lib/Target/AMDGPU/AMDGPUAtomicOptimizer.cpp - llvm - Git at Google

 //===-- AMDGPUAtomicOptimizer.cpp -----------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 /// \file
 /// This pass optimizes atomic operations by using a single lane of a wavefront
 /// to perform the atomic operation, thus reducing contention on that memory
 /// location.
 //
 //===----------------------------------------------------------------------===//

 #include "AMDGPU.h"
 #include "AMDGPUSubtarget.h"
 #include "llvm/Analysis/LegacyDivergenceAnalysis.h"
 #include "llvm/CodeGen/TargetPassConfig.h"
 #include "llvm/IR/IRBuilder.h"
 #include "llvm/IR/InstVisitor.h"
 #include "llvm/Transforms/Utils/BasicBlockUtils.h"

 #define DEBUG_TYPE "amdgpu-atomic-optimizer"

 using namespace llvm;

 namespace {

 enum DPP_CTRL {
   DPP_ROW_SR1 = 0x111,
   DPP_ROW_SR2 = 0x112,
   DPP_ROW_SR3 = 0x113,
   DPP_ROW_SR4 = 0x114,
   DPP_ROW_SR8 = 0x118,
   DPP_WF_SR1 = 0x138,
   DPP_ROW_BCAST15 = 0x142,
   DPP_ROW_BCAST31 = 0x143
 };

 struct ReplacementInfo {
   Instruction *I;
   Instruction::BinaryOps Op;
   unsigned ValIdx;
   bool ValDivergent;
 };

 class AMDGPUAtomicOptimizer : public FunctionPass,
                               public InstVisitor<AMDGPUAtomicOptimizer> {
 private:
   SmallVector<ReplacementInfo, 8> ToReplace;
   const LegacyDivergenceAnalysis *DA;
   const DataLayout *DL;
   DominatorTree *DT;
   bool HasDPP;
   bool IsPixelShader;

   void optimizeAtomic(Instruction &I, Instruction::BinaryOps Op,
                       unsigned ValIdx, bool ValDivergent) const;

   void setConvergent(CallInst *const CI) const;

 public:
   static char ID;

   AMDGPUAtomicOptimizer() : FunctionPass(ID) {}

   bool runOnFunction(Function &F) override;

   void getAnalysisUsage(AnalysisUsage &AU) const override {
     AU.addPreserved<DominatorTreeWrapperPass>();
     AU.addRequired<LegacyDivergenceAnalysis>();
     AU.addRequired<TargetPassConfig>();
   }

   void visitAtomicRMWInst(AtomicRMWInst &I);
   void visitIntrinsicInst(IntrinsicInst &I);
 };

 } // namespace

 char AMDGPUAtomicOptimizer::ID = 0;

 char &llvm::AMDGPUAtomicOptimizerID = AMDGPUAtomicOptimizer::ID;

 bool AMDGPUAtomicOptimizer::runOnFunction(Function &F) {
   if (skipFunction(F)) {
     return false;
   }

   DA = &getAnalysis<LegacyDivergenceAnalysis>();
   DL = &F.getParent()->getDataLayout();
   DominatorTreeWrapperPass *const DTW =
       getAnalysisIfAvailable<DominatorTreeWrapperPass>();
   DT = DTW ? &DTW->getDomTree() : nullptr;
   const TargetPassConfig &TPC = getAnalysis<TargetPassConfig>();
   const TargetMachine &TM = TPC.getTM<TargetMachine>();
   const GCNSubtarget &ST = TM.getSubtarget<GCNSubtarget>(F);
   HasDPP = ST.hasDPP();
   IsPixelShader = F.getCallingConv() == CallingConv::AMDGPU_PS;

   visit(F);

   const bool Changed = !ToReplace.empty();

   for (ReplacementInfo &Info : ToReplace) {
     optimizeAtomic(*Info.I, Info.Op, Info.ValIdx, Info.ValDivergent);
   }

   ToReplace.clear();

   return Changed;
 }

 void AMDGPUAtomicOptimizer::visitAtomicRMWInst(AtomicRMWInst &I) {
   // Early exit for unhandled address space atomic instructions.
   switch (I.getPointerAddressSpace()) {
   default:
     return;
   case AMDGPUAS::GLOBAL_ADDRESS:
   case AMDGPUAS::LOCAL_ADDRESS:
     break;
   }

   Instruction::BinaryOps Op;

   switch (I.getOperation()) {
   default:
     return;
   case AtomicRMWInst::Add:
     Op = Instruction::Add;
     break;
   case AtomicRMWInst::Sub:
     Op = Instruction::Sub;
     break;
   }

   const unsigned PtrIdx = 0;
   const unsigned ValIdx = 1;

   // If the pointer operand is divergent, then each lane is doing an atomic
   // operation on a different address, and we cannot optimize that.
   if (DA->isDivergent(I.getOperand(PtrIdx))) {
     return;
   }

   const bool ValDivergent = DA->isDivergent(I.getOperand(ValIdx));

