doxygen/GCNHazardRecognizer_8cpp_source.html

//===-- GCNHazardRecognizers.cpp - GCN Hazard Recognizer Impls ------------===//

//

// 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

//

//===----------------------------------------------------------------------===//

//

// This file implements hazard recognizers for scheduling on GCN processors.

//

//===----------------------------------------------------------------------===//


#include "GCNHazardRecognizer.h"

#include "GCNSubtarget.h"

#include "MCTargetDesc/AMDGPUMCTargetDesc.h"

#include "SIMachineFunctionInfo.h"

#include "llvm/CodeGen/MachineFrameInfo.h"

#include "llvm/CodeGen/MachineFunction.h"

#include "llvm/CodeGen/ScheduleDAG.h"

#include "llvm/TargetParser/TargetParser.h"


using namespace llvm;


namespace {


struct MFMAPaddingRatioParser : public cl::parser<unsigned> {

  MFMAPaddingRatioParser(cl::Option &O) : cl::parser<unsigned>(O) {}


  bool parse(cl::Option &O, StringRef ArgName, StringRef Arg, unsigned &Value) {

    if (Arg.getAsInteger(0, Value))

      return O.error("'" + Arg + "' value invalid for uint argument!");


    if (Value > 100)

      return O.error("'" + Arg + "' value must be in the range [0, 100]!");


    return false;

  }

};


} // end anonymous namespace


static cl::opt<unsigned, false, MFMAPaddingRatioParser>

    MFMAPaddingRatio("amdgpu-mfma-padding-ratio", cl::init(0), cl::Hidden,

                     cl::desc("Fill a percentage of the latency between "

                              "neighboring MFMA with s_nops."));


//===----------------------------------------------------------------------===//

// Hazard Recognizer Implementation

//===----------------------------------------------------------------------===//


static bool shouldRunLdsBranchVmemWARHazardFixup(const MachineFunction &MF,

                                                 const GCNSubtarget &ST);


GCNHazardRecognizer::GCNHazardRecognizer(const MachineFunction &MF) :

  IsHazardRecognizerMode(false),

  CurrCycleInstr(nullptr),

  MF(MF),

  ST(MF.getSubtarget<GCNSubtarget>()),

  TII(*ST.getInstrInfo()),

  TRI(TII.getRegisterInfo()),

  ClauseUses(TRI.getNumRegUnits()),

  ClauseDefs(TRI.getNumRegUnits()) {

  MaxLookAhead = MF.getRegInfo().isPhysRegUsed(AMDGPU::AGPR0) ? 19 : 5;

  TSchedModel.init(&ST);

  RunLdsBranchVmemWARHazardFixup = shouldRunLdsBranchVmemWARHazardFixup(MF, ST);

}


void GCNHazardRecognizer::Reset() {

  EmittedInstrs.clear();

}


void GCNHazardRecognizer::EmitInstruction(SUnit *SU) {

  EmitInstruction(SU->getInstr());

}


void GCNHazardRecognizer::EmitInstruction(MachineInstr *MI) {

  CurrCycleInstr = MI;

}


static bool isDivFMas(unsigned Opcode) {

  return Opcode == AMDGPU::V_DIV_FMAS_F32_e64 || Opcode == AMDGPU::V_DIV_FMAS_F64_e64;

}


static bool isSGetReg(unsigned Opcode) {

  return Opcode == AMDGPU::S_GETREG_B32;

}


static bool isSSetReg(unsigned Opcode) {

  switch (Opcode) {

  case AMDGPU::S_SETREG_B32:

  case AMDGPU::S_SETREG_B32_mode:

  case AMDGPU::S_SETREG_IMM32_B32:

  case AMDGPU::S_SETREG_IMM32_B32_mode:

    return true;

  }

  return false;

}


static bool isRWLane(unsigned Opcode) {

  return Opcode == AMDGPU::V_READLANE_B32 || Opcode == AMDGPU::V_WRITELANE_B32;

}


static bool isRFE(unsigned Opcode) {

  return Opcode == AMDGPU::S_RFE_B64;

}


static bool isSMovRel(unsigned Opcode) {

  switch (Opcode) {

  case AMDGPU::S_MOVRELS_B32:

  case AMDGPU::S_MOVRELS_B64:

  case AMDGPU::S_MOVRELD_B32:

  case AMDGPU::S_MOVRELD_B64:

    return true;

  default:

    return false;

  }

}


static bool isDGEMM(unsigned Opcode) {

  return AMDGPU::getMAIIsDGEMM(Opcode);

}


static bool isXDL(const GCNSubtarget &ST, const MachineInstr &MI) {

  unsigned Opcode = MI.getOpcode();


  if (!SIInstrInfo::isMAI(MI) ||

      isDGEMM(Opcode) ||

      Opcode == AMDGPU::V_ACCVGPR_WRITE_B32_e64 ||

      Opcode == AMDGPU::V_ACCVGPR_READ_B32_e64)

    return false;


  if (!ST.hasGFX940Insts())

    return true;


  return AMDGPU::getMAIIsGFX940XDL(Opcode);

}


static bool isSendMsgTraceDataOrGDS(const SIInstrInfo &TII,

                                    const MachineInstr &MI) {

  if (TII.isAlwaysGDS(MI.getOpcode()))

    return true;


  switch (MI.getOpcode()) {

  case AMDGPU::S_SENDMSG:

  case AMDGPU::S_SENDMSGHALT:

  case AMDGPU::S_TTRACEDATA:

    return true;

  // These DS opcodes don't support GDS.

  case AMDGPU::DS_NOP:

  case AMDGPU::DS_PERMUTE_B32:

  case AMDGPU::DS_BPERMUTE_B32:

    return false;

  default:

    if (TII.isDS(MI.getOpcode())) {

      int GDS = AMDGPU::getNamedOperandIdx(MI.getOpcode(),

                                           AMDGPU::OpName::gds);

      if (MI.getOperand(GDS).getImm())

        return true;

    }

    return false;

  }

}


static bool isPermlane(const MachineInstr &MI) {

  unsigned Opcode = MI.getOpcode();

  return Opcode == AMDGPU::V_PERMLANE16_B32_e64 ||

         Opcode == AMDGPU::V_PERMLANE64_B32 ||

         Opcode == AMDGPU::V_PERMLANEX16_B32_e64 ||

         Opcode == AMDGPU::V_PERMLANE16_VAR_B32_e64 ||

         Opcode == AMDGPU::V_PERMLANEX16_VAR_B32_e64;

}


static bool isLdsDma(const MachineInstr &MI) {

  return SIInstrInfo::isVALU(MI) &&

         (SIInstrInfo::isMUBUF(MI) || SIInstrInfo::isFLAT(MI));

}


static unsigned getHWReg(const SIInstrInfo *TII, const MachineInstr &RegInstr) {

  const MachineOperand *RegOp = TII->getNamedOperand(RegInstr,

                                                     AMDGPU::OpName::simm16);

  return std::get<0>(AMDGPU::Hwreg::HwregEncoding::decode(RegOp->getImm()));

}


ScheduleHazardRecognizer::HazardType

GCNHazardRecognizer::getHazardType(SUnit *SU, int Stalls) {

  MachineInstr *MI = SU->getInstr();

  // If we are not in "HazardRecognizerMode" and therefore not being run from

  // the scheduler, track possible stalls from hazards but don't insert noops.

  auto HazardType = IsHazardRecognizerMode ? NoopHazard : Hazard;


  if (MI->isBundle())

   return NoHazard;


  if (SIInstrInfo::isSMRD(*MI) && checkSMRDHazards(MI) > 0)

    return HazardType;


  if (ST.hasNSAtoVMEMBug() && checkNSAtoVMEMHazard(MI) > 0)

    return HazardType;


  if (checkFPAtomicToDenormModeHazard(MI) > 0)

    return HazardType;


  if (ST.hasNoDataDepHazard())

    return NoHazard;


  // FIXME: Should flat be considered vmem?

  if ((SIInstrInfo::isVMEM(*MI) ||

       SIInstrInfo::isFLAT(*MI))

      && checkVMEMHazards(MI) > 0)

    return HazardType;


  if (SIInstrInfo::isVALU(*MI) && checkVALUHazards(MI) > 0)

    return HazardType;


  if (SIInstrInfo::isDPP(*MI) && checkDPPHazards(MI) > 0)

    return HazardType;


  if (isDivFMas(MI->getOpcode()) && checkDivFMasHazards(MI) > 0)

    return HazardType;


  if (isRWLane(MI->getOpcode()) && checkRWLaneHazards(MI) > 0)

    return HazardType;


  if ((SIInstrInfo::isVALU(*MI) || SIInstrInfo::isVMEM(*MI) ||

       SIInstrInfo::isFLAT(*MI) || SIInstrInfo::isDS(*MI) ||

       SIInstrInfo::isEXP(*MI)) && checkMAIVALUHazards(MI) > 0)

    return HazardType;


  if (isSGetReg(MI->getOpcode()) && checkGetRegHazards(MI) > 0)

    return HazardType;


  if (isSSetReg(MI->getOpcode()) && checkSetRegHazards(MI) > 0)

    return HazardType;


  if (isRFE(MI->getOpcode()) && checkRFEHazards(MI) > 0)

    return HazardType;


  if (((ST.hasReadM0MovRelInterpHazard() &&

        (TII.isVINTRP(*MI) || isSMovRel(MI->getOpcode()) ||

         MI->getOpcode() == AMDGPU::DS_WRITE_ADDTID_B32 ||

         MI->getOpcode() == AMDGPU::DS_READ_ADDTID_B32)) ||

       (ST.hasReadM0SendMsgHazard() && isSendMsgTraceDataOrGDS(TII, *MI)) ||

       (ST.hasReadM0LdsDmaHazard() && isLdsDma(*MI)) ||

       (ST.hasReadM0LdsDirectHazard() &&

        MI->readsRegister(AMDGPU::LDS_DIRECT, /*TRI=*/nullptr))) &&

      checkReadM0Hazards(MI) > 0)

    return HazardType;


  if (SIInstrInfo::isMAI(*MI) && checkMAIHazards(MI) > 0)

    return HazardType;


  if ((SIInstrInfo::isVMEM(*MI) ||

       SIInstrInfo::isFLAT(*MI) ||

       SIInstrInfo::isDS(*MI)) && checkMAILdStHazards(MI) > 0)

    return HazardType;


  if (MI->isInlineAsm() && checkInlineAsmHazards(MI) > 0)

    return HazardType;


  return NoHazard;

}


static void insertNoopsInBundle(MachineInstr *MI, const SIInstrInfo &TII,

                                unsigned Quantity) {

  while (Quantity > 0) {

    unsigned Arg = std::min(Quantity, 8u);

    Quantity -= Arg;

    BuildMI(*MI->getParent(), MI, MI->getDebugLoc(), TII.get(AMDGPU::S_NOP))

        .addImm(Arg - 1);

  }

}


unsigned

GCNHazardRecognizer::getMFMAPipelineWaitStates(const MachineInstr &MI) const {

  const MCSchedClassDesc *SC = TSchedModel.resolveSchedClass(&MI);

  assert(TSchedModel.getWriteProcResBegin(SC) !=

         TSchedModel.getWriteProcResEnd(SC));

  return TSchedModel.getWriteProcResBegin(SC)->ReleaseAtCycle;

}


void GCNHazardRecognizer::processBundle() {

  MachineBasicBlock::instr_iterator MI = std::next(CurrCycleInstr->getIterator());

  MachineBasicBlock::instr_iterator E = CurrCycleInstr->getParent()->instr_end();

  // Check bundled MachineInstr's for hazards.

  for (; MI != E && MI->isInsideBundle(); ++MI) {

    CurrCycleInstr = &*MI;

    unsigned WaitStates = PreEmitNoopsCommon(CurrCycleInstr);


    if (IsHazardRecognizerMode) {

      fixHazards(CurrCycleInstr);


      insertNoopsInBundle(CurrCycleInstr, TII, WaitStates);

    }


    // It’s unnecessary to track more than MaxLookAhead instructions. Since we

    // include the bundled MI directly after, only add a maximum of

    // (MaxLookAhead - 1) noops to EmittedInstrs.

    for (unsigned i = 0, e = std::min(WaitStates, MaxLookAhead - 1); i < e; ++i)

      EmittedInstrs.push_front(nullptr);


    EmittedInstrs.push_front(CurrCycleInstr);

    EmittedInstrs.resize(MaxLookAhead);

  }

  CurrCycleInstr = nullptr;

}


void GCNHazardRecognizer::runOnInstruction(MachineInstr *MI) {

  assert(IsHazardRecognizerMode);


  unsigned NumPreNoops = PreEmitNoops(MI);

  EmitNoops(NumPreNoops);

  if (MI->isInsideBundle())

    insertNoopsInBundle(MI, TII, NumPreNoops);

  else

    TII.insertNoops(*MI->getParent(), MachineBasicBlock::iterator(MI),

                    NumPreNoops);

  EmitInstruction(MI);

  AdvanceCycle();

}


unsigned GCNHazardRecognizer::PreEmitNoops(MachineInstr *MI) {

  IsHazardRecognizerMode = true;

  CurrCycleInstr = MI;

  unsigned W = PreEmitNoopsCommon(MI);

  fixHazards(MI);

  CurrCycleInstr = nullptr;

  return W;

}


unsigned GCNHazardRecognizer::PreEmitNoopsCommon(MachineInstr *MI) {

  if (MI->isBundle())

    return 0;


  int WaitStates = 0;


  if (SIInstrInfo::isSMRD(*MI))

    return std::max(WaitStates, checkSMRDHazards(MI));


  if (ST.hasNSAtoVMEMBug())

    WaitStates = std::max(WaitStates, checkNSAtoVMEMHazard(MI));


  WaitStates = std::max(WaitStates, checkFPAtomicToDenormModeHazard(MI));


  if (ST.hasNoDataDepHazard())

    return WaitStates;


  if (SIInstrInfo::isVMEM(*MI) || SIInstrInfo::isFLAT(*MI))

    WaitStates = std::max(WaitStates, checkVMEMHazards(MI));


  if (SIInstrInfo::isVALU(*MI))

    WaitStates = std::max(WaitStates, checkVALUHazards(MI));


  if (SIInstrInfo::isDPP(*MI))

    WaitStates = std::max(WaitStates, checkDPPHazards(MI));


  if (isDivFMas(MI->getOpcode()))

    WaitStates = std::max(WaitStates, checkDivFMasHazards(MI));


  if (isRWLane(MI->getOpcode()))

    WaitStates = std::max(WaitStates, checkRWLaneHazards(MI));


  if ((SIInstrInfo::isVALU(*MI) || SIInstrInfo::isVMEM(*MI) ||

       SIInstrInfo::isFLAT(*MI) || SIInstrInfo::isDS(*MI) ||

       SIInstrInfo::isEXP(*MI)) && checkMAIVALUHazards(MI) > 0)

    WaitStates = std::max(WaitStates, checkMAIVALUHazards(MI));


  if (MI->isInlineAsm())

    return std::max(WaitStates, checkInlineAsmHazards(MI));


  if (isSGetReg(MI->getOpcode()))

    return std::max(WaitStates, checkGetRegHazards(MI));


  if (isSSetReg(MI->getOpcode()))

    return std::max(WaitStates, checkSetRegHazards(MI));


  if (isRFE(MI->getOpcode()))

    return std::max(WaitStates, checkRFEHazards(MI));


  if ((ST.hasReadM0MovRelInterpHazard() &&

       (TII.isVINTRP(*MI) || isSMovRel(MI->getOpcode()) ||

        MI->getOpcode() == AMDGPU::DS_WRITE_ADDTID_B32 ||

        MI->getOpcode() == AMDGPU::DS_READ_ADDTID_B32)) ||

      (ST.hasReadM0SendMsgHazard() && isSendMsgTraceDataOrGDS(TII, *MI)) ||

      (ST.hasReadM0LdsDmaHazard() && isLdsDma(*MI)) ||

      (ST.hasReadM0LdsDirectHazard() &&

       MI->readsRegister(AMDGPU::LDS_DIRECT, /*TRI=*/nullptr)))

    return std::max(WaitStates, checkReadM0Hazards(MI));


  if (SIInstrInfo::isMAI(*MI))

    return std::max(WaitStates, checkMAIHazards(MI));


  if (SIInstrInfo::isVMEM(*MI) ||

      SIInstrInfo::isFLAT(*MI) ||

      SIInstrInfo::isDS(*MI))

    return std::max(WaitStates, checkMAILdStHazards(MI));


  return WaitStates;

}


void GCNHazardRecognizer::EmitNoop() {

  EmittedInstrs.push_front(nullptr);

}


void GCNHazardRecognizer::AdvanceCycle() {

  // When the scheduler detects a stall, it will call AdvanceCycle() without

  // emitting any instructions.

  if (!CurrCycleInstr) {

    EmittedInstrs.push_front(nullptr);

    return;

  }


  if (CurrCycleInstr->isBundle()) {

    processBundle();

    return;

  }


  unsigned NumWaitStates = TII.getNumWaitStates(*CurrCycleInstr);

  if (!NumWaitStates) {

    CurrCycleInstr = nullptr;

    return;

  }


  // Keep track of emitted instructions

  EmittedInstrs.push_front(CurrCycleInstr);


  // Add a nullptr for each additional wait state after the first.  Make sure

  // not to add more than getMaxLookAhead() items to the list, since we

  // truncate the list to that size right after this loop.

  for (unsigned i = 1, e = std::min(NumWaitStates, getMaxLookAhead());

       i < e; ++i) {

    EmittedInstrs.push_front(nullptr);

  }


  // getMaxLookahead() is the largest number of wait states we will ever need

  // to insert, so there is no point in keeping track of more than that many

  // wait states.

  EmittedInstrs.resize(getMaxLookAhead());


  CurrCycleInstr = nullptr;

}


void GCNHazardRecognizer::RecedeCycle() {

  llvm_unreachable("hazard recognizer does not support bottom-up scheduling.");

}


//===----------------------------------------------------------------------===//

// Helper Functions

//===----------------------------------------------------------------------===//


using HazardFnResult = enum { HazardFound, HazardExpired, NoHazardFound };


using IsExpiredFn = function_ref<bool(const MachineInstr &, int WaitStates)>;

using GetNumWaitStatesFn = function_ref<unsigned int(const MachineInstr &)>;


// Search for a hazard in a block and its predecessors.

template <typename StateT>

static bool

hasHazard(StateT State,

          function_ref<HazardFnResult(StateT &, const MachineInstr &)> IsHazard,

          function_ref<void(StateT &, const MachineInstr &)> UpdateState,

          const MachineBasicBlock *MBB,

          MachineBasicBlock::const_reverse_instr_iterator I,

          DenseSet<const MachineBasicBlock *> &Visited) {

  for (auto E = MBB->instr_rend(); I != E; ++I) {

    // No need to look at parent BUNDLE instructions.

    if (I->isBundle())

      continue;


    switch (IsHazard(State, *I)) {

    case HazardFound:

      return true;

    case HazardExpired:

      return false;

    default:

      // Continue search

      break;

    }


    if (I->isInlineAsm() || I->isMetaInstruction())

      continue;


    UpdateState(State, *I);

  }


  for (MachineBasicBlock *Pred : MBB->predecessors()) {

    if (!Visited.insert(Pred).second)

      continue;


    if (hasHazard(State, IsHazard, UpdateState, Pred, Pred->instr_rbegin(),

                  Visited))

      return true;

  }


  return false;

}


// Returns a minimum wait states since \p I walking all predecessors.

// Only scans until \p IsExpired does not return true.

