doxygen/SPIRVModuleAnalysis_8cpp_source.html

//===- SPIRVModuleAnalysis.cpp - analysis of global instrs & regs - C++ -*-===//

//

// 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

//

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

//

// The analysis collects instructions that should be output at the module level

// and performs the global register numbering.

//

// The results of this analysis are used in AsmPrinter to rename registers

// globally and to output required instructions at the module level.

//

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


// TODO: uses or report_fatal_error (which is also deprecated) /

//       ReportFatalUsageError in this file should be refactored, as per LLVM

//       best practices, to rely on the Diagnostic infrastructure.


#include "SPIRVModuleAnalysis.h"

#include "MCTargetDesc/SPIRVBaseInfo.h"

#include "MCTargetDesc/SPIRVMCTargetDesc.h"

#include "SPIRV.h"

#include "SPIRVSubtarget.h"

#include "SPIRVTargetMachine.h"

#include "SPIRVUtils.h"

#include "llvm/ADT/STLExtras.h"

#include "llvm/CodeGen/MachineModuleInfo.h"

#include "llvm/CodeGen/TargetPassConfig.h"


using namespace llvm;


#define DEBUG_TYPE "spirv-module-analysis"


static cl::opt<bool>

    SPVDumpDeps("spv-dump-deps",

                cl::desc("Dump MIR with SPIR-V dependencies info"),

                cl::Optional, cl::init(false));


static cl::list<SPIRV::Capability::Capability>

    AvoidCapabilities("avoid-spirv-capabilities",

                      cl::desc("SPIR-V capabilities to avoid if there are "

                               "other options enabling a feature"),

                      cl::ZeroOrMore, cl::Hidden,

                      cl::values(clEnumValN(SPIRV::Capability::Shader, "Shader",

                                            "SPIR-V Shader capability")));

// Use sets instead of cl::list to check "if contains" condition


struct AvoidCapabilitiesSet {

  SmallSet<SPIRV::Capability::Capability, 4> S;

  AvoidCapabilitiesSet() { S.insert_range(AvoidCapabilities); }

};


char llvm::SPIRVModuleAnalysis::ID = 0;


INITIALIZE_PASS(SPIRVModuleAnalysis, DEBUG_TYPE, "SPIRV module analysis", true,

                true)


// Retrieve an unsigned from an MDNode with a list of them as operands.

static unsigned getMetadataUInt(MDNode *MdNode, unsigned OpIndex,


                                unsigned DefaultVal = 0) {

  if (MdNode && OpIndex < MdNode->getNumOperands()) {

    const auto &Op = MdNode->getOperand(OpIndex);

    return mdconst::extract<ConstantInt>(Op)->getZExtValue();

  }

  return DefaultVal;

}


static SPIRV::Requirements

getSymbolicOperandRequirements(SPIRV::OperandCategory::OperandCategory Category,

                               unsigned i, const SPIRVSubtarget &ST,

                               SPIRV::RequirementHandler &Reqs) {

  // A set of capabilities to avoid if there is another option.

  AvoidCapabilitiesSet AvoidCaps;

  if (!ST.isShader())

    AvoidCaps.S.insert(SPIRV::Capability::Shader);

  else

    AvoidCaps.S.insert(SPIRV::Capability::Kernel);


  VersionTuple ReqMinVer = getSymbolicOperandMinVersion(Category, i);

  VersionTuple ReqMaxVer = getSymbolicOperandMaxVersion(Category, i);

  VersionTuple SPIRVVersion = ST.getSPIRVVersion();

  bool MinVerOK = SPIRVVersion.empty() || SPIRVVersion >= ReqMinVer;

  bool MaxVerOK =

      ReqMaxVer.empty() || SPIRVVersion.empty() || SPIRVVersion <= ReqMaxVer;

  CapabilityList ReqCaps = getSymbolicOperandCapabilities(Category, i);

  ExtensionList ReqExts = getSymbolicOperandExtensions(Category, i);

  if (ReqCaps.empty()) {

    if (ReqExts.empty()) {

      if (MinVerOK && MaxVerOK)

        return {true, {}, {}, ReqMinVer, ReqMaxVer};

      return {false, {}, {}, VersionTuple(), VersionTuple()};

    }

  } else if (MinVerOK && MaxVerOK) {

    if (ReqCaps.size() == 1) {

      auto Cap = ReqCaps[0];

      if (Reqs.isCapabilityAvailable(Cap)) {

        ReqExts.append(getSymbolicOperandExtensions(

            SPIRV::OperandCategory::CapabilityOperand, Cap));

        return {true, {Cap}, std::move(ReqExts), ReqMinVer, ReqMaxVer};

      }

    } else {

      // By SPIR-V specification: "If an instruction, enumerant, or other

      // feature specifies multiple enabling capabilities, only one such

      // capability needs to be declared to use the feature." However, one

      // capability may be preferred over another. We use command line

      // argument(s) and AvoidCapabilities to avoid selection of certain

      // capabilities if there are other options.

      CapabilityList UseCaps;

      for (auto Cap : ReqCaps)

        if (Reqs.isCapabilityAvailable(Cap))

          UseCaps.push_back(Cap);

      for (size_t i = 0, Sz = UseCaps.size(); i < Sz; ++i) {

        auto Cap = UseCaps[i];

        if (i == Sz - 1 || !AvoidCaps.S.contains(Cap)) {

          ReqExts.append(getSymbolicOperandExtensions(

              SPIRV::OperandCategory::CapabilityOperand, Cap));

          return {true, {Cap}, std::move(ReqExts), ReqMinVer, ReqMaxVer};

        }

      }

    }

  }

  // If there are no capabilities, or we can't satisfy the version or

  // capability requirements, use the list of extensions (if the subtarget

  // can handle them all).

  if (llvm::all_of(ReqExts, [&ST](const SPIRV::Extension::Extension &Ext) {

        return ST.canUseExtension(Ext);

      })) {

    return {true,

            {},

            std::move(ReqExts),

            VersionTuple(),

            VersionTuple()}; // TODO: add versions to extensions.

  }

  return {false, {}, {}, VersionTuple(), VersionTuple()};

}


void SPIRVModuleAnalysis::setBaseInfo(const Module &M) {

  MAI.MaxID = 0;

  for (int i = 0; i < SPIRV::NUM_MODULE_SECTIONS; i++)

    MAI.MS[i].clear();

  MAI.RegisterAliasTable.clear();

  MAI.InstrsToDelete.clear();

  MAI.FuncMap.clear();

  MAI.GlobalVarList.clear();

  MAI.ExtInstSetMap.clear();

  MAI.Reqs.clear();

  MAI.Reqs.initAvailableCapabilities(*ST);


  // TODO: determine memory model and source language from the configuratoin.

  if (auto MemModel = M.getNamedMetadata("spirv.MemoryModel")) {

    auto MemMD = MemModel->getOperand(0);

    MAI.Addr = static_cast<SPIRV::AddressingModel::AddressingModel>(

        getMetadataUInt(MemMD, 0));

    MAI.Mem =

        static_cast<SPIRV::MemoryModel::MemoryModel>(getMetadataUInt(MemMD, 1));

  } else {

    // TODO: Add support for VulkanMemoryModel.

    MAI.Mem = ST->isShader() ? SPIRV::MemoryModel::GLSL450

                             : SPIRV::MemoryModel::OpenCL;

    if (MAI.Mem == SPIRV::MemoryModel::OpenCL) {

      unsigned PtrSize = ST->getPointerSize();

      MAI.Addr = PtrSize == 32   ? SPIRV::AddressingModel::Physical32

                 : PtrSize == 64 ? SPIRV::AddressingModel::Physical64

                                 : SPIRV::AddressingModel::Logical;

    } else {

      // TODO: Add support for PhysicalStorageBufferAddress.

      MAI.Addr = SPIRV::AddressingModel::Logical;

    }

  }

  // Get the OpenCL version number from metadata.

  // TODO: support other source languages.

  if (auto VerNode = M.getNamedMetadata("opencl.ocl.version")) {

    MAI.SrcLang = SPIRV::SourceLanguage::OpenCL_C;

    // Construct version literal in accordance with SPIRV-LLVM-Translator.

    // TODO: support multiple OCL version metadata.

    assert(VerNode->getNumOperands() > 0 && "Invalid SPIR");

    auto VersionMD = VerNode->getOperand(0);

    unsigned MajorNum = getMetadataUInt(VersionMD, 0, 2);

    unsigned MinorNum = getMetadataUInt(VersionMD, 1);

    unsigned RevNum = getMetadataUInt(VersionMD, 2);

    // Prevent Major part of OpenCL version to be 0

    MAI.SrcLangVersion =

        (std::max(1U, MajorNum) * 100 + MinorNum) * 1000 + RevNum;

  } else {

    // If there is no information about OpenCL version we are forced to generate

    // OpenCL 1.0 by default for the OpenCL environment to avoid puzzling

    // run-times with Unknown/0.0 version output. For a reference, LLVM-SPIRV

    // Translator avoids potential issues with run-times in a similar manner.

    if (!ST->isShader()) {

      MAI.SrcLang = SPIRV::SourceLanguage::OpenCL_CPP;

      MAI.SrcLangVersion = 100000;

    } else {

      MAI.SrcLang = SPIRV::SourceLanguage::Unknown;

      MAI.SrcLangVersion = 0;

    }

  }


  if (auto ExtNode = M.getNamedMetadata("opencl.used.extensions")) {

    for (unsigned I = 0, E = ExtNode->getNumOperands(); I != E; ++I) {

      MDNode *MD = ExtNode->getOperand(I);

      if (!MD || MD->getNumOperands() == 0)

        continue;

      for (unsigned J = 0, N = MD->getNumOperands(); J != N; ++J)

        MAI.SrcExt.insert(cast<MDString>(MD->getOperand(J))->getString());

    }

  }


  // Update required capabilities for this memory model, addressing model and

  // source language.

  MAI.Reqs.getAndAddRequirements(SPIRV::OperandCategory::MemoryModelOperand,

                                 MAI.Mem, *ST);

  MAI.Reqs.getAndAddRequirements(SPIRV::OperandCategory::SourceLanguageOperand,

                                 MAI.SrcLang, *ST);

  MAI.Reqs.getAndAddRequirements(SPIRV::OperandCategory::AddressingModelOperand,

                                 MAI.Addr, *ST);


  if (!ST->isShader()) {

    // TODO: check if it's required by default.

    MAI.ExtInstSetMap[static_cast<unsigned>(

        SPIRV::InstructionSet::OpenCL_std)] = MAI.getNextIDRegister();

  }

}


// Appends the signature of the decoration instructions that decorate R to

// Signature.

static void appendDecorationsForReg(const MachineRegisterInfo &MRI, Register R,

                                    InstrSignature &Signature) {

  for (MachineInstr &UseMI : MRI.use_instructions(R)) {

    // We don't handle OpDecorateId because getting the register alias for the

    // ID can cause problems, and we do not need it for now.

    if (UseMI.getOpcode() != SPIRV::OpDecorate &&

        UseMI.getOpcode() != SPIRV::OpMemberDecorate)

      continue;


    for (unsigned I = 0; I < UseMI.getNumOperands(); ++I) {

      const MachineOperand &MO = UseMI.getOperand(I);

      if (MO.isReg())

        continue;

      Signature.push_back(hash_value(MO));

    }

  }

}


// Returns a representation of an instruction as a vector of MachineOperand

// hash values, see llvm::hash_value(const MachineOperand &MO) for details.

// This creates a signature of the instruction with the same content

// that MachineOperand::isIdenticalTo uses for comparison.

static InstrSignature instrToSignature(const MachineInstr &MI,

                                       SPIRV::ModuleAnalysisInfo &MAI,

                                       bool UseDefReg) {

  Register DefReg;

  InstrSignature Signature{MI.getOpcode()};

  for (unsigned i = 0; i < MI.getNumOperands(); ++i) {

    // The only decorations that can be applied more than once to a given <id>

    // or structure member are FuncParamAttr (38), UserSemantic (5635),

    // CacheControlLoadINTEL (6442), and CacheControlStoreINTEL (6443). For all

    // the rest of decorations, we will only add to the signature the Opcode,

    // the id to which it applies, and the decoration id, disregarding any

    // decoration flags. This will ensure that any subsequent decoration with

    // the same id will be deemed as a duplicate. Then, at the call site, we

    // will be able to handle duplicates in the best way.

    unsigned Opcode = MI.getOpcode();

    if ((Opcode == SPIRV::OpDecorate) && i >= 2) {

      unsigned DecorationID = MI.getOperand(1).getImm();

      if (DecorationID != SPIRV::Decoration::FuncParamAttr &&

          DecorationID != SPIRV::Decoration::UserSemantic &&

          DecorationID != SPIRV::Decoration::CacheControlLoadINTEL &&

          DecorationID != SPIRV::Decoration::CacheControlStoreINTEL)

        continue;

    }

    const MachineOperand &MO = MI.getOperand(i);

    size_t h;

    if (MO.isReg()) {

      if (!UseDefReg && MO.isDef()) {

        assert(!DefReg.isValid() && "Multiple def registers.");

        DefReg = MO.getReg();

        continue;

      }

      Register RegAlias = MAI.getRegisterAlias(MI.getMF(), MO.getReg());

      if (!RegAlias.isValid()) {

        LLVM_DEBUG({

          dbgs() << "Unexpectedly, no global id found for the operand ";

          MO.print(dbgs());

          dbgs() << "\nInstruction: ";

          MI.print(dbgs());

          dbgs() << "\n";

        });

        report_fatal_error("All v-regs must have been mapped to global id's");

      }

      // mimic llvm::hash_value(const MachineOperand &MO)

      h = hash_combine(MO.getType(), (unsigned)RegAlias, MO.getSubReg(),

                       MO.isDef());

    } else {

      h = hash_value(MO);

    }

    Signature.push_back(h);

  }


  if (DefReg.isValid()) {

    // Decorations change the semantics of the current instruction. So two

    // identical instruction with different decorations cannot be merged. That

    // is why we add the decorations to the signature.

    appendDecorationsForReg(MI.getMF()->getRegInfo(), DefReg, Signature);

  }

  return Signature;

}


bool SPIRVModuleAnalysis::isDeclSection(const MachineRegisterInfo &MRI,

                                        const MachineInstr &MI) {

  unsigned Opcode = MI.getOpcode();

  switch (Opcode) {

  case SPIRV::OpTypeForwardPointer:

    // omit now, collect later

    return false;

  case SPIRV::OpVariable:

    return static_cast<SPIRV::StorageClass::StorageClass>(

               MI.getOperand(2).getImm()) != SPIRV::StorageClass::Function;

  case SPIRV::OpFunction:

  case SPIRV::OpFunctionParameter:

    return true;

  }

  if (GR->hasConstFunPtr() && Opcode == SPIRV::OpUndef) {

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

    for (MachineInstr &UseMI : MRI.use_instructions(DefReg)) {

      if (UseMI.getOpcode() != SPIRV::OpConstantFunctionPointerINTEL)

        continue;

      // it's a dummy definition, FP constant refers to a function,

      // and this is resolved in another way; let's skip this definition

      assert(UseMI.getOperand(2).isReg() &&

             UseMI.getOperand(2).getReg() == DefReg);

      MAI.setSkipEmission(&MI);

      return false;

    }

  }

  return TII->isTypeDeclInstr(MI) || TII->isConstantInstr(MI) ||

         TII->isInlineAsmDefInstr(MI);

}


// This is a special case of a function pointer refering to a possibly

// forward function declaration. The operand is a dummy OpUndef that

// requires a special treatment.

void SPIRVModuleAnalysis::visitFunPtrUse(

    Register OpReg, InstrGRegsMap &SignatureToGReg,

    std::map<const Value *, unsigned> &GlobalToGReg, const MachineFunction *MF,

    const MachineInstr &MI) {

  const MachineOperand *OpFunDef =

      GR->getFunctionDefinitionByUse(&MI.getOperand(2));

  assert(OpFunDef && OpFunDef->isReg());

  // find the actual function definition and number it globally in advance

  const MachineInstr *OpDefMI = OpFunDef->getParent();

  assert(OpDefMI && OpDefMI->getOpcode() == SPIRV::OpFunction);

  const MachineFunction *FunDefMF = OpDefMI->getParent()->getParent();

  const MachineRegisterInfo &FunDefMRI = FunDefMF->getRegInfo();

  do {

    visitDecl(FunDefMRI, SignatureToGReg, GlobalToGReg, FunDefMF, *OpDefMI);

    OpDefMI = OpDefMI->getNextNode();

  } while (OpDefMI && (OpDefMI->getOpcode() == SPIRV::OpFunction ||

                       OpDefMI->getOpcode() == SPIRV::OpFunctionParameter));

  // associate the function pointer with the newly assigned global number

  MCRegister GlobalFunDefReg =

      MAI.getRegisterAlias(FunDefMF, OpFunDef->getReg());

  assert(GlobalFunDefReg.isValid() &&

         "Function definition must refer to a global register");

  MAI.setRegisterAlias(MF, OpReg, GlobalFunDefReg);

}


// Depth first recursive traversal of dependencies. Repeated visits are guarded

// by MAI.hasRegisterAlias().

void SPIRVModuleAnalysis::visitDecl(

    const MachineRegisterInfo &MRI, InstrGRegsMap &SignatureToGReg,

    std::map<const Value *, unsigned> &GlobalToGReg, const MachineFunction *MF,

    const MachineInstr &MI) {

  unsigned Opcode = MI.getOpcode();


  // Process each operand of the instruction to resolve dependencies

  for (const MachineOperand &MO : MI.operands()) {

    if (!MO.isReg() || MO.isDef())

      continue;

    Register OpReg = MO.getReg();

    // Handle function pointers special case

    if (Opcode == SPIRV::OpConstantFunctionPointerINTEL &&

        MRI.getRegClass(OpReg) == &SPIRV::pIDRegClass) {

      visitFunPtrUse(OpReg, SignatureToGReg, GlobalToGReg, MF, MI);

      continue;

    }

    // Skip already processed instructions

    if (MAI.hasRegisterAlias(MF, MO.getReg()))

      continue;

    // Recursively visit dependencies

    if (const MachineInstr *OpDefMI = MRI.getUniqueVRegDef(OpReg)) {

      if (isDeclSection(MRI, *OpDefMI))

        visitDecl(MRI, SignatureToGReg, GlobalToGReg, MF, *OpDefMI);

      continue;