   // If the value operand is divergent, each lane is contributing a different
   // value to the atomic calculation. We can only optimize divergent values if
   // we have DPP available on our subtarget, and the atomic operation is 32
   // bits.
   if (ValDivergent && (!HasDPP || (DL->getTypeSizeInBits(I.getType()) != 32))) {
     return;
   }

   // If we get here, we can optimize the atomic using a single wavefront-wide
   // atomic operation to do the calculation for the entire wavefront, so
   // remember the instruction so we can come back to it.
   const ReplacementInfo Info = {&I, Op, ValIdx, ValDivergent};

   ToReplace.push_back(Info);
 }

 void AMDGPUAtomicOptimizer::visitIntrinsicInst(IntrinsicInst &I) {
   Instruction::BinaryOps Op;

   switch (I.getIntrinsicID()) {
   default:
     return;
   case Intrinsic::amdgcn_buffer_atomic_add:
   case Intrinsic::amdgcn_struct_buffer_atomic_add:
   case Intrinsic::amdgcn_raw_buffer_atomic_add:
     Op = Instruction::Add;
     break;
   case Intrinsic::amdgcn_buffer_atomic_sub:
   case Intrinsic::amdgcn_struct_buffer_atomic_sub:
   case Intrinsic::amdgcn_raw_buffer_atomic_sub:
     Op = Instruction::Sub;
     break;
   }

   const unsigned ValIdx = 0;

   const bool ValDivergent = DA->isDivergent(I.getOperand(ValIdx));

   // If the value operand is divergent, each lane is contributing a different
   // value to the atomic calculation. We can only optimize divergent values if
   // we have DPP available on our subtarget, and the atomic operation is 32
   // bits.
   if (ValDivergent && (!HasDPP || (DL->getTypeSizeInBits(I.getType()) != 32))) {
     return;
   }

   // If any of the other arguments to the intrinsic are divergent, we can't
   // optimize the operation.
   for (unsigned Idx = 1; Idx < I.getNumOperands(); Idx++) {
     if (DA->isDivergent(I.getOperand(Idx))) {
       return;
     }
   }

   // If we get here, we can optimize the atomic using a single wavefront-wide
   // atomic operation to do the calculation for the entire wavefront, so
   // remember the instruction so we can come back to it.
   const ReplacementInfo Info = {&I, Op, ValIdx, ValDivergent};

   ToReplace.push_back(Info);
 }

 void AMDGPUAtomicOptimizer::optimizeAtomic(Instruction &I,
                                            Instruction::BinaryOps Op,
                                            unsigned ValIdx,
                                            bool ValDivergent) const {
   // Start building just before the instruction.
   IRBuilder<> B(&I);

   // If we are in a pixel shader, because of how we have to mask out helper
   // lane invocations, we need to record the entry and exit BB's.
   BasicBlock *PixelEntryBB = nullptr;
   BasicBlock *PixelExitBB = nullptr;

   // If we're optimizing an atomic within a pixel shader, we need to wrap the
   // entire atomic operation in a helper-lane check. We do not want any helper
   // lanes that are around only for the purposes of derivatives to take part
   // in any cross-lane communication, and we use a branch on whether the lane is
   // live to do this.
   if (IsPixelShader) {
     // Record I's original position as the entry block.
     PixelEntryBB = I.getParent();

     Value *const Cond = B.CreateIntrinsic(Intrinsic::amdgcn_ps_live, {}, {});
     Instruction *const NonHelperTerminator =
         SplitBlockAndInsertIfThen(Cond, &I, false, nullptr, DT, nullptr);

     // Record I's new position as the exit block.
     PixelExitBB = I.getParent();

     I.moveBefore(NonHelperTerminator);
     B.SetInsertPoint(&I);
   }

   Type *const Ty = I.getType();
   const unsigned TyBitWidth = DL->getTypeSizeInBits(Ty);
   Type *const VecTy = VectorType::get(B.getInt32Ty(), 2);

   // This is the value in the atomic operation we need to combine in order to
   // reduce the number of atomic operations.
   Value *const V = I.getOperand(ValIdx);

   // We need to know how many lanes are active within the wavefront, and we do
   // this by doing a ballot of active lanes.
   CallInst *const Ballot =
       B.CreateIntrinsic(Intrinsic::amdgcn_icmp, {B.getInt32Ty()},
                         {B.getInt32(1), B.getInt32(0), B.getInt32(33)});
   setConvergent(Ballot);

