then we boost the threshold by the factor of 2x. If unrolling is not /// expected to reduce the running time, then we do not increase the /// threshold. unsigned MaxPercentThresholdBoost; /// The cost threshold for the unrolled loop when optimizing for size (set /// to UINT_MAX to disable). unsigned OptSizeThreshold; /// The cost threshold for the unrolled loop, like Threshold, but used /// for partial/runtime unrolling (set to UINT_MAX to disable). unsigned PartialThreshold; /// The cost threshold for the unrolled loop when optimizing for size, like /// OptSizeThreshold, but used for partial/runtime unrolling (set to /// UINT_MAX to disable). unsigned PartialOptSizeThreshold; /// A forced unrolling factor (the number of concatenated bodies of the /// original loop in the unrolled loop body). When set to 0, the unrolling /// transformation will select an unrolling factor based on the current cost /// threshold and other factors. unsigned Count; /// A forced peeling factor (the number of bodied of the original loop /// that should be peeled off before the loop body). When set to 0, the /// unrolling transformation will select a peeling factor based on profile /// information and other factors. unsigned PeelCount; /// Default unroll count for loops with run-time trip count. unsigned DefaultUnrollRuntimeCount; // Set the maximum unrolling factor. The unrolling factor may be selected // using the appropriate cost threshold, but may not exceed this number // (set to UINT_MAX to disable). This does not apply in cases where the // loop is being fully unrolled. unsigned MaxCount; /// Set the maximum unrolling factor for full unrolling. Like MaxCount, but /// applies even if full unrolling is selected. This allows a target to fall /// back to Partial unrolling if full unrolling is above FullUnrollMaxCount. unsigned FullUnrollMaxCount; // Represents number of instructions optimized when "back edge" // becomes "fall through" in unrolled loop. // For now we count a conditional branch on a backedge and a comparison // feeding it. unsigned BEInsns; /// Allow partial unrolling (unrolling of loops to expand the size of the /// loop body, not only to eliminate small constant-trip-count loops). bool Partial; /// Allow runtime unrolling (unrolling of loops to expand the size of the /// loop body even when the number of loop iterations is not known at /// compile time). bool Runtime; /// Allow generation of a loop remainder (extra iterations after unroll). bool AllowRemainder; /// Allow emitting expensive instructions (such as divisions) when computing /// the trip count of a loop for runtime unrolling. bool AllowExpensiveTripCount; /// Apply loop unroll on any kind of loop /// (mainly to loops that fail runtime unrolling). bool Force; /// Allow using trip count upper bound to unroll loops. bool UpperBound; /// Allow peeling off loop iterations for loops with low dynamic tripcount. bool AllowPeeling; /// Allow unrolling of all the iterations of the runtime loop remainder. bool UnrollRemainder; /// Allow unroll and jam. Used to enable unroll and jam for the target. bool UnrollAndJam; /// Threshold for unroll and jam, for inner loop size. The 'Threshold' /// value above is used during unroll and jam for the outer loop size. /// This value is used in the same manner to limit the size of the inner /// loop. unsigned UnrollAndJamInnerLoopThreshold; }; /// Get target-customized preferences for the generic loop unrolling /// transformation. The caller will initialize UP with the current /// target-independent defaults. void getUnrollingPreferences(Loop *L, ScalarEvolution &, UnrollingPreferences &UP) const; /// @} /// \name Scalar Target Information /// @{ /// Flags indicating the kind of support for population count. /// /// Compared to the SW implementation, HW support is supposed to /// significantly boost the performance when the population is dense, and it /// may or may not degrade performance if the population is sparse. A HW /// support is considered as "Fast" if it can outperform, or is on a par /// with, SW implementation when the population is sparse; otherwise, it is /// considered as "Slow". enum PopcntSupportKind { PSK_Software, PSK_SlowHardware, PSK_FastHardware }; /// Return true if the specified immediate is legal add immediate, that /// is the target has add instructions which can add a register with the /// immediate without having to materialize the immediate into a register. bool isLegalAddImmediate(int64_t Imm) const; /// Return true if the specified immediate is legal icmp immediate, /// that is the target has icmp instructions which can compare a register /// against the immediate without having to materialize the immediate into a /// register. bool isLegalICmpImmediate(int64_t Imm) const; /// Return true if the addressing mode represented by AM is legal for /// this target, for a load/store of the specified type. /// The type may be VoidTy, in which case only return true if the addressing /// mode is legal for a load/store of any legal type. /// If target returns true in LSRWithInstrQueries(), I may be valid. /// TODO: Handle pre/postinc as well. bool isLegalAddressingMode(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace = 0, Instruction *I = nullptr) const; /// Return true if LSR cost of C1 is lower than C1. bool isLSRCostLess(TargetTransformInfo::LSRCost &C1, TargetTransformInfo::LSRCost &C2) const; /// Return true if the target can fuse a compare and branch. /// Loop-strength-reduction (LSR) uses that knowledge to adjust its cost /// calculation for the instructions in a loop. bool canMacroFuseCmp() const; /// \return True is LSR should make efforts to create/preserve post-inc /// addressing mode expressions. bool shouldFavorPostInc() const; /// Return true if the target supports masked load/store /// AVX2 and AVX-512 targets allow masks for consecutive load and store bool isLegalMaskedStore(Type *DataType) const; bool isLegalMaskedLoad(Type *DataType) const; /// Return true if the target supports masked gather/scatter /// AVX-512 fully supports gather and scatter for vectors with 32 and 64 /// bits scalar type. bool isLegalMaskedScatter(Type *DataType) const; bool isLegalMaskedGather(Type *DataType) const; /// Return true if the target has a unified operation to calculate division /// and remainder. If so, the additional implicit multiplication and /// subtraction required to calculate a remainder from division are free. This /// can enable more aggressive transformations for division and remainder than /// would typically be allowed using throughput or size cost models. bool hasDivRemOp(Type *DataType, bool IsSigned) const; /// Return true if the given instruction (assumed to be a memory access /// instruction) has a volatile variant. If that's the case then we can avoid /// addrspacecast to generic