    }

    // Handle the unexpected case of no unique definition for the SPIR-V

    // instruction

    LLVM_DEBUG({

      dbgs() << "Unexpectedly, no unique definition for the operand ";

      MO.print(dbgs());

      dbgs() << "\nInstruction: ";

      MI.print(dbgs());

      dbgs() << "\n";

    });

    report_fatal_error(

        "No unique definition is found for the virtual register");

  }


  MCRegister GReg;

  bool IsFunDef = false;

  if (TII->isSpecConstantInstr(MI)) {

    GReg = MAI.getNextIDRegister();

    MAI.MS[SPIRV::MB_TypeConstVars].push_back(&MI);

  } else if (Opcode == SPIRV::OpFunction ||

             Opcode == SPIRV::OpFunctionParameter) {

    GReg = handleFunctionOrParameter(MF, MI, GlobalToGReg, IsFunDef);

  } else if (Opcode == SPIRV::OpTypeStruct ||

             Opcode == SPIRV::OpConstantComposite) {

    GReg = handleTypeDeclOrConstant(MI, SignatureToGReg);

    const MachineInstr *NextInstr = MI.getNextNode();

    while (NextInstr &&

           ((Opcode == SPIRV::OpTypeStruct &&

             NextInstr->getOpcode() == SPIRV::OpTypeStructContinuedINTEL) ||

            (Opcode == SPIRV::OpConstantComposite &&

             NextInstr->getOpcode() ==

                 SPIRV::OpConstantCompositeContinuedINTEL))) {

      MCRegister Tmp = handleTypeDeclOrConstant(*NextInstr, SignatureToGReg);

      MAI.setRegisterAlias(MF, NextInstr->getOperand(0).getReg(), Tmp);

      MAI.setSkipEmission(NextInstr);

      NextInstr = NextInstr->getNextNode();

    }

  } else if (TII->isTypeDeclInstr(MI) || TII->isConstantInstr(MI) ||

             TII->isInlineAsmDefInstr(MI)) {

    GReg = handleTypeDeclOrConstant(MI, SignatureToGReg);

  } else if (Opcode == SPIRV::OpVariable) {

    GReg = handleVariable(MF, MI, GlobalToGReg);

  } else {

    LLVM_DEBUG({

      dbgs() << "\nInstruction: ";

      MI.print(dbgs());

      dbgs() << "\n";

    });

    llvm_unreachable("Unexpected instruction is visited");

  }

  MAI.setRegisterAlias(MF, MI.getOperand(0).getReg(), GReg);

  if (!IsFunDef)

    MAI.setSkipEmission(&MI);

}


MCRegister SPIRVModuleAnalysis::handleFunctionOrParameter(

    const MachineFunction *MF, const MachineInstr &MI,

    std::map<const Value *, unsigned> &GlobalToGReg, bool &IsFunDef) {

  const Value *GObj = GR->getGlobalObject(MF, MI.getOperand(0).getReg());

  assert(GObj && "Unregistered global definition");

  const Function *F = dyn_cast<Function>(GObj);

  if (!F)

    F = dyn_cast<Argument>(GObj)->getParent();

  assert(F && "Expected a reference to a function or an argument");

  IsFunDef = !F->isDeclaration();

  auto [It, Inserted] = GlobalToGReg.try_emplace(GObj);

  if (!Inserted)

    return It->second;

  MCRegister GReg = MAI.getNextIDRegister();

  It->second = GReg;

  if (!IsFunDef)

    MAI.MS[SPIRV::MB_ExtFuncDecls].push_back(&MI);

  return GReg;

}


MCRegister

SPIRVModuleAnalysis::handleTypeDeclOrConstant(const MachineInstr &MI,

                                              InstrGRegsMap &SignatureToGReg) {

  InstrSignature MISign = instrToSignature(MI, MAI, false);

  auto [It, Inserted] = SignatureToGReg.try_emplace(MISign);

  if (!Inserted)

    return It->second;

  MCRegister GReg = MAI.getNextIDRegister();

  It->second = GReg;

  MAI.MS[SPIRV::MB_TypeConstVars].push_back(&MI);

  return GReg;

}


MCRegister SPIRVModuleAnalysis::handleVariable(

    const MachineFunction *MF, const MachineInstr &MI,

    std::map<const Value *, unsigned> &GlobalToGReg) {

  MAI.GlobalVarList.push_back(&MI);

  const Value *GObj = GR->getGlobalObject(MF, MI.getOperand(0).getReg());

  assert(GObj && "Unregistered global definition");

  auto [It, Inserted] = GlobalToGReg.try_emplace(GObj);

  if (!Inserted)

    return It->second;

  MCRegister GReg = MAI.getNextIDRegister();

  It->second = GReg;

  MAI.MS[SPIRV::MB_TypeConstVars].push_back(&MI);

  return GReg;

}


void SPIRVModuleAnalysis::collectDeclarations(const Module &M) {

  InstrGRegsMap SignatureToGReg;

  std::map<const Value *, unsigned> GlobalToGReg;

  for (const Function &F : M) {

    MachineFunction *MF = MMI->getMachineFunction(F);

    if (!MF)

      continue;

    const MachineRegisterInfo &MRI = MF->getRegInfo();

    unsigned PastHeader = 0;

    for (MachineBasicBlock &MBB : *MF) {

      for (MachineInstr &MI : MBB) {

        if (MI.getNumOperands() == 0)

          continue;

        unsigned Opcode = MI.getOpcode();

        if (Opcode == SPIRV::OpFunction) {

          if (PastHeader == 0) {

            PastHeader = 1;

            continue;

          }

        } else if (Opcode == SPIRV::OpFunctionParameter) {

          if (PastHeader < 2)

            continue;

        } else if (PastHeader > 0) {

          PastHeader = 2;

        }


        const MachineOperand &DefMO = MI.getOperand(0);

        switch (Opcode) {

        case SPIRV::OpExtension:

          MAI.Reqs.addExtension(SPIRV::Extension::Extension(DefMO.getImm()));

          MAI.setSkipEmission(&MI);

          break;

        case SPIRV::OpCapability:

          MAI.Reqs.addCapability(SPIRV::Capability::Capability(DefMO.getImm()));

          MAI.setSkipEmission(&MI);

          if (PastHeader > 0)

            PastHeader = 2;

          break;

        default:

          if (DefMO.isReg() && isDeclSection(MRI, MI) &&

              !MAI.hasRegisterAlias(MF, DefMO.getReg()))

            visitDecl(MRI, SignatureToGReg, GlobalToGReg, MF, MI);

        }

      }

    }

  }

}


// Look for IDs declared with Import linkage, and map the corresponding function

// to the register defining that variable (which will usually be the result of

// an OpFunction). This lets us call externally imported functions using

// the correct ID registers.

void SPIRVModuleAnalysis::collectFuncNames(MachineInstr &MI,

                                           const Function *F) {

  if (MI.getOpcode() == SPIRV::OpDecorate) {

    // If it's got Import linkage.

    auto Dec = MI.getOperand(1).getImm();

    if (Dec == SPIRV::Decoration::LinkageAttributes) {

      auto Lnk = MI.getOperand(MI.getNumOperands() - 1).getImm();

      if (Lnk == SPIRV::LinkageType::Import) {

        // Map imported function name to function ID register.

        const Function *ImportedFunc =

            F->getParent()->getFunction(getStringImm(MI, 2));

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

        MAI.FuncMap[ImportedFunc] = MAI.getRegisterAlias(MI.getMF(), Target);

      }

    }

  } else if (MI.getOpcode() == SPIRV::OpFunction) {

    // Record all internal OpFunction declarations.

    Register Reg = MI.defs().begin()->getReg();

    MCRegister GlobalReg = MAI.getRegisterAlias(MI.getMF(), Reg);

    assert(GlobalReg.isValid());

    MAI.FuncMap[F] = GlobalReg;

  }

}


// Collect the given instruction in the specified MS. We assume global register

// numbering has already occurred by this point. We can directly compare reg

// arguments when detecting duplicates.

static void collectOtherInstr(MachineInstr &MI, SPIRV::ModuleAnalysisInfo &MAI,

                              SPIRV::ModuleSectionType MSType, InstrTraces &IS,

                              bool Append = true) {

  MAI.setSkipEmission(&MI);

  InstrSignature MISign = instrToSignature(MI, MAI, true);

  auto FoundMI = IS.insert(std::move(MISign));

  if (!FoundMI.second) {

    if (MI.getOpcode() == SPIRV::OpDecorate) {

      assert(MI.getNumOperands() >= 2 &&

             "Decoration instructions must have at least 2 operands");

      assert(MSType == SPIRV::MB_Annotations &&

             "Only OpDecorate instructions can be duplicates");

      // For FPFastMathMode decoration, we need to merge the flags of the

      // duplicate decoration with the original one, so we need to find the

      // original instruction that has the same signature. For the rest of

      // instructions, we will simply skip the duplicate.

      if (MI.getOperand(1).getImm() != SPIRV::Decoration::FPFastMathMode)

        return; // Skip duplicates of other decorations.


      const SPIRV::InstrList &Decorations = MAI.MS[MSType];

      for (const MachineInstr *OrigMI : Decorations) {

        if (instrToSignature(*OrigMI, MAI, true) == MISign) {

          assert(OrigMI->getNumOperands() == MI.getNumOperands() &&

                 "Original instruction must have the same number of operands");

          assert(

              OrigMI->getNumOperands() == 3 &&

              "FPFastMathMode decoration must have 3 operands for OpDecorate");

          unsigned OrigFlags = OrigMI->getOperand(2).getImm();

          unsigned NewFlags = MI.getOperand(2).getImm();

          if (OrigFlags == NewFlags)

            return; // No need to merge, the flags are the same.


          // Emit warning about possible conflict between flags.

          unsigned FinalFlags = OrigFlags | NewFlags;

          llvm::errs()

              << "Warning: Conflicting FPFastMathMode decoration flags "

                 "in instruction: "

              << *OrigMI << "Original flags: " << OrigFlags

              << ", new flags: " << NewFlags

              << ". They will be merged on a best effort basis, but not "

                 "validated. Final flags: "

              << FinalFlags << "\n";

          MachineInstr *OrigMINonConst = const_cast<MachineInstr *>(OrigMI);

          MachineOperand &OrigFlagsOp = OrigMINonConst->getOperand(2);

          OrigFlagsOp = MachineOperand::CreateImm(FinalFlags);

          return; // Merge done, so we found a duplicate; don't add it to MAI.MS

        }

      }

      assert(false && "No original instruction found for the duplicate "

                      "OpDecorate, but we found one in IS.");

    }

    return; // insert failed, so we found a duplicate; don't add it to MAI.MS

  }

  // No duplicates, so add it.

  if (Append)

    MAI.MS[MSType].push_back(&MI);

  else

    MAI.MS[MSType].insert(MAI.MS[MSType].begin(), &MI);

}


// Some global instructions make reference to function-local ID regs, so cannot

// be correctly collected until these registers are globally numbered.

void SPIRVModuleAnalysis::processOtherInstrs(const Module &M) {

  InstrTraces IS;

  for (const Function &F : M) {

    if (F.isDeclaration())

      continue;

    MachineFunction *MF = MMI->getMachineFunction(F);

    assert(MF);


    for (MachineBasicBlock &MBB : *MF)

      for (MachineInstr &MI : MBB) {

        if (MAI.getSkipEmission(&MI))

          continue;

        const unsigned OpCode = MI.getOpcode();

        if (OpCode == SPIRV::OpString) {

          collectOtherInstr(MI, MAI, SPIRV::MB_DebugStrings, IS);

        } else if (OpCode == SPIRV::OpExtInst && MI.getOperand(2).isImm() &&

                   MI.getOperand(2).getImm() ==

                       SPIRV::InstructionSet::

                           NonSemantic_Shader_DebugInfo_100) {

          MachineOperand Ins = MI.getOperand(3);

          namespace NS = SPIRV::NonSemanticExtInst;

          static constexpr int64_t GlobalNonSemanticDITy[] = {

              NS::DebugSource, NS::DebugCompilationUnit, NS::DebugInfoNone,

              NS::DebugTypeBasic, NS::DebugTypePointer};

          bool IsGlobalDI = false;

          for (unsigned Idx = 0; Idx < std::size(GlobalNonSemanticDITy); ++Idx)

            IsGlobalDI |= Ins.getImm() == GlobalNonSemanticDITy[Idx];

          if (IsGlobalDI)

            collectOtherInstr(MI, MAI, SPIRV::MB_NonSemanticGlobalDI, IS);

        } else if (OpCode == SPIRV::OpName || OpCode == SPIRV::OpMemberName) {

          collectOtherInstr(MI, MAI, SPIRV::MB_DebugNames, IS);

        } else if (OpCode == SPIRV::OpEntryPoint) {

          collectOtherInstr(MI, MAI, SPIRV::MB_EntryPoints, IS);

        } else if (TII->isAliasingInstr(MI)) {

          collectOtherInstr(MI, MAI, SPIRV::MB_AliasingInsts, IS);

        } else if (TII->isDecorationInstr(MI)) {

          collectOtherInstr(MI, MAI, SPIRV::MB_Annotations, IS);

          collectFuncNames(MI, &F);

        } else if (TII->isConstantInstr(MI)) {

          // Now OpSpecConstant*s are not in DT,

          // but they need to be collected anyway.

          collectOtherInstr(MI, MAI, SPIRV::MB_TypeConstVars, IS);

        } else if (OpCode == SPIRV::OpFunction) {

          collectFuncNames(MI, &F);

        } else if (OpCode == SPIRV::OpTypeForwardPointer) {

          collectOtherInstr(MI, MAI, SPIRV::MB_TypeConstVars, IS, false);

        }

      }

  }

}


// Number registers in all functions globally from 0 onwards and store

// the result in global register alias table. Some registers are already

// numbered.

void SPIRVModuleAnalysis::numberRegistersGlobally(const Module &M) {

  for (const Function &F : M) {

    if (F.isDeclaration())

      continue;

    MachineFunction *MF = MMI->getMachineFunction(F);

    assert(MF);

    for (MachineBasicBlock &MBB : *MF) {

      for (MachineInstr &MI : MBB) {

        for (MachineOperand &Op : MI.operands()) {

          if (!Op.isReg())

            continue;

          Register Reg = Op.getReg();

          if (MAI.hasRegisterAlias(MF, Reg))

            continue;

          MCRegister NewReg = MAI.getNextIDRegister();

          MAI.setRegisterAlias(MF, Reg, NewReg);

        }

        if (MI.getOpcode() != SPIRV::OpExtInst)

          continue;

        auto Set = MI.getOperand(2).getImm();

        auto [It, Inserted] = MAI.ExtInstSetMap.try_emplace(Set);

        if (Inserted)

          It->second = MAI.getNextIDRegister();

      }

    }

  }

}


// RequirementHandler implementations.

void SPIRV::RequirementHandler::getAndAddRequirements(

    SPIRV::OperandCategory::OperandCategory Category, uint32_t i,

    const SPIRVSubtarget &ST) {

  addRequirements(getSymbolicOperandRequirements(Category, i, ST, *this));

}


void SPIRV::RequirementHandler::recursiveAddCapabilities(

    const CapabilityList &ToPrune) {

  for (const auto &Cap : ToPrune) {

    AllCaps.insert(Cap);

    CapabilityList ImplicitDecls =

        getSymbolicOperandCapabilities(OperandCategory::CapabilityOperand, Cap);

    recursiveAddCapabilities(ImplicitDecls);

  }

}


void SPIRV::RequirementHandler::addCapabilities(const CapabilityList &ToAdd) {

  for (const auto &Cap : ToAdd) {

    bool IsNewlyInserted = AllCaps.insert(Cap).second;

    if (!IsNewlyInserted) // Don't re-add if it's already been declared.

      continue;

    CapabilityList ImplicitDecls =

        getSymbolicOperandCapabilities(OperandCategory::CapabilityOperand, Cap);

    recursiveAddCapabilities(ImplicitDecls);

    MinimalCaps.push_back(Cap);

  }

}


void SPIRV::RequirementHandler::addRequirements(

    const SPIRV::Requirements &Req) {

  if (!Req.IsSatisfiable)

    report_fatal_error("Adding SPIR-V requirements this target can't satisfy.");


  if (Req.Cap.has_value())

    addCapabilities({Req.Cap.value()});


  addExtensions(Req.Exts);


  if (!Req.MinVer.empty()) {

    if (!MaxVersion.empty() && Req.MinVer > MaxVersion) {

      LLVM_DEBUG(dbgs() << "Conflicting version requirements: >= " << Req.MinVer

                        << " and <= " << MaxVersion << "\n");

      report_fatal_error("Adding SPIR-V requirements that can't be satisfied.");

    }


    if (MinVersion.empty() || Req.MinVer > MinVersion)

      MinVersion = Req.MinVer;

  }


  if (!Req.MaxVer.empty()) {

    if (!MinVersion.empty() && Req.MaxVer < MinVersion) {

      LLVM_DEBUG(dbgs() << "Conflicting version requirements: <= " << Req.MaxVer

                        << " and >= " << MinVersion << "\n");

      report_fatal_error("Adding SPIR-V requirements that can't be satisfied.");

    }


    if (MaxVersion.empty() || Req.MaxVer < MaxVersion)

      MaxVersion = Req.MaxVer;

  }

}


void SPIRV::RequirementHandler::checkSatisfiable(

    const SPIRVSubtarget &ST) const {

  // Report as many errors as possible before aborting the compilation.

  bool IsSatisfiable = true;

  auto TargetVer = ST.getSPIRVVersion();


  if (!MaxVersion.empty() && !TargetVer.empty() && MaxVersion < TargetVer) {

    LLVM_DEBUG(

        dbgs() << "Target SPIR-V version too high for required features\n"

               << "Required max version: " << MaxVersion << " target version "

               << TargetVer << "\n");

    IsSatisfiable = false;

  }


  if (!MinVersion.empty() && !TargetVer.empty() && MinVersion > TargetVer) {

    LLVM_DEBUG(dbgs() << "Target SPIR-V version too low for required features\n"

                      << "Required min version: " << MinVersion

                      << " target version " << TargetVer << "\n");

    IsSatisfiable = false;

  }


  if (!MinVersion.empty() && !MaxVersion.empty() && MinVersion > MaxVersion) {

    LLVM_DEBUG(

        dbgs()