// Can only be run in a hazard recognizer mode.

static int getWaitStatesSince(

    GCNHazardRecognizer::IsHazardFn IsHazard, const MachineBasicBlock *MBB,

    MachineBasicBlock::const_reverse_instr_iterator I, int WaitStates,

    IsExpiredFn IsExpired, DenseSet<const MachineBasicBlock *> &Visited,

    GetNumWaitStatesFn GetNumWaitStates = SIInstrInfo::getNumWaitStates) {

  for (auto E = MBB->instr_rend(); I != E; ++I) {

    // Don't add WaitStates for parent BUNDLE instructions.

    if (I->isBundle())

      continue;


    if (IsHazard(*I))

      return WaitStates;


    if (I->isInlineAsm())

      continue;


    WaitStates += GetNumWaitStates(*I);


    if (IsExpired(*I, WaitStates))

      return std::numeric_limits<int>::max();

  }


  int MinWaitStates = std::numeric_limits<int>::max();

  for (MachineBasicBlock *Pred : MBB->predecessors()) {

    if (!Visited.insert(Pred).second)

      continue;


    int W = getWaitStatesSince(IsHazard, Pred, Pred->instr_rbegin(), WaitStates,

                               IsExpired, Visited, GetNumWaitStates);


    MinWaitStates = std::min(MinWaitStates, W);

  }


  return MinWaitStates;

}


static int getWaitStatesSince(GCNHazardRecognizer::IsHazardFn IsHazard,

                              const MachineInstr *MI, IsExpiredFn IsExpired) {

  DenseSet<const MachineBasicBlock *> Visited;

  return getWaitStatesSince(IsHazard, MI->getParent(),

                            std::next(MI->getReverseIterator()),

                            0, IsExpired, Visited);

}


int GCNHazardRecognizer::getWaitStatesSince(IsHazardFn IsHazard, int Limit) {

  if (IsHazardRecognizerMode) {

    auto IsExpiredFn = [Limit](const MachineInstr &, int WaitStates) {

      return WaitStates >= Limit;

    };

    return ::getWaitStatesSince(IsHazard, CurrCycleInstr, IsExpiredFn);

  }


  int WaitStates = 0;

  for (MachineInstr *MI : EmittedInstrs) {

    if (MI) {

      if (IsHazard(*MI))

        return WaitStates;


      if (MI->isInlineAsm())

        continue;

    }

    ++WaitStates;


    if (WaitStates >= Limit)

      break;

  }

  return std::numeric_limits<int>::max();

}


int GCNHazardRecognizer::getWaitStatesSinceDef(unsigned Reg,

                                               IsHazardFn IsHazardDef,

                                               int Limit) {

  const SIRegisterInfo *TRI = ST.getRegisterInfo();


  auto IsHazardFn = [IsHazardDef, TRI, Reg](const MachineInstr &MI) {

    return IsHazardDef(MI) && MI.modifiesRegister(Reg, TRI);

  };


  return getWaitStatesSince(IsHazardFn, Limit);

}


int GCNHazardRecognizer::getWaitStatesSinceSetReg(IsHazardFn IsHazard,

                                                  int Limit) {

  auto IsHazardFn = [IsHazard](const MachineInstr &MI) {

    return isSSetReg(MI.getOpcode()) && IsHazard(MI);

  };


  return getWaitStatesSince(IsHazardFn, Limit);

}


//===----------------------------------------------------------------------===//

// No-op Hazard Detection

//===----------------------------------------------------------------------===//


static void addRegUnits(const SIRegisterInfo &TRI, BitVector &BV,

                        MCRegister Reg) {

  for (MCRegUnit Unit : TRI.regunits(Reg))

    BV.set(Unit);

}


static void addRegsToSet(const SIRegisterInfo &TRI,

                         iterator_range<MachineInstr::const_mop_iterator> Ops,

                         BitVector &DefSet, BitVector &UseSet) {

  for (const MachineOperand &Op : Ops) {

    if (Op.isReg())

      addRegUnits(TRI, Op.isDef() ? DefSet : UseSet, Op.getReg().asMCReg());

  }

}


void GCNHazardRecognizer::addClauseInst(const MachineInstr &MI) {

  addRegsToSet(TRI, MI.operands(), ClauseDefs, ClauseUses);

}


static bool breaksSMEMSoftClause(MachineInstr *MI) {

  return !SIInstrInfo::isSMRD(*MI);

}


static bool breaksVMEMSoftClause(MachineInstr *MI) {

  return !SIInstrInfo::isVMEM(*MI) && !SIInstrInfo::isFLAT(*MI);

}


int GCNHazardRecognizer::checkSoftClauseHazards(MachineInstr *MEM) {

  // SMEM soft clause are only present on VI+, and only matter if xnack is

  // enabled.

  if (!ST.isXNACKEnabled())

    return 0;


  bool IsSMRD = TII.isSMRD(*MEM);


  resetClause();


  // A soft-clause is any group of consecutive SMEM instructions.  The

  // instructions in this group may return out of order and/or may be

  // replayed (i.e. the same instruction issued more than once).

  //

  // In order to handle these situations correctly we need to make sure that

  // when a clause has more than one instruction, no instruction in the clause

  // writes to a register that is read by another instruction in the clause

  // (including itself). If we encounter this situation, we need to break the

  // clause by inserting a non SMEM instruction.


  for (MachineInstr *MI : EmittedInstrs) {

    // When we hit a non-SMEM instruction then we have passed the start of the

    // clause and we can stop.

    if (!MI)

      break;


    if (IsSMRD ? breaksSMEMSoftClause(MI) : breaksVMEMSoftClause(MI))

      break;


    addClauseInst(*MI);

  }


  if (ClauseDefs.none())

    return 0;


  // We need to make sure not to put loads and stores in the same clause if they

  // use the same address. For now, just start a new clause whenever we see a

  // store.

  if (MEM->mayStore())

    return 1;


  addClauseInst(*MEM);


  // If the set of defs and uses intersect then we cannot add this instruction

  // to the clause, so we have a hazard.

  return ClauseDefs.anyCommon(ClauseUses) ? 1 : 0;

}


int GCNHazardRecognizer::checkSMRDHazards(MachineInstr *SMRD) {

  int WaitStatesNeeded = 0;


  WaitStatesNeeded = checkSoftClauseHazards(SMRD);


  // This SMRD hazard only affects SI.

  if (!ST.hasSMRDReadVALUDefHazard())

    return WaitStatesNeeded;


  // A read of an SGPR by SMRD instruction requires 4 wait states when the

  // SGPR was written by a VALU instruction.

  int SmrdSgprWaitStates = 4;

  auto IsHazardDefFn = [this](const MachineInstr &MI) {

    return TII.isVALU(MI);

  };

  auto IsBufferHazardDefFn = [this](const MachineInstr &MI) {

    return TII.isSALU(MI);

  };


  bool IsBufferSMRD = TII.isBufferSMRD(*SMRD);


  for (const MachineOperand &Use : SMRD->uses()) {

    if (!Use.isReg())

      continue;

    int WaitStatesNeededForUse =

        SmrdSgprWaitStates - getWaitStatesSinceDef(Use.getReg(), IsHazardDefFn,

                                                   SmrdSgprWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    // This fixes what appears to be undocumented hardware behavior in SI where

    // s_mov writing a descriptor and s_buffer_load_dword reading the descriptor

    // needs some number of nops in between. We don't know how many we need, but

    // let's use 4. This wasn't discovered before probably because the only

    // case when this happens is when we expand a 64-bit pointer into a full

    // descriptor and use s_buffer_load_dword instead of s_load_dword, which was

    // probably never encountered in the closed-source land.

    if (IsBufferSMRD) {

      int WaitStatesNeededForUse =

        SmrdSgprWaitStates - getWaitStatesSinceDef(Use.getReg(),

                                                   IsBufferHazardDefFn,

                                                   SmrdSgprWaitStates);

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

    }

  }


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkVMEMHazards(MachineInstr* VMEM) {

  if (!ST.hasVMEMReadSGPRVALUDefHazard())

    return 0;


  int WaitStatesNeeded = checkSoftClauseHazards(VMEM);


  // A read of an SGPR by a VMEM instruction requires 5 wait states when the

  // SGPR was written by a VALU Instruction.

  const int VmemSgprWaitStates = 5;

  auto IsHazardDefFn = [this](const MachineInstr &MI) {

    return TII.isVALU(MI);

  };

  for (const MachineOperand &Use : VMEM->uses()) {

    if (!Use.isReg() || TRI.isVectorRegister(MF.getRegInfo(), Use.getReg()))

      continue;


    int WaitStatesNeededForUse =

        VmemSgprWaitStates - getWaitStatesSinceDef(Use.getReg(), IsHazardDefFn,

                                                   VmemSgprWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }

  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkDPPHazards(MachineInstr *DPP) {

  const SIRegisterInfo *TRI = ST.getRegisterInfo();

  const SIInstrInfo *TII = ST.getInstrInfo();


  // Check for DPP VGPR read after VALU VGPR write and EXEC write.

  int DppVgprWaitStates = 2;

  int DppExecWaitStates = 5;

  int WaitStatesNeeded = 0;

  auto IsHazardDefFn = [TII](const MachineInstr &MI) {

    return TII->isVALU(MI);

  };


  for (const MachineOperand &Use : DPP->uses()) {

    if (!Use.isReg() || !TRI->isVGPR(MF.getRegInfo(), Use.getReg()))

      continue;

    int WaitStatesNeededForUse =

        DppVgprWaitStates - getWaitStatesSinceDef(

                                Use.getReg(),

                                [](const MachineInstr &) { return true; },

                                DppVgprWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }


  WaitStatesNeeded = std::max(

      WaitStatesNeeded,

      DppExecWaitStates - getWaitStatesSinceDef(AMDGPU::EXEC, IsHazardDefFn,

                                                DppExecWaitStates));


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkDivFMasHazards(MachineInstr *DivFMas) {

  const SIInstrInfo *TII = ST.getInstrInfo();


  // v_div_fmas requires 4 wait states after a write to vcc from a VALU

  // instruction.

  const int DivFMasWaitStates = 4;

  auto IsHazardDefFn = [TII](const MachineInstr &MI) {

    return TII->isVALU(MI);

  };

  int WaitStatesNeeded = getWaitStatesSinceDef(AMDGPU::VCC, IsHazardDefFn,

                                               DivFMasWaitStates);


  return DivFMasWaitStates - WaitStatesNeeded;

}


int GCNHazardRecognizer::checkGetRegHazards(MachineInstr *GetRegInstr) {

  const SIInstrInfo *TII = ST.getInstrInfo();

  unsigned GetRegHWReg = getHWReg(TII, *GetRegInstr);


  const int GetRegWaitStates = 2;

  auto IsHazardFn = [TII, GetRegHWReg](const MachineInstr &MI) {

    return GetRegHWReg == getHWReg(TII, MI);

  };

  int WaitStatesNeeded = getWaitStatesSinceSetReg(IsHazardFn, GetRegWaitStates);


  return GetRegWaitStates - WaitStatesNeeded;

}


int GCNHazardRecognizer::checkSetRegHazards(MachineInstr *SetRegInstr) {

  const SIInstrInfo *TII = ST.getInstrInfo();

  unsigned HWReg = getHWReg(TII, *SetRegInstr);


  const int SetRegWaitStates = ST.getSetRegWaitStates();

  auto IsHazardFn = [TII, HWReg](const MachineInstr &MI) {

    return HWReg == getHWReg(TII, MI);

  };

  int WaitStatesNeeded = getWaitStatesSinceSetReg(IsHazardFn, SetRegWaitStates);

  return SetRegWaitStates - WaitStatesNeeded;

}


int GCNHazardRecognizer::createsVALUHazard(const MachineInstr &MI) {

  if (!MI.mayStore())

    return -1;


  const SIInstrInfo *TII = ST.getInstrInfo();

  unsigned Opcode = MI.getOpcode();

  const MCInstrDesc &Desc = MI.getDesc();


  int VDataIdx = AMDGPU::getNamedOperandIdx(Opcode, AMDGPU::OpName::vdata);

  int VDataRCID = -1;

  if (VDataIdx != -1)

    VDataRCID = Desc.operands()[VDataIdx].RegClass;


  if (TII->isMUBUF(MI) || TII->isMTBUF(MI)) {

    // There is no hazard if the instruction does not use vector regs

    // (like wbinvl1)

    if (VDataIdx == -1)

      return -1;

    // For MUBUF/MTBUF instructions this hazard only exists if the

    // instruction is not using a register in the soffset field.

    const MachineOperand *SOffset =

        TII->getNamedOperand(MI, AMDGPU::OpName::soffset);

    // If we have no soffset operand, then assume this field has been

    // hardcoded to zero.

    if (AMDGPU::getRegBitWidth(VDataRCID) > 64 &&

        (!SOffset || !SOffset->isReg()))

      return VDataIdx;

  }


  // MIMG instructions create a hazard if they don't use a 256-bit T# and

  // the store size is greater than 8 bytes and they have more than two bits

  // of their dmask set.

  // All our MIMG definitions use a 256-bit T#, so we can skip checking for them.

  if (TII->isMIMG(MI)) {

    int SRsrcIdx = AMDGPU::getNamedOperandIdx(Opcode, AMDGPU::OpName::srsrc);

    assert(SRsrcIdx != -1 &&

           AMDGPU::getRegBitWidth(Desc.operands()[SRsrcIdx].RegClass) == 256);

    (void)SRsrcIdx;

  }


  if (TII->isFLAT(MI)) {

    int DataIdx = AMDGPU::getNamedOperandIdx(Opcode, AMDGPU::OpName::vdata);

    if (AMDGPU::getRegBitWidth(Desc.operands()[DataIdx].RegClass) > 64)

      return DataIdx;

  }


  return -1;

}


int

GCNHazardRecognizer::checkVALUHazardsHelper(const MachineOperand &Def,

                                            const MachineRegisterInfo &MRI) {

  // Helper to check for the hazard where VMEM instructions that store more than

  // 8 bytes can have there store data over written by the next instruction.

  const SIRegisterInfo *TRI = ST.getRegisterInfo();


  const int VALUWaitStates = ST.hasGFX940Insts() ? 2 : 1;

  int WaitStatesNeeded = 0;


  if (!TRI->isVectorRegister(MRI, Def.getReg()))

    return WaitStatesNeeded;

  Register Reg = Def.getReg();

  auto IsHazardFn = [this, Reg, TRI](const MachineInstr &MI) {

    int DataIdx = createsVALUHazard(MI);

    return DataIdx >= 0 &&

           TRI->regsOverlap(MI.getOperand(DataIdx).getReg(), Reg);

  };

  int WaitStatesNeededForDef =

    VALUWaitStates - getWaitStatesSince(IsHazardFn, VALUWaitStates);

  WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkVALUHazards(MachineInstr *VALU) {

  int WaitStatesNeeded = 0;


  if (ST.hasTransForwardingHazard() && !SIInstrInfo::isTRANS(*VALU)) {

    const int TransDefWaitstates = 1;


    auto IsTransDefFn = [this, VALU](const MachineInstr &MI) {

      if (!SIInstrInfo::isTRANS(MI))

        return false;

      const SIRegisterInfo *TRI = ST.getRegisterInfo();

      const SIInstrInfo *TII = ST.getInstrInfo();

      Register Def = TII->getNamedOperand(MI, AMDGPU::OpName::vdst)->getReg();


      for (const MachineOperand &Use : VALU->explicit_uses()) {

        if (Use.isReg() && TRI->regsOverlap(Def, Use.getReg()))

          return true;

      }


      return false;

    };


    int WaitStatesNeededForDef =

        TransDefWaitstates -

        getWaitStatesSince(IsTransDefFn, TransDefWaitstates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

  }


  if (ST.hasDstSelForwardingHazard()) {

    const int Shift16DefWaitstates = 1;


    auto IsShift16BitDefFn = [this, VALU](const MachineInstr &MI) {

      if (!SIInstrInfo::isVALU(MI))

        return false;

      const SIInstrInfo *TII = ST.getInstrInfo();

      if (SIInstrInfo::isSDWA(MI)) {

        if (auto *DstSel = TII->getNamedOperand(MI, AMDGPU::OpName::dst_sel))

          if (DstSel->getImm() == AMDGPU::SDWA::DWORD)

            return false;

      } else {

        if (!AMDGPU::hasNamedOperand(MI.getOpcode(), AMDGPU::OpName::op_sel) ||

            !(TII->getNamedOperand(MI, AMDGPU::OpName::src0_modifiers)

                  ->getImm() &

              SISrcMods::DST_OP_SEL))

          return false;

      }

      const SIRegisterInfo *TRI = ST.getRegisterInfo();

      if (auto *Dst = TII->getNamedOperand(MI, AMDGPU::OpName::vdst)) {

        Register Def = Dst->getReg();


        for (const MachineOperand &Use : VALU->explicit_uses()) {

          if (Use.isReg() && TRI->regsOverlap(Def, Use.getReg()))

            return true;

        }

      }


      return false;

    };


    int WaitStatesNeededForDef =

        Shift16DefWaitstates -

        getWaitStatesSince(IsShift16BitDefFn, Shift16DefWaitstates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

  }


  if (ST.hasVDecCoExecHazard()) {

    const int VALUWriteSGPRVALUReadWaitstates = 2;

    const int VALUWriteEXECRWLane = 4;

    const int VALUWriteVGPRReadlaneRead = 1;


    const SIRegisterInfo *TRI = ST.getRegisterInfo();

    const MachineRegisterInfo &MRI = MF.getRegInfo();

    Register UseReg;

    auto IsVALUDefSGPRFn = [&UseReg, TRI](const MachineInstr &MI) {

      if (!SIInstrInfo::isVALU(MI))

        return false;

      return MI.modifiesRegister(UseReg, TRI);

    };


    for (const MachineOperand &Use : VALU->explicit_uses()) {

      if (!Use.isReg())

        continue;


      UseReg = Use.getReg();

      if (TRI->isSGPRReg(MRI, UseReg)) {

        int WaitStatesNeededForDef =

            VALUWriteSGPRVALUReadWaitstates -

            getWaitStatesSince(IsVALUDefSGPRFn,

                               VALUWriteSGPRVALUReadWaitstates);

        WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

      }

    }


    if (VALU->readsRegister(AMDGPU::VCC, TRI)) {

      UseReg = AMDGPU::VCC;

      int WaitStatesNeededForDef =

          VALUWriteSGPRVALUReadWaitstates -

          getWaitStatesSince(IsVALUDefSGPRFn, VALUWriteSGPRVALUReadWaitstates);

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

    }


    switch (VALU->getOpcode()) {

    case AMDGPU::V_READLANE_B32:

    case AMDGPU::V_READFIRSTLANE_B32: {

      MachineOperand *Src = TII.getNamedOperand(*VALU, AMDGPU::OpName::src0);

      UseReg = Src->getReg();

      int WaitStatesNeededForDef =

          VALUWriteVGPRReadlaneRead -

          getWaitStatesSince(IsVALUDefSGPRFn, VALUWriteVGPRReadlaneRead);

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

    }

      [[fallthrough]];

    case AMDGPU::V_WRITELANE_B32: {

      UseReg = AMDGPU::EXEC;

      int WaitStatesNeededForDef =

          VALUWriteEXECRWLane -

          getWaitStatesSince(IsVALUDefSGPRFn, VALUWriteEXECRWLane);

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForDef);

      break;

    }

    default:

      break;

    }

  }


  // This checks for the hazard where VMEM instructions that store more than

  // 8 bytes can have there store data over written by the next instruction.

  if (!ST.has12DWordStoreHazard())

    return WaitStatesNeeded;


  const MachineRegisterInfo &MRI = MF.getRegInfo();


  for (const MachineOperand &Def : VALU->defs()) {

    WaitStatesNeeded = std::max(WaitStatesNeeded, checkVALUHazardsHelper(Def, MRI));

  }


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkInlineAsmHazards(MachineInstr *IA) {

  // This checks for hazards associated with inline asm statements.