AS for volatile loads/stores. Default /// implementation returns false, which prevents address space inference for /// volatile loads/stores. bool hasVolatileVariant(Instruction *I, unsigned AddrSpace) const; /// Return true if target doesn't mind addresses in vectors. bool prefersVectorizedAddressing() const; /// Return the cost of the scaling factor used in the addressing /// mode represented by AM for this target, for a load/store /// of the specified type. /// If the AM is supported, the return value must be >= 0. /// If the AM is not supported, it returns a negative value. /// TODO: Handle pre/postinc as well. int getScalingFactorCost(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace = 0) const; /// Return true if the loop strength reduce pass should make /// Instruction* based TTI queries to isLegalAddressingMode(). This is /// needed on SystemZ, where e.g. a memcpy can only have a 12 bit unsigned /// immediate offset and no index register. bool LSRWithInstrQueries() const; /// Return true if it's free to truncate a value of type Ty1 to type /// Ty2. e.g. On x86 it's free to truncate a i32 value in register EAX to i16 /// by referencing its sub-register AX. bool isTruncateFree(Type *Ty1, Type *Ty2) const; /// Return true if it is profitable to hoist instruction in the /// then/else to before if. bool isProfitableToHoist(Instruction *I) const; bool useAA() const; /// Return true if this type is legal. bool isTypeLegal(Type *Ty) const; /// Returns the target's jmp_buf alignment in bytes. unsigned getJumpBufAlignment() const; /// Returns the target's jmp_buf size in bytes. unsigned getJumpBufSize() const; /// Return true if switches should be turned into lookup tables for the /// target. bool shouldBuildLookupTables() const; /// Return true if switches should be turned into lookup tables /// containing this constant value for the target. bool shouldBuildLookupTablesForConstant(Constant *C) const; /// Return true if the input function which is cold at all call sites, /// should use coldcc calling convention. bool useColdCCForColdCall(Function &F) const; unsigned getScalarizationOverhead(Type *Ty, bool Insert, bool Extract) const; unsigned getOperandsScalarizationOverhead(ArrayRef<const Value *> Args, unsigned VF) const; /// If target has efficient vector element load/store instructions, it can /// return true here so that insertion/extraction costs are not added to /// the scalarization cost of a load/store. bool supportsEfficientVectorElementLoadStore() const; /// Don't restrict interleaved unrolling to small loops. bool enableAggressiveInterleaving(bool LoopHasReductions) const; /// If not nullptr, enable inline expansion of memcmp. IsZeroCmp is /// true if this is the expansion of memcmp(p1, p2, s) == 0. struct MemCmpExpansionOptions { // The list of available load sizes (in bytes), sorted in decreasing order. SmallVector<unsigned, 8> LoadSizes; }; const MemCmpExpansionOptions *enableMemCmpExpansion(bool IsZeroCmp) const; /// Enable matching of interleaved access groups. bool enableInterleavedAccessVectorization() const; /// Enable matching of interleaved access groups that contain predicated /// accesses or gaps and therefore vectorized using masked /// vector loads/stores. bool enableMaskedInterleavedAccessVectorization() const; /// Indicate that it is potentially unsafe to automatically vectorize /// floating-point operations because the semantics of vector and scalar /// floating-point semantics may differ. For example, ARM NEON v7 SIMD math /// does not support IEEE-754 denormal numbers, while depending on the /// platform, scalar floating-point math does. /// This applies to floating-point math operations and calls, not memory /// operations, shuffles, or casts. bool isFPVectorizationPotentiallyUnsafe() const; /// Determine if the target supports unaligned memory accesses. bool allowsMisalignedMemoryAccesses(LLVMContext &Context, unsigned BitWidth, unsigned AddressSpace = 0, unsigned Alignment = 1, bool *Fast = nullptr) const; /// Return hardware support for population count. PopcntSupportKind getPopcntSupport(unsigned IntTyWidthInBit) const; /// Return true if the hardware has a fast square-root instruction. bool haveFastSqrt(Type *Ty) const; /// Return true if it is faster to check if a floating-point value is NaN /// (or not-NaN) versus a comparison against a constant FP zero value. /// Targets should override this if materializing a 0.0 for comparison is /// generally as cheap as checking for ordered/unordered. bool isFCmpOrdCheaperThanFCmpZero(Type *Ty) const; /// Return the expected cost of supporting the floating point operation /// of the specified type. int getFPOpCost(Type *Ty) const; /// Return the expected cost of materializing for the given integer /// immediate of the specified type. int getIntImmCost(const APInt &Imm, Type *Ty) const; /// Return the expected cost of materialization for the given integer /// immediate of the specified type for a given instruction. The cost can be /// zero if the immediate can be folded into the specified instruction. int getIntImmCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) const; int getIntImmCost(Intrinsic::ID IID, unsigned Idx, const APInt &Imm, Type *Ty) const; /// Return the expected cost for the given integer when optimising /// for size. This is different than the other integer immediate cost /// functions in that it is subtarget agnostic. This is useful when you e.g. /// target one ISA such as Aarch32 but smaller encodings could be possible /// with another such as Thumb. This return value is used as a penalty when /// the total costs for a constant is calculated (the bigger the cost, the /// more beneficial constant hoisting is). int getIntImmCodeSizeCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) const; /// @} /// \name Vector Target Information /// @{ /// The various kinds of shuffle patterns for vector queries. enum ShuffleKind { SK_Broadcast, ///< Broadcast element 0 to all other elements. SK_Reverse, ///< Reverse the order of the vector. SK_Select, ///< Selects elements from the corresponding lane of ///< either source operand. This is equivalent to a ///< vector select with a constant condition operand. SK_Transpose, ///< Transpose two vectors. SK_InsertSubvector, ///< InsertSubvector. Index indicates start offset. SK_ExtractSubvector,///< ExtractSubvector Index indicates start offset. SK_PermuteTwoSrc, ///< Merge elements from two source vectors into one ///< with any shuffle mask. SK_PermuteSingleSrc ///< Shuffle elements of single source vector with any ///< shuffle mask. }; /// Additional information about an operand's possible values. enum OperandValueKind { OK_AnyValue, // Operand can have any value. OK_UniformValue, // Operand is uniform (splat of a value). OK_UniformConstantValue, // Operand is