   // We need to know how many lanes are active within the wavefront that are
   // below us. If we counted each lane linearly starting from 0, a lane is
   // below us only if its associated index was less than ours. We do this by
   // using the mbcnt intrinsic.
   Value *const BitCast = B.CreateBitCast(Ballot, VecTy);
   Value *const ExtractLo = B.CreateExtractElement(BitCast, B.getInt32(0));
   Value *const ExtractHi = B.CreateExtractElement(BitCast, B.getInt32(1));
   CallInst *const PartialMbcnt = B.CreateIntrinsic(
       Intrinsic::amdgcn_mbcnt_lo, {}, {ExtractLo, B.getInt32(0)});
   CallInst *const Mbcnt = B.CreateIntrinsic(Intrinsic::amdgcn_mbcnt_hi, {},
                                             {ExtractHi, PartialMbcnt});

   Value *const MbcntCast = B.CreateIntCast(Mbcnt, Ty, false);

   Value *LaneOffset = nullptr;
   Value *NewV = nullptr;

   // If we have a divergent value in each lane, we need to combine the value
   // using DPP.
   if (ValDivergent) {
     Value *const Identity = B.getIntN(TyBitWidth, 0);

     // First we need to set all inactive invocations to 0, so that they can
     // correctly contribute to the final result.
     CallInst *const SetInactive =
         B.CreateIntrinsic(Intrinsic::amdgcn_set_inactive, Ty, {V, Identity});
     setConvergent(SetInactive);

     CallInst *const FirstDPP =
         B.CreateIntrinsic(Intrinsic::amdgcn_update_dpp, Ty,
                           {Identity, SetInactive, B.getInt32(DPP_WF_SR1),
                            B.getInt32(0xf), B.getInt32(0xf), B.getFalse()});
     setConvergent(FirstDPP);
     NewV = FirstDPP;

     const unsigned Iters = 7;
     const unsigned DPPCtrl[Iters] = {
         DPP_ROW_SR1, DPP_ROW_SR2,     DPP_ROW_SR3,    DPP_ROW_SR4,
         DPP_ROW_SR8, DPP_ROW_BCAST15, DPP_ROW_BCAST31};
     const unsigned RowMask[Iters] = {0xf, 0xf, 0xf, 0xf, 0xf, 0xa, 0xc};
     const unsigned BankMask[Iters] = {0xf, 0xf, 0xf, 0xe, 0xc, 0xf, 0xf};

     // This loop performs an exclusive scan across the wavefront, with all lanes
     // active (by using the WWM intrinsic).
     for (unsigned Idx = 0; Idx < Iters; Idx++) {
       Value *const UpdateValue = Idx < 3 ? FirstDPP : NewV;
       CallInst *const DPP = B.CreateIntrinsic(
           Intrinsic::amdgcn_update_dpp, Ty,
           {Identity, UpdateValue, B.getInt32(DPPCtrl[Idx]),
            B.getInt32(RowMask[Idx]), B.getInt32(BankMask[Idx]), B.getFalse()});
       setConvergent(DPP);

       NewV = B.CreateBinOp(Op, NewV, DPP);
     }

     LaneOffset = B.CreateIntrinsic(Intrinsic::amdgcn_wwm, Ty, NewV);
     NewV = B.CreateBinOp(Op, NewV, SetInactive);

     // Read the value from the last lane, which has accumlated the values of
     // each active lane in the wavefront. This will be our new value with which
     // we will provide to the atomic operation.
     if (TyBitWidth == 64) {
       Value *const ExtractLo = B.CreateTrunc(NewV, B.getInt32Ty());
       Value *const ExtractHi =
           B.CreateTrunc(B.CreateLShr(NewV, B.getInt64(32)), B.getInt32Ty());
       CallInst *const ReadLaneLo = B.CreateIntrinsic(
           Intrinsic::amdgcn_readlane, {}, {ExtractLo, B.getInt32(63)});
       setConvergent(ReadLaneLo);
       CallInst *const ReadLaneHi = B.CreateIntrinsic(
           Intrinsic::amdgcn_readlane, {}, {ExtractHi, B.getInt32(63)});
       setConvergent(ReadLaneHi);
       Value *const PartialInsert = B.CreateInsertElement(
           UndefValue::get(VecTy), ReadLaneLo, B.getInt32(0));
       Value *const Insert =
           B.CreateInsertElement(PartialInsert, ReadLaneHi, B.getInt32(1));
       NewV = B.CreateBitCast(Insert, Ty);
     } else if (TyBitWidth == 32) {
       CallInst *const ReadLane = B.CreateIntrinsic(Intrinsic::amdgcn_readlane,
                                                    {}, {NewV, B.getInt32(63)});
       setConvergent(ReadLane);
       NewV = ReadLane;
     } else {
       llvm_unreachable("Unhandled atomic bit width");
     }

     // Finally mark the readlanes in the WWM section.
     NewV = B.CreateIntrinsic(Intrinsic::amdgcn_wwm, Ty, NewV);
   } else {
     // Get the total number of active lanes we have by using popcount.
     Instruction *const Ctpop = B.CreateUnaryIntrinsic(Intrinsic::ctpop, Ballot);
     Value *const CtpopCast = B.CreateIntCast(Ctpop, Ty, false);

