llvm/lib/Target/NVPTX/NVPTXTargetTransformInfo.cpp - llvm-project - Git at Google

 //===-- 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/Analysis/LoopInfo.h"
 #include "llvm/Analysis/TargetTransformInfo.h"
 #include "llvm/Analysis/ValueTracking.h"
 #include "llvm/CodeGen/BasicTTIImpl.h"
 #include "llvm/CodeGen/CostTable.h"
 #include "llvm/CodeGen/TargetLowering.h"
 #include "llvm/IR/IntrinsicsNVPTX.h"
 #include "llvm/Support/Debug.h"
 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_load_inc_32:
     case Intrinsic::nvvm_atomic_load_dec_32:

     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) {
   // Without inter-procedural analysis, we conservatively assume that arguments
   // to __device__ functions are divergent.
   if (const Argument *Arg = dyn_cast<Argument>(V))
     return !isKernelFunction(*Arg->getParent());

   if (const Instruction *I = dyn_cast<Instruction>(V)) {
     // Without pointer analysis, we conservatively assume values loaded from
     // generic or local address space are divergent.
     if (const LoadInst *LI = dyn_cast<LoadInst>(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<IntrinsicInst>(I)) {
       // Instructions that read threadIdx are obviously divergent.
       if (readsThreadIndex(II) || readsLaneId(II))
         return true;
       // Handle the NVPTX atomic instrinsics 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<CallInst>(I))
       return true;
   }

   return false;
 }

 // Convert NVVM intrinsics to target-generic LLVM code where possible.
 static Instruction *simplifyNvvmIntrinsic(IntrinsicInst *II, InstCombiner &IC) {
   // 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,
   };

   // 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.
     Optional<Intrinsic::ID> IID;
     Optional<Instruction::CastOps> CastOp;
     Optional<Instruction::BinaryOps> BinaryOp;
     Optional<SpecialCase> Special;

     FtzRequirementTy FtzRequirement = FTZ_Any;

     SimplifyAction() = default;

     SimplifyAction(Intrinsic::ID IID, FtzRequirementTy FtzReq)
         : IID(IID), FtzRequirement(FtzReq) {}

     // 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_fabs_d:
       return {Intrinsic::fabs, FTZ_Any};
     case Intrinsic::nvvm_fabs_f:
       return {Intrinsic::fabs, FTZ_MustBeOff};
     case Intrinsic::nvvm_fabs_ftz_f:
       return {Intrinsic::fabs, 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_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_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_round_d:
       return {Intrinsic::round, FTZ_Any};
     case Intrinsic::nvvm_round_f:
       return {Intrinsic::round, FTZ_MustBeOff};
     case Intrinsic::nvvm_round_ftz_f:
       return {Intrinsic::round, FTZ_MustBeOn};
     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_sqrt_rn_f:
       return {Intrinsic::sqrt, FTZ_MustBeOff};
     case Intrinsic::nvvm_sqrt_rn_ftz_f:
       return {Intrinsic::sqrt, FTZ_MustBeOn};
     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};
     case Intrinsic::nvvm_i2d_rz:
     case Intrinsic::nvvm_i2f_rz:
     case Intrinsic::nvvm_ll2d_rz:
     case Intrinsic::nvvm_ll2f_rz:
       return {Instruction::SIToFP};
     case Intrinsic::nvvm_ui2d_rz:
     case Intrinsic::nvvm_ui2f_rz:
     case Intrinsic::nvvm_ull2d_rz:
     case Intrinsic::nvvm_ull2f_rz:
       return {Instruction::UIToFP};

     // NVVM intrinsics that map to LLVM binary ops.
     case Intrinsic::nvvm_add_rn_d:
       return {Instruction::FAdd, FTZ_Any};
     case Intrinsic::nvvm_add_rn_f:
       return {Instruction::FAdd, FTZ_MustBeOff};
     case Intrinsic::nvvm_add_rn_ftz_f:
       return {Instruction::FAdd, FTZ_MustBeOn};
     case Intrinsic::nvvm_mul_rn_d:
       return {Instruction::FMul, FTZ_Any};
     case Intrinsic::nvvm_mul_rn_f:
       return {Instruction::FMul, FTZ_MustBeOff};
     case Intrinsic::nvvm_mul_rn_ftz_f:
       return {Instruction::FMul, FTZ_MustBeOn};
     case Intrinsic::nvvm_div_rn_d:
       return {Instruction::FDiv, FTZ_Any};
     case Intrinsic::nvvm_div_rn_f:
       return {Instruction::FDiv, FTZ_MustBeOff};
     case Intrinsic::nvvm_div_rn_ftz_f:
       return {Instruction::FDiv, FTZ_MustBeOn};

