//===-- NVPTXTargetTransformInfo.cpp - NVPTX specific TTI -----------------===// // // 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 // //===----------------------------------------------------------------------===// #include "NVPTXTargetTransformInfo.h" #include "NVPTXUtilities.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/ValueTracking.h" #include "llvm/CodeGen/BasicTTIImpl.h" #include "llvm/CodeGen/TargetLowering.h" #include "llvm/IR/Constants.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/Intrinsics.h" #include "llvm/IR/IntrinsicsNVPTX.h" #include "llvm/IR/Value.h" #include "llvm/Support/Casting.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/NVPTXAddrSpace.h" #include "llvm/Transforms/InstCombine/InstCombiner.h" #include using namespace llvm; #define DEBUG_TYPE "NVPTXtti" // Whether the given intrinsic reads threadIdx.x/y/z. static bool readsThreadIndex(const IntrinsicInst *II) { switch (II->getIntrinsicID()) { default: return false; case Intrinsic::nvvm_read_ptx_sreg_tid_x: case Intrinsic::nvvm_read_ptx_sreg_tid_y: case Intrinsic::nvvm_read_ptx_sreg_tid_z: return true; } } static bool readsLaneId(const IntrinsicInst *II) { return II->getIntrinsicID() == Intrinsic::nvvm_read_ptx_sreg_laneid; } // Whether the given intrinsic is an atomic instruction in PTX. static bool isNVVMAtomic(const IntrinsicInst *II) { switch (II->getIntrinsicID()) { default: return false; case Intrinsic::nvvm_atomic_add_gen_f_cta: case Intrinsic::nvvm_atomic_add_gen_f_sys: case Intrinsic::nvvm_atomic_add_gen_i_cta: case Intrinsic::nvvm_atomic_add_gen_i_sys: case Intrinsic::nvvm_atomic_and_gen_i_cta: case Intrinsic::nvvm_atomic_and_gen_i_sys: case Intrinsic::nvvm_atomic_cas_gen_i_cta: case Intrinsic::nvvm_atomic_cas_gen_i_sys: case Intrinsic::nvvm_atomic_dec_gen_i_cta: case Intrinsic::nvvm_atomic_dec_gen_i_sys: case Intrinsic::nvvm_atomic_inc_gen_i_cta: case Intrinsic::nvvm_atomic_inc_gen_i_sys: case Intrinsic::nvvm_atomic_max_gen_i_cta: case Intrinsic::nvvm_atomic_max_gen_i_sys: case Intrinsic::nvvm_atomic_min_gen_i_cta: case Intrinsic::nvvm_atomic_min_gen_i_sys: case Intrinsic::nvvm_atomic_or_gen_i_cta: case Intrinsic::nvvm_atomic_or_gen_i_sys: case Intrinsic::nvvm_atomic_exch_gen_i_cta: case Intrinsic::nvvm_atomic_exch_gen_i_sys: case Intrinsic::nvvm_atomic_xor_gen_i_cta: case Intrinsic::nvvm_atomic_xor_gen_i_sys: return true; } } bool NVPTXTTIImpl::isSourceOfDivergence(const Value *V) const { // Without inter-procedural analysis, we conservatively assume that arguments // to __device__ functions are divergent. if (const Argument *Arg = dyn_cast(V)) return !isKernelFunction(*Arg->getParent()); if (const Instruction *I = dyn_cast(V)) { // Without pointer analysis, we conservatively assume values loaded from // generic or local address space are divergent. if (const LoadInst *LI = dyn_cast(I)) { unsigned AS = LI->getPointerAddressSpace(); return AS == ADDRESS_SPACE_GENERIC || AS == ADDRESS_SPACE_LOCAL; } // Atomic instructions may cause divergence. Atomic instructions are // executed sequentially across all threads in a warp. Therefore, an earlier // executed thread may see different memory inputs than a later executed // thread. For example, suppose *a = 0 initially. // // atom.global.add.s32 d, [a], 1 // // returns 0 for the first thread that enters the critical region, and 1 for // the second thread. if (I->isAtomic()) return true; if (const IntrinsicInst *II = dyn_cast(I)) { // Instructions that read threadIdx are obviously divergent. if (readsThreadIndex(II) || readsLaneId(II)) return true; // Handle the NVPTX atomic intrinsics that cannot be represented as an // atomic IR instruction. if (isNVVMAtomic(II)) return