  // Since inline asms can contain just about anything, we use this

  // to call/leverage other check*Hazard routines. Note that

  // this function doesn't attempt to address all possible inline asm

  // hazards (good luck), but is a collection of what has been

  // problematic thus far.


  // see checkVALUHazards()

  if (!ST.has12DWordStoreHazard())

    return 0;


  const MachineRegisterInfo &MRI = MF.getRegInfo();

  int WaitStatesNeeded = 0;


  for (const MachineOperand &Op :

       llvm::drop_begin(IA->operands(), InlineAsm::MIOp_FirstOperand)) {

    if (Op.isReg() && Op.isDef()) {

      WaitStatesNeeded =

          std::max(WaitStatesNeeded, checkVALUHazardsHelper(Op, MRI));

    }

  }


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkRWLaneHazards(MachineInstr *RWLane) {

  const SIInstrInfo *TII = ST.getInstrInfo();

  const SIRegisterInfo *TRI = ST.getRegisterInfo();

  const MachineRegisterInfo &MRI = MF.getRegInfo();


  const MachineOperand *LaneSelectOp =

      TII->getNamedOperand(*RWLane, AMDGPU::OpName::src1);


  if (!LaneSelectOp->isReg() || !TRI->isSGPRReg(MRI, LaneSelectOp->getReg()))

    return 0;


  Register LaneSelectReg = LaneSelectOp->getReg();

  auto IsHazardFn = [TII](const MachineInstr &MI) { return TII->isVALU(MI); };


  const int RWLaneWaitStates = 4;

  int WaitStatesSince = getWaitStatesSinceDef(LaneSelectReg, IsHazardFn,

                                              RWLaneWaitStates);

  return RWLaneWaitStates - WaitStatesSince;

}


int GCNHazardRecognizer::checkRFEHazards(MachineInstr *RFE) {

  if (!ST.hasRFEHazards())

    return 0;


  const SIInstrInfo *TII = ST.getInstrInfo();


  const int RFEWaitStates = 1;


  auto IsHazardFn = [TII](const MachineInstr &MI) {

    return getHWReg(TII, MI) == AMDGPU::Hwreg::ID_TRAPSTS;

  };

  int WaitStatesNeeded = getWaitStatesSinceSetReg(IsHazardFn, RFEWaitStates);

  return RFEWaitStates - WaitStatesNeeded;

}


int GCNHazardRecognizer::checkReadM0Hazards(MachineInstr *MI) {

  const SIInstrInfo *TII = ST.getInstrInfo();

  const int ReadM0WaitStates = 1;

  auto IsHazardFn = [TII](const MachineInstr &MI) { return TII->isSALU(MI); };

  return ReadM0WaitStates -

         getWaitStatesSinceDef(AMDGPU::M0, IsHazardFn, ReadM0WaitStates);

}


void GCNHazardRecognizer::fixHazards(MachineInstr *MI) {

  fixVMEMtoScalarWriteHazards(MI);

  fixVcmpxPermlaneHazards(MI);

  fixSMEMtoVectorWriteHazards(MI);

  fixVcmpxExecWARHazard(MI);

  fixLdsBranchVmemWARHazard(MI);

  if (ST.hasLdsDirect()) {

    fixLdsDirectVALUHazard(MI);

    fixLdsDirectVMEMHazard(MI);

  }

  fixVALUPartialForwardingHazard(MI);

  fixVALUTransUseHazard(MI);

  fixWMMAHazards(MI);

  fixShift64HighRegBug(MI);

  fixVALUMaskWriteHazard(MI);

  fixRequiredExportPriority(MI);

}


bool GCNHazardRecognizer::fixVcmpxPermlaneHazards(MachineInstr *MI) {

  if (!ST.hasVcmpxPermlaneHazard() || !isPermlane(*MI))

    return false;


  const SIInstrInfo *TII = ST.getInstrInfo();

  const SIRegisterInfo *TRI = ST.getRegisterInfo();

  auto IsHazardFn = [TII, TRI](const MachineInstr &MI) {

    return (TII->isVOPC(MI) ||

            ((TII->isVOP3(MI) || TII->isSDWA(MI)) && MI.isCompare())) &&

           MI.modifiesRegister(AMDGPU::EXEC, TRI);

  };


  auto IsExpiredFn = [](const MachineInstr &MI, int) {

    unsigned Opc = MI.getOpcode();

    return SIInstrInfo::isVALU(MI) && Opc != AMDGPU::V_NOP_e32 &&

           Opc != AMDGPU::V_NOP_e64 && Opc != AMDGPU::V_NOP_sdwa;

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  // V_NOP will be discarded by SQ.

  // Use V_MOV_B32 v?, v?. Register must be alive so use src0 of V_PERMLANE*

  // which is always a VGPR and available.

  auto *Src0 = TII->getNamedOperand(*MI, AMDGPU::OpName::src0);

  Register Reg = Src0->getReg();

  bool IsUndef = Src0->isUndef();

  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII->get(AMDGPU::V_MOV_B32_e32))

    .addReg(Reg, RegState::Define | (IsUndef ? RegState::Dead : 0))

    .addReg(Reg, IsUndef ? RegState::Undef : RegState::Kill);


  return true;

}


bool GCNHazardRecognizer::fixVMEMtoScalarWriteHazards(MachineInstr *MI) {

  if (!ST.hasVMEMtoScalarWriteHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!SIInstrInfo::isSALU(*MI) && !SIInstrInfo::isSMRD(*MI))

    return false;


  if (MI->getNumDefs() == 0)

    return false;


  const SIRegisterInfo *TRI = ST.getRegisterInfo();


  auto IsHazardFn = [TRI, MI](const MachineInstr &I) {

    if (!SIInstrInfo::isVMEM(I) && !SIInstrInfo::isDS(I) &&

        !SIInstrInfo::isFLAT(I))

      return false;


    for (const MachineOperand &Def : MI->defs()) {

      const MachineOperand *Op =

          I.findRegisterUseOperand(Def.getReg(), TRI, false);

      if (!Op)

        continue;

      return true;

    }

    return false;

  };


  auto IsExpiredFn = [](const MachineInstr &MI, int) {

    return SIInstrInfo::isVALU(MI) ||

           (MI.getOpcode() == AMDGPU::S_WAITCNT &&

            !MI.getOperand(0).getImm()) ||

           (MI.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

            AMDGPU::DepCtr::decodeFieldVmVsrc(MI.getOperand(0).getImm()) == 0);

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  const SIInstrInfo *TII = ST.getInstrInfo();

  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII->get(AMDGPU::S_WAITCNT_DEPCTR))

      .addImm(AMDGPU::DepCtr::encodeFieldVmVsrc(0));

  return true;

}


bool GCNHazardRecognizer::fixSMEMtoVectorWriteHazards(MachineInstr *MI) {

  if (!ST.hasSMEMtoVectorWriteHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!SIInstrInfo::isVALU(*MI))

    return false;


  unsigned SDSTName;

  switch (MI->getOpcode()) {

  case AMDGPU::V_READLANE_B32:

  case AMDGPU::V_READFIRSTLANE_B32:

    SDSTName = AMDGPU::OpName::vdst;

    break;

  default:

    SDSTName = AMDGPU::OpName::sdst;

    break;

  }


  const SIInstrInfo *TII = ST.getInstrInfo();

  const SIRegisterInfo *TRI = ST.getRegisterInfo();

  const AMDGPU::IsaVersion IV = AMDGPU::getIsaVersion(ST.getCPU());

  const MachineOperand *SDST = TII->getNamedOperand(*MI, SDSTName);

  if (!SDST) {

    for (const auto &MO : MI->implicit_operands()) {

      if (MO.isDef() && TRI->isSGPRClass(TRI->getPhysRegBaseClass(MO.getReg()))) {

        SDST = &MO;

        break;

      }

    }

  }


  if (!SDST)

    return false;


  const Register SDSTReg = SDST->getReg();

  auto IsHazardFn = [SDSTReg, TRI](const MachineInstr &I) {

    return SIInstrInfo::isSMRD(I) && I.readsRegister(SDSTReg, TRI);

  };


  auto IsExpiredFn = [TII, IV](const MachineInstr &MI, int) {

    if (TII->isSALU(MI)) {

      switch (MI.getOpcode()) {

      case AMDGPU::S_SETVSKIP:

      case AMDGPU::S_VERSION:

      case AMDGPU::S_WAITCNT_VSCNT:

      case AMDGPU::S_WAITCNT_VMCNT:

      case AMDGPU::S_WAITCNT_EXPCNT:

        // These instructions cannot not mitigate the hazard.

        return false;

      case AMDGPU::S_WAITCNT_LGKMCNT:

        // Reducing lgkmcnt count to 0 always mitigates the hazard.

        return (MI.getOperand(1).getImm() == 0) &&

               (MI.getOperand(0).getReg() == AMDGPU::SGPR_NULL);

      case AMDGPU::S_WAITCNT: {

        const int64_t Imm = MI.getOperand(0).getImm();

        AMDGPU::Waitcnt Decoded = AMDGPU::decodeWaitcnt(IV, Imm);

        // DsCnt corresponds to LGKMCnt here.

        return (Decoded.DsCnt == 0);

      }

      default:

        // SOPP instructions cannot mitigate the hazard.

        if (TII->isSOPP(MI))

          return false;

        // At this point the SALU can be assumed to mitigate the hazard

        // because either:

        // (a) it is independent of the at risk SMEM (breaking chain),

        // or

        // (b) it is dependent on the SMEM, in which case an appropriate

        //     s_waitcnt lgkmcnt _must_ exist between it and the at risk

        //     SMEM instruction.

        return true;

      }

    }

    return false;

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII->get(AMDGPU::S_MOV_B32), AMDGPU::SGPR_NULL)

      .addImm(0);

  return true;

}


bool GCNHazardRecognizer::fixVcmpxExecWARHazard(MachineInstr *MI) {

  if (!ST.hasVcmpxExecWARHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!SIInstrInfo::isVALU(*MI))

    return false;


  const SIRegisterInfo *TRI = ST.getRegisterInfo();

  if (!MI->modifiesRegister(AMDGPU::EXEC, TRI))

    return false;


  auto IsHazardFn = [TRI](const MachineInstr &I) {

    if (SIInstrInfo::isVALU(I))

      return false;

    return I.readsRegister(AMDGPU::EXEC, TRI);

  };


  const SIInstrInfo *TII = ST.getInstrInfo();

  auto IsExpiredFn = [TII, TRI](const MachineInstr &MI, int) {

    if (SIInstrInfo::isVALU(MI)) {

      if (TII->getNamedOperand(MI, AMDGPU::OpName::sdst))

        return true;

      for (auto MO : MI.implicit_operands())

        if (MO.isDef() && TRI->isSGPRClass(TRI->getPhysRegBaseClass(MO.getReg())))

          return true;

    }

    if (MI.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

        AMDGPU::DepCtr::decodeFieldSaSdst(MI.getOperand(0).getImm()) == 0)

      return true;

    return false;

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII->get(AMDGPU::S_WAITCNT_DEPCTR))

      .addImm(AMDGPU::DepCtr::encodeFieldSaSdst(0));

  return true;

}


static bool shouldRunLdsBranchVmemWARHazardFixup(const MachineFunction &MF,

                                                 const GCNSubtarget &ST) {

  if (!ST.hasLdsBranchVmemWARHazard())

    return false;


  // Check if the necessary condition for the hazard is met: both LDS and VMEM

  // instructions need to appear in the same function.

  bool HasLds = false;

  bool HasVmem = false;

  for (auto &MBB : MF) {

    for (auto &MI : MBB) {

      HasLds |= SIInstrInfo::isDS(MI);

      HasVmem |=

          SIInstrInfo::isVMEM(MI) || SIInstrInfo::isSegmentSpecificFLAT(MI);

      if (HasLds && HasVmem)

        return true;

    }

  }

  return false;

}


static bool isStoreCountWaitZero(const MachineInstr &I) {

  return I.getOpcode() == AMDGPU::S_WAITCNT_VSCNT &&

         I.getOperand(0).getReg() == AMDGPU::SGPR_NULL &&

         !I.getOperand(1).getImm();

}


bool GCNHazardRecognizer::fixLdsBranchVmemWARHazard(MachineInstr *MI) {

  if (!RunLdsBranchVmemWARHazardFixup)

    return false;


  assert(ST.hasLdsBranchVmemWARHazard());

  assert(!ST.hasExtendedWaitCounts());


  auto IsHazardInst = [](const MachineInstr &MI) {

    if (SIInstrInfo::isDS(MI))

      return 1;

    if (SIInstrInfo::isVMEM(MI) || SIInstrInfo::isSegmentSpecificFLAT(MI))

      return 2;

    return 0;

  };


  auto InstType = IsHazardInst(*MI);

  if (!InstType)

    return false;


  auto IsExpiredFn = [&IsHazardInst](const MachineInstr &I, int) {

    return IsHazardInst(I) || isStoreCountWaitZero(I);

  };


  auto IsHazardFn = [InstType, &IsHazardInst](const MachineInstr &I) {

    if (!I.isBranch())

      return false;


    auto IsHazardFn = [InstType, IsHazardInst](const MachineInstr &I) {

      auto InstType2 = IsHazardInst(I);

      return InstType2 && InstType != InstType2;

    };


    auto IsExpiredFn = [InstType, &IsHazardInst](const MachineInstr &I, int) {

      auto InstType2 = IsHazardInst(I);

      if (InstType == InstType2)

        return true;


      return isStoreCountWaitZero(I);

    };


    return ::getWaitStatesSince(IsHazardFn, &I, IsExpiredFn) !=

           std::numeric_limits<int>::max();

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  const SIInstrInfo *TII = ST.getInstrInfo();

  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII->get(AMDGPU::S_WAITCNT_VSCNT))

    .addReg(AMDGPU::SGPR_NULL, RegState::Undef)

    .addImm(0);


  return true;

}


bool GCNHazardRecognizer::fixLdsDirectVALUHazard(MachineInstr *MI) {

  if (!SIInstrInfo::isLDSDIR(*MI))

    return false;


  const int NoHazardWaitStates = 15;

  const MachineOperand *VDST = TII.getNamedOperand(*MI, AMDGPU::OpName::vdst);

  const Register VDSTReg = VDST->getReg();


  bool VisitedTrans = false;

  auto IsHazardFn = [this, VDSTReg, &VisitedTrans](const MachineInstr &I) {

    if (!SIInstrInfo::isVALU(I))

      return false;

    VisitedTrans = VisitedTrans || SIInstrInfo::isTRANS(I);

    // Cover both WAR and WAW

    return I.readsRegister(VDSTReg, &TRI) || I.modifiesRegister(VDSTReg, &TRI);

  };

  auto IsExpiredFn = [&](const MachineInstr &I, int WaitStates) {

    if (WaitStates >= NoHazardWaitStates)

      return true;

    // Instructions which cause va_vdst==0 expire hazard

    return SIInstrInfo::isVMEM(I) || SIInstrInfo::isFLAT(I) ||

           SIInstrInfo::isDS(I) || SIInstrInfo::isEXP(I);

  };

  auto GetWaitStatesFn = [](const MachineInstr &MI) {

    return SIInstrInfo::isVALU(MI) ? 1 : 0;

  };


  DenseSet<const MachineBasicBlock *> Visited;

  auto Count = ::getWaitStatesSince(IsHazardFn, MI->getParent(),

                                    std::next(MI->getReverseIterator()), 0,

                                    IsExpiredFn, Visited, GetWaitStatesFn);


  // Transcendentals can execute in parallel to other VALUs.

  // This makes va_vdst count unusable with a mixture of VALU and TRANS.

  if (VisitedTrans)

    Count = 0;


  MachineOperand *WaitVdstOp =

      TII.getNamedOperand(*MI, AMDGPU::OpName::waitvdst);

  WaitVdstOp->setImm(std::min(Count, NoHazardWaitStates));


  return true;

}


bool GCNHazardRecognizer::fixLdsDirectVMEMHazard(MachineInstr *MI) {

  if (!SIInstrInfo::isLDSDIR(*MI))

    return false;


  const MachineOperand *VDST = TII.getNamedOperand(*MI, AMDGPU::OpName::vdst);

  const Register VDSTReg = VDST->getReg();


  auto IsHazardFn = [this, VDSTReg](const MachineInstr &I) {

    if (!SIInstrInfo::isVMEM(I) && !SIInstrInfo::isFLAT(I) &&

        !SIInstrInfo::isDS(I))

      return false;

    return I.readsRegister(VDSTReg, &TRI) || I.modifiesRegister(VDSTReg, &TRI);

  };

  bool LdsdirCanWait = ST.hasLdsWaitVMSRC();

  // TODO: On GFX12 the hazard should expire on S_WAIT_LOADCNT/SAMPLECNT/BVHCNT

  // according to the type of VMEM instruction.

  auto IsExpiredFn = [this, LdsdirCanWait](const MachineInstr &I, int) {

    return SIInstrInfo::isVALU(I) || SIInstrInfo::isEXP(I) ||

           (I.getOpcode() == AMDGPU::S_WAITCNT && !I.getOperand(0).getImm()) ||

           (I.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

            AMDGPU::DepCtr::decodeFieldVmVsrc(I.getOperand(0).getImm()) == 0) ||

           (LdsdirCanWait && SIInstrInfo::isLDSDIR(I) &&

            !TII.getNamedOperand(I, AMDGPU::OpName::waitvsrc)->getImm());

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  if (LdsdirCanWait) {

    TII.getNamedOperand(*MI, AMDGPU::OpName::waitvsrc)->setImm(0);

  } else {

    BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

            TII.get(AMDGPU::S_WAITCNT_DEPCTR))

        .addImm(AMDGPU::DepCtr::encodeFieldVmVsrc(0));

  }


  return true;

}


bool GCNHazardRecognizer::fixVALUPartialForwardingHazard(MachineInstr *MI) {

  if (!ST.hasVALUPartialForwardingHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!ST.isWave64() || !SIInstrInfo::isVALU(*MI))

    return false;


  SmallSetVector<Register, 4> SrcVGPRs;


  for (const MachineOperand &Use : MI->explicit_uses()) {

    if (Use.isReg() && TRI.isVGPR(MF.getRegInfo(), Use.getReg()))

      SrcVGPRs.insert(Use.getReg());

  }


  // Only applies with >= 2 unique VGPR sources

  if (SrcVGPRs.size() <= 1)

    return false;


  // Look for the following pattern:

  //   Va <- VALU [PreExecPos]

  //   intv1

  //   Exec <- SALU [ExecPos]

  //   intv2

  //   Vb <- VALU [PostExecPos]

  //   intv3

  //   MI Va, Vb (WaitState = 0)

  //

  // Where:

  // intv1 + intv2 <= 2 VALUs

  // intv3 <= 4 VALUs

  //

  // If found, insert an appropriate S_WAITCNT_DEPCTR before MI.


  const int Intv1plus2MaxVALUs = 2;

  const int Intv3MaxVALUs = 4;

  const int IntvMaxVALUs = 6;

  const int NoHazardVALUWaitStates = IntvMaxVALUs + 2;


  struct StateType {

    SmallDenseMap<Register, int, 4> DefPos;

    int ExecPos = std::numeric_limits<int>::max();

    int VALUs = 0;

  };


  StateType State;