     // Calculate the new value we will be contributing to the atomic operation
     // for the entire wavefront.
     NewV = B.CreateMul(V, CtpopCast);
     LaneOffset = B.CreateMul(V, MbcntCast);
   }

   // We only want a single lane to enter our new control flow, and we do this
   // by checking if there are any active lanes below us. Only one lane will
   // have 0 active lanes below us, so that will be the only one to progress.
   Value *const Cond = B.CreateICmpEQ(MbcntCast, B.getIntN(TyBitWidth, 0));

   // Store I's original basic block before we split the block.
   BasicBlock *const EntryBB = I.getParent();

   // We need to introduce some new control flow to force a single lane to be
   // active. We do this by splitting I's basic block at I, and introducing the
   // new block such that:
   // entry --> single_lane -\
   //       \------------------> exit
   Instruction *const SingleLaneTerminator =
       SplitBlockAndInsertIfThen(Cond, &I, false, nullptr, DT, nullptr);

   // Move the IR builder into single_lane next.
   B.SetInsertPoint(SingleLaneTerminator);

   // Clone the original atomic operation into single lane, replacing the
   // original value with our newly created one.
   Instruction *const NewI = I.clone();
   B.Insert(NewI);
   NewI->setOperand(ValIdx, NewV);

   // Move the IR builder into exit next, and start inserting just before the
   // original instruction.
   B.SetInsertPoint(&I);

   // Create a PHI node to get our new atomic result into the exit block.
   PHINode *const PHI = B.CreatePHI(Ty, 2);
   PHI->addIncoming(UndefValue::get(Ty), EntryBB);
   PHI->addIncoming(NewI, SingleLaneTerminator->getParent());

   // We need to broadcast the value who was the lowest active lane (the first
   // lane) to all other lanes in the wavefront. We use an intrinsic for this,
   // but have to handle 64-bit broadcasts with two calls to this intrinsic.
   Value *BroadcastI = nullptr;

   if (TyBitWidth == 64) {
     Value *const ExtractLo = B.CreateTrunc(PHI, B.getInt32Ty());
     Value *const ExtractHi =
         B.CreateTrunc(B.CreateLShr(PHI, B.getInt64(32)), B.getInt32Ty());
     CallInst *const ReadFirstLaneLo =
         B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, ExtractLo);
     setConvergent(ReadFirstLaneLo);
     CallInst *const ReadFirstLaneHi =
         B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, ExtractHi);
     setConvergent(ReadFirstLaneHi);
     Value *const PartialInsert = B.CreateInsertElement(
         UndefValue::get(VecTy), ReadFirstLaneLo, B.getInt32(0));
     Value *const Insert =
         B.CreateInsertElement(PartialInsert, ReadFirstLaneHi, B.getInt32(1));
     BroadcastI = B.CreateBitCast(Insert, Ty);
   } else if (TyBitWidth == 32) {
     CallInst *const ReadFirstLane =
         B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, PHI);
     setConvergent(ReadFirstLane);
     BroadcastI = ReadFirstLane;
   } else {
     llvm_unreachable("Unhandled atomic bit width");
   }

   // Now that we have the result of our single atomic operation, we need to
   // get our individual lane's slice into the result. We use the lane offset we
   // previously calculated combined with the atomic result value we got from the
   // first lane, to get our lane's index into the atomic result.
   Value *const Result = B.CreateBinOp(Op, BroadcastI, LaneOffset);

   if (IsPixelShader) {
     // Need a final PHI to reconverge to above the helper lane branch mask.
     B.SetInsertPoint(PixelExitBB->getFirstNonPHI());

     PHINode *const PHI = B.CreatePHI(Ty, 2);
     PHI->addIncoming(UndefValue::get(Ty), PixelEntryBB);
     PHI->addIncoming(Result, I.getParent());
     I.replaceAllUsesWith(PHI);
   } else {
     // Replace the original atomic instruction with the new one.
     I.replaceAllUsesWith(Result);
   }

   // And delete the original.
   I.eraseFromParent();
 }

 void AMDGPUAtomicOptimizer::setConvergent(CallInst *const CI) const {
   CI->addAttribute(AttributeList::FunctionIndex, Attribute::Convergent);
 }

 INITIALIZE_PASS_BEGIN(AMDGPUAtomicOptimizer, DEBUG_TYPE,
                       "AMDGPU atomic optimizations", false, false)
 INITIALIZE_PASS_DEPENDENCY(LegacyDivergenceAnalysis)
 INITIALIZE_PASS_DEPENDENCY(TargetPassConfig)
 INITIALIZE_PASS_END(AMDGPUAtomicOptimizer, DEBUG_TYPE,
                     "AMDGPU atomic optimizations", false, false)