true; } // Conservatively consider the return value of function calls as divergent. // We could analyze callees with bodies more precisely using // inter-procedural analysis. if (isa(I)) return true; } return false; } // Convert NVVM intrinsics to target-generic LLVM code where possible. static Instruction *convertNvvmIntrinsicToLlvm(InstCombiner &IC, IntrinsicInst *II) { // Each NVVM intrinsic we can simplify can be replaced with one of: // // * an LLVM intrinsic, // * an LLVM cast operation, // * an LLVM binary operation, or // * ad-hoc LLVM IR for the particular operation. // Some transformations are only valid when the module's // flush-denormals-to-zero (ftz) setting is true/false, whereas other // transformations are valid regardless of the module's ftz setting. enum FtzRequirementTy { FTZ_Any, // Any ftz setting is ok. FTZ_MustBeOn, // Transformation is valid only if ftz is on. FTZ_MustBeOff, // Transformation is valid only if ftz is off. }; // Classes of NVVM intrinsics that can't be replaced one-to-one with a // target-generic intrinsic, cast op, or binary op but that we can nonetheless // simplify. enum SpecialCase { SPC_Reciprocal, SCP_FunnelShiftClamp, }; // SimplifyAction is a poor-man's variant (plus an additional flag) that // represents how to replace an NVVM intrinsic with target-generic LLVM IR. struct SimplifyAction { // Invariant: At most one of these Optionals has a value. std::optional IID; std::optional CastOp; std::optional BinaryOp; std::optional Special; FtzRequirementTy FtzRequirement = FTZ_Any; // Denormal handling is guarded by different attributes depending on the // type (denormal-fp-math vs denormal-fp-math-f32), take note of halfs. bool IsHalfTy = false; SimplifyAction() = default; SimplifyAction(Intrinsic::ID IID, FtzRequirementTy FtzReq, bool IsHalfTy = false) : IID(IID), FtzRequirement(FtzReq), IsHalfTy(IsHalfTy) {} // Cast operations don't have anything to do with FTZ, so we skip that // argument. SimplifyAction(Instruction::CastOps CastOp) : CastOp(CastOp) {} SimplifyAction(Instruction::BinaryOps BinaryOp, FtzRequirementTy FtzReq) : BinaryOp(BinaryOp), FtzRequirement(FtzReq) {} SimplifyAction(SpecialCase Special, FtzRequirementTy FtzReq) : Special(Special), FtzRequirement(FtzReq) {} }; // Try to generate a SimplifyAction describing how to replace our // IntrinsicInstr with target-generic LLVM IR. const SimplifyAction Action = [II]() -> SimplifyAction { switch (II->getIntrinsicID()) { // NVVM intrinsics that map directly to LLVM intrinsics. case Intrinsic::nvvm_ceil_d: return {Intrinsic::ceil, FTZ_Any}; case Intrinsic::nvvm_ceil_f: return {Intrinsic::ceil, FTZ_MustBeOff}; case Intrinsic::nvvm_ceil_ftz_f: return {Intrinsic::ceil, FTZ_MustBeOn}; case Intrinsic::nvvm_floor_d: return {Intrinsic::floor, FTZ_Any}; case Intrinsic::nvvm_floor_f: return {Intrinsic::floor, FTZ_MustBeOff}; case Intrinsic::nvvm_floor_ftz_f: return {Intrinsic::floor, FTZ_MustBeOn}; case Intrinsic::nvvm_fma_rn_d: return {Intrinsic::fma, FTZ_Any}; case Intrinsic::nvvm_fma_rn_f: return {Intrinsic::fma, FTZ_MustBeOff}; case Intrinsic::nvvm_fma_rn_ftz_f: return {Intrinsic::fma, FTZ_MustBeOn}; case Intrinsic::nvvm_fma_rn_f16: return {Intrinsic::fma, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fma_rn_ftz_f16: return {Intrinsic::fma, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fma_rn_f16x2: return {Intrinsic::fma, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fma_rn_ftz_f16x2: return {Intrinsic::fma, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fma_rn_bf16: return {Intrinsic::fma, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fma_rn_ftz_bf16: return {Intrinsic::fma, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fma_rn_bf16x2: return {Intrinsic::fma, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fma_rn_ftz_bf16x2: return {Intrinsic::fma, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmax_d: return {Intrinsic::maxnum, FTZ_Any}; case Intrinsic::nvvm_fmax_f: return {Intrinsic::maxnum, FTZ_MustBeOff}; case Intrinsic::nvvm_fmax_ftz_f: return {Intrinsic::maxnum, FTZ_MustBeOn}; case Intrinsic::nvvm_fmax_nan_f: return {Intrinsic::maximum, FTZ_MustBeOff}; case Intrinsic::nvvm_fmax_ftz_nan_f: return {Intrinsic::maximum, FTZ_MustBeOn}; case Intrinsic::nvvm_fmax_f16: return {Intrinsic::maxnum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmax_ftz_f16: return {Intrinsic::maxnum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmax_f16x2: return {Intrinsic::maxnum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmax_ftz_f16x2: return {Intrinsic::maxnum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmax_nan_f16: return {Intrinsic::maximum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmax_ftz_nan_f16: return {Intrinsic::maximum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmax_nan_f16x2: return {Intrinsic::maximum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmax_ftz_nan_f16x2: return {Intrinsic::maximum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmin_d: return {Intrinsic::minnum, FTZ_Any}; case Intrinsic::nvvm_fmin_f: return {Intrinsic::minnum, FTZ_MustBeOff}; case Intrinsic::nvvm_fmin_ftz_f: return {Intrinsic::minnum, FTZ_MustBeOn}; case Intrinsic::nvvm_fmin_nan_f: return {Intrinsic::minimum, FTZ_MustBeOff}; case Intrinsic::nvvm_fmin_ftz_nan_f: return {Intrinsic::minimum, FTZ_MustBeOn}; case Intrinsic::nvvm_fmin_f16: return {Intrinsic::minnum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmin_ftz_f16: return {Intrinsic::minnum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmin_f16x2: return {Intrinsic::minnum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmin_ftz_f16x2: return {Intrinsic::minnum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmin_nan_f16: return {Intrinsic::minimum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmin_ftz_nan_f16: return {Intrinsic::minimum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_fmin_nan_f16x2: return {Intrinsic::minimum, FTZ_MustBeOff, true}; case Intrinsic::nvvm_fmin_ftz_nan_f16x2: return {Intrinsic::minimum, FTZ_MustBeOn, true}; case Intrinsic::nvvm_sqrt_rn_d: return {Intrinsic::sqrt, FTZ_Any}; case Intrinsic::nvvm_sqrt_f: // nvvm_sqrt_f is a special case. For most intrinsics, foo_ftz_f is the // ftz version, and foo_f is the non-ftz version. But nvvm_sqrt_f adopts // the ftz-ness of the surrounding code. sqrt_rn_f and sqrt_rn_ftz_f are // the versions with explicit ftz-ness. return {Intrinsic::sqrt, FTZ_Any}; case Intrinsic::nvvm_trunc_d: return {Intrinsic::trunc, FTZ_Any}; case Intrinsic::nvvm_trunc_f: return {Intrinsic::trunc, FTZ_MustBeOff}; case Intrinsic::nvvm_trunc_ftz_f: return {Intrinsic::trunc, FTZ_MustBeOn}; // NVVM intrinsics that map to LLVM cast operations. // // Note that llvm's target-generic conversion operators correspond to the rz // (round to zero) versions of the nvvm conversion intrinsics, even though // most everything else here uses the rn (round to nearest even) nvvm ops. case Intrinsic::nvvm_d2i_rz: case Intrinsic::nvvm_f2i_rz: case Intrinsic::nvvm_d2ll_rz: case Intrinsic::nvvm_f2ll_rz: return {Instruction::FPToSI}; case Intrinsic::nvvm_d2ui_rz: case Intrinsic::nvvm_f2ui_rz: case Intrinsic::nvvm_d2ull_rz: case Intrinsic::nvvm_f2ull_rz: return {Instruction::FPToUI}; // Integer to floating-point uses RN rounding, not RZ case Intrinsic::nvvm_i2d_rn: case Intrinsic::nvvm_i2f_rn: case Intrinsic::nvvm_ll2d_rn: case Intrinsic::nvvm_ll2f_rn: return {Instruction::SIToFP}; case Intrinsic::nvvm_ui2d_rn: case Intrinsic::nvvm_ui2f_rn: case Intrinsic::nvvm_ull2d_rn: case Intrinsic::nvvm_ull2f_rn: return {Instruction::UIToFP}; // NVVM intrinsics that map to LLVM binary ops. case Intrinsic::nvvm_div_rn_d: return {Instruction::FDiv, FTZ_Any}; // The remainder of cases are NVVM intrinsics that map to LLVM idioms, but // need special handling. // // We seem to be missing intrinsics for rcp.approx.