     // 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_rcp_rn_f:
       return {SPC_Reciprocal, FTZ_MustBeOff};
     case Intrinsic::nvvm_rcp_rn_ftz_f:
       return {SPC_Reciprocal, FTZ_MustBeOn};

       // 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) {
     StringRef Attr = II->getFunction()
                          ->getFnAttribute("denormal-fp-math-f32")
                          .getValueAsString();
     DenormalMode Mode = parseDenormalFPAttribute(Attr);
     bool FtzEnabled = Mode.Output != DenormalMode::IEEE;

     if (FtzEnabled != (Action.FtzRequirement == FTZ_MustBeOn))
       return nullptr;
   }

   // Simplify to target-generic intrinsic.
   if (Action.IID) {
     SmallVector<Value *, 4> 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::getDeclaration(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());
   }
   llvm_unreachable("All SpecialCase enumerators should be handled in switch.");
 }

 Optional<Instruction *>
 NVPTXTTIImpl::instCombineIntrinsic(InstCombiner &IC, IntrinsicInst &II) const {
   if (Instruction *I = simplifyNvvmIntrinsic(&II, IC)) {
     return I;
   }
   return None;
 }

 InstructionCost NVPTXTTIImpl::getArithmeticInstrCost(
     unsigned Opcode, Type *Ty, TTI::TargetCostKind CostKind,
     TTI::OperandValueKind Opd1Info, TTI::OperandValueKind Opd2Info,
     TTI::OperandValueProperties Opd1PropInfo,
     TTI::OperandValueProperties Opd2PropInfo, ArrayRef<const Value *> Args,
     const Instruction *CxtI) {
   // Legalize the type.
   std::pair<InstructionCost, MVT> LT = TLI->getTypeLegalizationCost(DL, Ty);

   int ISD = TLI->InstructionOpcodeToISD(Opcode);

   switch (ISD) {
   default:
     return BaseT::getArithmeticInstrCost(Opcode, Ty, CostKind, Opd1Info,
                                          Opd2Info,
                                          Opd1PropInfo, Opd2PropInfo);
   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, Opd1Info,
                                          Opd2Info,
                                          Opd1PropInfo, Opd2PropInfo);
   }
 }

 void NVPTXTTIImpl::getUnrollingPreferences(Loop *L, ScalarEvolution &SE,
                                            TTI::UnrollingPreferences &UP,
                                            OptimizationRemarkEmitter *ORE) {
   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) {
   BaseT::getPeelingPreferences(L, SE, PP);
 }
	//===-- 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/Analysis/LoopInfo.h"
	#include "llvm/Analysis/TargetTransformInfo.h"
	#include "llvm/Analysis/ValueTracking.h"
	#include "llvm/CodeGen/BasicTTIImpl.h"
	#include "llvm/CodeGen/CostTable.h"
	#include "llvm/CodeGen/TargetLowering.h"
	#include "llvm/IR/IntrinsicsNVPTX.h"
	#include "llvm/Support/Debug.h"
	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_load_inc_32:
	case Intrinsic::nvvm_atomic_load_dec_32:

	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) {
	// Without inter-procedural analysis, we conservatively assume that arguments
	// to __device__ functions are divergent.
	if (const Argument *Arg = dyn_cast<Argument>(V))
	return !isKernelFunction(*Arg->getParent());

	if (const Instruction *I = dyn_cast<Instruction>(V)) {
	// Without pointer analysis, we conservatively assume values loaded from
	// generic or local address space are divergent.
	if (const LoadInst *LI = dyn_cast<LoadInst>(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<IntrinsicInst>(I)) {
	// Instructions that read threadIdx are obviously divergent.
	if (readsThreadIndex(II) \|\| readsLaneId(II))
	return true;
	// Handle the NVPTX atomic instrinsics 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<CallInst>(I))
	return true;
	}

	return false;
	}

	// Convert NVVM intrinsics to target-generic LLVM code where possible.
	static Instruction simplifyNvvmIntrinsic(IntrinsicInst II, InstCombiner &IC) {
	// 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,
	};

	// 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.
	Optional<Intrinsic::ID> IID;
	Optional<Instruction::CastOps> CastOp;
	Optional<Instruction::BinaryOps> BinaryOp;
	Optional<SpecialCase> Special;

	FtzRequirementTy FtzRequirement = FTZ_Any;

	SimplifyAction() = default;

	SimplifyAction(Intrinsic::ID IID, FtzRequirementTy FtzReq)
	: IID(IID), FtzRequirement(FtzReq) {}