 FunctionPass *llvm::createAMDGPUAtomicOptimizerPass() {
   return new AMDGPUAtomicOptimizer();
 }
	//===-- AMDGPUAtomicOptimizer.cpp -----------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	/// \file
	/// This pass optimizes atomic operations by using a single lane of a wavefront
	/// to perform the atomic operation, thus reducing contention on that memory
	/// location.
	//
	//===----------------------------------------------------------------------===//

	#include "AMDGPU.h"
	#include "AMDGPUSubtarget.h"
	#include "llvm/Analysis/LegacyDivergenceAnalysis.h"
	#include "llvm/CodeGen/TargetPassConfig.h"
	#include "llvm/IR/IRBuilder.h"
	#include "llvm/IR/InstVisitor.h"
	#include "llvm/Transforms/Utils/BasicBlockUtils.h"

	#define DEBUG_TYPE "amdgpu-atomic-optimizer"

	using namespace llvm;

	namespace {

	enum DPP_CTRL {
	DPP_ROW_SR1 = 0x111,
	DPP_ROW_SR2 = 0x112,
	DPP_ROW_SR3 = 0x113,
	DPP_ROW_SR4 = 0x114,
	DPP_ROW_SR8 = 0x118,
	DPP_WF_SR1 = 0x138,
	DPP_ROW_BCAST15 = 0x142,
	DPP_ROW_BCAST31 = 0x143
	};

	struct ReplacementInfo {
	Instruction *I;
	Instruction::BinaryOps Op;
	unsigned ValIdx;
	bool ValDivergent;
	};

	class AMDGPUAtomicOptimizer : public FunctionPass,
	public InstVisitor<AMDGPUAtomicOptimizer> {
	private:
	SmallVector<ReplacementInfo, 8> ToReplace;
	const LegacyDivergenceAnalysis *DA;
	const DataLayout *DL;
	DominatorTree *DT;
	bool HasDPP;
	bool IsPixelShader;

	void optimizeAtomic(Instruction &I, Instruction::BinaryOps Op,
	unsigned ValIdx, bool ValDivergent) const;

	void setConvergent(CallInst *const CI) const;

	public:
	static char ID;

	AMDGPUAtomicOptimizer() : FunctionPass(ID) {}

	bool runOnFunction(Function &F) override;

	void getAnalysisUsage(AnalysisUsage &AU) const override {
	AU.addPreserved<DominatorTreeWrapperPass>();
	AU.addRequired<LegacyDivergenceAnalysis>();
	AU.addRequired<TargetPassConfig>();
	}

	void visitAtomicRMWInst(AtomicRMWInst &I);
	void visitIntrinsicInst(IntrinsicInst &I);
	};

	} // namespace

	char AMDGPUAtomicOptimizer::ID = 0;

	char &llvm::AMDGPUAtomicOptimizerID = AMDGPUAtomicOptimizer::ID;

	bool AMDGPUAtomicOptimizer::runOnFunction(Function &F) {
	if (skipFunction(F)) {
	return false;
	}

	DA = &getAnalysis<LegacyDivergenceAnalysis>();
	DL = &F.getParent()->getDataLayout();
	DominatorTreeWrapperPass *const DTW =
	getAnalysisIfAvailable<DominatorTreeWrapperPass>();
	DT = DTW ? &DTW->getDomTree() : nullptr;
	const TargetPassConfig &TPC = getAnalysis<TargetPassConfig>();
	const TargetMachine &TM = TPC.getTM<TargetMachine>();
	const GCNSubtarget &ST = TM.getSubtarget<GCNSubtarget>(F);
	HasDPP = ST.hasDPP();
	IsPixelShader = F.getCallingConv() == CallingConv::AMDGPU_PS;

	visit(F);

	const bool Changed = !ToReplace.empty();

	for (ReplacementInfo &Info : ToReplace) {
	optimizeAtomic(*Info.I, Info.Op, Info.ValIdx, Info.ValDivergent);
	}

	ToReplace.clear();

	return Changed;
	}

	void AMDGPUAtomicOptimizer::visitAtomicRMWInst(AtomicRMWInst &I) {
	// Early exit for unhandled address space atomic instructions.
	switch (I.getPointerAddressSpace()) {
	default:
	return;
	case AMDGPUAS::GLOBAL_ADDRESS:
	case AMDGPUAS::LOCAL_ADDRESS:
	break;
	}

	Instruction::BinaryOps Op;

	switch (I.getOperation()) {
	default:
	return;
	case AtomicRMWInst::Add:
	Op = Instruction::Add;
	break;
	case AtomicRMWInst::Sub:
	Op = Instruction::Sub;
	break;
	}

	const unsigned PtrIdx = 0;
	const unsigned ValIdx = 1;

	// If the pointer operand is divergent, then each lane is doing an atomic
	// operation on a different address, and we cannot optimize that.
	if (DA->isDivergent(I.getOperand(PtrIdx))) {
	return;
	}

	const bool ValDivergent = DA->isDivergent(I.getOperand(ValIdx));