{ftz.}f32, which is just // as well. case Intrinsic::nvvm_rcp_rn_d: return {SPC_Reciprocal, FTZ_Any}; case Intrinsic::nvvm_fshl_clamp: case Intrinsic::nvvm_fshr_clamp: return {SCP_FunnelShiftClamp, FTZ_Any}; // We do not currently simplify intrinsics that give an approximate // answer. These include: // // - nvvm_cos_approx_{f,ftz_f} // - nvvm_ex2_approx_{d,f,ftz_f} // - nvvm_lg2_approx_{d,f,ftz_f} // - nvvm_sin_approx_{f,ftz_f} // - nvvm_sqrt_approx_{f,ftz_f} // - nvvm_rsqrt_approx_{d,f,ftz_f} // - nvvm_div_approx_{ftz_d,ftz_f,f} // - nvvm_rcp_approx_ftz_d // // Ideally we'd encode them as e.g. "fast call @llvm.cos", where "fast" // means that fastmath is enabled in the intrinsic. Unfortunately only // binary operators (currently) have a fastmath bit in SelectionDAG, so // this information gets lost and we can't select on it. // // TODO: div and rcp are lowered to a binary op, so these we could in // theory lower them to "fast fdiv". default: return {}; } }(); // If Action.FtzRequirementTy is not satisfied by the module's ftz state, we // can bail out now. (Notice that in the case that IID is not an NVVM // intrinsic, we don't have to look up any module metadata, as // FtzRequirementTy will be FTZ_Any.) if (Action.FtzRequirement != FTZ_Any) { // FIXME: Broken for f64 DenormalMode Mode = II->getFunction()->getDenormalMode( Action.IsHalfTy ? APFloat::IEEEhalf() : APFloat::IEEEsingle()); bool FtzEnabled = Mode.Output == DenormalMode::PreserveSign; if (FtzEnabled != (Action.FtzRequirement == FTZ_MustBeOn)) return nullptr; } // Simplify to target-generic intrinsic. if (Action.IID) { SmallVector Args(II->args()); // All the target-generic intrinsics currently of interest to us have one // type argument, equal to that of the nvvm intrinsic's argument. Type *Tys[] = {II->getArgOperand(0)->getType()}; return CallInst::Create( Intrinsic::getOrInsertDeclaration(II->getModule(), *Action.IID, Tys), Args); } // Simplify to target-generic binary op. if (Action.BinaryOp) return BinaryOperator::Create(*Action.BinaryOp, II->getArgOperand(0), II->getArgOperand(1), II->getName()); // Simplify to target-generic cast op. if (Action.CastOp) return CastInst::Create(*Action.CastOp, II->getArgOperand(0), II->getType(), II->getName()); // All that's left are the special cases. if (!Action.Special) return nullptr; switch (*Action.Special) { case SPC_Reciprocal: // Simplify reciprocal. return BinaryOperator::Create( Instruction::FDiv, ConstantFP::get(II->getArgOperand(0)->getType(), 1), II->getArgOperand(0), II->getName()); case SCP_FunnelShiftClamp: { // Canonicalize a clamping funnel shift to the generic llvm funnel shift // when possible, as this is easier for llvm to optimize further. if (const auto *ShiftConst = dyn_cast(II->getArgOperand(2))) { const bool IsLeft = II->getIntrinsicID() == Intrinsic::nvvm_fshl_clamp; if (ShiftConst->getZExtValue() >= II->getType()->getIntegerBitWidth()) return IC.replaceInstUsesWith(*II, II->getArgOperand(IsLeft ? 