  // This overloads expiry testing with all the hazard detection

  auto IsHazardFn = [&, this](StateType &State, const MachineInstr &I) {

    // Too many VALU states have passed

    if (State.VALUs > NoHazardVALUWaitStates)

      return HazardExpired;


    // Instructions which cause va_vdst==0 expire hazard

    if (SIInstrInfo::isVMEM(I) || SIInstrInfo::isFLAT(I) ||

        SIInstrInfo::isDS(I) || SIInstrInfo::isEXP(I) ||

        (I.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

         AMDGPU::DepCtr::decodeFieldVaVdst(I.getOperand(0).getImm()) == 0))

      return HazardExpired;


    // Track registers writes

    bool Changed = false;

    if (SIInstrInfo::isVALU(I)) {

      for (Register Src : SrcVGPRs) {

        if (!State.DefPos.count(Src) && I.modifiesRegister(Src, &TRI)) {

          State.DefPos[Src] = State.VALUs;

          Changed = true;

        }

      }

    } else if (SIInstrInfo::isSALU(I)) {

      if (State.ExecPos == std::numeric_limits<int>::max()) {

        if (!State.DefPos.empty() && I.modifiesRegister(AMDGPU::EXEC, &TRI)) {

          State.ExecPos = State.VALUs;

          Changed = true;

        }

      }

    }


    // Early expiration: too many VALUs in intv3

    if (State.VALUs > Intv3MaxVALUs && State.DefPos.empty())

      return HazardExpired;


    // Only evaluate state if something changed

    if (!Changed)

      return NoHazardFound;


    // Determine positions of VALUs pre/post exec change

    if (State.ExecPos == std::numeric_limits<int>::max())

      return NoHazardFound;


    int PreExecPos = std::numeric_limits<int>::max();

    int PostExecPos = std::numeric_limits<int>::max();


    for (auto Entry : State.DefPos) {

      int DefVALUs = Entry.second;

      if (DefVALUs != std::numeric_limits<int>::max()) {

        if (DefVALUs >= State.ExecPos)

          PreExecPos = std::min(PreExecPos, DefVALUs);

        else

          PostExecPos = std::min(PostExecPos, DefVALUs);

      }

    }


    // Need a VALUs post exec change

    if (PostExecPos == std::numeric_limits<int>::max())

      return NoHazardFound;


    // Too many VALUs in intv3?

    int Intv3VALUs = PostExecPos;

    if (Intv3VALUs > Intv3MaxVALUs)

      return HazardExpired;


    // Too many VALUs in intv2?

    int Intv2VALUs = (State.ExecPos - PostExecPos) - 1;

    if (Intv2VALUs > Intv1plus2MaxVALUs)

      return HazardExpired;


    // Need a VALUs pre exec change

    if (PreExecPos == std::numeric_limits<int>::max())

      return NoHazardFound;


    // Too many VALUs in intv1?

    int Intv1VALUs = PreExecPos - State.ExecPos;

    if (Intv1VALUs > Intv1plus2MaxVALUs)

      return HazardExpired;


    // Too many VALUs in intv1 + intv2

    if (Intv1VALUs + Intv2VALUs > Intv1plus2MaxVALUs)

      return HazardExpired;


    return HazardFound;

  };

  auto UpdateStateFn = [](StateType &State, const MachineInstr &MI) {

    if (SIInstrInfo::isVALU(MI))

      State.VALUs += 1;

  };


  DenseSet<const MachineBasicBlock *> Visited;

  if (!hasHazard<StateType>(State, IsHazardFn, UpdateStateFn, MI->getParent(),

                            std::next(MI->getReverseIterator()), Visited))

    return false;


  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII.get(AMDGPU::S_WAITCNT_DEPCTR))

      .addImm(0x0fff);


  return true;

}


bool GCNHazardRecognizer::fixVALUTransUseHazard(MachineInstr *MI) {

  if (!ST.hasVALUTransUseHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!SIInstrInfo::isVALU(*MI))

    return false;


  SmallSet<Register, 4> SrcVGPRs;


  for (const MachineOperand &Use : MI->explicit_uses()) {

    if (Use.isReg() && TRI.isVGPR(MF.getRegInfo(), Use.getReg()))

      SrcVGPRs.insert(Use.getReg());

  }


  // Look for the following pattern:

  //   Va <- TRANS VALU

  //   intv

  //   MI Va (WaitState = 0)

  //

  // Where:

  // intv <= 5 VALUs / 1 TRANS

  //

  // If found, insert an appropriate S_WAITCNT_DEPCTR before MI.


  const int IntvMaxVALUs = 5;

  const int IntvMaxTRANS = 1;


  struct StateType {

    int VALUs = 0;

    int TRANS = 0;

  };


  StateType State;


  // This overloads expiry testing with all the hazard detection

  auto IsHazardFn = [&, this](StateType &State, const MachineInstr &I) {

    // Too many VALU states have passed

    if (State.VALUs > IntvMaxVALUs || State.TRANS > IntvMaxTRANS)

      return HazardExpired;


    // Instructions which cause va_vdst==0 expire hazard

    if (SIInstrInfo::isVMEM(I) || SIInstrInfo::isFLAT(I) ||

        SIInstrInfo::isDS(I) || SIInstrInfo::isEXP(I) ||

        (I.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

         I.getOperand(0).getImm() == 0x0fff))

      return HazardExpired;


    // Track registers writes

    if (SIInstrInfo::isTRANS(I)) {

      for (Register Src : SrcVGPRs) {

        if (I.modifiesRegister(Src, &TRI)) {

          return HazardFound;

        }

      }

    }


    return NoHazardFound;

  };

  auto UpdateStateFn = [](StateType &State, const MachineInstr &MI) {

    if (SIInstrInfo::isVALU(MI))

      State.VALUs += 1;

    if (SIInstrInfo::isTRANS(MI))

      State.TRANS += 1;

  };


  DenseSet<const MachineBasicBlock *> Visited;

  if (!hasHazard<StateType>(State, IsHazardFn, UpdateStateFn, MI->getParent(),

                            std::next(MI->getReverseIterator()), Visited))

    return false;


  // Hazard is observed - insert a wait on va_dst counter to ensure hazard is

  // avoided.

  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(),

          TII.get(AMDGPU::S_WAITCNT_DEPCTR))

      .addImm(AMDGPU::DepCtr::encodeFieldVaVdst(0));


  return true;

}


bool GCNHazardRecognizer::fixWMMAHazards(MachineInstr *MI) {

  if (!SIInstrInfo::isWMMA(*MI) && !SIInstrInfo::isSWMMAC(*MI))

    return false;


  const SIInstrInfo *TII = ST.getInstrInfo();

  const SIRegisterInfo *TRI = ST.getRegisterInfo();


  auto IsHazardFn = [MI, TII, TRI, this](const MachineInstr &I) {

    if (!SIInstrInfo::isWMMA(I) && !SIInstrInfo::isSWMMAC(I))

      return false;


    // Src0(matrix A) or Src1(matrix B) of the current wmma instruction overlaps

    // with the dest(matrix D) of the previous wmma.

    const Register CurSrc0Reg =

        TII->getNamedOperand(*MI, AMDGPU::OpName::src0)->getReg();

    const Register CurSrc1Reg =

        TII->getNamedOperand(*MI, AMDGPU::OpName::src1)->getReg();


    const Register PrevDstReg =

        TII->getNamedOperand(I, AMDGPU::OpName::vdst)->getReg();


    if (TRI->regsOverlap(PrevDstReg, CurSrc0Reg) ||

        TRI->regsOverlap(PrevDstReg, CurSrc1Reg)) {

      return true;

    }


    // GFX12+ allows overlap of matrix C with PrevDstReg (hardware will stall)

    // but Index can't overlap with PrevDstReg.

    if (AMDGPU::isGFX12Plus(ST)) {

      if (SIInstrInfo::isSWMMAC(*MI)) {

        const Register CurIndex =

            TII->getNamedOperand(*MI, AMDGPU::OpName::src2)->getReg();

        if (TRI->regsOverlap(PrevDstReg, CurIndex))

          return true;

      }

      return false;

    }


    return false;

  };


  auto IsExpiredFn = [](const MachineInstr &I, int) {

    return SIInstrInfo::isVALU(I);

  };


  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  BuildMI(*MI->getParent(), MI, MI->getDebugLoc(), TII->get(AMDGPU::V_NOP_e32));


  return true;

}


bool GCNHazardRecognizer::fixShift64HighRegBug(MachineInstr *MI) {

  if (!ST.hasShift64HighRegBug())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  switch (MI->getOpcode()) {

  default:

    return false;

  case AMDGPU::V_LSHLREV_B64_e64:

  case AMDGPU::V_LSHRREV_B64_e64:

  case AMDGPU::V_ASHRREV_I64_e64:

    break;

  }


  MachineOperand *Amt = TII.getNamedOperand(*MI, AMDGPU::OpName::src0);

  if (!Amt->isReg())

    return false;


  Register AmtReg = Amt->getReg();

  const MachineRegisterInfo &MRI = MF.getRegInfo();

  // Check if this is a last VGPR in the allocation block.

  if (!TRI.isVGPR(MRI, AmtReg) || ((AmtReg - AMDGPU::VGPR0) & 7) != 7)

    return false;


  if (AmtReg != AMDGPU::VGPR255 && MRI.isPhysRegUsed(AmtReg + 1))

    return false;


  MachineOperand *Src1 = TII.getNamedOperand(*MI, AMDGPU::OpName::src1);

  bool OverlappedSrc = Src1->isReg() && TRI.regsOverlap(Src1->getReg(), AmtReg);

  bool OverlappedDst = MI->modifiesRegister(AmtReg, &TRI);

  bool Overlapped = OverlappedSrc || OverlappedDst;


  assert(!OverlappedDst || !OverlappedSrc ||

         Src1->getReg() == MI->getOperand(0).getReg());

  assert(ST.needsAlignedVGPRs());

  static_assert(AMDGPU::VGPR0 + 1 == AMDGPU::VGPR1);


  Register NewReg;

  for (MCRegister Reg : Overlapped ? AMDGPU::VReg_64_Align2RegClass

                                   : AMDGPU::VGPR_32RegClass) {

    if (!MI->modifiesRegister(Reg, &TRI) && !MI->readsRegister(Reg, &TRI)) {

      NewReg = Reg;

      break;

    }

  }


  Register NewAmt = Overlapped ? (Register)TRI.getSubReg(NewReg, AMDGPU::sub1)

                               : NewReg;

  Register NewAmtLo;


  if (Overlapped)

    NewAmtLo = TRI.getSubReg(NewReg, AMDGPU::sub0);


  DebugLoc DL = MI->getDebugLoc();

  MachineBasicBlock *MBB = MI->getParent();

  // Insert a full wait count because found register might be pending a wait.

  BuildMI(*MBB, MI, DL, TII.get(AMDGPU::S_WAITCNT))

      .addImm(0);


  // Insert V_SWAP_B32 instruction(s) and run hazard recognizer on them.

  if (Overlapped)

    runOnInstruction(

        BuildMI(*MBB, MI, DL, TII.get(AMDGPU::V_SWAP_B32), NewAmtLo)

            .addDef(AmtReg - 1)

            .addReg(AmtReg - 1, RegState::Undef)

            .addReg(NewAmtLo, RegState::Undef));

  runOnInstruction(BuildMI(*MBB, MI, DL, TII.get(AMDGPU::V_SWAP_B32), NewAmt)

                       .addDef(AmtReg)

                       .addReg(AmtReg, RegState::Undef)

                       .addReg(NewAmt, RegState::Undef));


  // Instructions emitted after the current instruction will be processed by the

  // parent loop of the hazard recognizer in a natural way.

  BuildMI(*MBB, std::next(MI->getIterator()), DL, TII.get(AMDGPU::V_SWAP_B32),

          AmtReg)

      .addDef(NewAmt)

      .addReg(NewAmt)

      .addReg(AmtReg);

  if (Overlapped)

    BuildMI(*MBB, std::next(MI->getIterator()), DL, TII.get(AMDGPU::V_SWAP_B32),

            AmtReg - 1)

        .addDef(NewAmtLo)

        .addReg(NewAmtLo)

        .addReg(AmtReg - 1);


  // Re-running hazard recognizer on the modified instruction is not necessary,

  // inserted V_SWAP_B32 has already both read and write new registers so

  // hazards related to these register has already been handled.

  Amt->setReg(NewAmt);

  Amt->setIsKill(false);

  // We do not update liveness, so verifier may see it as undef.

  Amt->setIsUndef();

  if (OverlappedDst)

    MI->getOperand(0).setReg(NewReg);

  if (OverlappedSrc) {

    Src1->setReg(NewReg);

    Src1->setIsKill(false);

    Src1->setIsUndef();

  }


  return true;

}


int GCNHazardRecognizer::checkNSAtoVMEMHazard(MachineInstr *MI) {

  int NSAtoVMEMWaitStates = 1;


  if (!ST.hasNSAtoVMEMBug())

    return 0;


  if (!SIInstrInfo::isMUBUF(*MI) && !SIInstrInfo::isMTBUF(*MI))

    return 0;


  const SIInstrInfo *TII = ST.getInstrInfo();

  const auto *Offset = TII->getNamedOperand(*MI, AMDGPU::OpName::offset);

  if (!Offset || (Offset->getImm() & 6) == 0)

    return 0;


  auto IsHazardFn = [TII](const MachineInstr &I) {

    if (!SIInstrInfo::isMIMG(I))

      return false;

    const AMDGPU::MIMGInfo *Info = AMDGPU::getMIMGInfo(I.getOpcode());

    return Info->MIMGEncoding == AMDGPU::MIMGEncGfx10NSA &&

           TII->getInstSizeInBytes(I) >= 16;

  };


  return NSAtoVMEMWaitStates - getWaitStatesSince(IsHazardFn, 1);

}


int GCNHazardRecognizer::checkFPAtomicToDenormModeHazard(MachineInstr *MI) {

  int FPAtomicToDenormModeWaitStates = 3;


  if (!ST.hasFPAtomicToDenormModeHazard())

    return 0;

  assert(!ST.hasExtendedWaitCounts());


  if (MI->getOpcode() != AMDGPU::S_DENORM_MODE)

    return 0;


  auto IsHazardFn = [](const MachineInstr &I) {

    if (!SIInstrInfo::isVMEM(I) && !SIInstrInfo::isFLAT(I))

      return false;

    return SIInstrInfo::isFPAtomic(I);

  };


  auto IsExpiredFn = [](const MachineInstr &MI, int WaitStates) {

    if (WaitStates >= 3 || SIInstrInfo::isVALU(MI))

      return true;


    switch (MI.getOpcode()) {

    case AMDGPU::S_WAITCNT:

    case AMDGPU::S_WAITCNT_VSCNT:

    case AMDGPU::S_WAITCNT_VMCNT:

    case AMDGPU::S_WAITCNT_EXPCNT:

    case AMDGPU::S_WAITCNT_LGKMCNT:

    case AMDGPU::S_WAIT_IDLE:

      return true;

    default:

      break;

    }


    return false;

  };


  return FPAtomicToDenormModeWaitStates -

         ::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn);

}


int GCNHazardRecognizer::checkMAIHazards(MachineInstr *MI) {

  assert(SIInstrInfo::isMAI(*MI));


  return ST.hasGFX90AInsts() ? checkMAIHazards90A(MI) : checkMAIHazards908(MI);

}


int GCNHazardRecognizer::checkMFMAPadding(MachineInstr *MI) {

  // Early exit if no padding is requested.

  if (MFMAPaddingRatio == 0)

    return 0;


  const SIMachineFunctionInfo *MFI = MF.getInfo<SIMachineFunctionInfo>();

  if (!SIInstrInfo::isMFMA(*MI) || MFI->getOccupancy() < 2)

    return 0;


  int NeighborMFMALatency = 0;

  auto IsNeighboringMFMA = [&NeighborMFMALatency,

                            this](const MachineInstr &MI) {

    if (!SIInstrInfo::isMFMA(MI))

      return false;


    NeighborMFMALatency = this->getMFMAPipelineWaitStates(MI);

    return true;

  };


  const int MaxMFMAPipelineWaitStates = 16;

  int WaitStatesSinceNeighborMFMA =

      getWaitStatesSince(IsNeighboringMFMA, MaxMFMAPipelineWaitStates);


  int NeighborMFMAPaddingNeeded =

      (NeighborMFMALatency * MFMAPaddingRatio / 100) -

      WaitStatesSinceNeighborMFMA;


  return std::max(0, NeighborMFMAPaddingNeeded);

}


int GCNHazardRecognizer::checkMAIHazards908(MachineInstr *MI) {

  int WaitStatesNeeded = 0;

  unsigned Opc = MI->getOpcode();


  auto IsVALUFn = [](const MachineInstr &MI) {

    return SIInstrInfo::isVALU(MI) || MI.isInlineAsm();

  };


  if (Opc != AMDGPU::V_ACCVGPR_READ_B32_e64) { // MFMA or v_accvgpr_write

    const int LegacyVALUWritesVGPRWaitStates = 2;

    const int VALUWritesExecWaitStates = 4;

    const int MaxWaitStates = 4;


    int WaitStatesNeededForUse = VALUWritesExecWaitStates -

      getWaitStatesSinceDef(AMDGPU::EXEC, IsVALUFn, MaxWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    if (WaitStatesNeeded < MaxWaitStates) {

      for (const MachineOperand &Use : MI->explicit_uses()) {

        const int MaxWaitStates = 2;


        if (!Use.isReg() || !TRI.isVGPR(MF.getRegInfo(), Use.getReg()))

          continue;


        int WaitStatesNeededForUse = LegacyVALUWritesVGPRWaitStates -

          getWaitStatesSinceDef(Use.getReg(), IsVALUFn, MaxWaitStates);

        WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


        if (WaitStatesNeeded == MaxWaitStates)

          break;

      }

    }

  }


  for (const MachineOperand &Op : MI->explicit_operands()) {

    if (!Op.isReg() || !TRI.isAGPR(MF.getRegInfo(), Op.getReg()))

      continue;


    if (Op.isDef() && Opc != AMDGPU::V_ACCVGPR_WRITE_B32_e64)

      continue;


    const int MFMAWritesAGPROverlappedSrcABWaitStates = 4;

    const int MFMAWritesAGPROverlappedSrcCWaitStates = 2;

    const int MFMA4x4WritesAGPRAccVgprReadWaitStates = 4;

    const int MFMA16x16WritesAGPRAccVgprReadWaitStates = 10;

    const int MFMA32x32WritesAGPRAccVgprReadWaitStates = 18;

    const int MFMA4x4WritesAGPRAccVgprWriteWaitStates = 1;

    const int MFMA16x16WritesAGPRAccVgprWriteWaitStates = 7;

    const int MFMA32x32WritesAGPRAccVgprWriteWaitStates = 15;

    const int MaxWaitStates = 18;

    Register Reg = Op.getReg();

    unsigned HazardDefLatency = 0;


    auto IsOverlappedMFMAFn = [Reg, &HazardDefLatency,

                               this](const MachineInstr &MI) {

      if (!SIInstrInfo::isMFMA(MI))

        return false;

      Register DstReg = MI.getOperand(0).getReg();

      if (DstReg == Reg)

        return false;

      HazardDefLatency =

          std::max(HazardDefLatency, TSchedModel.computeInstrLatency(&MI));

      return TRI.regsOverlap(DstReg, Reg);

    };


    int WaitStatesSinceDef = getWaitStatesSinceDef(Reg, IsOverlappedMFMAFn,

                                                   MaxWaitStates);

    int NeedWaitStates = MFMAWritesAGPROverlappedSrcABWaitStates;

    int SrcCIdx = AMDGPU::getNamedOperandIdx(Opc, AMDGPU::OpName::src2);

    int OpNo = Op.getOperandNo();

    if (OpNo == SrcCIdx) {

      NeedWaitStates = MFMAWritesAGPROverlappedSrcCWaitStates;

    } else if (Opc == AMDGPU::V_ACCVGPR_READ_B32_e64) {

      switch (HazardDefLatency) {

      case 2:  NeedWaitStates = MFMA4x4WritesAGPRAccVgprReadWaitStates;

               break;

      case 8:  NeedWaitStates = MFMA16x16WritesAGPRAccVgprReadWaitStates;

               break;

      case 16: [[fallthrough]];

      default: NeedWaitStates = MFMA32x32WritesAGPRAccVgprReadWaitStates;

               break;

      }

    } else if (Opc == AMDGPU::V_ACCVGPR_WRITE_B32_e64) {

      switch (HazardDefLatency) {

      case 2:  NeedWaitStates = MFMA4x4WritesAGPRAccVgprWriteWaitStates;

               break;

      case 8:  NeedWaitStates = MFMA16x16WritesAGPRAccVgprWriteWaitStates;

               break;

      case 16: [[fallthrough]];

      default: NeedWaitStates = MFMA32x32WritesAGPRAccVgprWriteWaitStates;

               break;

      }

    }


    int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSinceDef;

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    if (WaitStatesNeeded == MaxWaitStates)

      return WaitStatesNeeded; // Early exit.


    auto IsAccVgprWriteFn = [Reg, this](const MachineInstr &MI) {

      if (MI.getOpcode() != AMDGPU::V_ACCVGPR_WRITE_B32_e64)

        return false;

      Register DstReg = MI.getOperand(0).getReg();

      return TRI.regsOverlap(Reg, DstReg);

    };


    const int AccVGPRWriteMFMAReadSrcCWaitStates = 1;

    const int AccVGPRWriteMFMAReadSrcABWaitStates = 3;

    const int AccVGPRWriteAccVgprReadWaitStates = 3;

    NeedWaitStates = AccVGPRWriteMFMAReadSrcABWaitStates;

    if (OpNo == SrcCIdx)

      NeedWaitStates = AccVGPRWriteMFMAReadSrcCWaitStates;

    else if (Opc == AMDGPU::V_ACCVGPR_READ_B32_e64)

      NeedWaitStates = AccVGPRWriteAccVgprReadWaitStates;


    WaitStatesNeededForUse = NeedWaitStates -

      getWaitStatesSinceDef(Reg, IsAccVgprWriteFn, MaxWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    if (WaitStatesNeeded == MaxWaitStates)

      return WaitStatesNeeded; // Early exit.