        << "Version is too low for some features and too high for others.\n"

        << "Required SPIR-V min version: " << MinVersion

        << " required SPIR-V max version " << MaxVersion << "\n");

    IsSatisfiable = false;

  }


  AvoidCapabilitiesSet AvoidCaps;

  if (!ST.isShader())

    AvoidCaps.S.insert(SPIRV::Capability::Shader);

  else

    AvoidCaps.S.insert(SPIRV::Capability::Kernel);


  for (auto Cap : MinimalCaps) {

    if (AvailableCaps.contains(Cap) && !AvoidCaps.S.contains(Cap))

      continue;

    LLVM_DEBUG(dbgs() << "Capability not supported: "

                      << getSymbolicOperandMnemonic(

                             OperandCategory::CapabilityOperand, Cap)

                      << "\n");

    IsSatisfiable = false;

  }


  for (auto Ext : AllExtensions) {

    if (ST.canUseExtension(Ext))

      continue;

    LLVM_DEBUG(dbgs() << "Extension not supported: "

                      << getSymbolicOperandMnemonic(

                             OperandCategory::ExtensionOperand, Ext)

                      << "\n");

    IsSatisfiable = false;

  }


  if (!IsSatisfiable)

    report_fatal_error("Unable to meet SPIR-V requirements for this target.");

}


// Add the given capabilities and all their implicitly defined capabilities too.

void SPIRV::RequirementHandler::addAvailableCaps(const CapabilityList &ToAdd) {

  for (const auto Cap : ToAdd)

    if (AvailableCaps.insert(Cap).second)

      addAvailableCaps(getSymbolicOperandCapabilities(

          SPIRV::OperandCategory::CapabilityOperand, Cap));

}


void SPIRV::RequirementHandler::removeCapabilityIf(

    const Capability::Capability ToRemove,

    const Capability::Capability IfPresent) {

  if (AllCaps.contains(IfPresent))

    AllCaps.erase(ToRemove);

}


namespace llvm {

namespace SPIRV {

void RequirementHandler::initAvailableCapabilities(const SPIRVSubtarget &ST) {

  // Provided by both all supported Vulkan versions and OpenCl.

  addAvailableCaps({Capability::Shader, Capability::Linkage, Capability::Int8,

                    Capability::Int16});


  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 3)))

    addAvailableCaps({Capability::GroupNonUniform,

                      Capability::GroupNonUniformVote,

                      Capability::GroupNonUniformArithmetic,

                      Capability::GroupNonUniformBallot,

                      Capability::GroupNonUniformClustered,

                      Capability::GroupNonUniformShuffle,

                      Capability::GroupNonUniformShuffleRelative});


  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 6)))

    addAvailableCaps({Capability::DotProduct, Capability::DotProductInputAll,

                      Capability::DotProductInput4x8Bit,

                      Capability::DotProductInput4x8BitPacked,

                      Capability::DemoteToHelperInvocation});


  // Add capabilities enabled by extensions.

  for (auto Extension : ST.getAllAvailableExtensions()) {

    CapabilityList EnabledCapabilities =

        getCapabilitiesEnabledByExtension(Extension);

    addAvailableCaps(EnabledCapabilities);

  }


  if (!ST.isShader()) {

    initAvailableCapabilitiesForOpenCL(ST);

    return;

  }


  if (ST.isShader()) {

    initAvailableCapabilitiesForVulkan(ST);

    return;

  }


  report_fatal_error("Unimplemented environment for SPIR-V generation.");

}


void RequirementHandler::initAvailableCapabilitiesForOpenCL(

    const SPIRVSubtarget &ST) {

  // Add the min requirements for different OpenCL and SPIR-V versions.

  addAvailableCaps({Capability::Addresses, Capability::Float16Buffer,

                    Capability::Kernel, Capability::Vector16,

                    Capability::Groups, Capability::GenericPointer,

                    Capability::StorageImageWriteWithoutFormat,

                    Capability::StorageImageReadWithoutFormat});

  if (ST.hasOpenCLFullProfile())

    addAvailableCaps({Capability::Int64, Capability::Int64Atomics});

  if (ST.hasOpenCLImageSupport()) {

    addAvailableCaps({Capability::ImageBasic, Capability::LiteralSampler,

                      Capability::Image1D, Capability::SampledBuffer,

                      Capability::ImageBuffer});

    if (ST.isAtLeastOpenCLVer(VersionTuple(2, 0)))

      addAvailableCaps({Capability::ImageReadWrite});

  }

  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 1)) &&

      ST.isAtLeastOpenCLVer(VersionTuple(2, 2)))

    addAvailableCaps({Capability::SubgroupDispatch, Capability::PipeStorage});

  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 4)))

    addAvailableCaps({Capability::DenormPreserve, Capability::DenormFlushToZero,

                      Capability::SignedZeroInfNanPreserve,

                      Capability::RoundingModeRTE,

                      Capability::RoundingModeRTZ});

  // TODO: verify if this needs some checks.

  addAvailableCaps({Capability::Float16, Capability::Float64});


  // TODO: add OpenCL extensions.

}


void RequirementHandler::initAvailableCapabilitiesForVulkan(

    const SPIRVSubtarget &ST) {


  // Core in Vulkan 1.1 and earlier.

  addAvailableCaps({Capability::Int64, Capability::Float16, Capability::Float64,

                    Capability::GroupNonUniform, Capability::Image1D,

                    Capability::SampledBuffer, Capability::ImageBuffer,

                    Capability::UniformBufferArrayDynamicIndexing,

                    Capability::SampledImageArrayDynamicIndexing,

                    Capability::StorageBufferArrayDynamicIndexing,

                    Capability::StorageImageArrayDynamicIndexing,

                    Capability::DerivativeControl});


  // Became core in Vulkan 1.2

  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 5))) {

    addAvailableCaps(

        {Capability::ShaderNonUniformEXT, Capability::RuntimeDescriptorArrayEXT,

         Capability::InputAttachmentArrayDynamicIndexingEXT,

         Capability::UniformTexelBufferArrayDynamicIndexingEXT,

         Capability::StorageTexelBufferArrayDynamicIndexingEXT,

         Capability::UniformBufferArrayNonUniformIndexingEXT,

         Capability::SampledImageArrayNonUniformIndexingEXT,

         Capability::StorageBufferArrayNonUniformIndexingEXT,

         Capability::StorageImageArrayNonUniformIndexingEXT,

         Capability::InputAttachmentArrayNonUniformIndexingEXT,

         Capability::UniformTexelBufferArrayNonUniformIndexingEXT,

         Capability::StorageTexelBufferArrayNonUniformIndexingEXT});

  }


  // Became core in Vulkan 1.3

  if (ST.isAtLeastSPIRVVer(VersionTuple(1, 6)))

    addAvailableCaps({Capability::StorageImageWriteWithoutFormat,

                      Capability::StorageImageReadWithoutFormat});

}


} // namespace SPIRV

} // namespace llvm


// Add the required capabilities from a decoration instruction (including

// BuiltIns).

static void addOpDecorateReqs(const MachineInstr &MI, unsigned DecIndex,

                              SPIRV::RequirementHandler &Reqs,

                              const SPIRVSubtarget &ST) {

  int64_t DecOp = MI.getOperand(DecIndex).getImm();

  auto Dec = static_cast<SPIRV::Decoration::Decoration>(DecOp);

  Reqs.addRequirements(getSymbolicOperandRequirements(

      SPIRV::OperandCategory::DecorationOperand, Dec, ST, Reqs));


  if (Dec == SPIRV::Decoration::BuiltIn) {

    int64_t BuiltInOp = MI.getOperand(DecIndex + 1).getImm();

    auto BuiltIn = static_cast<SPIRV::BuiltIn::BuiltIn>(BuiltInOp);

    Reqs.addRequirements(getSymbolicOperandRequirements(

        SPIRV::OperandCategory::BuiltInOperand, BuiltIn, ST, Reqs));

  } else if (Dec == SPIRV::Decoration::LinkageAttributes) {

    int64_t LinkageOp = MI.getOperand(MI.getNumOperands() - 1).getImm();

    SPIRV::LinkageType::LinkageType LnkType =

        static_cast<SPIRV::LinkageType::LinkageType>(LinkageOp);

    if (LnkType == SPIRV::LinkageType::LinkOnceODR)

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_linkonce_odr);

  } else if (Dec == SPIRV::Decoration::CacheControlLoadINTEL ||

             Dec == SPIRV::Decoration::CacheControlStoreINTEL) {

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_cache_controls);

  } else if (Dec == SPIRV::Decoration::HostAccessINTEL) {

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_global_variable_host_access);

  } else if (Dec == SPIRV::Decoration::InitModeINTEL ||

             Dec == SPIRV::Decoration::ImplementInRegisterMapINTEL) {

    Reqs.addExtension(

        SPIRV::Extension::SPV_INTEL_global_variable_fpga_decorations);

  } else if (Dec == SPIRV::Decoration::NonUniformEXT) {

    Reqs.addRequirements(SPIRV::Capability::ShaderNonUniformEXT);

  } else if (Dec == SPIRV::Decoration::FPMaxErrorDecorationINTEL) {

    Reqs.addRequirements(SPIRV::Capability::FPMaxErrorINTEL);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_fp_max_error);

  } else if (Dec == SPIRV::Decoration::FPFastMathMode) {

    if (ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2)) {

      Reqs.addRequirements(SPIRV::Capability::FloatControls2);

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_float_controls2);

    }

  }

}


// Add requirements for image handling.

static void addOpTypeImageReqs(const MachineInstr &MI,

                               SPIRV::RequirementHandler &Reqs,

                               const SPIRVSubtarget &ST) {

  assert(MI.getNumOperands() >= 8 && "Insufficient operands for OpTypeImage");

  // The operand indices used here are based on the OpTypeImage layout, which

  // the MachineInstr follows as well.

  int64_t ImgFormatOp = MI.getOperand(7).getImm();

  auto ImgFormat = static_cast<SPIRV::ImageFormat::ImageFormat>(ImgFormatOp);

  Reqs.getAndAddRequirements(SPIRV::OperandCategory::ImageFormatOperand,

                             ImgFormat, ST);


  bool IsArrayed = MI.getOperand(4).getImm() == 1;

  bool IsMultisampled = MI.getOperand(5).getImm() == 1;

  bool NoSampler = MI.getOperand(6).getImm() == 2;

  // Add dimension requirements.

  assert(MI.getOperand(2).isImm());

  switch (MI.getOperand(2).getImm()) {

  case SPIRV::Dim::DIM_1D:

    Reqs.addRequirements(NoSampler ? SPIRV::Capability::Image1D

                                   : SPIRV::Capability::Sampled1D);

    break;

  case SPIRV::Dim::DIM_2D:

    if (IsMultisampled && NoSampler)

      Reqs.addRequirements(SPIRV::Capability::ImageMSArray);

    break;

  case SPIRV::Dim::DIM_Cube:

    Reqs.addRequirements(SPIRV::Capability::Shader);

    if (IsArrayed)

      Reqs.addRequirements(NoSampler ? SPIRV::Capability::ImageCubeArray

                                     : SPIRV::Capability::SampledCubeArray);

    break;

  case SPIRV::Dim::DIM_Rect:

    Reqs.addRequirements(NoSampler ? SPIRV::Capability::ImageRect

                                   : SPIRV::Capability::SampledRect);

    break;

  case SPIRV::Dim::DIM_Buffer:

    Reqs.addRequirements(NoSampler ? SPIRV::Capability::ImageBuffer

                                   : SPIRV::Capability::SampledBuffer);

    break;

  case SPIRV::Dim::DIM_SubpassData:

    Reqs.addRequirements(SPIRV::Capability::InputAttachment);

    break;

  }


  // Has optional access qualifier.

  if (!ST.isShader()) {

    if (MI.getNumOperands() > 8 &&

        MI.getOperand(8).getImm() == SPIRV::AccessQualifier::ReadWrite)

      Reqs.addRequirements(SPIRV::Capability::ImageReadWrite);

    else

      Reqs.addRequirements(SPIRV::Capability::ImageBasic);

  }

}


static bool isBFloat16Type(const SPIRVType *TypeDef) {

  return TypeDef && TypeDef->getNumOperands() == 3 &&

         TypeDef->getOpcode() == SPIRV::OpTypeFloat &&

         TypeDef->getOperand(1).getImm() == 16 &&

         TypeDef->getOperand(2).getImm() == SPIRV::FPEncoding::BFloat16KHR;

}


// Add requirements for handling atomic float instructions

#define ATOM_FLT_REQ_EXT_MSG(ExtName)                                          \

  "The atomic float instruction requires the following SPIR-V "                \

  "extension: SPV_EXT_shader_atomic_float" ExtName

static void AddAtomicVectorFloatRequirements(const MachineInstr &MI,

                                             SPIRV::RequirementHandler &Reqs,

                                             const SPIRVSubtarget &ST) {

  SPIRVType *VecTypeDef =

      MI.getMF()->getRegInfo().getVRegDef(MI.getOperand(1).getReg());


  const unsigned Rank = VecTypeDef->getOperand(2).getImm();

  if (Rank != 2 && Rank != 4)

    reportFatalUsageError("Result type of an atomic vector float instruction "

                          "must be a 2-component or 4 component vector");


  SPIRVType *EltTypeDef =

      MI.getMF()->getRegInfo().getVRegDef(VecTypeDef->getOperand(1).getReg());


  if (EltTypeDef->getOpcode() != SPIRV::OpTypeFloat ||

      EltTypeDef->getOperand(1).getImm() != 16)

    reportFatalUsageError(

        "The element type for the result type of an atomic vector float "

        "instruction must be a 16-bit floating-point scalar");


  if (isBFloat16Type(EltTypeDef))

    reportFatalUsageError(

        "The element type for the result type of an atomic vector float "

        "instruction cannot be a bfloat16 scalar");

  if (!ST.canUseExtension(SPIRV::Extension::SPV_NV_shader_atomic_fp16_vector))

    reportFatalUsageError(

        "The atomic float16 vector instruction requires the following SPIR-V "

        "extension: SPV_NV_shader_atomic_fp16_vector");


  Reqs.addExtension(SPIRV::Extension::SPV_NV_shader_atomic_fp16_vector);

  Reqs.addCapability(SPIRV::Capability::AtomicFloat16VectorNV);

}


static void AddAtomicFloatRequirements(const MachineInstr &MI,

                                       SPIRV::RequirementHandler &Reqs,

                                       const SPIRVSubtarget &ST) {

  assert(MI.getOperand(1).isReg() &&

         "Expect register operand in atomic float instruction");

  Register TypeReg = MI.getOperand(1).getReg();

  SPIRVType *TypeDef = MI.getMF()->getRegInfo().getVRegDef(TypeReg);


  if (TypeDef->getOpcode() == SPIRV::OpTypeVector)

    return AddAtomicVectorFloatRequirements(MI, Reqs, ST);


  if (TypeDef->getOpcode() != SPIRV::OpTypeFloat)

    report_fatal_error("Result type of an atomic float instruction must be a "

                       "floating-point type scalar");


  unsigned BitWidth = TypeDef->getOperand(1).getImm();

  unsigned Op = MI.getOpcode();

  if (Op == SPIRV::OpAtomicFAddEXT) {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_EXT_shader_atomic_float_add))

      report_fatal_error(ATOM_FLT_REQ_EXT_MSG("_add"), false);

    Reqs.addExtension(SPIRV::Extension::SPV_EXT_shader_atomic_float_add);

    switch (BitWidth) {

    case 16:

      if (isBFloat16Type(TypeDef)) {

        if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_16bit_atomics))

          report_fatal_error(

              "The atomic bfloat16 instruction requires the following SPIR-V "

              "extension: SPV_INTEL_16bit_atomics",

              false);

        Reqs.addExtension(SPIRV::Extension::SPV_INTEL_16bit_atomics);

        Reqs.addCapability(SPIRV::Capability::AtomicBFloat16AddINTEL);

      } else {

        if (!ST.canUseExtension(

                SPIRV::Extension::SPV_EXT_shader_atomic_float16_add))

          report_fatal_error(ATOM_FLT_REQ_EXT_MSG("16_add"), false);

        Reqs.addExtension(SPIRV::Extension::SPV_EXT_shader_atomic_float16_add);

        Reqs.addCapability(SPIRV::Capability::AtomicFloat16AddEXT);

      }

      break;

    case 32:

      Reqs.addCapability(SPIRV::Capability::AtomicFloat32AddEXT);

      break;

    case 64:

      Reqs.addCapability(SPIRV::Capability::AtomicFloat64AddEXT);

      break;

    default:

      report_fatal_error(

          "Unexpected floating-point type width in atomic float instruction");

    }

  } else {

    if (!ST.canUseExtension(

            SPIRV::Extension::SPV_EXT_shader_atomic_float_min_max))

      report_fatal_error(ATOM_FLT_REQ_EXT_MSG("_min_max"), false);

    Reqs.addExtension(SPIRV::Extension::SPV_EXT_shader_atomic_float_min_max);

    switch (BitWidth) {

    case 16:

      if (isBFloat16Type(TypeDef)) {

        if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_16bit_atomics))

          report_fatal_error(

              "The atomic bfloat16 instruction requires the following SPIR-V "

              "extension: SPV_INTEL_16bit_atomics",

              false);

        Reqs.addExtension(SPIRV::Extension::SPV_INTEL_16bit_atomics);

        Reqs.addCapability(SPIRV::Capability::AtomicBFloat16MinMaxINTEL);

      } else {

        Reqs.addCapability(SPIRV::Capability::AtomicFloat16MinMaxEXT);

      }

      break;

    case 32:

      Reqs.addCapability(SPIRV::Capability::AtomicFloat32MinMaxEXT);

      break;

    case 64:

      Reqs.addCapability(SPIRV::Capability::AtomicFloat64MinMaxEXT);

      break;

    default:

      report_fatal_error(

          "Unexpected floating-point type width in atomic float instruction");

    }

  }

}


bool isUniformTexelBuffer(MachineInstr *ImageInst) {

  if (ImageInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  uint32_t Dim = ImageInst->getOperand(2).getImm();

  uint32_t Sampled = ImageInst->getOperand(6).getImm();

  return Dim == SPIRV::Dim::DIM_Buffer && Sampled == 1;

}


bool isStorageTexelBuffer(MachineInstr *ImageInst) {

  if (ImageInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  uint32_t Dim = ImageInst->getOperand(2).getImm();

  uint32_t Sampled = ImageInst->getOperand(6).getImm();

  return Dim == SPIRV::Dim::DIM_Buffer && Sampled == 2;

}


bool isSampledImage(MachineInstr *ImageInst) {

  if (ImageInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  uint32_t Dim = ImageInst->getOperand(2).getImm();

  uint32_t Sampled = ImageInst->getOperand(6).getImm();

  return Dim != SPIRV::Dim::DIM_Buffer && Sampled == 1;

}


bool isInputAttachment(MachineInstr *ImageInst) {

  if (ImageInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  uint32_t Dim = ImageInst->getOperand(2).getImm();

  uint32_t Sampled = ImageInst->getOperand(6).getImm();

  return Dim == SPIRV::Dim::DIM_SubpassData && Sampled == 2;

}


bool isStorageImage(MachineInstr *ImageInst) {

  if (ImageInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  uint32_t Dim = ImageInst->getOperand(2).getImm();

  uint32_t Sampled = ImageInst->getOperand(6).getImm();

  return Dim != SPIRV::Dim::DIM_Buffer && Sampled == 2;

}


bool isCombinedImageSampler(MachineInstr *SampledImageInst) {

  if (SampledImageInst->getOpcode() != SPIRV::OpTypeSampledImage)

    return false;


  const MachineRegisterInfo &MRI = SampledImageInst->getMF()->getRegInfo();

  Register ImageReg = SampledImageInst->getOperand(1).getReg();

  auto *ImageInst = MRI.getUniqueVRegDef(ImageReg);

  return isSampledImage(ImageInst);

}


bool hasNonUniformDecoration(Register Reg, const MachineRegisterInfo &MRI) {

  for (const auto &MI : MRI.reg_instructions(Reg)) {

    if (MI.getOpcode() != SPIRV::OpDecorate)

      continue;


    uint32_t Dec = MI.getOperand(1).getImm();

    if (Dec == SPIRV::Decoration::NonUniformEXT)

      return true;

  }

  return false;

}


void addOpAccessChainReqs(const MachineInstr &Instr,

                          SPIRV::RequirementHandler &Handler,

                          const SPIRVSubtarget &Subtarget) {

  const MachineRegisterInfo &MRI = Instr.getMF()->getRegInfo();

  // Get the result type. If it is an image type, then the shader uses

  // descriptor indexing. The appropriate capabilities will be added based

  // on the specifics of the image.