1 : 0)); const unsigned FshIID = IsLeft ? Intrinsic::fshl : Intrinsic::fshr; return CallInst::Create(Intrinsic::getOrInsertDeclaration( II->getModule(), FshIID, II->getType()), SmallVector(II->args())); } return nullptr; } } llvm_unreachable("All SpecialCase enumerators should be handled in switch."); } // Returns true/false when we know the answer, nullopt otherwise. static std::optional evaluateIsSpace(Intrinsic::ID IID, unsigned AS) { if (AS == NVPTXAS::ADDRESS_SPACE_GENERIC || AS == NVPTXAS::ADDRESS_SPACE_PARAM) return std::nullopt; // Got to check at run-time. switch (IID) { case Intrinsic::nvvm_isspacep_global: return AS == NVPTXAS::ADDRESS_SPACE_GLOBAL; case Intrinsic::nvvm_isspacep_local: return AS == NVPTXAS::ADDRESS_SPACE_LOCAL; case Intrinsic::nvvm_isspacep_shared: // If shared cluster this can't be evaluated at compile time. if (AS == NVPTXAS::ADDRESS_SPACE_SHARED_CLUSTER) return std::nullopt; return AS == NVPTXAS::ADDRESS_SPACE_SHARED; case Intrinsic::nvvm_isspacep_shared_cluster: return AS == NVPTXAS::ADDRESS_SPACE_SHARED_CLUSTER || AS == NVPTXAS::ADDRESS_SPACE_SHARED; case Intrinsic::nvvm_isspacep_const: return AS == NVPTXAS::ADDRESS_SPACE_CONST; default: llvm_unreachable("Unexpected intrinsic"); } } // Returns an instruction pointer (may be nullptr if we do not know the answer). // Returns nullopt if `II` is not one of the `isspacep` intrinsics. // // TODO: If InferAddressSpaces were run early enough in the pipeline this could // be removed in favor of the constant folding that occurs there through // rewriteIntrinsicWithAddressSpace static std::optional handleSpaceCheckIntrinsics(InstCombiner &IC, IntrinsicInst &II) { switch (auto IID = II.getIntrinsicID()) { case Intrinsic::nvvm_isspacep_global: case Intrinsic::nvvm_isspacep_local: case Intrinsic::nvvm_isspacep_shared: case Intrinsic::nvvm_isspacep_shared_cluster: case Intrinsic::nvvm_isspacep_const: { Value *Op0 = II.getArgOperand(0); unsigned AS = Op0->getType()->getPointerAddressSpace(); // Peek through ASC to generic AS. // TODO: we could dig deeper through both ASCs and GEPs. if (AS == NVPTXAS::ADDRESS_SPACE_GENERIC) if (auto *ASCO = dyn_cast(Op0)) AS = ASCO->getOperand(0)->getType()->getPointerAddressSpace(); if (std::optional Answer = evaluateIsSpace(IID, AS)) return IC.replaceInstUsesWith(II, ConstantInt::get(II.getType(), *Answer)); return nullptr; // Don't know the answer, got to check at run time. } default: return std::nullopt; } } std::optional NVPTXTTIImpl::instCombineIntrinsic(InstCombiner &IC, IntrinsicInst &II) const { if (std::optional I = handleSpaceCheckIntrinsics(IC, II)) return *I; if (Instruction *I = convertNvvmIntrinsicToLlvm(IC, &II)) return I; return std::nullopt; } InstructionCost NVPTXTTIImpl::getInstructionCost(const User *U, ArrayRef Operands, TTI::TargetCostKind CostKind) const { if (const auto *CI = dyn_cast(U)) if (const auto *IA = dyn_cast(CI->getCalledOperand())) { // Without this implementation getCallCost() would return the number // of arguments+1 as the cost. Because the cost-model assumes it is a call // since it is classified as a call in the IR. A better cost model would // be to return the number of asm instructions embedded in the asm // string. StringRef AsmStr = IA->getAsmString(); const unsigned InstCount = count_if(split(AsmStr, ';'), [](StringRef AsmInst) { // Trim off scopes denoted by '{' and '}' as these can be ignored AsmInst = AsmInst.trim().ltrim("{} \t\n\v\f\r"); // This is pretty coarse but does a reasonably good job of // identifying things that look like instructions, possibly with a // predicate ("@"). return !AsmInst.empty() && (AsmInst[0] == '@' || isAlpha(AsmInst[0]) || AsmInst.find(".pragma") != StringRef::npos); }); return InstCount * TargetTransformInfo::TCC_Basic; } return BaseT::getInstructionCost(U, Operands, CostKind); } InstructionCost