  }


  if (Opc == AMDGPU::V_ACCVGPR_WRITE_B32_e64) {

    const int MFMA4x4ReadSrcCAccVgprWriteWaitStates = 0;

    const int MFMA16x16ReadSrcCAccVgprWriteWaitStates = 5;

    const int MFMA32x32ReadSrcCAccVgprWriteWaitStates = 13;

    const int MaxWaitStates = 13;

    Register DstReg = MI->getOperand(0).getReg();

    unsigned HazardDefLatency = 0;


    auto IsSrcCMFMAFn = [DstReg, &HazardDefLatency,

                         this](const MachineInstr &MI) {

      if (!SIInstrInfo::isMFMA(MI))

        return false;

      Register Reg = TII.getNamedOperand(MI, AMDGPU::OpName::src2)->getReg();

      HazardDefLatency =

          std::max(HazardDefLatency, TSchedModel.computeInstrLatency(&MI));

      return TRI.regsOverlap(Reg, DstReg);

    };


    int WaitStatesSince = getWaitStatesSince(IsSrcCMFMAFn, MaxWaitStates);

    int NeedWaitStates;

    switch (HazardDefLatency) {

    case 2:  NeedWaitStates = MFMA4x4ReadSrcCAccVgprWriteWaitStates;

             break;

    case 8:  NeedWaitStates = MFMA16x16ReadSrcCAccVgprWriteWaitStates;

             break;

    case 16: [[fallthrough]];

    default: NeedWaitStates = MFMA32x32ReadSrcCAccVgprWriteWaitStates;

             break;

    }


    int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSince;

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }


  // Pad neighboring MFMA with noops for better inter-wave performance.

  WaitStatesNeeded = std::max(WaitStatesNeeded, checkMFMAPadding(MI));


  return WaitStatesNeeded;

}


static int

GFX940_XDL_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(int NumPasses) {

  // 2 pass -> 3

  // 4 pass -> 5

  // 8 pass -> 9

  // 16 pass -> 17

  return NumPasses + 1;

}


static int

GFX940_SMFMA_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(int NumPasses) {

  // 2 pass -> 2

  // 4 pass -> 4

  // 8 pass -> 8

  // 16 pass -> 16

  return NumPasses;

}


static int

GFX940_SMFMA_N_PassWritesVGPROverlappedSrcABWaitStates(int NumPasses) {

  // 2 pass -> 4

  // 4 pass -> 6

  // 8 pass -> 10

  // 16 pass -> 18

  return NumPasses + 2;

}


static int GFX940_XDL_N_PassWritesVGPROverlappedSrcABWaitStates(int NumPasses) {

  // 2 pass -> 5

  // 4 pass -> 7

  // 8 pass -> 11

  // 16 pass -> 19

  return NumPasses + 3;

}


int GCNHazardRecognizer::checkMAIHazards90A(MachineInstr *MI) {

  int WaitStatesNeeded = 0;

  unsigned Opc = MI->getOpcode();


  auto IsLegacyVALUFn = [](const MachineInstr &MI) {

    return SIInstrInfo::isVALU(MI) && !SIInstrInfo::isMFMA(MI);

  };


  auto IsLegacyVALUNotDotFn = [](const MachineInstr &MI) {

    return SIInstrInfo::isVALU(MI) && !SIInstrInfo::isMFMA(MI) &&

           !SIInstrInfo::isDOT(MI);

  };


  if (!SIInstrInfo::isMFMA(*MI))

    return WaitStatesNeeded;


  const int VALUWritesExecWaitStates = 4;

  int WaitStatesNeededForUse = VALUWritesExecWaitStates -

    getWaitStatesSinceDef(AMDGPU::EXEC, IsLegacyVALUFn,

                          VALUWritesExecWaitStates);

  WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


  int SrcCIdx = AMDGPU::getNamedOperandIdx(Opc, AMDGPU::OpName::src2);


  // Loop for both DGEMM and S/HGEMM 2nd instruction.

  for (const MachineOperand &Use : MI->explicit_uses()) {

    const int LegacyVALUNotDotWritesVGPRWaitStates = 2;

    const int SMFMA4x4WritesVGPROverlappedSMFMASrcCWaitStates = 2;

    const int SMFMA16x16WritesVGPROverlappedSMFMASrcCWaitStates = 8;

    const int SMFMA32x32WritesVGPROverlappedSMFMASrcCWaitStates = 16;

    const int SMFMA4x4WritesVGPROverlappedDMFMASrcCWaitStates = 3;

    const int SMFMA16x16WritesVGPROverlappedDMFMASrcCWaitStates = 9;

    const int SMFMA32x32WritesVGPROverlappedDMFMASrcCWaitStates = 17;

    const int DMFMA16x16WritesVGPROverlappedSrcCWaitStates = 9;

    const int DMFMA4x4WritesVGPROverlappedSrcCWaitStates = 4;

    const int SMFMA4x4WritesVGPROverlappedSrcABWaitStates = 5;

    const int SMFMA16x16WritesVGPROverlappedSrcABWaitStates = 11;

    const int SMFMA32x32WritesVGPROverlappedSrcABWaitStates = 19;

    const int DMFMA4x4WritesVGPROverlappedMFMASrcABWaitStates = 6;

    const int DMFMA16x16WritesVGPROverlappedMFMASrcABWaitStates = 11;

    const int DMFMA4x4WritesVGPRFullSrcCWaitStates = 4;

    const int GFX940_SMFMA4x4WritesVGPRFullSrcCWaitStates = 2;

    const int MaxWaitStates = 19;


    if (!Use.isReg())

      continue;

    Register Reg = Use.getReg();

    bool FullReg;

    const MachineInstr *MI1;


    auto IsOverlappedMFMAFn = [Reg, &FullReg, &MI1,

                               this](const MachineInstr &MI) {

      if (!SIInstrInfo::isMFMA(MI))

        return false;

      Register DstReg = MI.getOperand(0).getReg();

      FullReg = (DstReg == Reg);

      MI1 = &MI;

      return TRI.regsOverlap(DstReg, Reg);

    };


    WaitStatesNeededForUse = LegacyVALUNotDotWritesVGPRWaitStates -

      getWaitStatesSinceDef(Reg, IsLegacyVALUNotDotFn, MaxWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    int NumWaitStates =

        getWaitStatesSinceDef(Reg, IsOverlappedMFMAFn, MaxWaitStates);

    if (NumWaitStates == std::numeric_limits<int>::max())

      continue;


    int OpNo = Use.getOperandNo();

    unsigned Opc1 = MI1->getOpcode();

    int NeedWaitStates = 0;

    if (OpNo == SrcCIdx) {

      if (!isDGEMM(Opc) && (!ST.hasGFX940Insts() && isDGEMM(Opc1))) {

        NeedWaitStates = 0;

      } else if (FullReg) {

        if ((Opc == AMDGPU::V_MFMA_F64_4X4X4F64_e64 ||

             Opc == AMDGPU::V_MFMA_F64_4X4X4F64_vgprcd_e64) &&

            (Opc1 == AMDGPU::V_MFMA_F64_4X4X4F64_e64 ||

             Opc1 == AMDGPU::V_MFMA_F64_4X4X4F64_vgprcd_e64))

          NeedWaitStates = DMFMA4x4WritesVGPRFullSrcCWaitStates;

        else if (ST.hasGFX940Insts() &&

                 TSchedModel.computeInstrLatency(MI1) == 2)

          NeedWaitStates = GFX940_SMFMA4x4WritesVGPRFullSrcCWaitStates;

      } else {

        switch (Opc1) {

        case AMDGPU::V_MFMA_F64_16X16X4F64_e64:

        case AMDGPU::V_MFMA_F64_16X16X4F64_vgprcd_e64:

        case AMDGPU::V_MFMA_F64_16X16X4F64_mac_e64:

        case AMDGPU::V_MFMA_F64_16X16X4F64_mac_vgprcd_e64:

          if (!isXDL(ST, *MI))

            NeedWaitStates = DMFMA16x16WritesVGPROverlappedSrcCWaitStates;

          break;

        case AMDGPU::V_MFMA_F64_4X4X4F64_e64:

        case AMDGPU::V_MFMA_F64_4X4X4F64_vgprcd_e64:

          if (!isXDL(ST, *MI))

            NeedWaitStates = DMFMA4x4WritesVGPROverlappedSrcCWaitStates;

          break;

        default:

          int NumPasses = TSchedModel.computeInstrLatency(MI1);

          if (ST.hasGFX940Insts()) {

            if (isXDL(ST, *MI) && !isXDL(ST, *MI1))

              break;


            NeedWaitStates =

                isXDL(ST, *MI1)

                    ? GFX940_XDL_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(

                          NumPasses)

                    : GFX940_SMFMA_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(

                          NumPasses);

            break;

          }


          switch (NumPasses) {

          case 2:

            NeedWaitStates =

                isDGEMM(Opc) ? SMFMA4x4WritesVGPROverlappedDMFMASrcCWaitStates

                             : SMFMA4x4WritesVGPROverlappedSMFMASrcCWaitStates;

            break;

          case 8:

            NeedWaitStates =

                isDGEMM(Opc)

                    ? SMFMA16x16WritesVGPROverlappedDMFMASrcCWaitStates

                    : SMFMA16x16WritesVGPROverlappedSMFMASrcCWaitStates;

            break;

          case 16:

            NeedWaitStates =

                isDGEMM(Opc)

                    ? SMFMA32x32WritesVGPROverlappedDMFMASrcCWaitStates

                    : SMFMA32x32WritesVGPROverlappedSMFMASrcCWaitStates;

            break;

          default:

            llvm_unreachable("unexpected number of passes");

          }

        }

      }

    } else {

      switch (Opc1) {

      case AMDGPU::V_MFMA_F64_16X16X4F64_e64:

      case AMDGPU::V_MFMA_F64_16X16X4F64_vgprcd_e64:

      case AMDGPU::V_MFMA_F64_16X16X4F64_mac_e64:

      case AMDGPU::V_MFMA_F64_16X16X4F64_mac_vgprcd_e64:

        NeedWaitStates = DMFMA16x16WritesVGPROverlappedMFMASrcABWaitStates;

        break;

      case AMDGPU::V_MFMA_F64_4X4X4F64_e64:

      case AMDGPU::V_MFMA_F64_4X4X4F64_vgprcd_e64:

        NeedWaitStates = DMFMA4x4WritesVGPROverlappedMFMASrcABWaitStates;

        break;

      default:

        int NumPasses = TSchedModel.computeInstrLatency(MI1);


        if (ST.hasGFX940Insts()) {

          NeedWaitStates =

              isXDL(ST, *MI1)

                  ? GFX940_XDL_N_PassWritesVGPROverlappedSrcABWaitStates(

                        NumPasses)

                  : GFX940_SMFMA_N_PassWritesVGPROverlappedSrcABWaitStates(

                        NumPasses);

          break;

        }


        switch (NumPasses) {

        case 2:

          NeedWaitStates = SMFMA4x4WritesVGPROverlappedSrcABWaitStates;

          break;

        case 4:

          llvm_unreachable("unexpected number of passes for mfma");

        case 8:

          NeedWaitStates = SMFMA16x16WritesVGPROverlappedSrcABWaitStates;

          break;

        case 16:

        default:

          NeedWaitStates = SMFMA32x32WritesVGPROverlappedSrcABWaitStates;

        }

      }

    }

    if (WaitStatesNeeded >= NeedWaitStates)

      continue;


    WaitStatesNeededForUse = NeedWaitStates - NumWaitStates;

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    if (WaitStatesNeeded == MaxWaitStates)

      break;

  }


  // Pad neighboring MFMA with noops for better inter-wave performance.

  WaitStatesNeeded = std::max(WaitStatesNeeded, checkMFMAPadding(MI));


  return WaitStatesNeeded;

}


int GCNHazardRecognizer::checkMAILdStHazards(MachineInstr *MI) {

  // On gfx90a+ relevant hazards are checked in checkMAIVALUHazards()

  if (!ST.hasMAIInsts() || ST.hasGFX90AInsts())

    return 0;


  int WaitStatesNeeded = 0;


  auto IsAccVgprReadFn = [](const MachineInstr &MI) {

    return MI.getOpcode() == AMDGPU::V_ACCVGPR_READ_B32_e64;

  };


  for (const MachineOperand &Op : MI->explicit_uses()) {

    if (!Op.isReg() || !TRI.isVGPR(MF.getRegInfo(), Op.getReg()))

      continue;


    Register Reg = Op.getReg();


    const int AccVgprReadLdStWaitStates = 2;

    const int VALUWriteAccVgprRdWrLdStDepVALUWaitStates = 1;

    const int MaxWaitStates = 2;


    int WaitStatesNeededForUse = AccVgprReadLdStWaitStates -

      getWaitStatesSinceDef(Reg, IsAccVgprReadFn, MaxWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


    if (WaitStatesNeeded == MaxWaitStates)

      return WaitStatesNeeded; // Early exit.


    auto IsVALUAccVgprRdWrCheckFn = [Reg, this](const MachineInstr &MI) {

      if (MI.getOpcode() != AMDGPU::V_ACCVGPR_READ_B32_e64 &&

          MI.getOpcode() != AMDGPU::V_ACCVGPR_WRITE_B32_e64)

        return false;

      auto IsVALUFn = [](const MachineInstr &MI) {

        return SIInstrInfo::isVALU(MI) && !SIInstrInfo::isMAI(MI);

      };

      return getWaitStatesSinceDef(Reg, IsVALUFn, 2 /*MaxWaitStates*/) <

             std::numeric_limits<int>::max();

    };


    WaitStatesNeededForUse = VALUWriteAccVgprRdWrLdStDepVALUWaitStates -

      getWaitStatesSince(IsVALUAccVgprRdWrCheckFn, MaxWaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }


  return WaitStatesNeeded;

}


static int GFX940_SMFMA_N_PassWriteVgprVALUWawWaitStates(int NumPasses) {

  // 2 pass -> 4

  // 4 pass -> 6

  // 8 pass -> 10

  // 16 pass -> 18

  return NumPasses + 2;

}


static int GFX940_XDL_N_PassWriteVgprVALUWawWaitStates(int NumPasses) {

  // 2 pass -> 5

  // 4 pass -> 7

  // 8 pass -> 11

  // 16 pass -> 19

  return NumPasses + 3;

}


static int GFX940_XDL_N_PassWriteVgprVALUMemExpReadWaitStates(int NumPasses) {

  // 2 pass -> 5

  // 4 pass -> 7

  // 8 pass -> 11

  // 16 pass -> 19

  return NumPasses + 3;

}


static int GFX940_SMFMA_N_PassWriteVgprVALUMemExpReadWaitStates(int NumPasses) {

  // 2 pass -> 4

  // 4 pass -> 6

  // 8 pass -> 10

  // 16 pass -> 18

  return NumPasses + 2;

}


int GCNHazardRecognizer::checkMAIVALUHazards(MachineInstr *MI) {

  if (!ST.hasGFX90AInsts())

    return 0;


  auto IsDGEMMFn = [](const MachineInstr &MI) -> bool {

    return isDGEMM(MI.getOpcode());

  };


  // This is checked in checkMAIHazards90A()

  if (SIInstrInfo::isMFMA(*MI))

    return 0;


  const MachineRegisterInfo &MRI = MF.getRegInfo();


  int WaitStatesNeeded = 0;


  bool IsMem = SIInstrInfo::isVMEM(*MI) ||

               SIInstrInfo::isFLAT(*MI) ||

               SIInstrInfo::isDS(*MI);

  bool IsMemOrExport = IsMem || SIInstrInfo::isEXP(*MI);

  bool IsVALU = SIInstrInfo::isVALU(*MI);


  const MachineInstr *MFMA = nullptr;

  unsigned Reg;

  auto IsMFMAWriteFn = [&Reg, &MFMA, this](const MachineInstr &MI) {

    if (!SIInstrInfo::isMFMA(MI) ||

        !TRI.regsOverlap(MI.getOperand(0).getReg(), Reg))

      return false;

    MFMA = &MI;

    return true;

  };


  const MachineInstr *DOT = nullptr;

  auto IsDotWriteFn = [&Reg, &DOT, this](const MachineInstr &MI) {

    if (!SIInstrInfo::isDOT(MI) ||

        !TRI.regsOverlap(MI.getOperand(0).getReg(), Reg))

      return false;

    DOT = &MI;

    return true;

  };


  bool DGEMMAfterVALUWrite = false;

  auto IsDGEMMHazard = [&DGEMMAfterVALUWrite, this](const MachineInstr &MI) {

    // Found DGEMM on reverse traversal to def.

    if (isDGEMM(MI.getOpcode()))

      DGEMMAfterVALUWrite = true;


    // Only hazard if register is defined by a VALU and a DGEMM is found after

    // after the def.

    if (!TII.isVALU(MI) || !DGEMMAfterVALUWrite)

      return false;


    return true;