  Register ResTypeReg = Instr.getOperand(1).getReg();

  MachineInstr *ResTypeInst = MRI.getUniqueVRegDef(ResTypeReg);


  assert(ResTypeInst->getOpcode() == SPIRV::OpTypePointer);

  uint32_t StorageClass = ResTypeInst->getOperand(1).getImm();

  if (StorageClass != SPIRV::StorageClass::StorageClass::UniformConstant &&

      StorageClass != SPIRV::StorageClass::StorageClass::Uniform &&

      StorageClass != SPIRV::StorageClass::StorageClass::StorageBuffer) {

    return;

  }


  bool IsNonUniform =

      hasNonUniformDecoration(Instr.getOperand(0).getReg(), MRI);


  auto FirstIndexReg = Instr.getOperand(3).getReg();

  bool FirstIndexIsConstant =

      Subtarget.getInstrInfo()->isConstantInstr(*MRI.getVRegDef(FirstIndexReg));


  if (StorageClass == SPIRV::StorageClass::StorageClass::StorageBuffer) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::StorageBufferArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::StorageBufferArrayDynamicIndexing);

    return;

  }


  Register PointeeTypeReg = ResTypeInst->getOperand(2).getReg();

  MachineInstr *PointeeType = MRI.getUniqueVRegDef(PointeeTypeReg);

  if (PointeeType->getOpcode() != SPIRV::OpTypeImage &&

      PointeeType->getOpcode() != SPIRV::OpTypeSampledImage &&

      PointeeType->getOpcode() != SPIRV::OpTypeSampler) {

    return;

  }


  if (isUniformTexelBuffer(PointeeType)) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::UniformTexelBufferArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::UniformTexelBufferArrayDynamicIndexingEXT);

  } else if (isInputAttachment(PointeeType)) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::InputAttachmentArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::InputAttachmentArrayDynamicIndexingEXT);

  } else if (isStorageTexelBuffer(PointeeType)) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::StorageTexelBufferArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::StorageTexelBufferArrayDynamicIndexingEXT);

  } else if (isSampledImage(PointeeType) ||

             isCombinedImageSampler(PointeeType) ||

             PointeeType->getOpcode() == SPIRV::OpTypeSampler) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::SampledImageArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::SampledImageArrayDynamicIndexing);

  } else if (isStorageImage(PointeeType)) {

    if (IsNonUniform)

      Handler.addRequirements(

          SPIRV::Capability::StorageImageArrayNonUniformIndexingEXT);

    else if (!FirstIndexIsConstant)

      Handler.addRequirements(

          SPIRV::Capability::StorageImageArrayDynamicIndexing);

  }

}


static bool isImageTypeWithUnknownFormat(SPIRVType *TypeInst) {

  if (TypeInst->getOpcode() != SPIRV::OpTypeImage)

    return false;

  assert(TypeInst->getOperand(7).isImm() && "The image format must be an imm.");

  return TypeInst->getOperand(7).getImm() == 0;

}


static void AddDotProductRequirements(const MachineInstr &MI,

                                      SPIRV::RequirementHandler &Reqs,

                                      const SPIRVSubtarget &ST) {

  if (ST.canUseExtension(SPIRV::Extension::SPV_KHR_integer_dot_product))

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_integer_dot_product);

  Reqs.addCapability(SPIRV::Capability::DotProduct);


  const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

  assert(MI.getOperand(2).isReg() && "Unexpected operand in dot");

  // We do not consider what the previous instruction is. This is just used

  // to get the input register and to check the type.

  const MachineInstr *Input = MRI.getVRegDef(MI.getOperand(2).getReg());

  assert(Input->getOperand(1).isReg() && "Unexpected operand in dot input");

  Register InputReg = Input->getOperand(1).getReg();


  SPIRVType *TypeDef = MRI.getVRegDef(InputReg);

  if (TypeDef->getOpcode() == SPIRV::OpTypeInt) {

    assert(TypeDef->getOperand(1).getImm() == 32);

    Reqs.addCapability(SPIRV::Capability::DotProductInput4x8BitPacked);

  } else if (TypeDef->getOpcode() == SPIRV::OpTypeVector) {

    SPIRVType *ScalarTypeDef = MRI.getVRegDef(TypeDef->getOperand(1).getReg());

    assert(ScalarTypeDef->getOpcode() == SPIRV::OpTypeInt);

    if (ScalarTypeDef->getOperand(1).getImm() == 8) {

      assert(TypeDef->getOperand(2).getImm() == 4 &&

             "Dot operand of 8-bit integer type requires 4 components");

      Reqs.addCapability(SPIRV::Capability::DotProductInput4x8Bit);

    } else {

      Reqs.addCapability(SPIRV::Capability::DotProductInputAll);

    }

  }

}


void addPrintfRequirements(const MachineInstr &MI,

                           SPIRV::RequirementHandler &Reqs,

                           const SPIRVSubtarget &ST) {

  SPIRVGlobalRegistry *GR = ST.getSPIRVGlobalRegistry();

  const SPIRVType *PtrType = GR->getSPIRVTypeForVReg(MI.getOperand(4).getReg());

  if (PtrType) {

    MachineOperand ASOp = PtrType->getOperand(1);

    if (ASOp.isImm()) {

      unsigned AddrSpace = ASOp.getImm();

      if (AddrSpace != SPIRV::StorageClass::UniformConstant) {

        if (!ST.canUseExtension(

                SPIRV::Extension::

                    SPV_EXT_relaxed_printf_string_address_space)) {

          report_fatal_error("SPV_EXT_relaxed_printf_string_address_space is "

                             "required because printf uses a format string not "

                             "in constant address space.",

                             false);

        }

        Reqs.addExtension(

            SPIRV::Extension::SPV_EXT_relaxed_printf_string_address_space);

      }

    }

  }

}


void addInstrRequirements(const MachineInstr &MI,

                          SPIRV::ModuleAnalysisInfo &MAI,

                          const SPIRVSubtarget &ST) {

  SPIRV::RequirementHandler &Reqs = MAI.Reqs;

  switch (MI.getOpcode()) {

  case SPIRV::OpMemoryModel: {

    int64_t Addr = MI.getOperand(0).getImm();

    Reqs.getAndAddRequirements(SPIRV::OperandCategory::AddressingModelOperand,

                               Addr, ST);

    int64_t Mem = MI.getOperand(1).getImm();

    Reqs.getAndAddRequirements(SPIRV::OperandCategory::MemoryModelOperand, Mem,

                               ST);

    break;

  }

  case SPIRV::OpEntryPoint: {

    int64_t Exe = MI.getOperand(0).getImm();

    Reqs.getAndAddRequirements(SPIRV::OperandCategory::ExecutionModelOperand,

                               Exe, ST);

    break;

  }

  case SPIRV::OpExecutionMode:

  case SPIRV::OpExecutionModeId: {

    int64_t Exe = MI.getOperand(1).getImm();

    Reqs.getAndAddRequirements(SPIRV::OperandCategory::ExecutionModeOperand,

                               Exe, ST);

    break;

  }

  case SPIRV::OpTypeMatrix:

    Reqs.addCapability(SPIRV::Capability::Matrix);

    break;

  case SPIRV::OpTypeInt: {

    unsigned BitWidth = MI.getOperand(1).getImm();

    if (BitWidth == 64)

      Reqs.addCapability(SPIRV::Capability::Int64);

    else if (BitWidth == 16)

      Reqs.addCapability(SPIRV::Capability::Int16);

    else if (BitWidth == 8)

      Reqs.addCapability(SPIRV::Capability::Int8);

    else if (BitWidth == 4 &&

             ST.canUseExtension(SPIRV::Extension::SPV_INTEL_int4)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_int4);

      Reqs.addCapability(SPIRV::Capability::Int4TypeINTEL);

    } else if (BitWidth != 32) {

      if (!ST.canUseExtension(

              SPIRV::Extension::SPV_ALTERA_arbitrary_precision_integers))

        reportFatalUsageError(

            "OpTypeInt type with a width other than 8, 16, 32 or 64 bits "

            "requires the following SPIR-V extension: "

            "SPV_ALTERA_arbitrary_precision_integers");

      Reqs.addExtension(

          SPIRV::Extension::SPV_ALTERA_arbitrary_precision_integers);

      Reqs.addCapability(SPIRV::Capability::ArbitraryPrecisionIntegersALTERA);

    }

    break;

  }

  case SPIRV::OpDot: {

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    SPIRVType *TypeDef = MRI.getVRegDef(MI.getOperand(1).getReg());

    if (isBFloat16Type(TypeDef))

      Reqs.addCapability(SPIRV::Capability::BFloat16DotProductKHR);

    break;

  }

  case SPIRV::OpTypeFloat: {

    unsigned BitWidth = MI.getOperand(1).getImm();

    if (BitWidth == 64)

      Reqs.addCapability(SPIRV::Capability::Float64);

    else if (BitWidth == 16) {

      if (isBFloat16Type(&MI)) {

        if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_bfloat16))

          report_fatal_error("OpTypeFloat type with bfloat requires the "

                             "following SPIR-V extension: SPV_KHR_bfloat16",

                             false);

        Reqs.addExtension(SPIRV::Extension::SPV_KHR_bfloat16);

        Reqs.addCapability(SPIRV::Capability::BFloat16TypeKHR);

      } else {

        Reqs.addCapability(SPIRV::Capability::Float16);

      }

    }

    break;

  }

  case SPIRV::OpTypeVector: {

    unsigned NumComponents = MI.getOperand(2).getImm();

    if (NumComponents == 8 || NumComponents == 16)

      Reqs.addCapability(SPIRV::Capability::Vector16);

    break;

  }

  case SPIRV::OpTypePointer: {

    auto SC = MI.getOperand(1).getImm();

    Reqs.getAndAddRequirements(SPIRV::OperandCategory::StorageClassOperand, SC,

                               ST);

    // If it's a type of pointer to float16 targeting OpenCL, add Float16Buffer

    // capability.

    if (ST.isShader())

      break;

    assert(MI.getOperand(2).isReg());

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    SPIRVType *TypeDef = MRI.getVRegDef(MI.getOperand(2).getReg());

    if ((TypeDef->getNumOperands() == 2) &&

        (TypeDef->getOpcode() == SPIRV::OpTypeFloat) &&

        (TypeDef->getOperand(1).getImm() == 16))

      Reqs.addCapability(SPIRV::Capability::Float16Buffer);

    break;

  }

  case SPIRV::OpExtInst: {

    if (MI.getOperand(2).getImm() ==

        static_cast<int64_t>(

            SPIRV::InstructionSet::NonSemantic_Shader_DebugInfo_100)) {

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_non_semantic_info);

      break;

    }

    if (MI.getOperand(3).getImm() ==

        static_cast<int64_t>(SPIRV::OpenCLExtInst::printf)) {

      addPrintfRequirements(MI, Reqs, ST);

      break;

    }

    // TODO: handle bfloat16 extended instructions when

    // SPV_INTEL_bfloat16_arithmetic is enabled.

    break;

  }

  case SPIRV::OpAliasDomainDeclINTEL:

  case SPIRV::OpAliasScopeDeclINTEL:

  case SPIRV::OpAliasScopeListDeclINTEL: {

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_memory_access_aliasing);

    Reqs.addCapability(SPIRV::Capability::MemoryAccessAliasingINTEL);

    break;

  }

  case SPIRV::OpBitReverse:

  case SPIRV::OpBitFieldInsert:

  case SPIRV::OpBitFieldSExtract:

  case SPIRV::OpBitFieldUExtract:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_bit_instructions)) {

      Reqs.addCapability(SPIRV::Capability::Shader);

      break;

    }

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_bit_instructions);

    Reqs.addCapability(SPIRV::Capability::BitInstructions);

    break;

  case SPIRV::OpTypeRuntimeArray:

    Reqs.addCapability(SPIRV::Capability::Shader);

    break;

  case SPIRV::OpTypeOpaque:

  case SPIRV::OpTypeEvent:

    Reqs.addCapability(SPIRV::Capability::Kernel);

    break;

  case SPIRV::OpTypePipe:

  case SPIRV::OpTypeReserveId:

    Reqs.addCapability(SPIRV::Capability::Pipes);

    break;

  case SPIRV::OpTypeDeviceEvent:

  case SPIRV::OpTypeQueue:

  case SPIRV::OpBuildNDRange:

    Reqs.addCapability(SPIRV::Capability::DeviceEnqueue);

    break;

  case SPIRV::OpDecorate:

  case SPIRV::OpDecorateId:

  case SPIRV::OpDecorateString:

    addOpDecorateReqs(MI, 1, Reqs, ST);

    break;

  case SPIRV::OpMemberDecorate:

  case SPIRV::OpMemberDecorateString:

    addOpDecorateReqs(MI, 2, Reqs, ST);

    break;

  case SPIRV::OpInBoundsPtrAccessChain:

    Reqs.addCapability(SPIRV::Capability::Addresses);

    break;

  case SPIRV::OpConstantSampler:

    Reqs.addCapability(SPIRV::Capability::LiteralSampler);

    break;

  case SPIRV::OpInBoundsAccessChain:

  case SPIRV::OpAccessChain:

    addOpAccessChainReqs(MI, Reqs, ST);

    break;

  case SPIRV::OpTypeImage:

    addOpTypeImageReqs(MI, Reqs, ST);

    break;

  case SPIRV::OpTypeSampler:

    if (!ST.isShader()) {

      Reqs.addCapability(SPIRV::Capability::ImageBasic);

    }

    break;

  case SPIRV::OpTypeForwardPointer:

    // TODO: check if it's OpenCL's kernel.