uniform constant. OK_NonUniformConstantValue // Operand is a non uniform constant value. }; /// Additional properties of an operand's values. enum OperandValueProperties { OP_None = 0, OP_PowerOf2 = 1 }; /// \return The number of scalar or vector registers that the target has. /// If 'Vectors' is true, it returns the number of vector registers. If it is /// set to false, it returns the number of scalar registers. unsigned getNumberOfRegisters(bool Vector) const; /// \return The width of the largest scalar or vector register type. unsigned getRegisterBitWidth(bool Vector) const; /// \return The width of the smallest vector register type. unsigned getMinVectorRegisterBitWidth() const; /// \return True if the vectorization factor should be chosen to /// make the vector of the smallest element type match the size of a /// vector register. For wider element types, this could result in /// creating vectors that span multiple vector registers. /// If false, the vectorization factor will be chosen based on the /// size of the widest element type. bool shouldMaximizeVectorBandwidth(bool OptSize) const; /// \return The minimum vectorization factor for types of given element /// bit width, or 0 if there is no mimimum VF. The returned value only /// applies when shouldMaximizeVectorBandwidth returns true. unsigned getMinimumVF(unsigned ElemWidth) const; /// \return True if it should be considered for address type promotion. /// \p AllowPromotionWithoutCommonHeader Set true if promoting \p I is /// profitable without finding other extensions fed by the same input. bool shouldConsiderAddressTypePromotion( const Instruction &I, bool &AllowPromotionWithoutCommonHeader) const; /// \return The size of a cache line in bytes. unsigned getCacheLineSize() const; /// The possible cache levels enum class CacheLevel { L1D, // The L1 data cache L2D, // The L2 data cache // We currently do not model L3 caches, as their sizes differ widely between // microarchitectures. Also, we currently do not have a use for L3 cache // size modeling yet. }; /// \return The size of the cache level in bytes, if available. llvm::Optional<unsigned> getCacheSize(CacheLevel Level) const; /// \return The associativity of the cache level, if available. llvm::Optional<unsigned> getCacheAssociativity(CacheLevel Level) const; /// \return How much before a load we should place the prefetch instruction. /// This is currently measured in number of instructions. unsigned getPrefetchDistance() const; /// \return Some HW prefetchers can handle accesses up to a certain constant /// stride. This is the minimum stride in bytes where it makes sense to start /// adding SW prefetches. The default is 1, i.e. prefetch with any stride. unsigned getMinPrefetchStride() const; /// \return The maximum number of iterations to prefetch ahead. If the /// required number of iterations is more than this number, no prefetching is /// performed. unsigned getMaxPrefetchIterationsAhead() const; /// \return The maximum interleave factor that any transform should try to /// perform for this target. This number depends on the level of parallelism /// and the number of execution units in the CPU. unsigned getMaxInterleaveFactor(unsigned VF) const; /// Collect properties of V used in cost analysis, e.g. OP_PowerOf2. static OperandValueKind getOperandInfo(Value *V, OperandValueProperties &OpProps); /// This is an approximation of reciprocal throughput of a math/logic op. /// A higher cost indicates less expected throughput. /// From Agner Fog's guides, reciprocal throughput is "the average number of /// clock cycles per instruction when the instructions are not part of a /// limiting dependency chain." /// Therefore, costs should be scaled to account for multiple execution units /// on the target that can process this type of instruction. For example, if /// there are 5 scalar integer units and 2 vector integer units that can /// calculate an 'add' in a single cycle, this model should indicate that the /// cost of the vector add instruction is 2.5 times the cost of the scalar /// add instruction. /// \p Args is an optional argument which holds the instruction operands /// values so the TTI can analyze those values searching for special /// cases or optimizations based on those values. int getArithmeticInstrCost( unsigned Opcode, Type *Ty, OperandValueKind Opd1Info = OK_AnyValue, OperandValueKind Opd2Info = OK_AnyValue, OperandValueProperties Opd1PropInfo = OP_None, OperandValueProperties Opd2PropInfo = OP_None, ArrayRef<const Value *> Args = ArrayRef<const Value *>()) const; /// \return The cost of a shuffle instruction of kind Kind and of type Tp. /// The index and subtype parameters are used by the subvector insertion and /// extraction shuffle kinds to show the insert/extract point and the type of /// the subvector being inserted/extracted. /// NOTE: For subvector extractions Tp represents the source type. int getShuffleCost(ShuffleKind Kind, Type *Tp, int Index = 0, Type *SubTp = nullptr) const; /// \return The expected cost of cast instructions, such as bitcast, trunc, /// zext, etc. If there is an existing instruction that holds Opcode, it /// may be passed in the 'I' parameter. int getCastInstrCost(unsigned Opcode, Type *Dst, Type *Src, const Instruction *I = nullptr) const; /// \return The expected cost of a sign- or zero-extended vector extract. Use /// -1 to indicate that there is no information about the index value. int getExtractWithExtendCost(unsigned Opcode, Type *Dst, VectorType *VecTy, unsigned Index = -1) const; /// \return The expected cost of control-flow related instructions such as /// Phi, Ret, Br. int getCFInstrCost(unsigned Opcode) const; /// \returns The expected cost of compare and select instructions. If there /// is an existing instruction that holds Opcode, it may be passed in the /// 'I' parameter. int getCmpSelInstrCost(unsigned Opcode, Type *ValTy, Type *CondTy = nullptr, const Instruction *I = nullptr) const; /// \return The expected cost of vector Insert and Extract. /// Use -1 to indicate that there is no information on the index value. int getVectorInstrCost(unsigned Opcode, Type *Val, unsigned Index = -1) const; /// \return The cost of Load and Store instructions. int getMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace, const Instruction *I = nullptr) const; /// \return The cost of masked Load and Store instructions. int getMaskedMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace) const; /// \return The cost of Gather or Scatter operation /// \p Opcode - is a type of memory access Load or Store /// \p DataTy - a vector type of the data to be loaded or stored /// \p Ptr - pointer [or vector of pointers] - address[es] in memory /// \p VariableMask - true when the memory access is predicated with a mask /// that is not a compile-time constant /// \p Alignment - alignment of single element int getGatherScatterOpCost(unsigned Opcode, Type *DataTy, Value *Ptr, bool VariableMask, unsigned Alignment) const; /// \return The cost of the interleaved memory operation. /// \p Opcode is the memory operation code /// \p VecTy is the vector type of the interleaved access. /// \p Factor is the interleave factor /// \p Indices is the indices for interleaved load members (as interleaved /// load allows gaps) /// \p Alignment is the alignment of the memory operation /// \p AddressSpace is address space of the pointer. /// \p UseMaskForCond indicates if the memory access is predicated. /// \p UseMaskForGaps indicates if gaps should be masked. int getInterleavedMemoryOpCost(unsigned Opcode, Type *VecTy, unsigned Factor, ArrayRef<unsigned> Indices, unsigned Alignment, unsigned AddressSpace, bool UseMaskForCond = false, bool UseMaskForGaps = false) const; /// Calculate the cost of performing a vector reduction. /// /// This is the cost of reducing the vector value of type \p Ty to a scalar /// value using the operation denoted by \p Opcode. The form of the reduction /// can either be a pairwise reduction or a reduction that splits the vector /// at every reduction level. /// /// Pairwise: /// (v0, v1, v2, v3) /// ((v0+v1), (v2+v3), undef, undef) /// Split: /// (v0, v1, v2, v3) /// ((v0+v2), (v1+v3), undef, undef) int getArithmeticReductionCost(unsigned Opcode, Type *Ty, bool IsPairwiseForm) const; int getMinMaxReductionCost(Type *Ty, Type *CondTy, bool IsPairwiseForm, bool IsUnsigned) const; /// \returns The cost of Intrinsic instructions. Analyses the real arguments. /// Three cases are handled: 1. scalar instruction 2. vector instruction /// 3. scalar instruction which is to be vectorized with VF. int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Value *> Args, FastMathFlags FMF, unsigned VF = 1) const; /// \returns The cost of Intrinsic instructions. Types analysis only. /// If ScalarizationCostPassed is UINT_MAX, the cost of scalarizing the /// arguments and the return value will be computed based on types. int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Type *> Tys, FastMathFlags FMF, unsigned ScalarizationCostPassed = UINT_MAX) const; /// \returns The cost of Call instructions. int getCallInstrCost(Function *F, Type *RetTy, ArrayRef<Type *> Tys) const; /// \returns The number of pieces into which the provided type must be /// split during legalization. Zero is returned when the answer is unknown. unsigned getNumberOfParts(Type *Tp) const; /// \returns The cost of the address computation. For most targets this can be /// merged into the instruction indexing mode. Some targets might want to /// distinguish between address computation for memory operations on vector /// types and scalar types. Such targets should override this function. /// The 'SE' parameter holds pointer for the scalar evolution object which /// is used in order to get the Ptr step value in case of constant stride. /// The 'Ptr' parameter holds SCEV of the access pointer. int getAddressComputationCost(Type *Ty, ScalarEvolution *SE = nullptr, const SCEV *Ptr = nullptr) const; /// \returns The cost, if any, of keeping values of the given types alive /// over a callsite. /// /// Some types may require the use of register classes that do not have /// any callee-saved registers, so would require a spill and fill. unsigned getCostOfKeepingLiveOverCall(ArrayRef<Type *> Tys) const; /// \returns True if the intrinsic is a supported memory intrinsic. Info /// will contain additional information - whether the intrinsic may write /// or read to memory, volatility and the pointer. Info is undefined /// if false is returned. bool getTgtMemIntrinsic(IntrinsicInst *Inst, MemIntrinsicInfo &Info) const; /// \returns The maximum element size, in bytes, for an element /// unordered-atomic memory intrinsic. unsigned getAtomicMemIntrinsicMaxElementSize() const; /// \returns A value which is the result of the given memory intrinsic. New /// instructions may be created to extract the result from the given intrinsic /// memory operation. Returns nullptr if the target cannot create a result /// from the given intrinsic. Value *getOrCreateResultFromMemIntrinsic(IntrinsicInst *Inst, Type *ExpectedType) const; /// \returns The type to use in a loop expansion of a memcpy call. Type *getMemcpyLoopLoweringType(LLVMContext &Context, Value *Length, unsigned SrcAlign, unsigned DestAlign) const; /// \param[out] OpsOut The operand types to copy RemainingBytes of memory. /// \param RemainingBytes The number of bytes to copy. /// /// Calculates the operand types to use when copying \p RemainingBytes of /// memory, where source and destination alignments are \p SrcAlign and /// \p DestAlign respectively. void getMemcpyLoopResidualLoweringType(SmallVectorImpl<Type *> &OpsOut, LLVMContext &Context, unsigned RemainingBytes, unsigned SrcAlign, unsigned DestAlign) const; /// \returns True if the two functions have compatible attributes for inlining /// purposes. bool areInlineCompatible(const Function *Caller, const Function *Callee) const; /// The type of load/store indexing. enum MemIndexedMode { MIM_Unindexed, ///< No indexing. MIM_PreInc, ///< Pre-incrementing. MIM_PreDec, ///< Pre-decrementing. MIM_PostInc, ///< Post-incrementing. MIM_PostDec ///< Post-decrementing. }; /// \returns True if the specified indexed load for the given type is legal. bool isIndexedLoadLegal(enum MemIndexedMode Mode, Type *Ty) const; /// \returns True if the specified indexed store for the given type is legal. bool isIndexedStoreLegal(enum MemIndexedMode Mode, Type *Ty) const; /// \returns The bitwidth of the largest vector type that should be used to /// load/store in the given address space. unsigned getLoadStoreVecRegBitWidth(unsigned AddrSpace) const; /// \returns True if the load instruction is legal to vectorize. bool isLegalToVectorizeLoad(LoadInst *LI) const; /// \returns True if the store instruction is legal to vectorize. bool isLegalToVectorizeStore(StoreInst *SI) const; /// \returns True if it is legal to vectorize the given load chain. bool isLegalToVectorizeLoadChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const; /// \returns True if it is legal to vectorize the given store chain. bool isLegalToVectorizeStoreChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const; /// \returns The new vector factor value if the target doesn't support \p /// SizeInBytes loads or has a better vector factor. unsigned getLoadVectorFactor(unsigned VF, unsigned LoadSize, unsigned ChainSizeInBytes, VectorType *VecTy) const; /// \returns The new vector factor value if the target doesn't support \p /// SizeInBytes stores or has a better vector factor. unsigned getStoreVectorFactor(unsigned VF, unsigned StoreSize, unsigned ChainSizeInBytes, VectorType *VecTy) const; /// Flags describing the kind of vector reduction. struct ReductionFlags { ReductionFlags() : IsMaxOp(false), IsSigned(false), NoNaN(false) {} bool IsMaxOp; ///< If the op a min/max kind, true if it's a max operation. bool IsSigned; ///< Whether the operation is a signed int reduction. bool NoNaN; ///< If op is an fp min/max, whether NaNs may be present. }; /// \returns True if the target wants to handle the given reduction idiom in /// the intrinsics form instead of the shuffle form. bool useReductionIntrinsic(unsigned Opcode, Type *Ty, ReductionFlags Flags) const; /// \returns True if the target wants to expand the given reduction intrinsic /// into a shuffle sequence. bool shouldExpandReduction(const IntrinsicInst *II) const; /// @} private: /// Estimate the latency of specified instruction. /// Returns 1 as the default value. int getInstructionLatency(const Instruction *I) const; /// Returns the expected throughput cost of the instruction. /// Returns -1 if the cost is unknown. int getInstructionThroughput(const Instruction *I) const; /// The abstract base class used to type erase specific TTI /// implementations. class Concept; /// The template model for the base class which wraps a concrete /// implementation in a type erased interface. template <typename T> class Model; std::unique_ptr<Concept> TTIImpl; }; class TargetTransformInfo::Concept { public: virtual ~Concept() = 0; virtual const DataLayout &getDataLayout() const = 0; virtual int getOperationCost(unsigned Opcode, Type *Ty, Type *OpTy) = 0; virtual int getGEPCost(Type *PointeeType, const Value *Ptr, ArrayRef<const Value *> Operands) = 0; virtual int getExtCost(const Instruction *I, const Value *Src) = 0; virtual int getCallCost(FunctionType *FTy, int NumArgs) = 0; virtual int getCallCost(const Function *F, int NumArgs) = 0; virtual int getCallCost(const Function *F, ArrayRef<const Value *> Arguments) = 0; virtual unsigned getInliningThresholdMultiplier() = 0; virtual int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<Type *> ParamTys) = 0; virtual int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<const Value *> Arguments) = 0; virtual unsigned getEstimatedNumberOfCaseClusters(const SwitchInst &SI, unsigned &JTSize) = 0; virtual int getUserCost(const User *U, ArrayRef<const Value *> Operands) = 0; virtual bool hasBranchDivergence() = 0; virtual bool isSourceOfDivergence(const Value *V) = 0; virtual bool isAlwaysUniform(const Value *V) = 0; virtual unsigned getFlatAddressSpace() = 0; virtual bool isLoweredToCall(const Function *F) = 0; virtual void getUnrollingPreferences(Loop *L, ScalarEvolution &, UnrollingPreferences &UP) = 0; virtual bool isLegalAddImmediate(int64_t Imm) = 0; virtual bool isLegalICmpImmediate(int64_t Imm) = 0; virtual bool isLegalAddressingMode(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace, Instruction *I) = 0; virtual bool isLSRCostLess(TargetTransformInfo::LSRCost &C1, TargetTransformInfo::LSRCost &C2) = 0; virtual bool canMacroFuseCmp() = 0; virtual bool shouldFavorPostInc() const = 0; virtual bool isLegalMaskedStore(Type *DataType) = 0; virtual bool isLegalMaskedLoad(Type *DataType) = 0; virtual bool isLegalMaskedScatter(Type *DataType) = 0; virtual bool isLegalMaskedGather(Type *DataType) = 0; virtual bool hasDivRemOp(Type *DataType, bool IsSigned) = 0; virtual bool hasVolatileVariant(Instruction *I, unsigned AddrSpace) = 0; virtual bool prefersVectorizedAddressing() = 0; virtual int getScalingFactorCost(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace) = 0; virtual bool LSRWithInstrQueries() = 0; virtual bool isTruncateFree(Type *Ty1, Type *Ty2) = 0; virtual bool isProfitableToHoist(Instruction *I) = 0; virtual bool useAA() = 0; virtual bool isTypeLegal(Type *Ty) = 0; virtual unsigned getJumpBufAlignment() = 0; virtual unsigned getJumpBufSize() = 0; virtual bool shouldBuildLookupTables() = 0; virtual bool shouldBuildLookupTablesForConstant(Constant *C) = 0; virtual bool useColdCCForColdCall(Function &F) = 0; virtual unsigned getScalarizationOverhead(Type *Ty, bool Insert, bool Extract) = 0; virtual unsigned getOperandsScalarizationOverhead(ArrayRef<const Value *> Args, unsigned VF) = 0; virtual bool supportsEfficientVectorElementLoadStore() = 0; virtual bool enableAggressiveInterleaving(bool LoopHasReductions) = 0; virtual const MemCmpExpansionOptions *enableMemCmpExpansion( bool IsZeroCmp) const = 0; virtual bool enableInterleavedAccessVectorization() = 0; virtual bool enableMaskedInterleavedAccessVectorization() = 0; virtual bool isFPVectorizationPotentiallyUnsafe() = 0; virtual bool allowsMisalignedMemoryAccesses(LLVMContext &Context, unsigned BitWidth, unsigned AddressSpace, unsigned Alignment, bool *Fast) = 0; virtual PopcntSupportKind getPopcntSupport(unsigned IntTyWidthInBit) = 0; virtual bool haveFastSqrt(Type *Ty) = 0; virtual bool isFCmpOrdCheaperThanFCmpZero(Type *Ty) = 0; virtual int getFPOpCost(Type *Ty) = 0; virtual int getIntImmCodeSizeCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) = 0; virtual int getIntImmCost(const APInt &Imm, Type *Ty) = 0; virtual int getIntImmCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) = 0; virtual int getIntImmCost(Intrinsic::ID IID, unsigned Idx, const APInt &Imm, Type *Ty) = 0; virtual unsigned getNumberOfRegisters(bool Vector) = 0; virtual unsigned getRegisterBitWidth(bool Vector) const = 0; virtual unsigned getMinVectorRegisterBitWidth() = 0; virtual bool shouldMaximizeVectorBandwidth(bool OptSize) const = 0; virtual unsigned getMinimumVF(unsigned ElemWidth) const = 0; virtual bool shouldConsiderAddressTypePromotion( const Instruction &I, bool &AllowPromotionWithoutCommonHeader) = 0; virtual unsigned getCacheLineSize() = 0; virtual llvm::Optional<unsigned> getCacheSize(CacheLevel Level) = 0; virtual llvm::Optional<unsigned> getCacheAssociativity(CacheLevel Level) = 0; virtual unsigned getPrefetchDistance() = 0; virtual unsigned getMinPrefetchStride() = 0; virtual unsigned getMaxPrefetchIterationsAhead() = 0; virtual unsigned getMaxInterleaveFactor(unsigned VF) = 0; virtual unsigned getArithmeticInstrCost(unsigned Opcode, Type *Ty, OperandValueKind Opd1Info, OperandValueKind Opd2Info, OperandValueProperties Opd1PropInfo, OperandValueProperties Opd2PropInfo, ArrayRef<const Value *> Args) = 0; virtual int getShuffleCost(ShuffleKind Kind, Type *Tp, int Index, Type *SubTp) = 0; virtual int getCastInstrCost(unsigned Opcode, Type *Dst, Type *Src, const Instruction *I) = 0; virtual int getExtractWithExtendCost(unsigned Opcode, Type *Dst, VectorType *VecTy, unsigned Index) = 0; virtual int getCFInstrCost(unsigned Opcode) = 0; virtual int getCmpSelInstrCost(unsigned Opcode, Type *ValTy, Type *CondTy, const Instruction *I) = 0; virtual int getVectorInstrCost(unsigned Opcode, Type *Val, unsigned Index) = 0; virtual int getMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace, const Instruction *I) = 0; virtual int getMaskedMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace) = 0; virtual int getGatherScatterOpCost(unsigned Opcode, Type *DataTy, Value *Ptr, bool VariableMask, unsigned Alignment) = 0; virtual int getInterleavedMemoryOpCost(unsigned Opcode, Type *VecTy, unsigned Factor, ArrayRef<unsigned> Indices, unsigned Alignment, unsigned AddressSpace, bool UseMaskForCond = false, bool UseMaskForGaps = false) = 0; virtual int getArithmeticReductionCost(unsigned Opcode, Type *Ty, bool IsPairwiseForm) = 0; virtual int getMinMaxReductionCost(Type *Ty, Type *CondTy, bool IsPairwiseForm, bool IsUnsigned) = 0; virtual int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Type *> Tys, FastMathFlags FMF, unsigned ScalarizationCostPassed) = 0; virtual int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Value *> Args, FastMathFlags FMF, unsigned VF) = 0; virtual int getCallInstrCost(Function *F, Type *RetTy, ArrayRef<Type *> Tys) = 0; virtual unsigned getNumberOfParts(Type *Tp) = 0; virtual int getAddressComputationCost(Type *Ty, ScalarEvolution *SE, const SCEV *Ptr) = 0; virtual unsigned getCostOfKeepingLiveOverCall(ArrayRef<Type *> Tys) = 0; virtual bool getTgtMemIntrinsic(IntrinsicInst *Inst, MemIntrinsicInfo &Info) = 0; virtual unsigned getAtomicMemIntrinsicMaxElementSize() const = 0; virtual Value *getOrCreateResultFromMemIntrinsic(IntrinsicInst *Inst, Type *ExpectedType) = 0; virtual Type *getMemcpyLoopLoweringType(LLVMContext &Context, Value *Length, unsigned SrcAlign, unsigned DestAlign) const = 0; virtual void getMemcpyLoopResidualLoweringType( SmallVectorImpl<Type *> &OpsOut, LLVMContext &Context, unsigned RemainingBytes, unsigned SrcAlign, unsigned DestAlign) const = 0; virtual bool areInlineCompatible(const Function *Caller, const Function *Callee) const = 0; virtual bool isIndexedLoadLegal(MemIndexedMode Mode, Type *Ty) const = 0; virtual bool isIndexedStoreLegal(MemIndexedMode Mode,Type *Ty) const = 0; virtual unsigned getLoadStoreVecRegBitWidth(unsigned AddrSpace) const = 0; virtual bool isLegalToVectorizeLoad(LoadInst *LI) const = 0; virtual bool isLegalToVectorizeStore(StoreInst *SI) const = 0; virtual bool isLegalToVectorizeLoadChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const = 0; virtual bool isLegalToVectorizeStoreChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const = 0; virtual unsigned getLoadVectorFactor(unsigned VF, unsigned LoadSize, unsigned ChainSizeInBytes, VectorType *VecTy) const = 0; virtual unsigned getStoreVectorFactor(unsigned VF, unsigned StoreSize, unsigned ChainSizeInBytes, VectorType *VecTy) const = 0; virtual bool useReductionIntrinsic(unsigned Opcode, Type *Ty, ReductionFlags) const = 0; virtual bool shouldExpandReduction(const IntrinsicInst *II) const = 0; virtual int getInstructionLatency(const Instruction *I) = 0; }; template <typename T> class TargetTransformInfo::Model final : public TargetTransformInfo::Concept { T Impl; public: Model(T Impl) : Impl(std::move(Impl)) {} ~Model() override {} const DataLayout &getDataLayout() const override { return Impl.getDataLayout(); } int getOperationCost(unsigned Opcode, Type *Ty, Type *OpTy) override { return Impl.getOperationCost(Opcode, Ty, OpTy); } int getGEPCost(Type *PointeeType, const Value *Ptr, ArrayRef<const Value *> Operands) override { return Impl.getGEPCost(PointeeType, Ptr, Operands); } int getExtCost(const Instruction *I, const Value *Src) override { return Impl.getExtCost(I, Src); } int getCallCost(FunctionType *FTy, int NumArgs) override { return Impl.getCallCost(FTy, NumArgs); } int getCallCost(const Function *F, int NumArgs) override { return Impl.getCallCost(F, NumArgs); } int getCallCost(const Function *F, ArrayRef<const Value *> Arguments) override { return Impl.getCallCost(F, Arguments); } unsigned getInliningThresholdMultiplier() override { return Impl.getInliningThresholdMultiplier(); } int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<Type *> ParamTys) override { return Impl.getIntrinsicCost(IID, RetTy, ParamTys); } int getIntrinsicCost(Intrinsic::ID IID, Type *RetTy, ArrayRef<const Value *> Arguments) override { return Impl.getIntrinsicCost(IID, RetTy, Arguments); } int getUserCost(const User *U, ArrayRef<const Value *> Operands) override { return Impl.getUserCost(U, Operands); } bool hasBranchDivergence() override { return Impl.hasBranchDivergence(); } bool isSourceOfDivergence(const Value *V) override { return Impl.isSourceOfDivergence(V); } bool isAlwaysUniform(const Value *V) override { return Impl.isAlwaysUniform(V); } unsigned getFlatAddressSpace() override { return Impl.getFlatAddressSpace(); } bool isLoweredToCall(const Function *F) override { return Impl.isLoweredToCall(F); } void getUnrollingPreferences(Loop *L, ScalarEvolution &SE, UnrollingPreferences &UP) override { return Impl.getUnrollingPreferences(L, SE, UP); } bool isLegalAddImmediate(int64_t Imm) override { return Impl.isLegalAddImmediate(Imm); } bool isLegalICmpImmediate(int64_t Imm) override { return Impl.isLegalICmpImmediate(Imm); } bool isLegalAddressingMode(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace, Instruction *I) override { return Impl.isLegalAddressingMode(Ty, BaseGV, BaseOffset, HasBaseReg, Scale, AddrSpace, I); } bool isLSRCostLess(TargetTransformInfo::LSRCost &C1, TargetTransformInfo::LSRCost &C2) override { return Impl.isLSRCostLess(C1, C2); } bool canMacroFuseCmp() override { return Impl.canMacroFuseCmp(); } bool shouldFavorPostInc() const override { return Impl.shouldFavorPostInc(); } bool isLegalMaskedStore(Type *DataType) override { return Impl.isLegalMaskedStore(DataType); } bool isLegalMaskedLoad(Type *DataType) override { return Impl.isLegalMaskedLoad(DataType); } bool isLegalMaskedScatter(Type *DataType) override { return Impl.isLegalMaskedScatter(DataType); } bool isLegalMaskedGather(Type *DataType) override { return Impl.isLegalMaskedGather(DataType); } bool hasDivRemOp(Type *DataType, bool IsSigned) override { return Impl.hasDivRemOp(DataType, IsSigned); } bool hasVolatileVariant(Instruction *I, unsigned AddrSpace) override { return Impl.hasVolatileVariant(I, AddrSpace); } bool prefersVectorizedAddressing() override { return Impl.prefersVectorizedAddressing(); } int getScalingFactorCost(Type *Ty, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, unsigned AddrSpace) override { return Impl.getScalingFactorCost(Ty, BaseGV, BaseOffset, HasBaseReg, Scale, AddrSpace); } bool LSRWithInstrQueries() override { return Impl.LSRWithInstrQueries(); } bool isTruncateFree(Type *Ty1, Type *Ty2) override { return Impl.isTruncateFree(Ty1, Ty2); } bool isProfitableToHoist(Instruction *I) override { return Impl.isProfitableToHoist(I); } bool useAA() override { return Impl.useAA(); } bool