NVPTXTTIImpl::getArithmeticInstrCost( unsigned Opcode, Type *Ty, TTI::TargetCostKind CostKind, TTI::OperandValueInfo Op1Info, TTI::OperandValueInfo Op2Info, ArrayRef Args, const Instruction *CxtI) const { // Legalize the type. std::pair LT = getTypeLegalizationCost(Ty); int ISD = TLI->InstructionOpcodeToISD(Opcode); switch (ISD) { default: return BaseT::getArithmeticInstrCost(Opcode, Ty, CostKind, Op1Info, Op2Info); case ISD::ADD: case ISD::MUL: case ISD::XOR: case ISD::OR: case ISD::AND: // The machine code (SASS) simulates an i64 with two i32. Therefore, we // estimate that arithmetic operations on i64 are twice as expensive as // those on types that can fit into one machine register. if (LT.second.SimpleTy == MVT::i64) return 2 * LT.first; // Delegate other cases to the basic TTI. return BaseT::getArithmeticInstrCost(Opcode, Ty, CostKind, Op1Info, Op2Info); } } void NVPTXTTIImpl::getUnrollingPreferences( Loop *L, ScalarEvolution &SE, TTI::UnrollingPreferences &UP, OptimizationRemarkEmitter *ORE) const { BaseT::getUnrollingPreferences(L, SE, UP, ORE); // Enable partial unrolling and runtime unrolling, but reduce the // threshold. This partially unrolls small loops which are often // unrolled by the PTX to SASS compiler and unrolling earlier can be // beneficial. UP.Partial = UP.Runtime = true; UP.PartialThreshold = UP.Threshold / 4; } void NVPTXTTIImpl::getPeelingPreferences(Loop *L, ScalarEvolution &SE, TTI::PeelingPreferences &PP) const { BaseT::getPeelingPreferences(L, SE, PP); } bool NVPTXTTIImpl::collectFlatAddressOperands(SmallVectorImpl &OpIndexes, Intrinsic::ID IID) const { switch (IID) { case Intrinsic::nvvm_isspacep_const: case Intrinsic::nvvm_isspacep_global: case Intrinsic::nvvm_isspacep_local: case Intrinsic::nvvm_isspacep_shared: case Intrinsic::nvvm_isspacep_shared_cluster: { OpIndexes.push_back(0); return true; } } return false; } Value *NVPTXTTIImpl::rewriteIntrinsicWithAddressSpace(IntrinsicInst *II, Value *OldV, Value *NewV) const { const Intrinsic::ID IID = II->getIntrinsicID(); switch (IID) { case Intrinsic::nvvm_isspacep_const: case Intrinsic::nvvm_isspacep_global: case Intrinsic::nvvm_isspacep_local: case Intrinsic::nvvm_isspacep_shared: case Intrinsic::nvvm_isspacep_shared_cluster: { const unsigned NewAS = NewV->getType()->getPointerAddressSpace(); if (const auto R = evaluateIsSpace(IID, NewAS)) return ConstantInt::get(II->getType(), *R); return nullptr; } } return nullptr; } unsigned NVPTXTTIImpl::getLoadStoreVecRegBitWidth(unsigned AddrSpace) const { // 256 bit loads/stores are currently only supported for global address space if (ST->has256BitVectorLoadStore(AddrSpace)) return 256; return 128; } unsigned NVPTXTTIImpl::getAssumedAddrSpace(const Value *V) const { if (isa(V)) return ADDRESS_SPACE_LOCAL; if (const Argument *Arg = dyn_cast(V)) { if (isKernelFunction(*Arg->getParent())) { const NVPTXTargetMachine &TM = static_cast(getTLI()->getTargetMachine()); if (TM.getDrvInterface() == NVPTX::CUDA && !Arg->hasByValAttr()) return ADDRESS_SPACE_GLOBAL; } else { // We assume that all device parameters that are passed byval will be // placed in the local AS. Very simple cases will be updated after ISel to // use the device param space where possible. if (Arg->hasByValAttr()) return ADDRESS_SPACE_LOCAL; } } return -1; } void NVPTXTTIImpl::collectKernelLaunchBounds( const Function &F, SmallVectorImpl> &LB) const { if (const auto Val = getMaxClusterRank(F)) LB.push_back({"maxclusterrank", *Val}); const auto MaxNTID = getMaxNTID(F); if (MaxNTID.size() > 0) LB.push_back({"maxntidx", MaxNTID[0]}); if (MaxNTID.size() > 1) LB.push_back({"maxntidy", MaxNTID[1]}); if (MaxNTID.size() > 2) LB.push_back({"maxntidz", MaxNTID[2]}); }