    Reqs.addCapability(SPIRV::Capability::Addresses);

    break;

  case SPIRV::OpAtomicFlagTestAndSet:

  case SPIRV::OpAtomicLoad:

  case SPIRV::OpAtomicStore:

  case SPIRV::OpAtomicExchange:

  case SPIRV::OpAtomicCompareExchange:

  case SPIRV::OpAtomicIIncrement:

  case SPIRV::OpAtomicIDecrement:

  case SPIRV::OpAtomicIAdd:

  case SPIRV::OpAtomicISub:

  case SPIRV::OpAtomicUMin:

  case SPIRV::OpAtomicUMax:

  case SPIRV::OpAtomicSMin:

  case SPIRV::OpAtomicSMax:

  case SPIRV::OpAtomicAnd:

  case SPIRV::OpAtomicOr:

  case SPIRV::OpAtomicXor: {

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    const MachineInstr *InstrPtr = &MI;

    if (MI.getOpcode() == SPIRV::OpAtomicStore) {

      assert(MI.getOperand(3).isReg());

      InstrPtr = MRI.getVRegDef(MI.getOperand(3).getReg());

      assert(InstrPtr && "Unexpected type instruction for OpAtomicStore");

    }

    assert(InstrPtr->getOperand(1).isReg() && "Unexpected operand in atomic");

    Register TypeReg = InstrPtr->getOperand(1).getReg();

    SPIRVType *TypeDef = MRI.getVRegDef(TypeReg);

    if (TypeDef->getOpcode() == SPIRV::OpTypeInt) {

      unsigned BitWidth = TypeDef->getOperand(1).getImm();

      if (BitWidth == 64)

        Reqs.addCapability(SPIRV::Capability::Int64Atomics);

    }

    break;

  }

  case SPIRV::OpGroupNonUniformIAdd:

  case SPIRV::OpGroupNonUniformFAdd:

  case SPIRV::OpGroupNonUniformIMul:

  case SPIRV::OpGroupNonUniformFMul:

  case SPIRV::OpGroupNonUniformSMin:

  case SPIRV::OpGroupNonUniformUMin:

  case SPIRV::OpGroupNonUniformFMin:

  case SPIRV::OpGroupNonUniformSMax:

  case SPIRV::OpGroupNonUniformUMax:

  case SPIRV::OpGroupNonUniformFMax:

  case SPIRV::OpGroupNonUniformBitwiseAnd:

  case SPIRV::OpGroupNonUniformBitwiseOr:

  case SPIRV::OpGroupNonUniformBitwiseXor:

  case SPIRV::OpGroupNonUniformLogicalAnd:

  case SPIRV::OpGroupNonUniformLogicalOr:

  case SPIRV::OpGroupNonUniformLogicalXor: {

    assert(MI.getOperand(3).isImm());

    int64_t GroupOp = MI.getOperand(3).getImm();

    switch (GroupOp) {

    case SPIRV::GroupOperation::Reduce:

    case SPIRV::GroupOperation::InclusiveScan:

    case SPIRV::GroupOperation::ExclusiveScan:

      Reqs.addCapability(SPIRV::Capability::GroupNonUniformArithmetic);

      break;

    case SPIRV::GroupOperation::ClusteredReduce:

      Reqs.addCapability(SPIRV::Capability::GroupNonUniformClustered);

      break;

    case SPIRV::GroupOperation::PartitionedReduceNV:

    case SPIRV::GroupOperation::PartitionedInclusiveScanNV:

    case SPIRV::GroupOperation::PartitionedExclusiveScanNV:

      Reqs.addCapability(SPIRV::Capability::GroupNonUniformPartitionedNV);

      break;

    }

    break;

  }

  case SPIRV::OpImageQueryFormat: {

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

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    static const unsigned CompareOps[] = {

        SPIRV::OpIEqual,       SPIRV::OpINotEqual,

        SPIRV::OpUGreaterThan, SPIRV::OpUGreaterThanEqual,

        SPIRV::OpULessThan,    SPIRV::OpULessThanEqual,

        SPIRV::OpSGreaterThan, SPIRV::OpSGreaterThanEqual,

        SPIRV::OpSLessThan,    SPIRV::OpSLessThanEqual};


    auto CheckAndAddExtension = [&](int64_t ImmVal) {

      if (ImmVal == 4323 || ImmVal == 4324) {

        if (ST.canUseExtension(SPIRV::Extension::SPV_EXT_image_raw10_raw12))

          Reqs.addExtension(SPIRV::Extension::SPV_EXT_image_raw10_raw12);

        else

          report_fatal_error("This requires the "

                             "SPV_EXT_image_raw10_raw12 extension");

      }

    };


    for (MachineInstr &UseInst : MRI.use_instructions(ResultReg)) {

      unsigned Opc = UseInst.getOpcode();


      if (Opc == SPIRV::OpSwitch) {

        for (const MachineOperand &Op : UseInst.operands())

          if (Op.isImm())

            CheckAndAddExtension(Op.getImm());

      } else if (llvm::is_contained(CompareOps, Opc)) {

        for (unsigned i = 1; i < UseInst.getNumOperands(); ++i) {

          Register UseReg = UseInst.getOperand(i).getReg();

          MachineInstr *ConstInst = MRI.getVRegDef(UseReg);

          if (ConstInst && ConstInst->getOpcode() == SPIRV::OpConstantI) {

            int64_t ImmVal = ConstInst->getOperand(2).getImm();

            if (ImmVal)

              CheckAndAddExtension(ImmVal);

          }

        }

      }

    }

    break;

  }


  case SPIRV::OpGroupNonUniformShuffle:

  case SPIRV::OpGroupNonUniformShuffleXor:

    Reqs.addCapability(SPIRV::Capability::GroupNonUniformShuffle);

    break;

  case SPIRV::OpGroupNonUniformShuffleUp:

  case SPIRV::OpGroupNonUniformShuffleDown:

    Reqs.addCapability(SPIRV::Capability::GroupNonUniformShuffleRelative);

    break;

  case SPIRV::OpGroupAll:

  case SPIRV::OpGroupAny:

  case SPIRV::OpGroupBroadcast:

  case SPIRV::OpGroupIAdd:

  case SPIRV::OpGroupFAdd:

  case SPIRV::OpGroupFMin:

  case SPIRV::OpGroupUMin:

  case SPIRV::OpGroupSMin:

  case SPIRV::OpGroupFMax:

  case SPIRV::OpGroupUMax:

  case SPIRV::OpGroupSMax:

    Reqs.addCapability(SPIRV::Capability::Groups);

    break;

  case SPIRV::OpGroupNonUniformElect:

    Reqs.addCapability(SPIRV::Capability::GroupNonUniform);

    break;

  case SPIRV::OpGroupNonUniformAll:

  case SPIRV::OpGroupNonUniformAny:

  case SPIRV::OpGroupNonUniformAllEqual:

    Reqs.addCapability(SPIRV::Capability::GroupNonUniformVote);

    break;

  case SPIRV::OpGroupNonUniformBroadcast:

  case SPIRV::OpGroupNonUniformBroadcastFirst:

  case SPIRV::OpGroupNonUniformBallot:

  case SPIRV::OpGroupNonUniformInverseBallot:

  case SPIRV::OpGroupNonUniformBallotBitExtract:

  case SPIRV::OpGroupNonUniformBallotBitCount:

  case SPIRV::OpGroupNonUniformBallotFindLSB:

  case SPIRV::OpGroupNonUniformBallotFindMSB:

    Reqs.addCapability(SPIRV::Capability::GroupNonUniformBallot);

    break;

  case SPIRV::OpSubgroupShuffleINTEL:

  case SPIRV::OpSubgroupShuffleDownINTEL:

  case SPIRV::OpSubgroupShuffleUpINTEL:

  case SPIRV::OpSubgroupShuffleXorINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_subgroups)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_subgroups);

      Reqs.addCapability(SPIRV::Capability::SubgroupShuffleINTEL);

    }

    break;

  case SPIRV::OpSubgroupBlockReadINTEL:

  case SPIRV::OpSubgroupBlockWriteINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_subgroups)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_subgroups);

      Reqs.addCapability(SPIRV::Capability::SubgroupBufferBlockIOINTEL);

    }

    break;

  case SPIRV::OpSubgroupImageBlockReadINTEL:

  case SPIRV::OpSubgroupImageBlockWriteINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_subgroups)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_subgroups);

      Reqs.addCapability(SPIRV::Capability::SubgroupImageBlockIOINTEL);

    }

    break;

  case SPIRV::OpSubgroupImageMediaBlockReadINTEL:

  case SPIRV::OpSubgroupImageMediaBlockWriteINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_media_block_io)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_media_block_io);

      Reqs.addCapability(SPIRV::Capability::SubgroupImageMediaBlockIOINTEL);

    }

    break;

  case SPIRV::OpAssumeTrueKHR:

  case SPIRV::OpExpectKHR:

    if (ST.canUseExtension(SPIRV::Extension::SPV_KHR_expect_assume)) {

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_expect_assume);

      Reqs.addCapability(SPIRV::Capability::ExpectAssumeKHR);

    }

    break;

  case SPIRV::OpFmaKHR:

    if (ST.canUseExtension(SPIRV::Extension::SPV_KHR_fma)) {

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_fma);

      Reqs.addCapability(SPIRV::Capability::FmaKHR);

    }

    break;

  case SPIRV::OpPtrCastToCrossWorkgroupINTEL:

  case SPIRV::OpCrossWorkgroupCastToPtrINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_usm_storage_classes)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_usm_storage_classes);

      Reqs.addCapability(SPIRV::Capability::USMStorageClassesINTEL);

    }

    break;

  case SPIRV::OpConstantFunctionPointerINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_function_pointers)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_function_pointers);

      Reqs.addCapability(SPIRV::Capability::FunctionPointersINTEL);

    }

    break;

  case SPIRV::OpGroupNonUniformRotateKHR:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_subgroup_rotate))

      report_fatal_error("OpGroupNonUniformRotateKHR instruction requires the "

                         "following SPIR-V extension: SPV_KHR_subgroup_rotate",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_subgroup_rotate);

    Reqs.addCapability(SPIRV::Capability::GroupNonUniformRotateKHR);

    Reqs.addCapability(SPIRV::Capability::GroupNonUniform);

    break;

  case SPIRV::OpFixedCosALTERA:

  case SPIRV::OpFixedSinALTERA:

  case SPIRV::OpFixedCosPiALTERA:

  case SPIRV::OpFixedSinPiALTERA:

  case SPIRV::OpFixedExpALTERA:

  case SPIRV::OpFixedLogALTERA:

  case SPIRV::OpFixedRecipALTERA:

  case SPIRV::OpFixedSqrtALTERA:

  case SPIRV::OpFixedSinCosALTERA:

  case SPIRV::OpFixedSinCosPiALTERA:

  case SPIRV::OpFixedRsqrtALTERA:

    if (!ST.canUseExtension(

            SPIRV::Extension::SPV_ALTERA_arbitrary_precision_fixed_point))

      report_fatal_error("This instruction requires the "

                         "following SPIR-V extension: "

                         "SPV_ALTERA_arbitrary_precision_fixed_point",

                         false);

    Reqs.addExtension(

        SPIRV::Extension::SPV_ALTERA_arbitrary_precision_fixed_point);

    Reqs.addCapability(SPIRV::Capability::ArbitraryPrecisionFixedPointALTERA);

    break;

  case SPIRV::OpGroupIMulKHR:

  case SPIRV::OpGroupFMulKHR:

  case SPIRV::OpGroupBitwiseAndKHR:

  case SPIRV::OpGroupBitwiseOrKHR:

  case SPIRV::OpGroupBitwiseXorKHR:

  case SPIRV::OpGroupLogicalAndKHR:

  case SPIRV::OpGroupLogicalOrKHR:

  case SPIRV::OpGroupLogicalXorKHR:

    if (ST.canUseExtension(

            SPIRV::Extension::SPV_KHR_uniform_group_instructions)) {

      Reqs.addExtension(SPIRV::Extension::SPV_KHR_uniform_group_instructions);

      Reqs.addCapability(SPIRV::Capability::GroupUniformArithmeticKHR);

    }

    break;

  case SPIRV::OpReadClockKHR:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_shader_clock))

      report_fatal_error("OpReadClockKHR instruction requires the "

                         "following SPIR-V extension: SPV_KHR_shader_clock",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_shader_clock);

    Reqs.addCapability(SPIRV::Capability::ShaderClockKHR);

    break;

  case SPIRV::OpFunctionPointerCallINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_function_pointers)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_function_pointers);

      Reqs.addCapability(SPIRV::Capability::FunctionPointersINTEL);

    }

    break;

  case SPIRV::OpAtomicFAddEXT:

  case SPIRV::OpAtomicFMinEXT:

  case SPIRV::OpAtomicFMaxEXT:

    AddAtomicFloatRequirements(MI, Reqs, ST);

    break;

  case SPIRV::OpConvertBF16ToFINTEL:

  case SPIRV::OpConvertFToBF16INTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_bfloat16_conversion)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_bfloat16_conversion);

      Reqs.addCapability(SPIRV::Capability::BFloat16ConversionINTEL);

    }

    break;

  case SPIRV::OpRoundFToTF32INTEL:

    if (ST.canUseExtension(

            SPIRV::Extension::SPV_INTEL_tensor_float32_conversion)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_tensor_float32_conversion);

      Reqs.addCapability(SPIRV::Capability::TensorFloat32RoundingINTEL);

    }

    break;

  case SPIRV::OpVariableLengthArrayINTEL:

  case SPIRV::OpSaveMemoryINTEL:

  case SPIRV::OpRestoreMemoryINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_variable_length_array)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_variable_length_array);

      Reqs.addCapability(SPIRV::Capability::VariableLengthArrayINTEL);

    }

    break;

  case SPIRV::OpAsmTargetINTEL:

  case SPIRV::OpAsmINTEL:

  case SPIRV::OpAsmCallINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_inline_assembly)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_inline_assembly);

      Reqs.addCapability(SPIRV::Capability::AsmINTEL);

    }

    break;

  case SPIRV::OpTypeCooperativeMatrixKHR: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix))

      report_fatal_error(

          "OpTypeCooperativeMatrixKHR type requires the "

          "following SPIR-V extension: SPV_KHR_cooperative_matrix",

          false);

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix);

    Reqs.addCapability(SPIRV::Capability::CooperativeMatrixKHR);

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    SPIRVType *TypeDef = MRI.getVRegDef(MI.getOperand(1).getReg());

    if (isBFloat16Type(TypeDef))

      Reqs.addCapability(SPIRV::Capability::BFloat16CooperativeMatrixKHR);

    break;

  }

  case SPIRV::OpArithmeticFenceEXT:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_EXT_arithmetic_fence))

      report_fatal_error("OpArithmeticFenceEXT requires the "

                         "following SPIR-V extension: SPV_EXT_arithmetic_fence",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_EXT_arithmetic_fence);

    Reqs.addCapability(SPIRV::Capability::ArithmeticFenceEXT);

    break;

  case SPIRV::OpControlBarrierArriveINTEL:

  case SPIRV::OpControlBarrierWaitINTEL:

    if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_split_barrier)) {

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_split_barrier);

      Reqs.addCapability(SPIRV::Capability::SplitBarrierINTEL);

    }

    break;

  case SPIRV::OpCooperativeMatrixMulAddKHR: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix))

      report_fatal_error("Cooperative matrix instructions require the "

                         "following SPIR-V extension: "

                         "SPV_KHR_cooperative_matrix",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix);

    Reqs.addCapability(SPIRV::Capability::CooperativeMatrixKHR);

    constexpr unsigned MulAddMaxSize = 6;

    if (MI.getNumOperands() != MulAddMaxSize)

      break;

    const int64_t CoopOperands = MI.getOperand(MulAddMaxSize - 1).getImm();

    if (CoopOperands &

        SPIRV::CooperativeMatrixOperands::MatrixAAndBTF32ComponentsINTEL) {

      if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix))

        report_fatal_error("MatrixAAndBTF32ComponentsINTEL type interpretation "

                           "require the following SPIR-V extension: "

                           "SPV_INTEL_joint_matrix",

                           false);

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

      Reqs.addCapability(

          SPIRV::Capability::CooperativeMatrixTF32ComponentTypeINTEL);

    }

    if (CoopOperands & SPIRV::CooperativeMatrixOperands::

                           MatrixAAndBBFloat16ComponentsINTEL ||

        CoopOperands &

            SPIRV::CooperativeMatrixOperands::MatrixCBFloat16ComponentsINTEL ||

        CoopOperands & SPIRV::CooperativeMatrixOperands::

                           MatrixResultBFloat16ComponentsINTEL) {

      if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix))

        report_fatal_error("***BF16ComponentsINTEL type interpretations "

                           "require the following SPIR-V extension: "

                           "SPV_INTEL_joint_matrix",

                           false);

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

      Reqs.addCapability(

          SPIRV::Capability::CooperativeMatrixBFloat16ComponentTypeINTEL);

    }

    break;

  }

  case SPIRV::OpCooperativeMatrixLoadKHR:

  case SPIRV::OpCooperativeMatrixStoreKHR:

  case SPIRV::OpCooperativeMatrixLoadCheckedINTEL:

  case SPIRV::OpCooperativeMatrixStoreCheckedINTEL:

  case SPIRV::OpCooperativeMatrixPrefetchINTEL: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix))

      report_fatal_error("Cooperative matrix instructions require the "

                         "following SPIR-V extension: "

                         "SPV_KHR_cooperative_matrix",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_KHR_cooperative_matrix);

    Reqs.addCapability(SPIRV::Capability::CooperativeMatrixKHR);


    // Check Layout operand in case if it's not a standard one and add the

    // appropriate capability.

    std::unordered_map<unsigned, unsigned> LayoutToInstMap = {

        {SPIRV::OpCooperativeMatrixLoadKHR, 3},

        {SPIRV::OpCooperativeMatrixStoreKHR, 2},

        {SPIRV::OpCooperativeMatrixLoadCheckedINTEL, 5},

        {SPIRV::OpCooperativeMatrixStoreCheckedINTEL, 4},

        {SPIRV::OpCooperativeMatrixPrefetchINTEL, 4}};


    const auto OpCode = MI.getOpcode();

    const unsigned LayoutNum = LayoutToInstMap[OpCode];

    Register RegLayout = MI.getOperand(LayoutNum).getReg();

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    MachineInstr *MILayout = MRI.getUniqueVRegDef(RegLayout);

    if (MILayout->getOpcode() == SPIRV::OpConstantI) {

      const unsigned LayoutVal = MILayout->getOperand(2).getImm();

      if (LayoutVal ==

          static_cast<unsigned>(SPIRV::CooperativeMatrixLayout::PackedINTEL)) {

        if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix))

          report_fatal_error("PackedINTEL layout require the following SPIR-V "

                             "extension: SPV_INTEL_joint_matrix",

                             false);

        Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

        Reqs.addCapability(SPIRV::Capability::PackedCooperativeMatrixINTEL);

      }

    }


    // Nothing to do.

    if (OpCode == SPIRV::OpCooperativeMatrixLoadKHR ||

        OpCode == SPIRV::OpCooperativeMatrixStoreKHR)

      break;


    std::string InstName;

    switch (OpCode) {

    case SPIRV::OpCooperativeMatrixPrefetchINTEL:

      InstName = "OpCooperativeMatrixPrefetchINTEL";

      break;

    case SPIRV::OpCooperativeMatrixLoadCheckedINTEL:

      InstName = "OpCooperativeMatrixLoadCheckedINTEL";

      break;

    case SPIRV::OpCooperativeMatrixStoreCheckedINTEL:

      InstName = "OpCooperativeMatrixStoreCheckedINTEL";

      break;

    }


    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix)) {

      const std::string ErrorMsg =

          InstName + " instruction requires the "

                     "following SPIR-V extension: SPV_INTEL_joint_matrix";

      report_fatal_error(ErrorMsg.c_str(), false);

    }

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

    if (OpCode == SPIRV::OpCooperativeMatrixPrefetchINTEL) {

      Reqs.addCapability(SPIRV::Capability::CooperativeMatrixPrefetchINTEL);

      break;

    }

    Reqs.addCapability(

        SPIRV::Capability::CooperativeMatrixCheckedInstructionsINTEL);

    break;

  }

  case SPIRV::OpCooperativeMatrixConstructCheckedINTEL:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix))

      report_fatal_error("OpCooperativeMatrixConstructCheckedINTEL "

                         "instructions require the following SPIR-V extension: "

                         "SPV_INTEL_joint_matrix",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

    Reqs.addCapability(

        SPIRV::Capability::CooperativeMatrixCheckedInstructionsINTEL);

    break;

  case SPIRV::OpReadPipeBlockingALTERA:

  case SPIRV::OpWritePipeBlockingALTERA:

    if (ST.canUseExtension(SPIRV::Extension::SPV_ALTERA_blocking_pipes)) {

      Reqs.addExtension(SPIRV::Extension::SPV_ALTERA_blocking_pipes);