  };


  int SrcCIdx = AMDGPU::getNamedOperandIdx(MI->getOpcode(),

                                           AMDGPU::OpName::src2);


  if (IsMemOrExport || IsVALU) {

    const int SMFMA4x4WriteVgprVALUMemExpReadWaitStates = 5;

    const int SMFMA16x16WriteVgprVALUMemExpReadWaitStates = 11;

    const int SMFMA32x32WriteVgprVALUMemExpReadWaitStates = 19;

    const int DMFMA4x4WriteVgprMemExpReadWaitStates = 9;

    const int DMFMA16x16WriteVgprMemExpReadWaitStates = 18;

    const int DMFMA4x4WriteVgprVALUReadWaitStates = 6;

    const int DMFMA16x16WriteVgprVALUReadWaitStates = 11;

    const int DotWriteSameDotReadSrcAB = 3;

    const int DotWriteDifferentVALURead = 3;

    const int DMFMABetweenVALUWriteVMEMRead = 2;

    const int MaxWaitStates = 19;


    for (const MachineOperand &Use : MI->explicit_uses()) {

      if (!Use.isReg())

        continue;

      Reg = Use.getReg();


      DOT = nullptr;

      int WaitStatesSinceDef = getWaitStatesSinceDef(Reg, IsDotWriteFn,

                                                     MaxWaitStates);

      if (DOT) {

        int NeedWaitStates = 0;

        if (DOT->getOpcode() == MI->getOpcode()) {

          if (&Use - &MI->getOperand(0) != SrcCIdx)

            NeedWaitStates = DotWriteSameDotReadSrcAB;

        } else {

          NeedWaitStates = DotWriteDifferentVALURead;

        }


        int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSinceDef;

        WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

      }


      // Workaround for HW data hazard bug observed only in GFX90A. When there

      // is a DGEMM instruction in-between a VALU and a VMEM instruction it

      // causes the SQ to incorrectly not insert two wait states between the two

      // instructions needed to avoid data hazard.

      if (IsMem && ST.hasGFX90AInsts() && !ST.hasGFX940Insts()) {

        DGEMMAfterVALUWrite = false;

        if (TRI.isVectorRegister(MRI, Reg)) {

          int WaitStatesNeededForUse =

                DMFMABetweenVALUWriteVMEMRead -

                getWaitStatesSinceDef(Reg, IsDGEMMHazard,

                                      DMFMABetweenVALUWriteVMEMRead);


          WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

        }

      }


      MFMA = nullptr;

      WaitStatesSinceDef =

          getWaitStatesSinceDef(Reg, IsMFMAWriteFn, MaxWaitStates);

      if (!MFMA)

        continue;


      unsigned HazardDefLatency = TSchedModel.computeInstrLatency(MFMA);

      int NumPasses = HazardDefLatency;

      int NeedWaitStates = MaxWaitStates;


      if (isDGEMM(MFMA->getOpcode())) {

        switch (HazardDefLatency) {

        case 4:

          NeedWaitStates = IsMemOrExport ? DMFMA4x4WriteVgprMemExpReadWaitStates

                                         : DMFMA4x4WriteVgprVALUReadWaitStates;

          break;

        case 8:

        case 16:

          NeedWaitStates = IsMemOrExport

                               ? DMFMA16x16WriteVgprMemExpReadWaitStates

                               : DMFMA16x16WriteVgprVALUReadWaitStates;

          break;

        default:

          llvm_unreachable("unexpected dgemm");

        }

      } else if (ST.hasGFX940Insts()) {

        NeedWaitStates =

            isXDL(ST, *MFMA)

                ? GFX940_XDL_N_PassWriteVgprVALUMemExpReadWaitStates(NumPasses)

                : GFX940_SMFMA_N_PassWriteVgprVALUMemExpReadWaitStates(

                      NumPasses);

      } else {

        switch (HazardDefLatency) {

        case 2:

          NeedWaitStates = SMFMA4x4WriteVgprVALUMemExpReadWaitStates;

          break;

        case 8:

          NeedWaitStates = SMFMA16x16WriteVgprVALUMemExpReadWaitStates;

          break;

        case 16:

          NeedWaitStates = SMFMA32x32WriteVgprVALUMemExpReadWaitStates;

          break;

        default:

          llvm_unreachable("unexpected number of passes for mfma");

        }

      }


      int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSinceDef;

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


      if (WaitStatesNeeded == MaxWaitStates)

        break;

    }

  }


  unsigned Opc = MI->getOpcode();

  const int DMFMAToFMA64WaitStates = 2;

  if ((Opc == AMDGPU::V_FMA_F64_e64 ||

       Opc == AMDGPU::V_FMAC_F64_e32 || Opc == AMDGPU::V_FMAC_F64_e64 ||

       Opc == AMDGPU::V_FMAC_F64_dpp) &&

      WaitStatesNeeded < DMFMAToFMA64WaitStates) {

    int WaitStatesNeededForUse = DMFMAToFMA64WaitStates -

      getWaitStatesSince(IsDGEMMFn, DMFMAToFMA64WaitStates);

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }


  if (!IsVALU && !IsMemOrExport)

    return WaitStatesNeeded;


  for (const MachineOperand &Def : MI->defs()) {

    const int SMFMA4x4WriteVgprVALUWawWaitStates = 5;

    const int SMFMA16x16WriteVgprVALUWawWaitStates = 11;

    const int SMFMA32x32WriteVgprVALUWawWaitStates = 19;

    const int SMFMA4x4ReadVgprVALUWarWaitStates = 1;

    const int GFX940_XDL4PassReadVgprVALUWarWaitStates = 3;

    const int SMFMA16x16ReadVgprVALUWarWaitStates = 7;

    const int SMFMA32x32ReadVgprVALUWarWaitStates = 15;

    const int DMFMA4x4WriteVgprVALUWriteWaitStates = 6;

    const int DMFMA16x16WriteVgprVALUWriteWaitStates = 11;

    const int DotWriteDifferentVALUWrite = 3;

    const int MaxWaitStates = 19;

    const int MaxWarWaitStates = 15;


    Reg = Def.getReg();


    DOT = nullptr;

    int WaitStatesSinceDef = getWaitStatesSinceDef(Reg, IsDotWriteFn,

                                                   MaxWaitStates);

    if (DOT && DOT->getOpcode() != MI->getOpcode())

      WaitStatesNeeded = std::max(WaitStatesNeeded, DotWriteDifferentVALUWrite -

                                                    WaitStatesSinceDef);


    MFMA = nullptr;

    WaitStatesSinceDef =

        getWaitStatesSinceDef(Reg, IsMFMAWriteFn, MaxWaitStates);

    if (MFMA) {

      int NeedWaitStates = MaxWaitStates;

      int NumPasses = TSchedModel.computeInstrLatency(MFMA);


      if (isDGEMM(MFMA->getOpcode())) {

        switch (NumPasses) {

        case 4:

          NeedWaitStates = DMFMA4x4WriteVgprVALUWriteWaitStates;

          break;

        case 8:

        case 16:

          NeedWaitStates = DMFMA16x16WriteVgprVALUWriteWaitStates;

          break;

        default:

          llvm_unreachable("unexpected number of cycles for dgemm");

        }

      } else if (ST.hasGFX940Insts()) {

        NeedWaitStates =

            isXDL(ST, *MFMA)

                ? GFX940_XDL_N_PassWriteVgprVALUWawWaitStates(NumPasses)

                : GFX940_SMFMA_N_PassWriteVgprVALUWawWaitStates(NumPasses);

      } else {

        switch (NumPasses) {

        case 2:

          NeedWaitStates = SMFMA4x4WriteVgprVALUWawWaitStates;

          break;

        case 8:

          NeedWaitStates = SMFMA16x16WriteVgprVALUWawWaitStates;

          break;

        case 16:

          NeedWaitStates = SMFMA32x32WriteVgprVALUWawWaitStates;

          break;

        default:

          llvm_unreachable("Unexpected number of passes for mfma");

        }

      }


      int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSinceDef;

      WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);


      if (WaitStatesNeeded == MaxWaitStates)

        break;

    }


    auto IsSMFMAReadAsCFn = [&Reg, &MFMA, this](const MachineInstr &MI) {

      if (!SIInstrInfo::isMFMA(MI) || isDGEMM(MI.getOpcode()) ||

          !MI.readsRegister(Reg, &TRI))

        return false;


      if (ST.hasGFX940Insts() && !isXDL(ST, MI))

        return false;


      const MachineOperand *SrcC =

          TII.getNamedOperand(MI, AMDGPU::OpName::src2);

      assert(SrcC);

      if (!SrcC->isReg() || !TRI.regsOverlap(SrcC->getReg(), Reg))

        return false;


      MFMA = &MI;

      return true;

    };


    MFMA = nullptr;

    int WaitStatesSinceUse = getWaitStatesSince(IsSMFMAReadAsCFn,

                                                MaxWarWaitStates);

    if (!MFMA)

      continue;


    unsigned HazardDefLatency = TSchedModel.computeInstrLatency(MFMA);

    int NeedWaitStates = MaxWaitStates;

    switch (HazardDefLatency) {

    case 2:  NeedWaitStates = SMFMA4x4ReadVgprVALUWarWaitStates;

             break;

    case 4:  assert(ST.hasGFX940Insts());

             NeedWaitStates = GFX940_XDL4PassReadVgprVALUWarWaitStates;

             break;

    case 8:  NeedWaitStates = SMFMA16x16ReadVgprVALUWarWaitStates;

             break;

    case 16: [[fallthrough]];

    default: NeedWaitStates = SMFMA32x32ReadVgprVALUWarWaitStates;

             break;

    }


    int WaitStatesNeededForUse = NeedWaitStates - WaitStatesSinceUse;

    WaitStatesNeeded = std::max(WaitStatesNeeded, WaitStatesNeededForUse);

  }


  return WaitStatesNeeded;

}


bool GCNHazardRecognizer::ShouldPreferAnother(SUnit *SU) {

  if (!SU->isInstr())

    return false;


  const MachineInstr *MAI = nullptr;


  auto IsMFMAFn = [&MAI](const MachineInstr &MI) {

    MAI = nullptr;

    if (SIInstrInfo::isMFMA(MI))

      MAI = &MI;

    return MAI != nullptr;

  };


  MachineInstr *MI = SU->getInstr();

  if (IsMFMAFn(*MI)) {

    int W = getWaitStatesSince(IsMFMAFn, 16);

    if (MAI)

      return W < (int)TSchedModel.computeInstrLatency(MAI);

  }


  return false;

}


bool GCNHazardRecognizer::fixVALUMaskWriteHazard(MachineInstr *MI) {

  if (!ST.hasVALUMaskWriteHazard())

    return false;

  assert(!ST.hasExtendedWaitCounts());


  if (!ST.isWave64() || !SIInstrInfo::isSALU(*MI))

    return false;


  // The hazard sequence is three instructions:

  //   1. VALU reads SGPR as mask

  //   2. SALU writes SGPR

  //   3. SALU reads SGPR

  // The hazard can expire if the distance between 2 and 3 is sufficient.

  // In practice this happens <10% of the time, hence this always assumes

  // the hazard exists if 1 and 2 are present to avoid searching.


  const MachineOperand *SDSTOp = TII.getNamedOperand(*MI, AMDGPU::OpName::sdst);

  if (!SDSTOp || !SDSTOp->isReg())

    return false;


  const Register HazardReg = SDSTOp->getReg();

  if (HazardReg == AMDGPU::EXEC ||

      HazardReg == AMDGPU::EXEC_LO ||

      HazardReg == AMDGPU::EXEC_HI ||

      HazardReg == AMDGPU::M0)

    return false;


  auto IsHazardFn = [HazardReg, this](const MachineInstr &I) {

    switch (I.getOpcode()) {

    case AMDGPU::V_ADDC_U32_e32:

    case AMDGPU::V_ADDC_U32_dpp:

    case AMDGPU::V_CNDMASK_B16_e32:

    case AMDGPU::V_CNDMASK_B16_dpp:

    case AMDGPU::V_CNDMASK_B32_e32:

    case AMDGPU::V_CNDMASK_B32_dpp:

    case AMDGPU::V_DIV_FMAS_F32_e64:

    case AMDGPU::V_DIV_FMAS_F64_e64:

    case AMDGPU::V_SUBB_U32_e32:

    case AMDGPU::V_SUBB_U32_dpp:

    case AMDGPU::V_SUBBREV_U32_e32:

    case AMDGPU::V_SUBBREV_U32_dpp:

      // These implicitly read VCC as mask source.

      return HazardReg == AMDGPU::VCC ||

             HazardReg == AMDGPU::VCC_LO ||

             HazardReg == AMDGPU::VCC_HI;

    case AMDGPU::V_ADDC_U32_e64:

    case AMDGPU::V_ADDC_U32_e64_dpp:

    case AMDGPU::V_CNDMASK_B16_e64:

    case AMDGPU::V_CNDMASK_B16_e64_dpp:

    case AMDGPU::V_CNDMASK_B32_e64:

    case AMDGPU::V_CNDMASK_B32_e64_dpp:

    case AMDGPU::V_SUBB_U32_e64:

    case AMDGPU::V_SUBB_U32_e64_dpp:

    case AMDGPU::V_SUBBREV_U32_e64:

    case AMDGPU::V_SUBBREV_U32_e64_dpp: {

      // Only check mask register overlaps.

      const MachineOperand *SSRCOp = TII.getNamedOperand(I, AMDGPU::OpName::src2);

      assert(SSRCOp);

      return TRI.regsOverlap(SSRCOp->getReg(), HazardReg);

    }

    default:

      return false;

    }

  };


  const MachineRegisterInfo &MRI = MF.getRegInfo();

  auto IsExpiredFn = [&MRI, this](const MachineInstr &I, int) {

    // s_waitcnt_depctr sa_sdst(0) mitigates hazard.

    if (I.getOpcode() == AMDGPU::S_WAITCNT_DEPCTR &&

        AMDGPU::DepCtr::decodeFieldSaSdst(I.getOperand(0).getImm()) == 0)

      return true;


    // VALU access to any SGPR or literal constant other than HazardReg

    // mitigates hazard. No need to check HazardReg here as this will

    // only be called when !IsHazardFn.

    if (!SIInstrInfo::isVALU(I))

      return false;

    for (int OpNo = 0, End = I.getNumOperands(); OpNo < End; ++OpNo) {

      const MachineOperand &Op = I.getOperand(OpNo);

      if (Op.isReg()) {

        Register OpReg = Op.getReg();

        // Only consider uses

        if (!Op.isUse())

          continue;

        // Ignore EXEC

        if (OpReg == AMDGPU::EXEC ||

            OpReg == AMDGPU::EXEC_LO ||

            OpReg == AMDGPU::EXEC_HI)

          continue;

        // Ignore all implicit uses except VCC

        if (Op.isImplicit()) {

          if (OpReg == AMDGPU::VCC ||

              OpReg == AMDGPU::VCC_LO ||

              OpReg == AMDGPU::VCC_HI)

            return true;

          continue;

        }

        if (TRI.isSGPRReg(MRI, OpReg))

          return true;

      } else {

        const MCInstrDesc &InstDesc = I.getDesc();

        const MCOperandInfo &OpInfo = InstDesc.operands()[OpNo];

        if (!TII.isInlineConstant(Op, OpInfo))

          return true;

      }

    }

    return false;

  };


  // Check for hazard

  if (::getWaitStatesSince(IsHazardFn, MI, IsExpiredFn) ==

      std::numeric_limits<int>::max())

    return false;


  auto NextMI = std::next(MI->getIterator());


  // Add s_waitcnt_depctr sa_sdst(0) after SALU write.

  BuildMI(*MI->getParent(), NextMI, MI->getDebugLoc(),

          TII.get(AMDGPU::S_WAITCNT_DEPCTR))

      .addImm(AMDGPU::DepCtr::encodeFieldSaSdst(0));


  // SALU write may be s_getpc in a bundle.

  if (MI->getOpcode() == AMDGPU::S_GETPC_B64) {

    // Update offsets of any references in the bundle.

    while (NextMI != MI->getParent()->end() &&

           NextMI->isBundledWithPred()) {

      for (auto &Operand : NextMI->operands()) {

        if (Operand.isGlobal())

          Operand.setOffset(Operand.getOffset() + 4);

      }

      NextMI++;

    }

  }


  return true;

}


static bool ensureEntrySetPrio(MachineFunction *MF, int Priority,

                               const SIInstrInfo &TII) {

  MachineBasicBlock &EntryMBB = MF->front();

  if (EntryMBB.begin() != EntryMBB.end()) {

    auto &EntryMI = *EntryMBB.begin();

    if (EntryMI.getOpcode() == AMDGPU::S_SETPRIO &&

        EntryMI.getOperand(0).getImm() >= Priority)

      return false;

  }


  BuildMI(EntryMBB, EntryMBB.begin(), DebugLoc(), TII.get(AMDGPU::S_SETPRIO))

      .addImm(Priority);

  return true;

}


bool GCNHazardRecognizer::fixRequiredExportPriority(MachineInstr *MI) {

  if (!ST.hasRequiredExportPriority())

    return false;


  // Assume the following shader types will never have exports,

  // and avoid adding or adjusting S_SETPRIO.

  MachineBasicBlock *MBB = MI->getParent();

  MachineFunction *MF = MBB->getParent();

  auto CC = MF->getFunction().getCallingConv();

  switch (CC) {

  case CallingConv::AMDGPU_CS:

  case CallingConv::AMDGPU_CS_Chain:

  case CallingConv::AMDGPU_CS_ChainPreserve:

  case CallingConv::AMDGPU_KERNEL:

    return false;

  default:

    break;

  }


  const int MaxPriority = 3;

  const int NormalPriority = 2;

  const int PostExportPriority = 0;


  auto It = MI->getIterator();

  switch (MI->getOpcode()) {

  case AMDGPU::S_ENDPGM:

  case AMDGPU::S_ENDPGM_SAVED:

  case AMDGPU::S_ENDPGM_ORDERED_PS_DONE:

  case AMDGPU::SI_RETURN_TO_EPILOG:

    // Ensure shader with calls raises priority at entry.

    // This ensures correct priority if exports exist in callee.

    if (MF->getFrameInfo().hasCalls())

      return ensureEntrySetPrio(MF, NormalPriority, TII);

    return false;

  case AMDGPU::S_SETPRIO: {

    // Raise minimum priority unless in workaround.

    auto &PrioOp = MI->getOperand(0);

    int Prio = PrioOp.getImm();

    bool InWA = (Prio == PostExportPriority) &&

                (It != MBB->begin() && TII.isEXP(*std::prev(It)));

    if (InWA || Prio >= NormalPriority)

      return false;

    PrioOp.setImm(std::min(Prio + NormalPriority, MaxPriority));

    return true;

  }

  default:

    if (!TII.isEXP(*MI))

      return false;

    break;

  }


  // Check entry priority at each export (as there will only be a few).

  // Note: amdgpu_gfx can only be a callee, so defer to caller setprio.

  bool Changed = false;

  if (CC != CallingConv::AMDGPU_Gfx)

    Changed = ensureEntrySetPrio(MF, NormalPriority, TII);


  auto NextMI = std::next(It);

  bool EndOfShader = false;

  if (NextMI != MBB->end()) {

    // Only need WA at end of sequence of exports.

    if (TII.isEXP(*NextMI))

      return Changed;

    // Assume appropriate S_SETPRIO after export means WA already applied.

    if (NextMI->getOpcode() == AMDGPU::S_SETPRIO &&

        NextMI->getOperand(0).getImm() == PostExportPriority)

      return Changed;

    EndOfShader = NextMI->getOpcode() == AMDGPU::S_ENDPGM;

  }


  const DebugLoc &DL = MI->getDebugLoc();


  // Lower priority.