	// 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_fabs_d:
	return {Intrinsic::fabs, FTZ_Any};
	case Intrinsic::nvvm_fabs_f:
	return {Intrinsic::fabs, FTZ_MustBeOff};
	case Intrinsic::nvvm_fabs_ftz_f:
	return {Intrinsic::fabs, 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_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_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_round_d:
	return {Intrinsic::round, FTZ_Any};
	case Intrinsic::nvvm_round_f:
	return {Intrinsic::round, FTZ_MustBeOff};
	case Intrinsic::nvvm_round_ftz_f:
	return {Intrinsic::round, FTZ_MustBeOn};
	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_sqrt_rn_f:
	return {Intrinsic::sqrt, FTZ_MustBeOff};
	case Intrinsic::nvvm_sqrt_rn_ftz_f:
	return {Intrinsic::sqrt, FTZ_MustBeOn};
	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};
	case Intrinsic::nvvm_i2d_rz:
	case Intrinsic::nvvm_i2f_rz:
	case Intrinsic::nvvm_ll2d_rz:
	case Intrinsic::nvvm_ll2f_rz:
	return {Instruction::SIToFP};
	case Intrinsic::nvvm_ui2d_rz:
	case Intrinsic::nvvm_ui2f_rz:
	case Intrinsic::nvvm_ull2d_rz:
	case Intrinsic::nvvm_ull2f_rz:
	return {Instruction::UIToFP};

	// NVVM intrinsics that map to LLVM binary ops.
	case Intrinsic::nvvm_add_rn_d:
	return {Instruction::FAdd, FTZ_Any};
	case Intrinsic::nvvm_add_rn_f:
	return {Instruction::FAdd, FTZ_MustBeOff};
	case Intrinsic::nvvm_add_rn_ftz_f:
	return {Instruction::FAdd, FTZ_MustBeOn};
	case Intrinsic::nvvm_mul_rn_d:
	return {Instruction::FMul, FTZ_Any};
	case Intrinsic::nvvm_mul_rn_f:
	return {Instruction::FMul, FTZ_MustBeOff};
	case Intrinsic::nvvm_mul_rn_ftz_f:
	return {Instruction::FMul, FTZ_MustBeOn};
	case Intrinsic::nvvm_div_rn_d:
	return {Instruction::FDiv, FTZ_Any};
	case Intrinsic::nvvm_div_rn_f:
	return {Instruction::FDiv, FTZ_MustBeOff};
	case Intrinsic::nvvm_div_rn_ftz_f:
	return {Instruction::FDiv, FTZ_MustBeOn};

	// 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_rcp_rn_f:
	return {SPC_Reciprocal, FTZ_MustBeOff};
	case Intrinsic::nvvm_rcp_rn_ftz_f:
	return {SPC_Reciprocal, FTZ_MustBeOn};

	// 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) {
	StringRef Attr = II->getFunction()
	->getFnAttribute("denormal-fp-math-f32")
	.getValueAsString();
	DenormalMode Mode = parseDenormalFPAttribute(Attr);
	bool FtzEnabled = Mode.Output != DenormalMode::IEEE;

	if (FtzEnabled != (Action.FtzRequirement == FTZ_MustBeOn))
	return nullptr;
	}

	// Simplify to target-generic intrinsic.
	if (Action.IID) {
	SmallVector<Value *, 4> 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::getDeclaration(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());
	}
	llvm_unreachable("All SpecialCase enumerators should be handled in switch.");
	}

	Optional<Instruction *>
	NVPTXTTIImpl::instCombineIntrinsic(InstCombiner &IC, IntrinsicInst &II) const {
	if (Instruction *I = simplifyNvvmIntrinsic(&II, IC)) {
	return I;
	}
	return None;
	}

	InstructionCost NVPTXTTIImpl::getArithmeticInstrCost(
	unsigned Opcode, Type *Ty, TTI::TargetCostKind CostKind,
	TTI::OperandValueKind Opd1Info, TTI::OperandValueKind Opd2Info,
	TTI::OperandValueProperties Opd1PropInfo,
	TTI::OperandValueProperties Opd2PropInfo, ArrayRef<const Value *> Args,
	const Instruction *CxtI) {
	// Legalize the type.
	std::pair<InstructionCost, MVT> LT = TLI->getTypeLegalizationCost(DL, Ty);

	int ISD = TLI->InstructionOpcodeToISD(Opcode);

	switch (ISD) {
	default:
	return BaseT::getArithmeticInstrCost(Opcode, Ty, CostKind, Opd1Info,
	Opd2Info,
	Opd1PropInfo, Opd2PropInfo);
	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, Opd1Info,
	Opd2Info,
	Opd1PropInfo, Opd2PropInfo);
	}
	}

	void NVPTXTTIImpl::getUnrollingPreferences(Loop *L, ScalarEvolution &SE,
	TTI::UnrollingPreferences &UP,
	OptimizationRemarkEmitter *ORE) {
	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) {
	BaseT::getPeelingPreferences(L, SE, PP);
	}