      Reqs.addCapability(SPIRV::Capability::BlockingPipesALTERA);

    }

    break;

  case SPIRV::OpCooperativeMatrixGetElementCoordINTEL:

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_joint_matrix))

      report_fatal_error("OpCooperativeMatrixGetElementCoordINTEL requires the "

                         "following SPIR-V extension: SPV_INTEL_joint_matrix",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_joint_matrix);

    Reqs.addCapability(

        SPIRV::Capability::CooperativeMatrixInvocationInstructionsINTEL);

    break;

  case SPIRV::OpConvertHandleToImageINTEL:

  case SPIRV::OpConvertHandleToSamplerINTEL:

  case SPIRV::OpConvertHandleToSampledImageINTEL: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_bindless_images))

      report_fatal_error("OpConvertHandleTo[Image/Sampler/SampledImage]INTEL "

                         "instructions require the following SPIR-V extension: "

                         "SPV_INTEL_bindless_images",

                         false);

    SPIRVGlobalRegistry *GR = ST.getSPIRVGlobalRegistry();

    SPIRV::AddressingModel::AddressingModel AddrModel = MAI.Addr;

    SPIRVType *TyDef = GR->getSPIRVTypeForVReg(MI.getOperand(1).getReg());

    if (MI.getOpcode() == SPIRV::OpConvertHandleToImageINTEL &&

        TyDef->getOpcode() != SPIRV::OpTypeImage) {

      report_fatal_error("Incorrect return type for the instruction "

                         "OpConvertHandleToImageINTEL",

                         false);

    } else if (MI.getOpcode() == SPIRV::OpConvertHandleToSamplerINTEL &&

               TyDef->getOpcode() != SPIRV::OpTypeSampler) {

      report_fatal_error("Incorrect return type for the instruction "

                         "OpConvertHandleToSamplerINTEL",

                         false);

    } else if (MI.getOpcode() == SPIRV::OpConvertHandleToSampledImageINTEL &&

               TyDef->getOpcode() != SPIRV::OpTypeSampledImage) {

      report_fatal_error("Incorrect return type for the instruction "

                         "OpConvertHandleToSampledImageINTEL",

                         false);

    }

    SPIRVType *SpvTy = GR->getSPIRVTypeForVReg(MI.getOperand(2).getReg());

    unsigned Bitwidth = GR->getScalarOrVectorBitWidth(SpvTy);

    if (!(Bitwidth == 32 && AddrModel == SPIRV::AddressingModel::Physical32) &&

        !(Bitwidth == 64 && AddrModel == SPIRV::AddressingModel::Physical64)) {

      report_fatal_error(

          "Parameter value must be a 32-bit scalar in case of "

          "Physical32 addressing model or a 64-bit scalar in case of "

          "Physical64 addressing model",

          false);

    }

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_bindless_images);

    Reqs.addCapability(SPIRV::Capability::BindlessImagesINTEL);

    break;

  }

  case SPIRV::OpSubgroup2DBlockLoadINTEL:

  case SPIRV::OpSubgroup2DBlockLoadTransposeINTEL:

  case SPIRV::OpSubgroup2DBlockLoadTransformINTEL:

  case SPIRV::OpSubgroup2DBlockPrefetchINTEL:

  case SPIRV::OpSubgroup2DBlockStoreINTEL: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_2d_block_io))

      report_fatal_error("OpSubgroup2DBlock[Load/LoadTranspose/LoadTransform/"

                         "Prefetch/Store]INTEL instructions require the "

                         "following SPIR-V extension: SPV_INTEL_2d_block_io",

                         false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_2d_block_io);

    Reqs.addCapability(SPIRV::Capability::Subgroup2DBlockIOINTEL);


    const auto OpCode = MI.getOpcode();

    if (OpCode == SPIRV::OpSubgroup2DBlockLoadTransposeINTEL) {

      Reqs.addCapability(SPIRV::Capability::Subgroup2DBlockTransposeINTEL);

      break;

    }

    if (OpCode == SPIRV::OpSubgroup2DBlockLoadTransformINTEL) {

      Reqs.addCapability(SPIRV::Capability::Subgroup2DBlockTransformINTEL);

      break;

    }

    break;

  }

  case SPIRV::OpKill: {

    Reqs.addCapability(SPIRV::Capability::Shader);

  } break;

  case SPIRV::OpDemoteToHelperInvocation:

    Reqs.addCapability(SPIRV::Capability::DemoteToHelperInvocation);


    if (ST.canUseExtension(

            SPIRV::Extension::SPV_EXT_demote_to_helper_invocation)) {

      if (!ST.isAtLeastSPIRVVer(llvm::VersionTuple(1, 6)))

        Reqs.addExtension(

            SPIRV::Extension::SPV_EXT_demote_to_helper_invocation);

    }

    break;

  case SPIRV::OpSDot:

  case SPIRV::OpUDot:

  case SPIRV::OpSUDot:

  case SPIRV::OpSDotAccSat:

  case SPIRV::OpUDotAccSat:

  case SPIRV::OpSUDotAccSat:

    AddDotProductRequirements(MI, Reqs, ST);

    break;

  case SPIRV::OpImageSampleImplicitLod:

    Reqs.addCapability(SPIRV::Capability::Shader);

    break;

  case SPIRV::OpImageRead: {

    Register ImageReg = MI.getOperand(2).getReg();

    SPIRVType *TypeDef = ST.getSPIRVGlobalRegistry()->getResultType(

        ImageReg, const_cast<MachineFunction *>(MI.getMF()));

    // OpImageRead and OpImageWrite can use Unknown Image Formats

    // when the Kernel capability is declared. In the OpenCL environment we are

    // not allowed to produce

    // StorageImageReadWithoutFormat/StorageImageWriteWithoutFormat, see

    // https://github.com/KhronosGroup/SPIRV-Headers/issues/487


    if (isImageTypeWithUnknownFormat(TypeDef) && ST.isShader())

      Reqs.addCapability(SPIRV::Capability::StorageImageReadWithoutFormat);

    break;

  }

  case SPIRV::OpImageWrite: {

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

    SPIRVType *TypeDef = ST.getSPIRVGlobalRegistry()->getResultType(

        ImageReg, const_cast<MachineFunction *>(MI.getMF()));

    // OpImageRead and OpImageWrite can use Unknown Image Formats

    // when the Kernel capability is declared. In the OpenCL environment we are

    // not allowed to produce

    // StorageImageReadWithoutFormat/StorageImageWriteWithoutFormat, see

    // https://github.com/KhronosGroup/SPIRV-Headers/issues/487


    if (isImageTypeWithUnknownFormat(TypeDef) && ST.isShader())

      Reqs.addCapability(SPIRV::Capability::StorageImageWriteWithoutFormat);

    break;

  }

  case SPIRV::OpTypeStructContinuedINTEL:

  case SPIRV::OpConstantCompositeContinuedINTEL:

  case SPIRV::OpSpecConstantCompositeContinuedINTEL:

  case SPIRV::OpCompositeConstructContinuedINTEL: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_long_composites))

      report_fatal_error(

          "Continued instructions require the "

          "following SPIR-V extension: SPV_INTEL_long_composites",

          false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_long_composites);

    Reqs.addCapability(SPIRV::Capability::LongCompositesINTEL);

    break;

  }

  case SPIRV::OpArbitraryFloatEQALTERA:

  case SPIRV::OpArbitraryFloatGEALTERA:

  case SPIRV::OpArbitraryFloatGTALTERA:

  case SPIRV::OpArbitraryFloatLEALTERA:

  case SPIRV::OpArbitraryFloatLTALTERA:

  case SPIRV::OpArbitraryFloatCbrtALTERA:

  case SPIRV::OpArbitraryFloatCosALTERA:

  case SPIRV::OpArbitraryFloatCosPiALTERA:

  case SPIRV::OpArbitraryFloatExp10ALTERA:

  case SPIRV::OpArbitraryFloatExp2ALTERA:

  case SPIRV::OpArbitraryFloatExpALTERA:

  case SPIRV::OpArbitraryFloatExpm1ALTERA:

  case SPIRV::OpArbitraryFloatHypotALTERA:

  case SPIRV::OpArbitraryFloatLog10ALTERA:

  case SPIRV::OpArbitraryFloatLog1pALTERA:

  case SPIRV::OpArbitraryFloatLog2ALTERA:

  case SPIRV::OpArbitraryFloatLogALTERA:

  case SPIRV::OpArbitraryFloatRecipALTERA:

  case SPIRV::OpArbitraryFloatSinCosALTERA:

  case SPIRV::OpArbitraryFloatSinCosPiALTERA:

  case SPIRV::OpArbitraryFloatSinALTERA:

  case SPIRV::OpArbitraryFloatSinPiALTERA:

  case SPIRV::OpArbitraryFloatSqrtALTERA:

  case SPIRV::OpArbitraryFloatACosALTERA:

  case SPIRV::OpArbitraryFloatACosPiALTERA:

  case SPIRV::OpArbitraryFloatAddALTERA:

  case SPIRV::OpArbitraryFloatASinALTERA:

  case SPIRV::OpArbitraryFloatASinPiALTERA:

  case SPIRV::OpArbitraryFloatATan2ALTERA:

  case SPIRV::OpArbitraryFloatATanALTERA:

  case SPIRV::OpArbitraryFloatATanPiALTERA:

  case SPIRV::OpArbitraryFloatCastFromIntALTERA:

  case SPIRV::OpArbitraryFloatCastALTERA:

  case SPIRV::OpArbitraryFloatCastToIntALTERA:

  case SPIRV::OpArbitraryFloatDivALTERA:

  case SPIRV::OpArbitraryFloatMulALTERA:

  case SPIRV::OpArbitraryFloatPowALTERA:

  case SPIRV::OpArbitraryFloatPowNALTERA:

  case SPIRV::OpArbitraryFloatPowRALTERA:

  case SPIRV::OpArbitraryFloatRSqrtALTERA:

  case SPIRV::OpArbitraryFloatSubALTERA: {

    if (!ST.canUseExtension(

            SPIRV::Extension::SPV_ALTERA_arbitrary_precision_floating_point))

      report_fatal_error(

          "Floating point instructions can't be translated correctly without "

          "enabled SPV_ALTERA_arbitrary_precision_floating_point extension!",

          false);

    Reqs.addExtension(

        SPIRV::Extension::SPV_ALTERA_arbitrary_precision_floating_point);

    Reqs.addCapability(

        SPIRV::Capability::ArbitraryPrecisionFloatingPointALTERA);

    break;

  }

  case SPIRV::OpSubgroupMatrixMultiplyAccumulateINTEL: {

    if (!ST.canUseExtension(

            SPIRV::Extension::SPV_INTEL_subgroup_matrix_multiply_accumulate))

      report_fatal_error(

          "OpSubgroupMatrixMultiplyAccumulateINTEL instruction requires the "

          "following SPIR-V "

          "extension: SPV_INTEL_subgroup_matrix_multiply_accumulate",

          false);

    Reqs.addExtension(

        SPIRV::Extension::SPV_INTEL_subgroup_matrix_multiply_accumulate);

    Reqs.addCapability(

        SPIRV::Capability::SubgroupMatrixMultiplyAccumulateINTEL);

    break;

  }

  case SPIRV::OpBitwiseFunctionINTEL: {

    if (!ST.canUseExtension(

            SPIRV::Extension::SPV_INTEL_ternary_bitwise_function))

      report_fatal_error(

          "OpBitwiseFunctionINTEL instruction requires the following SPIR-V "

          "extension: SPV_INTEL_ternary_bitwise_function",

          false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_ternary_bitwise_function);

    Reqs.addCapability(SPIRV::Capability::TernaryBitwiseFunctionINTEL);

    break;

  }

  case SPIRV::OpCopyMemorySized: {

    Reqs.addCapability(SPIRV::Capability::Addresses);

    // TODO: Add UntypedPointersKHR when implemented.

    break;

  }

  case SPIRV::OpPredicatedLoadINTEL:

  case SPIRV::OpPredicatedStoreINTEL: {

    if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_predicated_io))

      report_fatal_error(

          "OpPredicated[Load/Store]INTEL instructions require "

          "the following SPIR-V extension: SPV_INTEL_predicated_io",

          false);

    Reqs.addExtension(SPIRV::Extension::SPV_INTEL_predicated_io);

    Reqs.addCapability(SPIRV::Capability::PredicatedIOINTEL);

    break;

  }

  case SPIRV::OpFAddS:

  case SPIRV::OpFSubS:

  case SPIRV::OpFMulS:

  case SPIRV::OpFDivS:

  case SPIRV::OpFRemS:

  case SPIRV::OpFMod:

  case SPIRV::OpFNegate:

  case SPIRV::OpFAddV:

  case SPIRV::OpFSubV:

  case SPIRV::OpFMulV:

  case SPIRV::OpFDivV:

  case SPIRV::OpFRemV:

  case SPIRV::OpFNegateV: {

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    SPIRVType *TypeDef = MRI.getVRegDef(MI.getOperand(1).getReg());

    if (TypeDef->getOpcode() == SPIRV::OpTypeVector)

      TypeDef = MRI.getVRegDef(TypeDef->getOperand(1).getReg());

    if (isBFloat16Type(TypeDef)) {

      if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_bfloat16_arithmetic))

        report_fatal_error(

            "Arithmetic instructions with bfloat16 arguments require the "

            "following SPIR-V extension: SPV_INTEL_bfloat16_arithmetic",

            false);

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_bfloat16_arithmetic);

      Reqs.addCapability(SPIRV::Capability::BFloat16ArithmeticINTEL);

    }

    break;

  }

  case SPIRV::OpOrdered:

  case SPIRV::OpUnordered:

  case SPIRV::OpFOrdEqual:

  case SPIRV::OpFOrdNotEqual:

  case SPIRV::OpFOrdLessThan:

  case SPIRV::OpFOrdLessThanEqual:

  case SPIRV::OpFOrdGreaterThan:

  case SPIRV::OpFOrdGreaterThanEqual:

  case SPIRV::OpFUnordEqual:

  case SPIRV::OpFUnordNotEqual:

  case SPIRV::OpFUnordLessThan:

  case SPIRV::OpFUnordLessThanEqual:

  case SPIRV::OpFUnordGreaterThan:

  case SPIRV::OpFUnordGreaterThanEqual: {

    const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();

    MachineInstr *OperandDef = MRI.getVRegDef(MI.getOperand(2).getReg());

    SPIRVType *TypeDef = MRI.getVRegDef(OperandDef->getOperand(1).getReg());

    if (TypeDef->getOpcode() == SPIRV::OpTypeVector)

      TypeDef = MRI.getVRegDef(TypeDef->getOperand(1).getReg());

    if (isBFloat16Type(TypeDef)) {

      if (!ST.canUseExtension(SPIRV::Extension::SPV_INTEL_bfloat16_arithmetic))

        report_fatal_error(

            "Relational instructions with bfloat16 arguments require the "

            "following SPIR-V extension: SPV_INTEL_bfloat16_arithmetic",

            false);

      Reqs.addExtension(SPIRV::Extension::SPV_INTEL_bfloat16_arithmetic);

      Reqs.addCapability(SPIRV::Capability::BFloat16ArithmeticINTEL);

    }

    break;

  }

  case SPIRV::OpDPdxCoarse:

  case SPIRV::OpDPdyCoarse:

  case SPIRV::OpDPdxFine:

  case SPIRV::OpDPdyFine: {

    Reqs.addCapability(SPIRV::Capability::DerivativeControl);

    break;

  }


  default:

    break;

  }


  // If we require capability Shader, then we can remove the requirement for

  // the BitInstructions capability, since Shader is a superset capability

  // of BitInstructions.