isTypeLegal(Type *Ty) override { return Impl.isTypeLegal(Ty); } unsigned getJumpBufAlignment() override { return Impl.getJumpBufAlignment(); } unsigned getJumpBufSize() override { return Impl.getJumpBufSize(); } bool shouldBuildLookupTables() override { return Impl.shouldBuildLookupTables(); } bool shouldBuildLookupTablesForConstant(Constant *C) override { return Impl.shouldBuildLookupTablesForConstant(C); } bool useColdCCForColdCall(Function &F) override { return Impl.useColdCCForColdCall(F); } unsigned getScalarizationOverhead(Type *Ty, bool Insert, bool Extract) override { return Impl.getScalarizationOverhead(Ty, Insert, Extract); } unsigned getOperandsScalarizationOverhead(ArrayRef<const Value *> Args, unsigned VF) override { return Impl.getOperandsScalarizationOverhead(Args, VF); } bool supportsEfficientVectorElementLoadStore() override { return Impl.supportsEfficientVectorElementLoadStore(); } bool enableAggressiveInterleaving(bool LoopHasReductions) override { return Impl.enableAggressiveInterleaving(LoopHasReductions); } const MemCmpExpansionOptions *enableMemCmpExpansion( bool IsZeroCmp) const override { return Impl.enableMemCmpExpansion(IsZeroCmp); } bool enableInterleavedAccessVectorization() override { return Impl.enableInterleavedAccessVectorization(); } bool enableMaskedInterleavedAccessVectorization() override { return Impl.enableMaskedInterleavedAccessVectorization(); } bool isFPVectorizationPotentiallyUnsafe() override { return Impl.isFPVectorizationPotentiallyUnsafe(); } bool allowsMisalignedMemoryAccesses(LLVMContext &Context, unsigned BitWidth, unsigned AddressSpace, unsigned Alignment, bool *Fast) override { return Impl.allowsMisalignedMemoryAccesses(Context, BitWidth, AddressSpace, Alignment, Fast); } PopcntSupportKind getPopcntSupport(unsigned IntTyWidthInBit) override { return Impl.getPopcntSupport(IntTyWidthInBit); } bool haveFastSqrt(Type *Ty) override { return Impl.haveFastSqrt(Ty); } bool isFCmpOrdCheaperThanFCmpZero(Type *Ty) override { return Impl.isFCmpOrdCheaperThanFCmpZero(Ty); } int getFPOpCost(Type *Ty) override { return Impl.getFPOpCost(Ty); } int getIntImmCodeSizeCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) override { return Impl.getIntImmCodeSizeCost(Opc, Idx, Imm, Ty); } int getIntImmCost(const APInt &Imm, Type *Ty) override { return Impl.getIntImmCost(Imm, Ty); } int getIntImmCost(unsigned Opc, unsigned Idx, const APInt &Imm, Type *Ty) override { return Impl.getIntImmCost(Opc, Idx, Imm, Ty); } int getIntImmCost(Intrinsic::ID IID, unsigned Idx, const APInt &Imm, Type *Ty) override { return Impl.getIntImmCost(IID, Idx, Imm, Ty); } unsigned getNumberOfRegisters(bool Vector) override { return Impl.getNumberOfRegisters(Vector); } unsigned getRegisterBitWidth(bool Vector) const override { return Impl.getRegisterBitWidth(Vector); } unsigned getMinVectorRegisterBitWidth() override { return Impl.getMinVectorRegisterBitWidth(); } bool shouldMaximizeVectorBandwidth(bool OptSize) const override { return Impl.shouldMaximizeVectorBandwidth(OptSize); } unsigned getMinimumVF(unsigned ElemWidth) const override { return Impl.getMinimumVF(ElemWidth); } bool shouldConsiderAddressTypePromotion( const Instruction &I, bool &AllowPromotionWithoutCommonHeader) override { return Impl.shouldConsiderAddressTypePromotion( I, AllowPromotionWithoutCommonHeader); } unsigned getCacheLineSize() override { return Impl.getCacheLineSize(); } llvm::Optional<unsigned> getCacheSize(CacheLevel Level) override { return Impl.getCacheSize(Level); } llvm::Optional<unsigned> getCacheAssociativity(CacheLevel Level) override { return Impl.getCacheAssociativity(Level); } unsigned getPrefetchDistance() override { return Impl.getPrefetchDistance(); } unsigned getMinPrefetchStride() override { return Impl.getMinPrefetchStride(); } unsigned getMaxPrefetchIterationsAhead() override { return Impl.getMaxPrefetchIterationsAhead(); } unsigned getMaxInterleaveFactor(unsigned VF) override { return Impl.getMaxInterleaveFactor(VF); } unsigned getEstimatedNumberOfCaseClusters(const SwitchInst &SI, unsigned &JTSize) override { return Impl.getEstimatedNumberOfCaseClusters(SI, JTSize); } unsigned getArithmeticInstrCost(unsigned Opcode, Type *Ty, OperandValueKind Opd1Info, OperandValueKind Opd2Info, OperandValueProperties Opd1PropInfo, OperandValueProperties Opd2PropInfo, ArrayRef<const Value *> Args) override { return Impl.getArithmeticInstrCost(Opcode, Ty, Opd1Info, Opd2Info, Opd1PropInfo, Opd2PropInfo, Args); } int getShuffleCost(ShuffleKind Kind, Type *Tp, int Index, Type *SubTp) override { return Impl.getShuffleCost(Kind, Tp, Index, SubTp); } int getCastInstrCost(unsigned Opcode, Type *Dst, Type *Src, const Instruction *I) override { return Impl.getCastInstrCost(Opcode, Dst, Src, I); } int getExtractWithExtendCost(unsigned Opcode, Type *Dst, VectorType *VecTy, unsigned Index) override { return Impl.getExtractWithExtendCost(Opcode, Dst, VecTy, Index); } int getCFInstrCost(unsigned Opcode) override { return Impl.getCFInstrCost(Opcode); } int getCmpSelInstrCost(unsigned Opcode, Type *ValTy, Type *CondTy, const Instruction *I) override { return Impl.getCmpSelInstrCost(Opcode, ValTy, CondTy, I); } int getVectorInstrCost(unsigned Opcode, Type *Val, unsigned Index) override { return Impl.getVectorInstrCost(Opcode, Val, Index); } int getMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace, const Instruction *I) override { return Impl.getMemoryOpCost(Opcode, Src, Alignment, AddressSpace, I); } int getMaskedMemoryOpCost(unsigned Opcode, Type *Src, unsigned Alignment, unsigned AddressSpace) override { return Impl.getMaskedMemoryOpCost(Opcode, Src, Alignment, AddressSpace); } int getGatherScatterOpCost(unsigned Opcode, Type *DataTy, Value *Ptr, bool VariableMask, unsigned Alignment) override { return Impl.getGatherScatterOpCost(Opcode, DataTy, Ptr, VariableMask, Alignment); } int getInterleavedMemoryOpCost(unsigned Opcode, Type *VecTy, unsigned Factor, ArrayRef<unsigned> Indices, unsigned Alignment, unsigned AddressSpace, bool UseMaskForCond, bool UseMaskForGaps) override { return Impl.getInterleavedMemoryOpCost(Opcode, VecTy, Factor, Indices, Alignment, AddressSpace, UseMaskForCond, UseMaskForGaps); } int getArithmeticReductionCost(unsigned Opcode, Type *Ty, bool IsPairwiseForm) override { return Impl.getArithmeticReductionCost(Opcode, Ty, IsPairwiseForm); } int getMinMaxReductionCost(Type *Ty, Type *CondTy, bool IsPairwiseForm, bool IsUnsigned) override { return Impl.getMinMaxReductionCost(Ty, CondTy, IsPairwiseForm, IsUnsigned); } int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Type *> Tys, FastMathFlags FMF, unsigned ScalarizationCostPassed) override { return Impl.getIntrinsicInstrCost(ID, RetTy, Tys, FMF, ScalarizationCostPassed); } int getIntrinsicInstrCost(Intrinsic::ID ID, Type *RetTy, ArrayRef<Value *> Args, FastMathFlags FMF, unsigned VF) override { return Impl.getIntrinsicInstrCost(ID, RetTy, Args, FMF, VF); } int getCallInstrCost(Function *F, Type *RetTy, ArrayRef<Type *> Tys) override { return Impl.getCallInstrCost(F, RetTy, Tys); } unsigned getNumberOfParts(Type *Tp) override { return Impl.getNumberOfParts(Tp); } int getAddressComputationCost(Type *Ty, ScalarEvolution *SE, const SCEV *Ptr) override { return Impl.getAddressComputationCost(Ty, SE, Ptr); } unsigned getCostOfKeepingLiveOverCall(ArrayRef<Type *> Tys) override { return Impl.getCostOfKeepingLiveOverCall(Tys); } bool getTgtMemIntrinsic(IntrinsicInst *Inst, MemIntrinsicInfo &Info) override { return Impl.getTgtMemIntrinsic(Inst, Info); } unsigned getAtomicMemIntrinsicMaxElementSize() const override { return Impl.getAtomicMemIntrinsicMaxElementSize(); } Value *getOrCreateResultFromMemIntrinsic(IntrinsicInst *Inst, Type *ExpectedType) override { return Impl.getOrCreateResultFromMemIntrinsic(Inst, ExpectedType); } Type *getMemcpyLoopLoweringType(LLVMContext &Context, Value *Length, unsigned SrcAlign, unsigned DestAlign) const override { return Impl.getMemcpyLoopLoweringType(Context, Length, SrcAlign, DestAlign); } void getMemcpyLoopResidualLoweringType(SmallVectorImpl<Type *> &OpsOut, LLVMContext &Context, unsigned RemainingBytes, unsigned SrcAlign, unsigned DestAlign) const override { Impl.getMemcpyLoopResidualLoweringType(OpsOut, Context, RemainingBytes, SrcAlign, DestAlign); } bool areInlineCompatible(const Function *Caller, const Function *Callee) const override { return Impl.areInlineCompatible(Caller, Callee); } bool isIndexedLoadLegal(MemIndexedMode Mode, Type *Ty) const override { return Impl.isIndexedLoadLegal(Mode, Ty, getDataLayout()); } bool isIndexedStoreLegal(MemIndexedMode Mode, Type *Ty) const override { return Impl.isIndexedStoreLegal(Mode, Ty, getDataLayout()); } unsigned getLoadStoreVecRegBitWidth(unsigned AddrSpace) const override { return Impl.getLoadStoreVecRegBitWidth(AddrSpace); } bool isLegalToVectorizeLoad(LoadInst *LI) const override { return Impl.isLegalToVectorizeLoad(LI); } bool isLegalToVectorizeStore(StoreInst *SI) const override { return Impl.isLegalToVectorizeStore(SI); } bool isLegalToVectorizeLoadChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const override { return Impl.isLegalToVectorizeLoadChain(ChainSizeInBytes, Alignment, AddrSpace); } bool isLegalToVectorizeStoreChain(unsigned ChainSizeInBytes, unsigned Alignment, unsigned AddrSpace) const override { return Impl.isLegalToVectorizeStoreChain(ChainSizeInBytes, Alignment, AddrSpace); } unsigned getLoadVectorFactor(unsigned VF, unsigned LoadSize, unsigned ChainSizeInBytes, VectorType *VecTy) const override { return Impl.getLoadVectorFactor(VF, LoadSize, ChainSizeInBytes, VecTy); } unsigned getStoreVectorFactor(unsigned VF, unsigned StoreSize, unsigned ChainSizeInBytes, VectorType *VecTy) const override { return Impl.getStoreVectorFactor(VF, StoreSize, ChainSizeInBytes, VecTy); } bool useReductionIntrinsic(unsigned Opcode, Type *Ty, ReductionFlags Flags) const override { return Impl.useReductionIntrinsic(Opcode, Ty, Flags); } bool shouldExpandReduction(const IntrinsicInst *II) const override { return Impl.shouldExpandReduction(II); } int getInstructionLatency(const Instruction *I) override { return Impl.getInstructionLatency(I); } }; template <typename T> TargetTransformInfo::TargetTransformInfo(T Impl) : TTIImpl(new Model<T>(Impl)) {} /// Analysis pass providing the \c TargetTransformInfo. /// /// The core idea of the TargetIRAnalysis is to expose an interface through /// which LLVM targets can analyze and provide information about the middle /// end's target-independent IR. This supports use cases such as target-aware /// cost modeling of IR constructs. /// /// This is a function analysis because much of the cost modeling for targets /// is done in a subtarget specific way and LLVM supports compiling different /// functions targeting different subtargets in order to support runtime /// dispatch according to the observed subtarget. class TargetIRAnalysis : public AnalysisInfoMixin<TargetIRAnalysis> { public: typedef TargetTransformInfo Result; /// Default construct a target IR analysis. /// /// This will use the module's datalayout to construct a baseline /// conservative TTI result. TargetIRAnalysis(); /// Construct an IR analysis pass around a target-provide callback. /// /// The callback will be called with a particular function for which the TTI /// is needed and must return a TTI object for that function. TargetIRAnalysis(std::function<Result(const Function &)> TTICallback); // Value semantics. We spell out the constructors for MSVC. TargetIRAnalysis(const TargetIRAnalysis &Arg) : TTICallback(Arg.TTICallback) {} TargetIRAnalysis(TargetIRAnalysis &&Arg) : TTICallback(std::move(Arg.TTICallback)) {} TargetIRAnalysis &operator=(const TargetIRAnalysis &RHS) { TTICallback = RHS.TTICallback; return *this; } TargetIRAnalysis &operator=(TargetIRAnalysis &&RHS) { TTICallback = std::move(RHS.TTICallback); return *this; } Result run(const Function &F, FunctionAnalysisManager &); private: friend AnalysisInfoMixin<TargetIRAnalysis>; static AnalysisKey Key; /// The callback used to produce a result. /// /// We use a completely opaque callback so that targets can provide whatever /// mechanism they desire for constructing the TTI for a given function. /// /// FIXME: Should we really use std::function? It's relatively inefficient. /// It might be possible to arrange for even stateful callbacks to outlive /// the analysis and thus use a function_ref which would be lighter weight. /// This may also be less error prone as the callback is likely to reference /// the external TargetMachine, and that reference needs to never dangle. std::function<Result(const Function &)> TTICallback; /// Helper function used as the callback in the default constructor. static Result getDefaultTTI(const Function &F); }; /// Wrapper pass for TargetTransformInfo. /// /// This pass can be constructed from a TTI object which it stores internally /// and is queried by passes. class TargetTransformInfoWrapperPass : public ImmutablePass { TargetIRAnalysis TIRA; Optional<TargetTransformInfo> TTI; virtual void anchor(); public: static char ID; /// We must provide a default constructor for the pass but it should /// never be used. /// /// Use the constructor below or call one of the creation routines. TargetTransformInfoWrapperPass(); explicit TargetTransformInfoWrapperPass(TargetIRAnalysis TIRA); TargetTransformInfo &getTTI(const Function &F); }; /// Create an analysis pass wrapper around a TTI object. /// /// This analysis pass just holds the TTI instance and makes it available to /// clients. ImmutablePass *createTargetTransformInfoWrapperPass(TargetIRAnalysis TIRA); } // End llvm namespace #endif