  BuildMI(*MBB, NextMI, DL, TII.get(AMDGPU::S_SETPRIO))

      .addImm(PostExportPriority);


  if (!EndOfShader) {

    // Wait for exports to complete.

    BuildMI(*MBB, NextMI, DL, TII.get(AMDGPU::S_WAITCNT_EXPCNT))

        .addReg(AMDGPU::SGPR_NULL)

        .addImm(0);

  }


  BuildMI(*MBB, NextMI, DL, TII.get(AMDGPU::S_NOP)).addImm(0);

  BuildMI(*MBB, NextMI, DL, TII.get(AMDGPU::S_NOP)).addImm(0);


  if (!EndOfShader) {

    // Return to normal (higher) priority.

    BuildMI(*MBB, NextMI, DL, TII.get(AMDGPU::S_SETPRIO))

        .addImm(NormalPriority);

  }


  return true;

}

MRI
unsigned const MachineRegisterInfo * MRI
Definition: AArch64AdvSIMDScalarPass.cpp:105

AMDGPUMCTargetDesc.h
Provides AMDGPU specific target descriptions.

MBB
MachineBasicBlock & MBB
Definition: ARMSLSHardening.cpp:71

DL
MachineBasicBlock MachineBasicBlock::iterator DebugLoc DL
Definition: ARMSLSHardening.cpp:73

Info
Analysis containing CSE Info
Definition: CSEInfo.cpp:27

End
bool End
Definition: ELF_riscv.cpp:480

MFMAPaddingRatio
static cl::opt< unsigned, false, MFMAPaddingRatioParser > MFMAPaddingRatio("amdgpu-mfma-padding-ratio", cl::init(0), cl::Hidden, cl::desc("Fill a percentage of the latency between " "neighboring MFMA with s_nops."))

shouldRunLdsBranchVmemWARHazardFixup
static bool shouldRunLdsBranchVmemWARHazardFixup(const MachineFunction &MF, const GCNSubtarget &ST)
Definition: GCNHazardRecognizer.cpp:1324

isSGetReg
static bool isSGetReg(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:84

breaksSMEMSoftClause
static bool breaksSMEMSoftClause(MachineInstr *MI)
Definition: GCNHazardRecognizer.cpp:613

isXDL
static bool isXDL(const GCNSubtarget &ST, const MachineInstr &MI)
Definition: GCNHazardRecognizer.cpp:123

isLdsDma
static bool isLdsDma(const MachineInstr &MI)
Definition: GCNHazardRecognizer.cpp:173

isRFE
static bool isRFE(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:103

isRWLane
static bool isRWLane(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:99

isSMovRel
static bool isSMovRel(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:107

isStoreCountWaitZero
static bool isStoreCountWaitZero(const MachineInstr &I)
Definition: GCNHazardRecognizer.cpp:1345

breaksVMEMSoftClause
static bool breaksVMEMSoftClause(MachineInstr *MI)
Definition: GCNHazardRecognizer.cpp:617

isSSetReg
static bool isSSetReg(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:88

hasHazard
static bool hasHazard(StateT State, function_ref< HazardFnResult(StateT &, const MachineInstr &)> IsHazard, function_ref< void(StateT &, const MachineInstr &)> UpdateState, const MachineBasicBlock *MBB, MachineBasicBlock::const_reverse_instr_iterator I, DenseSet< const MachineBasicBlock * > &Visited)
Definition: GCNHazardRecognizer.cpp:458

addRegUnits
static void addRegUnits(const SIRegisterInfo &TRI, BitVector &BV, MCRegister Reg)
Definition: GCNHazardRecognizer.cpp:594

getHWReg
static unsigned getHWReg(const SIInstrInfo *TII, const MachineInstr &RegInstr)
Definition: GCNHazardRecognizer.cpp:178

isDivFMas
static bool isDivFMas(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:80

GFX940_XDL_N_PassWritesVGPROverlappedSrcABWaitStates
static int GFX940_XDL_N_PassWritesVGPROverlappedSrcABWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2169

HazardFnResult
enum { HazardFound, HazardExpired, NoHazardFound } HazardFnResult
Definition: GCNHazardRecognizer.cpp:450

GFX940_XDL_N_PassWriteVgprVALUWawWaitStates
static int GFX940_XDL_N_PassWriteVgprVALUWawWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2424

GFX940_XDL_N_PassWritesVGPROverlappedSMFMASrcCWaitStates
static int GFX940_XDL_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2143

GFX940_SMFMA_N_PassWritesVGPROverlappedSrcABWaitStates
static int GFX940_SMFMA_N_PassWritesVGPROverlappedSrcABWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2161

isDGEMM
static bool isDGEMM(unsigned Opcode)
Definition: GCNHazardRecognizer.cpp:119

getWaitStatesSince
static int getWaitStatesSince(GCNHazardRecognizer::IsHazardFn IsHazard, const MachineBasicBlock *MBB, MachineBasicBlock::const_reverse_instr_iterator I, int WaitStates, IsExpiredFn IsExpired, DenseSet< const MachineBasicBlock * > &Visited, GetNumWaitStatesFn GetNumWaitStates=SIInstrInfo::getNumWaitStates)
Definition: GCNHazardRecognizer.cpp:500

GFX940_SMFMA_N_PassWriteVgprVALUMemExpReadWaitStates
static int GFX940_SMFMA_N_PassWriteVgprVALUMemExpReadWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2440

GFX940_SMFMA_N_PassWritesVGPROverlappedSMFMASrcCWaitStates
static int GFX940_SMFMA_N_PassWritesVGPROverlappedSMFMASrcCWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2152

ensureEntrySetPrio
static bool ensureEntrySetPrio(MachineFunction *MF, int Priority, const SIInstrInfo &TII)
Definition: GCNHazardRecognizer.cpp:2901

addRegsToSet
static void addRegsToSet(const SIRegisterInfo &TRI, iterator_range< MachineInstr::const_mop_iterator > Ops, BitVector &DefSet, BitVector &UseSet)
Definition: GCNHazardRecognizer.cpp:600

insertNoopsInBundle
static void insertNoopsInBundle(MachineInstr *MI, const SIInstrInfo &TII, unsigned Quantity)
Definition: GCNHazardRecognizer.cpp:263

isSendMsgTraceDataOrGDS
static bool isSendMsgTraceDataOrGDS(const SIInstrInfo &TII, const MachineInstr &MI)
Definition: GCNHazardRecognizer.cpp:138

isPermlane
static bool isPermlane(const MachineInstr &MI)
Definition: GCNHazardRecognizer.cpp:164

GFX940_SMFMA_N_PassWriteVgprVALUWawWaitStates
static int GFX940_SMFMA_N_PassWriteVgprVALUWawWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2416

GFX940_XDL_N_PassWriteVgprVALUMemExpReadWaitStates
static int GFX940_XDL_N_PassWriteVgprVALUMemExpReadWaitStates(int NumPasses)
Definition: GCNHazardRecognizer.cpp:2432

GCNHazardRecognizer.h

GCNSubtarget.h
AMD GCN specific subclass of TargetSubtarget.

UseReg
static Register UseReg(const MachineOperand &MO)
Definition: HexagonCopyToCombine.cpp:252

TII
const HexagonInstrInfo * TII
Definition: HexagonCopyToCombine.cpp:125

MI
IRTranslator LLVM IR MI
Definition: IRTranslator.cpp:113

I
#define I(x, y, z)
Definition: MD5.cpp:58

MachineFrameInfo.h

MachineFunction.h

TRI
unsigned const TargetRegisterInfo * TRI
Definition: MachineSink.cpp:1928

if
if(VerifyEach)
Definition: PassBuilderBindings.cpp:72

CC
auto CC
Definition: RISCVRedundantCopyElimination.cpp:79

assert
assert(ImpDefSCC.getReg()==AMDGPU::SCC &&ImpDefSCC.isDef())

SIMachineFunctionInfo.h

ScheduleDAG.h

TargetParser.h

IV
static const uint32_t IV[8]
Definition: blake3_impl.h:78

bool

llvm::BitVector
Definition: BitVector.h:82

llvm::BitVector::anyCommon
bool anyCommon(const BitVector &RHS) const
Test if any common bits are set.
Definition: BitVector.h:489

llvm::BitVector::set
BitVector & set()
Definition: BitVector.h:351

llvm::BitVector::none
bool none() const
none - Returns true if none of the bits are set.
Definition: BitVector.h:188

llvm::DWARFExpression::Operation
This class represents an Operation in the Expression.
Definition: DWARFExpression.h:32

llvm::DebugLoc
A debug info location.
Definition: DebugLoc.h:33

llvm::DenseSet
Implements a dense probed hash-table based set.
Definition: DenseSet.h:271

llvm::Function::getCallingConv
CallingConv::ID getCallingConv() const
getCallingConv()/setCallingConv(CC) - These method get and set the calling convention of this functio...
Definition: Function.h:274

llvm::GCNHazardRecognizer::EmitNoop
void EmitNoop() override
EmitNoop - This callback is invoked when a noop was added to the instruction stream.
Definition: GCNHazardRecognizer.cpp:400

llvm::GCNHazardRecognizer::Reset
void Reset() override
Reset - This callback is invoked when a new block of instructions is about to be schedule.
Definition: GCNHazardRecognizer.cpp:68

llvm::GCNHazardRecognizer::PreEmitNoops
unsigned PreEmitNoops(MachineInstr *) override
This overload will be used when the hazard recognizer is being used by a non-scheduling pass,...
Definition: GCNHazardRecognizer.cpp:321

llvm::GCNHazardRecognizer::EmitInstruction
void EmitInstruction(SUnit *SU) override
EmitInstruction - This callback is invoked when an instruction is emitted, to advance the hazard stat...
Definition: GCNHazardRecognizer.cpp:72

llvm::GCNHazardRecognizer::IsHazardFn
function_ref< bool(const MachineInstr &)> IsHazardFn
Definition: GCNHazardRecognizer.h:34

llvm::GCNHazardRecognizer::AdvanceCycle
void AdvanceCycle() override
AdvanceCycle - This callback is invoked whenever the next top-down instruction to be scheduled cannot...
Definition: GCNHazardRecognizer.cpp:404

llvm::GCNHazardRecognizer::PreEmitNoopsCommon
unsigned PreEmitNoopsCommon(MachineInstr *)
Definition: GCNHazardRecognizer.cpp:330

llvm::GCNHazardRecognizer::ShouldPreferAnother
bool ShouldPreferAnother(SUnit *SU) override
ShouldPreferAnother - This callback may be invoked if getHazardType returns NoHazard.
Definition: GCNHazardRecognizer.cpp:2741

llvm::GCNHazardRecognizer::getHazardType
HazardType getHazardType(SUnit *SU, int Stalls) override
getHazardType - Return the hazard type of emitting this node.
Definition: GCNHazardRecognizer.cpp:185

llvm::GCNHazardRecognizer::GCNHazardRecognizer
GCNHazardRecognizer(const MachineFunction &MF)
Definition: GCNHazardRecognizer.cpp:54

llvm::GCNHazardRecognizer::RecedeCycle
void RecedeCycle() override
RecedeCycle - This callback is invoked whenever the next bottom-up instruction to be scheduled cannot...
Definition: GCNHazardRecognizer.cpp:442

llvm::GCNSubtarget
Definition: GCNSubtarget.h:35

llvm::GCNSubtarget::hasShift64HighRegBug
bool hasShift64HighRegBug() const
Definition: GCNSubtarget.h:1197

llvm::GCNSubtarget::hasFPAtomicToDenormModeHazard
bool hasFPAtomicToDenormModeHazard() const
Definition: GCNSubtarget.h:1227

llvm::GCNSubtarget::hasLdsBranchVmemWARHazard
bool hasLdsBranchVmemWARHazard() const
Definition: GCNSubtarget.h:1191

llvm::GCNSubtarget::hasGFX90AInsts
bool hasGFX90AInsts() const
Definition: GCNSubtarget.h:1225

llvm::GCNSubtarget::hasDstSelForwardingHazard
bool hasDstSelForwardingHazard() const
Definition: GCNSubtarget.h:1207

llvm::GCNSubtarget::hasMAIInsts
bool hasMAIInsts() const
Definition: GCNSubtarget.h:815

llvm::GCNSubtarget::getInstrInfo
const SIInstrInfo * getInstrInfo() const override
Definition: GCNSubtarget.h:266

llvm::GCNSubtarget::hasVALUMaskWriteHazard
bool hasVALUMaskWriteHazard() const
Definition: GCNSubtarget.h:1247

llvm::GCNSubtarget::needsAlignedVGPRs
bool needsAlignedVGPRs() const
Return if operations acting on VGPR tuples require even alignment.
Definition: GCNSubtarget.h:1250

llvm::GCNSubtarget::hasVcmpxExecWARHazard
bool hasVcmpxExecWARHazard() const
Definition: GCNSubtarget.h:1187

llvm::GCNSubtarget::hasReadM0MovRelInterpHazard
bool hasReadM0MovRelInterpHazard() const
Definition: GCNSubtarget.h:1150

llvm::GCNSubtarget::getRegisterInfo
const SIRegisterInfo * getRegisterInfo() const override
Definition: GCNSubtarget.h:278

llvm::GCNSubtarget::hasRequiredExportPriority
bool hasRequiredExportPriority() const
Definition: GCNSubtarget.h:1286

llvm::GCNSubtarget::hasLdsWaitVMSRC
bool hasLdsWaitVMSRC() const
Definition: GCNSubtarget.h:1235

llvm::GCNSubtarget::hasExtendedWaitCounts
bool hasExtendedWaitCounts() const
Definition: GCNSubtarget.h:1290

llvm::GCNSubtarget::hasVcmpxPermlaneHazard
bool hasVcmpxPermlaneHazard() const
Definition: GCNSubtarget.h:1167

llvm::GCNSubtarget::has12DWordStoreHazard
bool has12DWordStoreHazard() const
Definition: GCNSubtarget.h:1141

llvm::GCNSubtarget::hasVALUPartialForwardingHazard
bool hasVALUPartialForwardingHazard() const
Definition: GCNSubtarget.h:1237

llvm::GCNSubtarget::hasNoDataDepHazard
bool hasNoDataDepHazard() const
Definition: GCNSubtarget.h:928

llvm::GCNSubtarget::getSetRegWaitStates
unsigned getSetRegWaitStates() const
Number of hazard wait states for s_setreg_b32/s_setreg_imm32_b32.
Definition: GCNSubtarget.h:509

llvm::GCNSubtarget::hasTransForwardingHazard
bool hasTransForwardingHazard() const
Definition: GCNSubtarget.h:1203

llvm::GCNSubtarget::hasGFX940Insts
bool hasGFX940Insts() const
Definition: GCNSubtarget.h:1276

llvm::GCNSubtarget::hasReadM0LdsDmaHazard
bool hasReadM0LdsDmaHazard() const
Definition: GCNSubtarget.h:1159

llvm::GCNSubtarget::hasSMEMtoVectorWriteHazard
bool hasSMEMtoVectorWriteHazard() const
Definition: GCNSubtarget.h:1175

llvm::GCNSubtarget::hasVMEMtoScalarWriteHazard
bool hasVMEMtoScalarWriteHazard() const
Definition: GCNSubtarget.h:1171

llvm::GCNSubtarget::hasNSAtoVMEMBug
bool hasNSAtoVMEMBug() const
Definition: GCNSubtarget.h:1217

llvm::GCNSubtarget::hasVDecCoExecHazard
bool hasVDecCoExecHazard() const
Definition: GCNSubtarget.h:1213

llvm::GCNSubtarget::hasReadM0SendMsgHazard
bool hasReadM0SendMsgHazard() const
Definition: GCNSubtarget.h:1154

llvm::GCNSubtarget::hasReadM0LdsDirectHazard
bool hasReadM0LdsDirectHazard() const
Definition: GCNSubtarget.h:1163

llvm::GCNSubtarget::isXNACKEnabled
bool isXNACKEnabled() const
Definition: GCNSubtarget.h:605

llvm::GCNSubtarget::hasSMRDReadVALUDefHazard
bool hasSMRDReadVALUDefHazard() const
A read of an SGPR by SMRD instruction requires 4 wait states when the SGPR was written by a VALU inst...
Definition: GCNSubtarget.h:494

llvm::GCNSubtarget::hasRFEHazards
bool hasRFEHazards() const
Definition: GCNSubtarget.h:504

llvm::GCNSubtarget::hasVMEMReadSGPRVALUDefHazard
bool hasVMEMReadSGPRVALUDefHazard() const
A read of an SGPR by a VMEM instruction requires 5 wait states when the SGPR was written by a VALU In...
Definition: GCNSubtarget.h:500

llvm::GCNSubtarget::isWave64
bool isWave64() const
Definition: GCNSubtarget.h:1523

llvm::GCNSubtarget::hasVALUTransUseHazard
bool hasVALUTransUseHazard() const
Definition: GCNSubtarget.h:1241

llvm::GCNSubtarget::hasLdsDirect
bool hasLdsDirect() const
Definition: GCNSubtarget.h:1233

llvm::InlineAsm::MIOp_FirstOperand
@ MIOp_FirstOperand
Definition: InlineAsm.h:211

llvm::MCInstrDesc
Describe properties that are true of each instruction in the target description file.
Definition: MCInstrDesc.h:198

llvm::MCInstrDesc::operands
ArrayRef< MCOperandInfo > operands() const
Definition: MCInstrDesc.h:239

llvm::MCOperandInfo
This holds information about one operand of a machine instruction, indicating the register class for ...
Definition: MCInstrDesc.h:85

llvm::MCRegister
Wrapper class representing physical registers. Should be passed by value.
Definition: MCRegister.h:33

llvm::MachineBasicBlock
Definition: MachineBasicBlock.h:124

llvm::MachineBasicBlock::const_reverse_instr_iterator
Instructions::const_reverse_iterator const_reverse_instr_iterator
Definition: MachineBasicBlock.h:316

llvm::MachineBasicBlock::begin
iterator begin()
Definition: MachineBasicBlock.h:354

llvm::MachineBasicBlock::instr_rend
reverse_instr_iterator instr_rend()
Definition: MachineBasicBlock.h:344

llvm::MachineBasicBlock::instr_iterator
Instructions::iterator instr_iterator
Definition: MachineBasicBlock.h:313

llvm::MachineBasicBlock::instr_end
instr_iterator instr_end()
Definition: MachineBasicBlock.h:340

llvm::MachineBasicBlock::end
iterator end()
Definition: MachineBasicBlock.h:356

llvm::MachineBasicBlock::getParent
const MachineFunction * getParent() const
Return the MachineFunction containing this basic block.
Definition: MachineBasicBlock.h:310

llvm::MachineBasicBlock::predecessors
iterator_range< pred_iterator > predecessors()
Definition: MachineBasicBlock.h:435

llvm::MachineFrameInfo::hasCalls
bool hasCalls() const
Return true if the current function has any function calls.
Definition: MachineFrameInfo.h:621

llvm::MachineFunction
Definition: MachineFunction.h:258

llvm::MachineFunction::getFrameInfo
MachineFrameInfo & getFrameInfo()
getFrameInfo - Return the frame info object for the current function.
Definition: MachineFunction.h:733

llvm::MachineFunction::getRegInfo
MachineRegisterInfo & getRegInfo()
getRegInfo - Return information about the registers currently in use.
Definition: MachineFunction.h:727

llvm::MachineFunction::getFunction
Function & getFunction()
Return the LLVM function that this machine code represents.
Definition: MachineFunction.h:683

llvm::MachineFunction::getInfo
Ty * getInfo()
getInfo - Keep track of various per-function pieces of information for backends that would like to do...
Definition: MachineFunction.h:815