	// If the value operand is divergent, each lane is contributing a different
	// value to the atomic calculation. We can only optimize divergent values if
	// we have DPP available on our subtarget, and the atomic operation is 32
	// bits.
	if (ValDivergent && (!HasDPP \|\| (DL->getTypeSizeInBits(I.getType()) != 32))) {
	return;
	}

	// If we get here, we can optimize the atomic using a single wavefront-wide
	// atomic operation to do the calculation for the entire wavefront, so
	// remember the instruction so we can come back to it.
	const ReplacementInfo Info = {&I, Op, ValIdx, ValDivergent};

	ToReplace.push_back(Info);
	}

	void AMDGPUAtomicOptimizer::visitIntrinsicInst(IntrinsicInst &I) {
	Instruction::BinaryOps Op;

	switch (I.getIntrinsicID()) {
	default:
	return;
	case Intrinsic::amdgcn_buffer_atomic_add:
	case Intrinsic::amdgcn_struct_buffer_atomic_add:
	case Intrinsic::amdgcn_raw_buffer_atomic_add:
	Op = Instruction::Add;
	break;
	case Intrinsic::amdgcn_buffer_atomic_sub:
	case Intrinsic::amdgcn_struct_buffer_atomic_sub:
	case Intrinsic::amdgcn_raw_buffer_atomic_sub:
	Op = Instruction::Sub;
	break;
	}

	const unsigned ValIdx = 0;

	const bool ValDivergent = DA->isDivergent(I.getOperand(ValIdx));

	// If the value operand is divergent, each lane is contributing a different
	// value to the atomic calculation. We can only optimize divergent values if
	// we have DPP available on our subtarget, and the atomic operation is 32
	// bits.
	if (ValDivergent && (!HasDPP \|\| (DL->getTypeSizeInBits(I.getType()) != 32))) {
	return;
	}

	// If any of the other arguments to the intrinsic are divergent, we can't
	// optimize the operation.
	for (unsigned Idx = 1; Idx < I.getNumOperands(); Idx++) {
	if (DA->isDivergent(I.getOperand(Idx))) {
	return;
	}
	}

	// If we get here, we can optimize the atomic using a single wavefront-wide
	// atomic operation to do the calculation for the entire wavefront, so
	// remember the instruction so we can come back to it.
	const ReplacementInfo Info = {&I, Op, ValIdx, ValDivergent};

	ToReplace.push_back(Info);
	}

	void AMDGPUAtomicOptimizer::optimizeAtomic(Instruction &I,
	Instruction::BinaryOps Op,
	unsigned ValIdx,
	bool ValDivergent) const {
	// Start building just before the instruction.
	IRBuilder<> B(&I);

	// If we are in a pixel shader, because of how we have to mask out helper
	// lane invocations, we need to record the entry and exit BB's.
	BasicBlock *PixelEntryBB = nullptr;
	BasicBlock *PixelExitBB = nullptr;

	// If we're optimizing an atomic within a pixel shader, we need to wrap the
	// entire atomic operation in a helper-lane check. We do not want any helper
	// lanes that are around only for the purposes of derivatives to take part
	// in any cross-lane communication, and we use a branch on whether the lane is
	// live to do this.
	if (IsPixelShader) {
	// Record I's original position as the entry block.
	PixelEntryBB = I.getParent();

	Value *const Cond = B.CreateIntrinsic(Intrinsic::amdgcn_ps_live, {}, {});
	Instruction *const NonHelperTerminator =
	SplitBlockAndInsertIfThen(Cond, &I, false, nullptr, DT, nullptr);

	// Record I's new position as the exit block.
	PixelExitBB = I.getParent();

	I.moveBefore(NonHelperTerminator);
	B.SetInsertPoint(&I);
	}

	Type *const Ty = I.getType();
	const unsigned TyBitWidth = DL->getTypeSizeInBits(Ty);
	Type *const VecTy = VectorType::get(B.getInt32Ty(), 2);

	// This is the value in the atomic operation we need to combine in order to
	// reduce the number of atomic operations.
	Value *const V = I.getOperand(ValIdx);

	// We need to know how many lanes are active within the wavefront, and we do
	// this by doing a ballot of active lanes.
	CallInst *const Ballot =
	B.CreateIntrinsic(Intrinsic::amdgcn_icmp, {B.getInt32Ty()},
	{B.getInt32(1), B.getInt32(0), B.getInt32(33)});
	setConvergent(Ballot);