  Reqs.removeCapabilityIf(SPIRV::Capability::BitInstructions,

                          SPIRV::Capability::Shader);

}


static void collectReqs(const Module &M, SPIRV::ModuleAnalysisInfo &MAI,

                        MachineModuleInfo *MMI, const SPIRVSubtarget &ST) {

  // Collect requirements for existing instructions.

  for (const Function &F : M) {

    MachineFunction *MF = MMI->getMachineFunction(F);

    if (!MF)

      continue;

    for (const MachineBasicBlock &MBB : *MF)

      for (const MachineInstr &MI : MBB)

        addInstrRequirements(MI, MAI, ST);

  }

  // Collect requirements for OpExecutionMode instructions.

  auto Node = M.getNamedMetadata("spirv.ExecutionMode");

  if (Node) {

    bool RequireFloatControls = false, RequireIntelFloatControls2 = false,

         RequireKHRFloatControls2 = false,

         VerLower14 = !ST.isAtLeastSPIRVVer(VersionTuple(1, 4));

    bool HasIntelFloatControls2 =

        ST.canUseExtension(SPIRV::Extension::SPV_INTEL_float_controls2);

    bool HasKHRFloatControls2 =

        ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2);

    for (unsigned i = 0; i < Node->getNumOperands(); i++) {

      MDNode *MDN = cast<MDNode>(Node->getOperand(i));

      const MDOperand &MDOp = MDN->getOperand(1);

      if (auto *CMeta = dyn_cast<ConstantAsMetadata>(MDOp)) {

        Constant *C = CMeta->getValue();

        if (ConstantInt *Const = dyn_cast<ConstantInt>(C)) {

          auto EM = Const->getZExtValue();

          // SPV_KHR_float_controls is not available until v1.4:

          // add SPV_KHR_float_controls if the version is too low

          switch (EM) {

          case SPIRV::ExecutionMode::DenormPreserve:

          case SPIRV::ExecutionMode::DenormFlushToZero:

          case SPIRV::ExecutionMode::RoundingModeRTE:

          case SPIRV::ExecutionMode::RoundingModeRTZ:

            RequireFloatControls = VerLower14;

            MAI.Reqs.getAndAddRequirements(

                SPIRV::OperandCategory::ExecutionModeOperand, EM, ST);

            break;

          case SPIRV::ExecutionMode::RoundingModeRTPINTEL:

          case SPIRV::ExecutionMode::RoundingModeRTNINTEL:

          case SPIRV::ExecutionMode::FloatingPointModeALTINTEL:

          case SPIRV::ExecutionMode::FloatingPointModeIEEEINTEL:

            if (HasIntelFloatControls2) {

              RequireIntelFloatControls2 = true;

              MAI.Reqs.getAndAddRequirements(

                  SPIRV::OperandCategory::ExecutionModeOperand, EM, ST);

            }

            break;

          case SPIRV::ExecutionMode::FPFastMathDefault: {

            if (HasKHRFloatControls2) {

              RequireKHRFloatControls2 = true;

              MAI.Reqs.getAndAddRequirements(

                  SPIRV::OperandCategory::ExecutionModeOperand, EM, ST);

            }

            break;

          }

          case SPIRV::ExecutionMode::ContractionOff:

          case SPIRV::ExecutionMode::SignedZeroInfNanPreserve:

            if (HasKHRFloatControls2) {

              RequireKHRFloatControls2 = true;

              MAI.Reqs.getAndAddRequirements(

                  SPIRV::OperandCategory::ExecutionModeOperand,

                  SPIRV::ExecutionMode::FPFastMathDefault, ST);

            } else {

              MAI.Reqs.getAndAddRequirements(

                  SPIRV::OperandCategory::ExecutionModeOperand, EM, ST);

            }

            break;

          default:

            MAI.Reqs.getAndAddRequirements(

                SPIRV::OperandCategory::ExecutionModeOperand, EM, ST);

          }

        }

      }

    }

    if (RequireFloatControls &&

        ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls))

      MAI.Reqs.addExtension(SPIRV::Extension::SPV_KHR_float_controls);

    if (RequireIntelFloatControls2)

      MAI.Reqs.addExtension(SPIRV::Extension::SPV_INTEL_float_controls2);

    if (RequireKHRFloatControls2)

      MAI.Reqs.addExtension(SPIRV::Extension::SPV_KHR_float_controls2);

  }

  for (const Function &F : M) {

    if (F.isDeclaration())

      continue;

    if (F.getMetadata("reqd_work_group_size"))

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::LocalSize, ST);

    if (F.getFnAttribute("hlsl.numthreads").isValid()) {

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::LocalSize, ST);

    }

    if (F.getFnAttribute("enable-maximal-reconvergence").getValueAsBool()) {

      MAI.Reqs.addExtension(SPIRV::Extension::SPV_KHR_maximal_reconvergence);

    }

    if (F.getMetadata("work_group_size_hint"))

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::LocalSizeHint, ST);

    if (F.getMetadata("intel_reqd_sub_group_size"))

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::SubgroupSize, ST);

    if (F.getMetadata("max_work_group_size"))

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::MaxWorkgroupSizeINTEL, ST);

    if (F.getMetadata("vec_type_hint"))

      MAI.Reqs.getAndAddRequirements(

          SPIRV::OperandCategory::ExecutionModeOperand,

          SPIRV::ExecutionMode::VecTypeHint, ST);


    if (F.hasOptNone()) {

      if (ST.canUseExtension(SPIRV::Extension::SPV_INTEL_optnone)) {

        MAI.Reqs.addExtension(SPIRV::Extension::SPV_INTEL_optnone);

        MAI.Reqs.addCapability(SPIRV::Capability::OptNoneINTEL);

      } else if (ST.canUseExtension(SPIRV::Extension::SPV_EXT_optnone)) {

        MAI.Reqs.addExtension(SPIRV::Extension::SPV_EXT_optnone);

        MAI.Reqs.addCapability(SPIRV::Capability::OptNoneEXT);

      }

    }

  }

}


static unsigned getFastMathFlags(const MachineInstr &I,

                                 const SPIRVSubtarget &ST) {

  unsigned Flags = SPIRV::FPFastMathMode::None;

  bool CanUseKHRFloatControls2 =

      ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2);

  if (I.getFlag(MachineInstr::MIFlag::FmNoNans))

    Flags |= SPIRV::FPFastMathMode::NotNaN;

  if (I.getFlag(MachineInstr::MIFlag::FmNoInfs))

    Flags |= SPIRV::FPFastMathMode::NotInf;

  if (I.getFlag(MachineInstr::MIFlag::FmNsz))

    Flags |= SPIRV::FPFastMathMode::NSZ;

  if (I.getFlag(MachineInstr::MIFlag::FmArcp))

    Flags |= SPIRV::FPFastMathMode::AllowRecip;

  if (I.getFlag(MachineInstr::MIFlag::FmContract) && CanUseKHRFloatControls2)

    Flags |= SPIRV::FPFastMathMode::AllowContract;

  if (I.getFlag(MachineInstr::MIFlag::FmReassoc)) {

    if (CanUseKHRFloatControls2)

      // LLVM reassoc maps to SPIRV transform, see

      // https://github.com/KhronosGroup/SPIRV-Registry/issues/326 for details.

      // Because we are enabling AllowTransform, we must enable AllowReassoc and

      // AllowContract too, as required by SPIRV spec. Also, we used to map

      // MIFlag::FmReassoc to FPFastMathMode::Fast, which now should instead by

      // replaced by turning all the other bits instead. Therefore, we're

      // enabling every bit here except None and Fast.

      Flags |= SPIRV::FPFastMathMode::NotNaN | SPIRV::FPFastMathMode::NotInf |

               SPIRV::FPFastMathMode::NSZ | SPIRV::FPFastMathMode::AllowRecip |

               SPIRV::FPFastMathMode::AllowTransform |

               SPIRV::FPFastMathMode::AllowReassoc |

               SPIRV::FPFastMathMode::AllowContract;

    else

      Flags |= SPIRV::FPFastMathMode::Fast;

  }


  if (CanUseKHRFloatControls2) {

    // Error out if SPIRV::FPFastMathMode::Fast is enabled.

    assert(!(Flags & SPIRV::FPFastMathMode::Fast) &&

           "SPIRV::FPFastMathMode::Fast is deprecated and should not be used "

           "anymore.");


    // Error out if AllowTransform is enabled without AllowReassoc and

    // AllowContract.

    assert((!(Flags & SPIRV::FPFastMathMode::AllowTransform) ||

            ((Flags & SPIRV::FPFastMathMode::AllowReassoc &&

              Flags & SPIRV::FPFastMathMode::AllowContract))) &&

           "SPIRV::FPFastMathMode::AllowTransform requires AllowReassoc and "

           "AllowContract flags to be enabled as well.");

  }


  return Flags;

}


static bool isFastMathModeAvailable(const SPIRVSubtarget &ST) {

  if (ST.isKernel())

    return true;

  if (ST.getSPIRVVersion() < VersionTuple(1, 2))

    return false;

  return ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2);

}


static void handleMIFlagDecoration(

    MachineInstr &I, const SPIRVSubtarget &ST, const SPIRVInstrInfo &TII,

    SPIRV::RequirementHandler &Reqs, const SPIRVGlobalRegistry *GR,

    SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec) {

  if (I.getFlag(MachineInstr::MIFlag::NoSWrap) && TII.canUseNSW(I) &&

      getSymbolicOperandRequirements(SPIRV::OperandCategory::DecorationOperand,

                                     SPIRV::Decoration::NoSignedWrap, ST, Reqs)

          .IsSatisfiable) {

    buildOpDecorate(I.getOperand(0).getReg(), I, TII,

                    SPIRV::Decoration::NoSignedWrap, {});

  }

  if (I.getFlag(MachineInstr::MIFlag::NoUWrap) && TII.canUseNUW(I) &&

      getSymbolicOperandRequirements(SPIRV::OperandCategory::DecorationOperand,

                                     SPIRV::Decoration::NoUnsignedWrap, ST,

                                     Reqs)

          .IsSatisfiable) {

    buildOpDecorate(I.getOperand(0).getReg(), I, TII,

                    SPIRV::Decoration::NoUnsignedWrap, {});

  }

  if (!TII.canUseFastMathFlags(

          I, ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2)))

    return;


  unsigned FMFlags = getFastMathFlags(I, ST);

  if (FMFlags == SPIRV::FPFastMathMode::None) {

    // We also need to check if any FPFastMathDefault info was set for the

    // types used in this instruction.

    if (FPFastMathDefaultInfoVec.empty())

      return;


    // There are three types of instructions that can use fast math flags:

    // 1. Arithmetic instructions (FAdd, FMul, FSub, FDiv, FRem, etc.)

    // 2. Relational instructions (FCmp, FOrd, FUnord, etc.)

    // 3. Extended instructions (ExtInst)

    // For arithmetic instructions, the floating point type can be in the

    // result type or in the operands, but they all must be the same.

    // For the relational and logical instructions, the floating point type

    // can only be in the operands 1 and 2, not the result type. Also, the

    // operands must have the same type. For the extended instructions, the

    // floating point type can be in the result type or in the operands. It's

    // unclear if the operands and the result type must be the same. Let's

    // assume they must be. Therefore, for 1. and 2., we can check the first

    // operand type, and for 3. we can check the result type.

    assert(I.getNumOperands() >= 3 && "Expected at least 3 operands");

    Register ResReg = I.getOpcode() == SPIRV::OpExtInst

                          ? I.getOperand(1).getReg()

                          : I.getOperand(2).getReg();

    SPIRVType *ResType = GR->getSPIRVTypeForVReg(ResReg, I.getMF());

    const Type *Ty = GR->getTypeForSPIRVType(ResType);

    Ty = Ty->isVectorTy() ? cast<VectorType>(Ty)->getElementType() : Ty;


    // Match instruction type with the FPFastMathDefaultInfoVec.

    bool Emit = false;

    for (SPIRV::FPFastMathDefaultInfo &Elem : FPFastMathDefaultInfoVec) {

      if (Ty == Elem.Ty) {

        FMFlags = Elem.FastMathFlags;

        Emit = Elem.ContractionOff || Elem.SignedZeroInfNanPreserve ||

               Elem.FPFastMathDefault;

        break;

      }

    }


    if (FMFlags == SPIRV::FPFastMathMode::None && !Emit)

      return;

  }

  if (isFastMathModeAvailable(ST)) {

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

    buildOpDecorate(DstReg, I, TII, SPIRV::Decoration::FPFastMathMode,

                    {FMFlags});

  }

}


// Walk all functions and add decorations related to MI flags.

static void addDecorations(const Module &M, const SPIRVInstrInfo &TII,

                           MachineModuleInfo *MMI, const SPIRVSubtarget &ST,

                           SPIRV::ModuleAnalysisInfo &MAI,

                           const SPIRVGlobalRegistry *GR) {

  for (const Function &F : M) {

    MachineFunction *MF = MMI->getMachineFunction(F);

    if (!MF)

      continue;


    for (auto &MBB : *MF)

      for (auto &MI : MBB)

        handleMIFlagDecoration(MI, ST, TII, MAI.Reqs, GR,

                               MAI.FPFastMathDefaultInfoMap[&F]);

  }

}


static void addMBBNames(const Module &M, const SPIRVInstrInfo &TII,

                        MachineModuleInfo *MMI, const SPIRVSubtarget &ST,

                        SPIRV::ModuleAnalysisInfo &MAI) {

  for (const Function &F : M) {

    MachineFunction *MF = MMI->getMachineFunction(F);

    if (!MF)

      continue;

    MachineRegisterInfo &MRI = MF->getRegInfo();

    for (auto &MBB : *MF) {

      if (!MBB.hasName() || MBB.empty())

        continue;

      // Emit basic block names.

      Register Reg = MRI.createGenericVirtualRegister(LLT::scalar(64));

      MRI.setRegClass(Reg, &SPIRV::IDRegClass);

      buildOpName(Reg, MBB.getName(), *std::prev(MBB.end()), TII);

      MCRegister GlobalReg = MAI.getOrCreateMBBRegister(MBB);

      MAI.setRegisterAlias(MF, Reg, GlobalReg);

    }

  }

}


// patching Instruction::PHI to SPIRV::OpPhi

static void patchPhis(const Module &M, SPIRVGlobalRegistry *GR,

                      const SPIRVInstrInfo &TII, MachineModuleInfo *MMI) {

  for (const Function &F : M) {

    MachineFunction *MF = MMI->getMachineFunction(F);

    if (!MF)

      continue;

    for (auto &MBB : *MF) {

      for (MachineInstr &MI : MBB.phis()) {

        MI.setDesc(TII.get(SPIRV::OpPhi));

        Register ResTypeReg = GR->getSPIRVTypeID(

            GR->getSPIRVTypeForVReg(MI.getOperand(0).getReg(), MF));

        MI.insert(MI.operands_begin() + 1,

                  {MachineOperand::CreateReg(ResTypeReg, false)});

      }

    }


    MF->getProperties().setNoPHIs();

  }

}


static SPIRV::FPFastMathDefaultInfoVector &getOrCreateFPFastMathDefaultInfoVec(

    const Module &M, SPIRV::ModuleAnalysisInfo &MAI, const Function *F) {

  auto it = MAI.FPFastMathDefaultInfoMap.find(F);

  if (it != MAI.FPFastMathDefaultInfoMap.end())

    return it->second;


  // If the map does not contain the entry, create a new one. Initialize it to

  // contain all 3 elements sorted by bit width of target type: {half, float,

  // double}.

  SPIRV::FPFastMathDefaultInfoVector FPFastMathDefaultInfoVec;

  FPFastMathDefaultInfoVec.emplace_back(Type::getHalfTy(M.getContext()),

                                        SPIRV::FPFastMathMode::None);

  FPFastMathDefaultInfoVec.emplace_back(Type::getFloatTy(M.getContext()),

                                        SPIRV::FPFastMathMode::None);

  FPFastMathDefaultInfoVec.emplace_back(Type::getDoubleTy(M.getContext()),

                                        SPIRV::FPFastMathMode::None);

  return MAI.FPFastMathDefaultInfoMap[F] = std::move(FPFastMathDefaultInfoVec);

}


static SPIRV::FPFastMathDefaultInfo &getFPFastMathDefaultInfo(

    SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec,

    const Type *Ty) {

  size_t BitWidth = Ty->getScalarSizeInBits();

  int Index =

      SPIRV::FPFastMathDefaultInfoVector::computeFPFastMathDefaultInfoVecIndex(

          BitWidth);

  assert(Index >= 0 && Index < 3 &&

         "Expected FPFastMathDefaultInfo for half, float, or double");

  assert(FPFastMathDefaultInfoVec.size() == 3 &&

         "Expected FPFastMathDefaultInfoVec to have exactly 3 elements");

  return FPFastMathDefaultInfoVec[Index];

}


static void collectFPFastMathDefaults(const Module &M,

                                      SPIRV::ModuleAnalysisInfo &MAI,

                                      const SPIRVSubtarget &ST) {

  if (!ST.canUseExtension(SPIRV::Extension::SPV_KHR_float_controls2))

    return;


  // Store the FPFastMathDefaultInfo in the FPFastMathDefaultInfoMap.

  // We need the entry point (function) as the key, and the target

  // type and flags as the value.

  // We also need to check ContractionOff and SignedZeroInfNanPreserve

  // execution modes, as they are now deprecated and must be replaced

  // with FPFastMathDefaultInfo.

  auto Node = M.getNamedMetadata("spirv.ExecutionMode");

  if (!Node)

    return;


  for (unsigned i = 0; i < Node->getNumOperands(); i++) {

    MDNode *MDN = cast<MDNode>(Node->getOperand(i));

    assert(MDN->getNumOperands() >= 2 && "Expected at least 2 operands");

    const Function *F = cast<Function>(

        cast<ConstantAsMetadata>(MDN->getOperand(0))->getValue());

    const auto EM =

        cast<ConstantInt>(

            cast<ConstantAsMetadata>(MDN->getOperand(1))->getValue())

            ->getZExtValue();

    if (EM == SPIRV::ExecutionMode::FPFastMathDefault) {

      assert(MDN->getNumOperands() == 4 &&

             "Expected 4 operands for FPFastMathDefault");


      const Type *T = cast<ValueAsMetadata>(MDN->getOperand(2))->getType();

      unsigned Flags =

          cast<ConstantInt>(

              cast<ConstantAsMetadata>(MDN->getOperand(3))->getValue())

              ->getZExtValue();

      SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec =

          getOrCreateFPFastMathDefaultInfoVec(M, MAI, F);

      SPIRV::FPFastMathDefaultInfo &Info =

          getFPFastMathDefaultInfo(FPFastMathDefaultInfoVec, T);

      Info.FastMathFlags = Flags;

      Info.FPFastMathDefault = true;

    } else if (EM == SPIRV::ExecutionMode::ContractionOff) {

      assert(MDN->getNumOperands() == 2 &&

             "Expected no operands for ContractionOff");


      // We need to save this info for every possible FP type, i.e. {half,

      // float, double, fp128}.

      SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec =

          getOrCreateFPFastMathDefaultInfoVec(M, MAI, F);

      for (SPIRV::FPFastMathDefaultInfo &Info : FPFastMathDefaultInfoVec) {

        Info.ContractionOff = true;

      }

    } else if (EM == SPIRV::ExecutionMode::SignedZeroInfNanPreserve) {

      assert(MDN->getNumOperands() == 3 &&

             "Expected 1 operand for SignedZeroInfNanPreserve");

      unsigned TargetWidth =

          cast<ConstantInt>(

              cast<ConstantAsMetadata>(MDN->getOperand(2))->getValue())

              ->getZExtValue();

      // We need to save this info only for the FP type with TargetWidth.

      SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec =

          getOrCreateFPFastMathDefaultInfoVec(M, MAI, F);

      int Index = SPIRV::FPFastMathDefaultInfoVector::

          computeFPFastMathDefaultInfoVecIndex(TargetWidth);

      assert(Index >= 0 && Index < 3 &&

             "Expected FPFastMathDefaultInfo for half, float, or double");

      assert(FPFastMathDefaultInfoVec.size() == 3 &&

             "Expected FPFastMathDefaultInfoVec to have exactly 3 elements");

      FPFastMathDefaultInfoVec[Index].SignedZeroInfNanPreserve = true;

    }

  }

}


struct SPIRV::ModuleAnalysisInfo SPIRVModuleAnalysis::MAI;


void SPIRVModuleAnalysis::getAnalysisUsage(AnalysisUsage &AU) const {

  AU.addRequired<TargetPassConfig>();

  AU.addRequired<MachineModuleInfoWrapperPass>();

}


bool SPIRVModuleAnalysis::runOnModule(Module &M) {

  SPIRVTargetMachine &TM =

      getAnalysis<TargetPassConfig>().getTM<SPIRVTargetMachine>();

  ST = TM.getSubtargetImpl();

  GR = ST->getSPIRVGlobalRegistry();

  TII = ST->getInstrInfo();


  MMI = &getAnalysis<MachineModuleInfoWrapperPass>().getMMI();


  setBaseInfo(M);


  patchPhis(M, GR, *TII, MMI);


  addMBBNames(M, *TII, MMI, *ST, MAI);

  collectFPFastMathDefaults(M, MAI, *ST);

  addDecorations(M, *TII, MMI, *ST, MAI, GR);


  collectReqs(M, MAI, MMI, *ST);


  // Process type/const/global var/func decl instructions, number their

  // destination registers from 0 to N, collect Extensions and Capabilities.

  collectReqs(M, MAI, MMI, *ST);

  collectDeclarations(M);


  // Number rest of registers from N+1 onwards.

  numberRegistersGlobally(M);


  // Collect OpName, OpEntryPoint, OpDecorate etc, process other instructions.

  processOtherInstrs(M);


  // If there are no entry points, we need the Linkage capability.

  if (MAI.MS[SPIRV::MB_EntryPoints].empty())

    MAI.Reqs.addCapability(SPIRV::Capability::Linkage);


  // Set maximum ID used.