llvm::MachineFunction::front
const MachineBasicBlock & front() const
Definition: MachineFunction.h:933

llvm::MachineInstrBuilder::addImm
const MachineInstrBuilder & addImm(int64_t Val) const
Add a new immediate operand.
Definition: MachineInstrBuilder.h:133

llvm::MachineInstrBuilder::addReg
const MachineInstrBuilder & addReg(Register RegNo, unsigned flags=0, unsigned SubReg=0) const
Add a new virtual register operand.
Definition: MachineInstrBuilder.h:99

llvm::MachineInstrBuilder::addDef
const MachineInstrBuilder & addDef(Register RegNo, unsigned Flags=0, unsigned SubReg=0) const
Add a virtual register definition operand.
Definition: MachineInstrBuilder.h:118

llvm::MachineInstrBundleIterator< MachineInstr >

llvm::MachineInstr
Representation of each machine instruction.
Definition: MachineInstr.h:69

llvm::MachineInstr::getOpcode
unsigned getOpcode() const
Returns the opcode of this MachineInstr.
Definition: MachineInstr.h:569

llvm::MachineInstr::getParent
const MachineBasicBlock * getParent() const
Definition: MachineInstr.h:346

llvm::MachineInstr::isBundle
bool isBundle() const
Definition: MachineInstr.h:1422

llvm::MachineInstr::mayStore
bool mayStore(QueryType Type=AnyInBundle) const
Return true if this instruction could possibly modify memory.
Definition: MachineInstr.h:1149

llvm::MachineOperand
MachineOperand class - Representation of each machine instruction operand.
Definition: MachineOperand.h:48

llvm::MachineOperand::setImm
void setImm(int64_t immVal)
Definition: MachineOperand.h:684

llvm::MachineOperand::getImm
int64_t getImm() const
Definition: MachineOperand.h:556

llvm::MachineOperand::isReg
bool isReg() const
isReg - Tests if this is a MO_Register operand.
Definition: MachineOperand.h:329

llvm::MachineOperand::setReg
void setReg(Register Reg)
Change the register this operand corresponds to.
Definition: MachineOperand.cpp:61

llvm::MachineOperand::setIsKill
void setIsKill(bool Val=true)
Definition: MachineOperand.h:519

llvm::MachineOperand::setIsUndef
void setIsUndef(bool Val=true)
Definition: MachineOperand.h:530

llvm::MachineOperand::getReg
Register getReg() const
getReg - Returns the register number.
Definition: MachineOperand.h:369

llvm::MachineRegisterInfo
MachineRegisterInfo - Keep track of information for virtual and physical registers,...
Definition: MachineRegisterInfo.h:51

llvm::MachineRegisterInfo::isPhysRegUsed
bool isPhysRegUsed(MCRegister PhysReg, bool SkipRegMaskTest=false) const
Return true if the specified register is modified or read in this function.
Definition: MachineRegisterInfo.cpp:600

llvm::Register
Wrapper class representing virtual and physical registers.
Definition: Register.h:19

llvm::SIInstrInfo
Definition: SIInstrInfo.h:83

llvm::SIInstrInfo::isMAI
static bool isMAI(const MachineInstr &MI)
Definition: SIInstrInfo.h:792

llvm::SIInstrInfo::isDS
static bool isDS(const MachineInstr &MI)
Definition: SIInstrInfo.h:554

llvm::SIInstrInfo::isVMEM
static bool isVMEM(const MachineInstr &MI)
Definition: SIInstrInfo.h:432

llvm::SIInstrInfo::isSMRD
static bool isSMRD(const MachineInstr &MI)
Definition: SIInstrInfo.h:544

llvm::SIInstrInfo::isMTBUF
static bool isMTBUF(const MachineInstr &MI)
Definition: SIInstrInfo.h:536

llvm::SIInstrInfo::isEXP
static bool isEXP(const MachineInstr &MI)
Definition: SIInstrInfo.h:649

llvm::SIInstrInfo::isSALU
static bool isSALU(const MachineInstr &MI)
Definition: SIInstrInfo.h:408

llvm::SIInstrInfo::isSDWA
static bool isSDWA(const MachineInstr &MI)
Definition: SIInstrInfo.h:512

llvm::SIInstrInfo::insertNoops
void insertNoops(MachineBasicBlock &MBB, MachineBasicBlock::iterator MI, unsigned Quantity) const override
Definition: SIInstrInfo.cpp:1999

llvm::SIInstrInfo::isVINTRP
static bool isVINTRP(const MachineInstr &MI)
Definition: SIInstrInfo.h:784

llvm::SIInstrInfo::isDOT
static bool isDOT(const MachineInstr &MI)
Definition: SIInstrInfo.h:805

llvm::SIInstrInfo::isSWMMAC
static bool isSWMMAC(const MachineInstr &MI)
Definition: SIInstrInfo.h:821

llvm::SIInstrInfo::isLDSDIR
static bool isLDSDIR(const MachineInstr &MI)
Definition: SIInstrInfo.h:833

llvm::SIInstrInfo::isBufferSMRD
bool isBufferSMRD(const MachineInstr &MI) const
Definition: SIInstrInfo.cpp:9023

llvm::SIInstrInfo::isTRANS
static bool isTRANS(const MachineInstr &MI)
Definition: SIInstrInfo.h:768

llvm::SIInstrInfo::isMUBUF
static bool isMUBUF(const MachineInstr &MI)
Definition: SIInstrInfo.h:528

llvm::SIInstrInfo::isSegmentSpecificFLAT
static bool isSegmentSpecificFLAT(const MachineInstr &MI)
Definition: SIInstrInfo.h:618

llvm::SIInstrInfo::isDPP
static bool isDPP(const MachineInstr &MI)
Definition: SIInstrInfo.h:760

llvm::SIInstrInfo::isMFMA
static bool isMFMA(const MachineInstr &MI)
Definition: SIInstrInfo.h:800

llvm::SIInstrInfo::isFPAtomic
static bool isFPAtomic(const MachineInstr &MI)
Definition: SIInstrInfo.h:916

llvm::SIInstrInfo::isMIMG
static bool isMIMG(const MachineInstr &MI)
Definition: SIInstrInfo.h:580

llvm::SIInstrInfo::getNumWaitStates
static unsigned getNumWaitStates(const MachineInstr &MI)
Return the number of wait states that result from executing this instruction.
Definition: SIInstrInfo.cpp:2086

llvm::SIInstrInfo::isWMMA
static bool isWMMA(const MachineInstr &MI)
Definition: SIInstrInfo.h:809

llvm::SIInstrInfo::isFLAT
static bool isFLAT(const MachineInstr &MI)
Definition: SIInstrInfo.h:612

llvm::SIInstrInfo::isVALU
static bool isVALU(const MachineInstr &MI)
Definition: SIInstrInfo.h:416

llvm::SIMachineFunctionInfo
This class keeps track of the SPI_SP_INPUT_ADDR config register, which tells the hardware which inter...
Definition: SIMachineFunctionInfo.h:376

llvm::SIMachineFunctionInfo::getOccupancy
unsigned getOccupancy() const
Definition: SIMachineFunctionInfo.h:1059

llvm::SIRegisterInfo
Definition: SIRegisterInfo.h:32

llvm::SUnit
Scheduling unit. This is a node in the scheduling DAG.
Definition: ScheduleDAG.h:242

llvm::SUnit::isInstr
bool isInstr() const
Returns true if this SUnit refers to a machine instruction as opposed to an SDNode.
Definition: ScheduleDAG.h:378

llvm::SUnit::getInstr
MachineInstr * getInstr() const
Returns the representative MachineInstr for this SUnit.
Definition: ScheduleDAG.h:390

llvm::ScheduleHazardRecognizer::getMaxLookAhead
unsigned getMaxLookAhead() const
Definition: ScheduleHazardRecognizer.h:43

llvm::ScheduleHazardRecognizer::MaxLookAhead
unsigned MaxLookAhead
MaxLookAhead - Indicate the number of cycles in the scoreboard state.
Definition: ScheduleHazardRecognizer.h:31

llvm::ScheduleHazardRecognizer::HazardType
HazardType
Definition: ScheduleHazardRecognizer.h:37

llvm::ScheduleHazardRecognizer::NoHazard
@ NoHazard
Definition: ScheduleHazardRecognizer.h:38

llvm::ScheduleHazardRecognizer::NoopHazard
@ NoopHazard
Definition: ScheduleHazardRecognizer.h:40

llvm::ScheduleHazardRecognizer::Hazard
@ Hazard
Definition: ScheduleHazardRecognizer.h:39

llvm::ScheduleHazardRecognizer::EmitNoops
virtual void EmitNoops(unsigned Quantity)
EmitNoops - This callback is invoked when noops were added to the instruction stream.
Definition: ScheduleHazardRecognizer.h:120

llvm::SetVector::size
size_type size() const
Determine the number of elements in the SetVector.
Definition: SetVector.h:98

llvm::SetVector::insert
bool insert(const value_type &X)
Insert a new element into the SetVector.
Definition: SetVector.h:162

llvm::SmallDenseMap
Definition: DenseMap.h:926

llvm::SmallSetVector
A SetVector that performs no allocations if smaller than a certain size.
Definition: SetVector.h:370

llvm::SmallSet
SmallSet - This maintains a set of unique values, optimizing for the case when the set is small (less...
Definition: SmallSet.h:135

llvm::SmallSet::insert
std::pair< const_iterator, bool > insert(const T &V)
insert - Insert an element into the set if it isn't already there.
Definition: SmallSet.h:179

llvm::StringRef
StringRef - Represent a constant reference to a string, i.e.
Definition: StringRef.h:50

llvm::StringRef::getAsInteger
bool getAsInteger(unsigned Radix, T &Result) const
Parse the current string as an integer of the specified radix.
Definition: StringRef.h:455

llvm::TargetSchedModel::getWriteProcResEnd
ProcResIter getWriteProcResEnd(const MCSchedClassDesc *SC) const
Definition: TargetSchedule.h:137

llvm::TargetSchedModel::resolveSchedClass
const MCSchedClassDesc * resolveSchedClass(const MachineInstr *MI) const
Return the MCSchedClassDesc for this instruction.
Definition: TargetSchedule.cpp:121

llvm::TargetSchedModel::init
void init(const TargetSubtargetInfo *TSInfo)
Initialize the machine model for instruction scheduling.
Definition: TargetSchedule.cpp:51

llvm::TargetSchedModel::getWriteProcResBegin
ProcResIter getWriteProcResBegin(const MCSchedClassDesc *SC) const
Definition: TargetSchedule.h:133

llvm::Use
A Use represents the edge between a Value definition and its users.
Definition: Use.h:43

llvm::Use::getOperandNo
unsigned getOperandNo() const
Return the operand # of this use in its User.
Definition: Use.cpp:31

llvm::Value
LLVM Value Representation.
Definition: Value.h:74

llvm::cl::Option
Definition: CommandLine.h:250

llvm::cl::opt
Definition: CommandLine.h:1423

llvm::cl::parser
Definition: CommandLine.h:823

llvm::detail::DenseSetImpl::insert
std::pair< iterator, bool > insert(const ValueT &V)
Definition: DenseSet.h:206

llvm::function_ref
An efficient, type-erasing, non-owning reference to a callable.
Definition: STLFunctionalExtras.h:36

llvm::ilist_node_impl::getIterator
self_iterator getIterator()
Definition: ilist_node.h:132

llvm::iterator_range
A range adaptor for a pair of iterators.
Definition: iterator_range.h:42

unsigned

llvm_unreachable
#define llvm_unreachable(msg)
Marks that the current location is not supposed to be reachable.
Definition: ErrorHandling.h:143

false
Definition: StackSlotColoring.cpp:194

llvm::AArch64PACKey::IA
@ IA
Definition: AArch64BaseInfo.h:820

llvm::AMDGPU::DepCtr::encodeFieldVaVdst
unsigned encodeFieldVaVdst(unsigned Encoded, unsigned VaVdst)
Definition: AMDGPUBaseInfo.cpp:1682

llvm::AMDGPU::DepCtr::decodeFieldSaSdst
unsigned decodeFieldSaSdst(unsigned Encoded)
Definition: AMDGPUBaseInfo.cpp:1670

llvm::AMDGPU::DepCtr::encodeFieldVmVsrc
unsigned encodeFieldVmVsrc(unsigned Encoded, unsigned VmVsrc)
Definition: AMDGPUBaseInfo.cpp:1674

llvm::AMDGPU::DepCtr::encodeFieldSaSdst
unsigned encodeFieldSaSdst(unsigned Encoded, unsigned SaSdst)
Definition: AMDGPUBaseInfo.cpp:1690

llvm::AMDGPU::DepCtr::decodeFieldVaVdst
unsigned decodeFieldVaVdst(unsigned Encoded)
Definition: AMDGPUBaseInfo.cpp:1666

llvm::AMDGPU::DepCtr::decodeFieldVmVsrc
unsigned decodeFieldVmVsrc(unsigned Encoded)
Definition: AMDGPUBaseInfo.cpp:1662

llvm::AMDGPU::Hwreg::ID_TRAPSTS
@ ID_TRAPSTS
Definition: SIDefines.h:507

llvm::AMDGPU::SDWA::DWORD
@ DWORD
Definition: SIDefines.h:885

llvm::AMDGPU::getMIMGInfo
LLVM_READONLY const MIMGInfo * getMIMGInfo(unsigned Opc)

llvm::AMDGPU::decodeWaitcnt
void decodeWaitcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned &Vmcnt, unsigned &Expcnt, unsigned &Lgkmcnt)
Decodes Vmcnt, Expcnt and Lgkmcnt from given Waitcnt for given isa Version, and writes decoded values...
Definition: AMDGPUBaseInfo.cpp:1424

llvm::AMDGPU::getNamedOperandIdx
LLVM_READONLY int16_t getNamedOperandIdx(uint16_t Opcode, uint16_t NamedIdx)

llvm::AMDGPU::isGFX12Plus
bool isGFX12Plus(const MCSubtargetInfo &STI)
Definition: AMDGPUBaseInfo.cpp:2162

llvm::AMDGPU::getIsaVersion
IsaVersion getIsaVersion(StringRef GPU)
Definition: TargetParser.cpp:225

llvm::AMDGPU::getMAIIsGFX940XDL
bool getMAIIsGFX940XDL(unsigned Opc)
Definition: AMDGPUBaseInfo.cpp:523

llvm::AMDGPU::hasNamedOperand
LLVM_READONLY bool hasNamedOperand(uint64_t Opcode, uint64_t NamedIdx)
Definition: AMDGPUBaseInfo.h:383

llvm::AMDGPU::getRegBitWidth
unsigned getRegBitWidth(const TargetRegisterClass &RC)
Get the size in bits of a register from the register class RC.
Definition: SIRegisterInfo.cpp:2607

llvm::AMDGPU::getMAIIsDGEMM
bool getMAIIsDGEMM(unsigned Opc)
Returns true if MAI operation is a double precision GEMM.
Definition: AMDGPUBaseInfo.cpp:518

llvm::COFF::Entry
@ Entry
Definition: COFF.h:811

llvm::CallingConv::AMDGPU_CS
@ AMDGPU_CS
Used for Mesa/AMDPAL compute shaders.
Definition: CallingConv.h:197

llvm::CallingConv::AMDGPU_KERNEL
@ AMDGPU_KERNEL
Used for AMDGPU code object kernels.
Definition: CallingConv.h:200

llvm::CallingConv::AMDGPU_Gfx
@ AMDGPU_Gfx
Used for AMD graphics targets.
Definition: CallingConv.h:232

llvm::CallingConv::AMDGPU_CS_ChainPreserve
@ AMDGPU_CS_ChainPreserve
Used on AMDGPUs to give the middle-end more control over argument placement.
Definition: CallingConv.h:249

llvm::CallingConv::AMDGPU_CS_Chain
@ AMDGPU_CS_Chain
Used on AMDGPUs to give the middle-end more control over argument placement.
Definition: CallingConv.h:245

llvm::GraphProgram::DOT
@ DOT
Definition: GraphWriter.h:51

llvm::PPCISD::SC
@ SC
CHAIN = SC CHAIN, Imm128 - System call.
Definition: PPCISelLowering.h:432

llvm::RISCVFenceField::O
@ O
Definition: RISCVBaseInfo.h:317

llvm::RISCVMatInt::Imm
@ Imm
Definition: RISCVMatInt.h:24

llvm::RegState::Dead
@ Dead
Unused definition.
Definition: MachineInstrBuilder.h:52

llvm::RegState::Define
@ Define
Register definition.
Definition: MachineInstrBuilder.h:46

llvm::RegState::Kill
@ Kill
The last use of a register.
Definition: MachineInstrBuilder.h:50

llvm::RegState::Undef
@ Undef
Value of the register doesn't matter.
Definition: MachineInstrBuilder.h:54

llvm::SIInstrFlags::VALU
@ VALU
Definition: SIDefines.h:56

llvm::SIInstrFlags::SMRD
@ SMRD
Definition: SIDefines.h:82

llvm::SIInstrFlags::TRANS
@ TRANS
Definition: SIDefines.h:77

llvm::SISrcMods::DST_OP_SEL
@ DST_OP_SEL
Definition: SIDefines.h:294

llvm::X86Disassembler::Reg
Reg
All possible values of the reg field in the ModR/M byte.
Definition: X86DisassemblerDecoder.h:614

llvm::cl::Hidden
@ Hidden
Definition: CommandLine.h:137

llvm::cl::init
initializer< Ty > init(const Ty &Val)
Definition: CommandLine.h:443

llvm::numbers::e
constexpr double e
Definition: MathExtras.h:47

llvm::rdf::Def
NodeAddr< DefNode * > Def
Definition: RDFGraph.h:384

llvm
This is an optimization pass for GlobalISel generic memory operations.
Definition: AddressRanges.h:18

llvm::drop_begin
auto drop_begin(T &&RangeOrContainer, size_t N=1)
Return a range covering RangeOrContainer with the first N elements excluded.
Definition: STLExtras.h:329

llvm::Offset
@ Offset
Definition: DWP.cpp:480

llvm::ScanOptions::DPP
@ DPP

llvm::BuildMI
MachineInstrBuilder BuildMI(MachineFunction &MF, const MIMetadata &MIMD, const MCInstrDesc &MCID)
Builder interface. Specify how to create the initial instruction itself.
Definition: MachineInstrBuilder.h:373

llvm::AMDGPU::EncodingFields::decode
static std::tuple< typename Fields::ValueType... > decode(uint64_t Encoded)
Definition: AMDGPUBaseInfo.h:373

llvm::AMDGPU::IsaVersion
Instruction set architecture version.
Definition: TargetParser.h:127

llvm::AMDGPU::MIMGInfo
Definition: AMDGPUBaseInfo.h:492

llvm::AMDGPU::Waitcnt
Represents the counter values to wait for in an s_waitcnt instruction.
Definition: AMDGPUBaseInfo.h:923

llvm::AMDGPU::Waitcnt::DsCnt
unsigned DsCnt
Definition: AMDGPUBaseInfo.h:926

llvm::DWARFExpression::Operation::Description
Description of the encoding of one expression Op.
Definition: DWARFExpression.h:66

llvm::MCSchedClassDesc
Summarize the scheduling resources required for an instruction of a particular scheduling class.
Definition: MCSchedule.h:118

llvm::MCWriteProcResEntry::ReleaseAtCycle
uint16_t ReleaseAtCycle
Cycle at which the resource will be released by an instruction, relatively to the cycle in which the ...
Definition: MCSchedule.h:68

llvm::cl::desc
Definition: CommandLine.h:409

parse
Definition: regcomp.c:192