	// We need to know how many lanes are active within the wavefront that are
	// below us. If we counted each lane linearly starting from 0, a lane is
	// below us only if its associated index was less than ours. We do this by
	// using the mbcnt intrinsic.
	Value *const BitCast = B.CreateBitCast(Ballot, VecTy);
	Value *const ExtractLo = B.CreateExtractElement(BitCast, B.getInt32(0));
	Value *const ExtractHi = B.CreateExtractElement(BitCast, B.getInt32(1));
	CallInst *const PartialMbcnt = B.CreateIntrinsic(
	Intrinsic::amdgcn_mbcnt_lo, {}, {ExtractLo, B.getInt32(0)});
	CallInst *const Mbcnt = B.CreateIntrinsic(Intrinsic::amdgcn_mbcnt_hi, {},
	{ExtractHi, PartialMbcnt});

	Value *const MbcntCast = B.CreateIntCast(Mbcnt, Ty, false);

	Value *LaneOffset = nullptr;
	Value *NewV = nullptr;

	// If we have a divergent value in each lane, we need to combine the value
	// using DPP.
	if (ValDivergent) {
	Value *const Identity = B.getIntN(TyBitWidth, 0);

	// First we need to set all inactive invocations to 0, so that they can
	// correctly contribute to the final result.
	CallInst *const SetInactive =
	B.CreateIntrinsic(Intrinsic::amdgcn_set_inactive, Ty, {V, Identity});
	setConvergent(SetInactive);

	CallInst *const FirstDPP =
	B.CreateIntrinsic(Intrinsic::amdgcn_update_dpp, Ty,
	{Identity, SetInactive, B.getInt32(DPP_WF_SR1),
	B.getInt32(0xf), B.getInt32(0xf), B.getFalse()});
	setConvergent(FirstDPP);
	NewV = FirstDPP;

	const unsigned Iters = 7;
	const unsigned DPPCtrl[Iters] = {
	DPP_ROW_SR1, DPP_ROW_SR2, DPP_ROW_SR3, DPP_ROW_SR4,
	DPP_ROW_SR8, DPP_ROW_BCAST15, DPP_ROW_BCAST31};
	const unsigned RowMask[Iters] = {0xf, 0xf, 0xf, 0xf, 0xf, 0xa, 0xc};
	const unsigned BankMask[Iters] = {0xf, 0xf, 0xf, 0xe, 0xc, 0xf, 0xf};

	// This loop performs an exclusive scan across the wavefront, with all lanes
	// active (by using the WWM intrinsic).
	for (unsigned Idx = 0; Idx < Iters; Idx++) {
	Value *const UpdateValue = Idx < 3 ? FirstDPP : NewV;
	CallInst *const DPP = B.CreateIntrinsic(
	Intrinsic::amdgcn_update_dpp, Ty,
	{Identity, UpdateValue, B.getInt32(DPPCtrl[Idx]),
	B.getInt32(RowMask[Idx]), B.getInt32(BankMask[Idx]), B.getFalse()});
	setConvergent(DPP);

	NewV = B.CreateBinOp(Op, NewV, DPP);
	}

	LaneOffset = B.CreateIntrinsic(Intrinsic::amdgcn_wwm, Ty, NewV);
	NewV = B.CreateBinOp(Op, NewV, SetInactive);

	// Read the value from the last lane, which has accumlated the values of
	// each active lane in the wavefront. This will be our new value with which
	// we will provide to the atomic operation.
	if (TyBitWidth == 64) {
	Value *const ExtractLo = B.CreateTrunc(NewV, B.getInt32Ty());
	Value *const ExtractHi =
	B.CreateTrunc(B.CreateLShr(NewV, B.getInt64(32)), B.getInt32Ty());
	CallInst *const ReadLaneLo = B.CreateIntrinsic(
	Intrinsic::amdgcn_readlane, {}, {ExtractLo, B.getInt32(63)});
	setConvergent(ReadLaneLo);
	CallInst *const ReadLaneHi = B.CreateIntrinsic(
	Intrinsic::amdgcn_readlane, {}, {ExtractHi, B.getInt32(63)});
	setConvergent(ReadLaneHi);
	Value *const PartialInsert = B.CreateInsertElement(
	UndefValue::get(VecTy), ReadLaneLo, B.getInt32(0));
	Value *const Insert =
	B.CreateInsertElement(PartialInsert, ReadLaneHi, B.getInt32(1));
	NewV = B.CreateBitCast(Insert, Ty);
	} else if (TyBitWidth == 32) {
	CallInst *const ReadLane = B.CreateIntrinsic(Intrinsic::amdgcn_readlane,
	{}, {NewV, B.getInt32(63)});
	setConvergent(ReadLane);
	NewV = ReadLane;
	} else {
	llvm_unreachable("Unhandled atomic bit width");
	}

	// Finally mark the readlanes in the WWM section.
	NewV = B.CreateIntrinsic(Intrinsic::amdgcn_wwm, Ty, NewV);
	} else {
	// Get the total number of active lanes we have by using popcount.
	Instruction *const Ctpop = B.CreateUnaryIntrinsic(Intrinsic::ctpop, Ballot);
	Value *const CtpopCast = B.CreateIntCast(Ctpop, Ty, false);

	// Calculate the new value we will be contributing to the atomic operation
	// for the entire wavefront.
	NewV = B.CreateMul(V, CtpopCast);
	LaneOffset = B.CreateMul(V, MbcntCast);
	}

	// We only want a single lane to enter our new control flow, and we do this
	// by checking if there are any active lanes below us. Only one lane will
	// have 0 active lanes below us, so that will be the only one to progress.
	Value *const Cond = B.CreateICmpEQ(MbcntCast, B.getIntN(TyBitWidth, 0));

	// Store I's original basic block before we split the block.
	BasicBlock *const EntryBB = I.getParent();

	// We need to introduce some new control flow to force a single lane to be
	// active. We do this by splitting I's basic block at I, and introducing the
	// new block such that:
	// entry --> single_lane -\
	// \------------------> exit
	Instruction *const SingleLaneTerminator =
	SplitBlockAndInsertIfThen(Cond, &I, false, nullptr, DT, nullptr);

	// Move the IR builder into single_lane next.
	B.SetInsertPoint(SingleLaneTerminator);

	// Clone the original atomic operation into single lane, replacing the
	// original value with our newly created one.
	Instruction *const NewI = I.clone();
	B.Insert(NewI);
	NewI->setOperand(ValIdx, NewV);

	// Move the IR builder into exit next, and start inserting just before the
	// original instruction.
	B.SetInsertPoint(&I);

	// Create a PHI node to get our new atomic result into the exit block.
	PHINode *const PHI = B.CreatePHI(Ty, 2);
	PHI->addIncoming(UndefValue::get(Ty), EntryBB);
	PHI->addIncoming(NewI, SingleLaneTerminator->getParent());

	// We need to broadcast the value who was the lowest active lane (the first
	// lane) to all other lanes in the wavefront. We use an intrinsic for this,
	// but have to handle 64-bit broadcasts with two calls to this intrinsic.
	Value *BroadcastI = nullptr;

	if (TyBitWidth == 64) {
	Value *const ExtractLo = B.CreateTrunc(PHI, B.getInt32Ty());
	Value *const ExtractHi =
	B.CreateTrunc(B.CreateLShr(PHI, B.getInt64(32)), B.getInt32Ty());
	CallInst *const ReadFirstLaneLo =
	B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, ExtractLo);
	setConvergent(ReadFirstLaneLo);
	CallInst *const ReadFirstLaneHi =
	B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, ExtractHi);
	setConvergent(ReadFirstLaneHi);
	Value *const PartialInsert = B.CreateInsertElement(
	UndefValue::get(VecTy), ReadFirstLaneLo, B.getInt32(0));
	Value *const Insert =
	B.CreateInsertElement(PartialInsert, ReadFirstLaneHi, B.getInt32(1));
	BroadcastI = B.CreateBitCast(Insert, Ty);
	} else if (TyBitWidth == 32) {
	CallInst *const ReadFirstLane =
	B.CreateIntrinsic(Intrinsic::amdgcn_readfirstlane, {}, PHI);
	setConvergent(ReadFirstLane);
	BroadcastI = ReadFirstLane;
	} else {
	llvm_unreachable("Unhandled atomic bit width");
	}

	// Now that we have the result of our single atomic operation, we need to
	// get our individual lane's slice into the result. We use the lane offset we
	// previously calculated combined with the atomic result value we got from the
	// first lane, to get our lane's index into the atomic result.
	Value *const Result = B.CreateBinOp(Op, BroadcastI, LaneOffset);

	if (IsPixelShader) {
	// Need a final PHI to reconverge to above the helper lane branch mask.
	B.SetInsertPoint(PixelExitBB->getFirstNonPHI());

	PHINode *const PHI = B.CreatePHI(Ty, 2);
	PHI->addIncoming(UndefValue::get(Ty), PixelEntryBB);
	PHI->addIncoming(Result, I.getParent());
	I.replaceAllUsesWith(PHI);
	} else {
	// Replace the original atomic instruction with the new one.
	I.replaceAllUsesWith(Result);
	}

	// And delete the original.
	I.eraseFromParent();
	}

	void AMDGPUAtomicOptimizer::setConvergent(CallInst *const CI) const {
	CI->addAttribute(AttributeList::FunctionIndex, Attribute::Convergent);
	}

	INITIALIZE_PASS_BEGIN(AMDGPUAtomicOptimizer, DEBUG_TYPE,
	"AMDGPU atomic optimizations", false, false)
	INITIALIZE_PASS_DEPENDENCY(LegacyDivergenceAnalysis)
	INITIALIZE_PASS_DEPENDENCY(TargetPassConfig)
	INITIALIZE_PASS_END(AMDGPUAtomicOptimizer, DEBUG_TYPE,
	"AMDGPU atomic optimizations", false, false)

	FunctionPass *llvm::createAMDGPUAtomicOptimizerPass() {
	return new AMDGPUAtomicOptimizer();
	}