  GR->setBound(MAI.MaxID);


  return false;

}


MRI
unsigned const MachineRegisterInfo * MRI
Definition AArch64AdvSIMDScalarPass.cpp:103

UseMI
MachineInstrBuilder & UseMI
Definition AArch64ExpandPseudoInsts.cpp:120

assert
assert(UImm &&(UImm !=~static_cast< T >(0)) &&"Invalid immediate!")

const
aarch64 promote const
Definition AArch64PromoteConstant.cpp:228

ToRemove
ReachingDefInfo InstSet & ToRemove
Definition ARMLowOverheadLoops.cpp:527

MBB
MachineBasicBlock & MBB
Definition ARMSLSHardening.cpp:71

E
static GCRegistry::Add< CoreCLRGC > E("coreclr", "CoreCLR-compatible GC")

clEnumValN
#define clEnumValN(ENUMVAL, FLAGNAME, DESC)
Definition CommandLine.h:687

DEBUG_TYPE
#define DEBUG_TYPE
Definition GenericCycleImpl.h:31

UseReg
static Register UseReg(const MachineOperand &MO)
Definition HexagonCopyToCombine.cpp:245

TII
const HexagonInstrInfo * TII
Definition HexagonCopyToCombine.cpp:118

MI
IRTranslator LLVM IR MI
Definition IRTranslator.cpp:110

F
#define F(x, y, z)
Definition MD5.cpp:54

I
#define I(x, y, z)
Definition MD5.cpp:57

MachineModuleInfo.h

Reg
Register Reg
Definition MachineSink.cpp:2119

Register
Promote Memory to Register
Definition Mem2Reg.cpp:110

T
#define T
Definition Mips16ISelLowering.cpp:282

INITIALIZE_PASS
#define INITIALIZE_PASS(passName, arg, name, cfg, analysis)
Definition PassSupport.h:56

Opc
auto Opc
Definition RISCVRedundantCopyElimination.cpp:77

SPIRVBaseInfo.h

getOrCreateFPFastMathDefaultInfoVec
static SPIRV::FPFastMathDefaultInfoVector & getOrCreateFPFastMathDefaultInfoVec(const Module &M, DenseMap< Function *, SPIRV::FPFastMathDefaultInfoVector > &FPFastMathDefaultInfoMap, Function *F)
Definition SPIRVEmitIntrinsics.cpp:2351

getFPFastMathDefaultInfo
static SPIRV::FPFastMathDefaultInfo & getFPFastMathDefaultInfo(SPIRV::FPFastMathDefaultInfoVector &FPFastMathDefaultInfoVec, const Type *Ty)
Definition SPIRVEmitIntrinsics.cpp:2373

SPIRVMCTargetDesc.h

ATOM_FLT_REQ_EXT_MSG
#define ATOM_FLT_REQ_EXT_MSG(ExtName)

SPVDumpDeps
static cl::opt< bool > SPVDumpDeps("spv-dump-deps", cl::desc("Dump MIR with SPIR-V dependencies info"), cl::Optional, cl::init(false))

DefaultVal
unsigned unsigned DefaultVal
Definition SPIRVModuleAnalysis.cpp:61

OpIndex
unsigned OpIndex
Definition SPIRVModuleAnalysis.cpp:60

AvoidCapabilities
static cl::list< SPIRV::Capability::Capability > AvoidCapabilities("avoid-spirv-capabilities", cl::desc("SPIR-V capabilities to avoid if there are " "other options enabling a feature"), cl::ZeroOrMore, cl::Hidden, cl::values(clEnumValN(SPIRV::Capability::Shader, "Shader", "SPIR-V Shader capability")))

SPIRVModuleAnalysis.h

SPIRVSubtarget.h

SPIRVTargetMachine.h

SPIRVUtils.h

SPIRV.h

STLExtras.h
This file contains some templates that are useful if you are working with the STL at all.

LLVM_DEBUG
#define LLVM_DEBUG(...)
Definition Debug.h:114

TargetPassConfig.h
Target-Independent Code Generator Pass Configuration Options pass.

Input
The Input class is used to parse a yaml document into in-memory structs and vectors.
Definition YAMLTraits.h:1313

Node
Definition ItaniumDemangle.h:166

llvm::ConstantInt
This is the shared class of boolean and integer constants.
Definition Constants.h:87

llvm::Constant
This is an important base class in LLVM.
Definition Constant.h:43

llvm::Function
Definition Function.h:64

llvm::LLT::scalar
static constexpr LLT scalar(unsigned SizeInBits)
Get a low-level scalar or aggregate "bag of bits".
Definition LowLevelType.h:43

llvm::MCRegister
Wrapper class representing physical registers. Should be passed by value.
Definition MCRegister.h:41

llvm::MCRegister::isValid
constexpr bool isValid() const
Definition MCRegister.h:84

llvm::MDNode
Metadata node.
Definition Metadata.h:1080

llvm::MDNode::getOperand
const MDOperand & getOperand(unsigned I) const
Definition Metadata.h:1444

llvm::MDNode::getNumOperands
unsigned getNumOperands() const
Return number of MDNode operands.
Definition Metadata.h:1450

llvm::MDOperand
Tracking metadata reference owned by Metadata.
Definition Metadata.h:902

llvm::MachineBasicBlock
Definition MachineBasicBlock.h:122

llvm::MachineBasicBlock::getParent
const MachineFunction * getParent() const
Return the MachineFunction containing this basic block.
Definition MachineBasicBlock.h:331

llvm::MachineFunction
Definition MachineFunction.h:294

llvm::MachineFunction::getRegInfo
MachineRegisterInfo & getRegInfo()
getRegInfo - Return information about the registers currently in use.
Definition MachineFunction.h:780

llvm::MachineFunction::getProperties
const MachineFunctionProperties & getProperties() const
Get the function properties.
Definition MachineFunction.h:861

llvm::MachineInstrBuilder::getReg
Register getReg(unsigned Idx) const
Get the register for the operand index.
Definition MachineInstrBuilder.h:196

llvm::MachineInstr
Representation of each machine instruction.
Definition MachineInstr.h:72

llvm::MachineInstr::getOpcode
unsigned getOpcode() const
Returns the opcode of this MachineInstr.
Definition MachineInstr.h:599

llvm::MachineInstr::getParent
const MachineBasicBlock * getParent() const
Definition MachineInstr.h:371

llvm::MachineInstr::getNumOperands
unsigned getNumOperands() const
Retuns the total number of operands.
Definition MachineInstr.h:602

llvm::MachineInstr::NoUWrap
@ NoUWrap
Definition MachineInstr.h:108

llvm::MachineInstr::FmArcp
@ FmArcp
Definition MachineInstr.h:100

llvm::MachineInstr::FmNoInfs
@ FmNoInfs
Definition MachineInstr.h:96

llvm::MachineInstr::FmReassoc
@ FmReassoc
Definition MachineInstr.h:106

llvm::MachineInstr::FmContract
@ FmContract
Definition MachineInstr.h:102

llvm::MachineInstr::FmNoNans
@ FmNoNans
Definition MachineInstr.h:94

llvm::MachineInstr::FmNsz
@ FmNsz
Definition MachineInstr.h:98

llvm::MachineInstr::NoSWrap
@ NoSWrap
Definition MachineInstr.h:110

llvm::MachineInstr::getMF
LLVM_ABI const MachineFunction * getMF() const
Return the function that contains the basic block that this instruction belongs to.
Definition MachineInstr.cpp:786

llvm::MachineInstr::getOperand
const MachineOperand & getOperand(unsigned i) const
Definition MachineInstr.h:607

llvm::MachineModuleInfoWrapperPass
Definition MachineModuleInfo.h:173

llvm::MachineModuleInfo
This class contains meta information specific to a module.
Definition MachineModuleInfo.h:83

llvm::MachineModuleInfo::getMachineFunction
LLVM_ABI MachineFunction * getMachineFunction(const Function &F) const
Returns the MachineFunction associated to IR function F if there is one, otherwise nullptr.
Definition MachineModuleInfo.cpp:72

llvm::MachineOperand
MachineOperand class - Representation of each machine instruction operand.
Definition MachineOperand.h:49

llvm::MachineOperand::getSubReg
unsigned getSubReg() const
Definition MachineOperand.h:377

llvm::MachineOperand::getImm
int64_t getImm() const
Definition MachineOperand.h:560

llvm::MachineOperand::isReg
bool isReg() const
isReg - Tests if this is a MO_Register operand.
Definition MachineOperand.h:331

llvm::MachineOperand::isDef
bool isDef() const
Definition MachineOperand.h:387

llvm::MachineOperand::isImm
bool isImm() const
isImm - Tests if this is a MO_Immediate operand.
Definition MachineOperand.h:333

llvm::MachineOperand::print
LLVM_ABI void print(raw_ostream &os, const TargetRegisterInfo *TRI=nullptr) const
Print the MachineOperand to os.
Definition MachineOperand.cpp:800

llvm::MachineOperand::getParent
MachineInstr * getParent()
getParent - Return the instruction that this operand belongs to.
Definition MachineOperand.h:246

llvm::MachineOperand::CreateImm
static MachineOperand CreateImm(int64_t Val)
Definition MachineOperand.h:833

llvm::MachineOperand::getType
MachineOperandType getType() const
getType - Returns the MachineOperandType for this operand.
Definition MachineOperand.h:227

llvm::MachineOperand::getReg
Register getReg() const
getReg - Returns the register number.
Definition MachineOperand.h:372

llvm::MachineRegisterInfo
MachineRegisterInfo - Keep track of information for virtual and physical registers,...
Definition MachineRegisterInfo.h:53

llvm::Module
A Module instance is used to store all the information related to an LLVM module.
Definition Module.h:67

llvm::Pass::print
virtual void print(raw_ostream &OS, const Module *M) const
print - Print out the internal state of the pass.
Definition Pass.cpp:140

llvm::Pass::getAnalysis
AnalysisType & getAnalysis() const
getAnalysis<AnalysisType>() - This function is used by subclasses to get to the analysis information ...
Definition PassAnalysisSupport.h:224

llvm::Register
Wrapper class representing virtual and physical registers.
Definition Register.h:20

llvm::Register::isValid
constexpr bool isValid() const
Definition Register.h:112

llvm::SPIRVGlobalRegistry
Definition SPIRVGlobalRegistry.h:31

llvm::SPIRVGlobalRegistry::getSPIRVTypeForVReg
SPIRVType * getSPIRVTypeForVReg(Register VReg, const MachineFunction *MF=nullptr) const
Definition SPIRVGlobalRegistry.cpp:1237

llvm::SPIRVGlobalRegistry::getTypeForSPIRVType
const Type * getTypeForSPIRVType(const SPIRVType *Ty) const
Definition SPIRVGlobalRegistry.h:318

llvm::SPIRVGlobalRegistry::getSPIRVTypeID
Register getSPIRVTypeID(const SPIRVType *SpirvType) const
Definition SPIRVGlobalRegistry.cpp:1080

llvm::SPIRVGlobalRegistry::getScalarOrVectorBitWidth
unsigned getScalarOrVectorBitWidth(const SPIRVType *Type) const
Definition SPIRVGlobalRegistry.cpp:1365

llvm::SPIRVInstrInfo
Definition SPIRVInstrInfo.h:25

llvm::SPIRVInstrInfo::isConstantInstr
bool isConstantInstr(const MachineInstr &MI) const
Definition SPIRVInstrInfo.cpp:29

llvm::SPIRVSubtarget
Definition SPIRVSubtarget.h:38

llvm::SPIRVSubtarget::getInstrInfo
const SPIRVInstrInfo * getInstrInfo() const override
Definition SPIRVSubtarget.h:136

llvm::SPIRVSubtarget::getSPIRVGlobalRegistry
SPIRVGlobalRegistry * getSPIRVGlobalRegistry() const
Definition SPIRVSubtarget.h:119

llvm::SPIRVTargetMachine
Definition SPIRVTargetMachine.h:21

llvm::SPIRVTargetMachine::getSubtargetImpl
const SPIRVSubtarget * getSubtargetImpl() const
Definition SPIRVTargetMachine.h:32

llvm::SmallSet
SmallSet - This maintains a set of unique values, optimizing for the case when the set is small (less...
Definition SmallSet.h:133

llvm::SmallSet::contains
bool contains(const T &V) const
Check if the SmallSet contains the given element.
Definition SmallSet.h:228

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:183

llvm::SmallVectorImpl::emplace_back
reference emplace_back(ArgTypes &&... Args)
Definition SmallVector.h:946

llvm::SmallVectorImpl::append
void append(ItTy in_start, ItTy in_end)
Add the specified range to the end of the SmallVector.
Definition SmallVector.h:686

llvm::SmallVectorImpl::insert
iterator insert(iterator I, T &&Elt)
Definition SmallVector.h:814

llvm::SmallVectorTemplateBase::push_back
void push_back(const T &Elt)
Definition SmallVector.h:419

llvm::SmallVectorTemplateCommon::size
size_t size() const
Definition SmallVector.h:80

llvm::SmallVectorTemplateCommon::begin
iterator begin()
Definition SmallVector.h:273

llvm::SmallVectorTemplateCommon::empty
bool empty() const
Definition SmallVector.h:83

llvm::TargetPassConfig
Target-Independent Code Generator Pass Configuration Options.
Definition TargetPassConfig.h:84

llvm::Type
The instances of the Type class are immutable: once they are created, they are never changed.
Definition Type.h:45

llvm::Type::isVectorTy
bool isVectorTy() const
True if this is an instance of VectorType.
Definition Type.h:273

llvm::Type::getDoubleTy
static LLVM_ABI Type * getDoubleTy(LLVMContext &C)
Definition Type.cpp:285

llvm::Type::getFloatTy
static LLVM_ABI Type * getFloatTy(LLVMContext &C)
Definition Type.cpp:284

llvm::Type::getHalfTy
static LLVM_ABI Type * getHalfTy(LLVMContext &C)
Definition Type.cpp:282

llvm::VersionTuple
Represents a version number in the form major[.minor[.subminor[.build]]].
Definition VersionTuple.h:30

llvm::VersionTuple::empty
bool empty() const
Determine whether this version information is empty (e.g., all version components are zero).
Definition VersionTuple.h:67

llvm::cl::list
Definition CommandLine.h:1697

llvm::cl::opt
Definition CommandLine.h:1454

llvm::ilist_node_with_parent::getNextNode
NodeTy * getNextNode()
Get the next node, or nullptr for the list tail.
Definition ilist_node.h:348

uint32_t

llvm_unreachable
#define llvm_unreachable(msg)
Marks that the current location is not supposed to be reachable.
Definition ErrorHandling.h:164

llvm::AMDGPU::Exp::Target
Target
Definition SIDefines.h:1014

llvm::ARM_MB::ST
@ ST
Definition ARMBaseInfo.h:73

llvm::ARM::ProfileKind::M
@ M
Definition ARMTargetParser.h:171

llvm::CallingConv::C
@ C
The default llvm calling convention, compatible with C.
Definition CallingConv.h:34

llvm::NVPTX::Const
@ Const
Definition NVPTX.h:190

llvm::SPIRV::CooperativeMatrixOperands
Definition SPIRVBaseInfo.h:225

llvm::SPIRV::Extension
Definition SPIRVBaseInfo.h:30

llvm::SPIRV
Definition SPIRVConvergenceRegionAnalysis.h:30

llvm::SPIRV::ModuleSectionType
ModuleSectionType
Definition SPIRVModuleAnalysis.h:31

llvm::SPIRV::MB_Annotations
@ MB_Annotations
Definition SPIRVModuleAnalysis.h:39

llvm::SPIRV::MB_AliasingInsts
@ MB_AliasingInsts
Definition SPIRVModuleAnalysis.h:38

llvm::SPIRV::MB_NonSemanticGlobalDI
@ MB_NonSemanticGlobalDI
Definition SPIRVModuleAnalysis.h:41

llvm::SPIRV::MB_TypeConstVars
@ MB_TypeConstVars
Definition SPIRVModuleAnalysis.h:40

llvm::SPIRV::MB_DebugNames
@ MB_DebugNames
Definition SPIRVModuleAnalysis.h:35

llvm::SPIRV::MB_DebugStrings
@ MB_DebugStrings
Definition SPIRVModuleAnalysis.h:36

llvm::SPIRV::NUM_MODULE_SECTIONS
@ NUM_MODULE_SECTIONS
Definition SPIRVModuleAnalysis.h:43

llvm::SPIRV::MB_ExtFuncDecls
@ MB_ExtFuncDecls
Definition SPIRVModuleAnalysis.h:42

llvm::SPIRV::MB_EntryPoints
@ MB_EntryPoints
Definition SPIRVModuleAnalysis.h:33

llvm::SPIRV::InstrList
SmallVector< const MachineInstr * > InstrList
Definition SPIRVModuleAnalysis.h:128

llvm::XCOFF::StorageClass
StorageClass
Definition XCOFF.h:171

llvm::cl::ZeroOrMore
@ ZeroOrMore
Definition CommandLine.h:115

llvm::cl::Optional
@ Optional
Definition CommandLine.h:114

llvm::cl::Hidden
@ Hidden
Definition CommandLine.h:138

llvm::cl::values
ValuesClass values(OptsTy... Options)
Helper to build a ValuesClass by forwarding a variable number of arguments as an initializer list to ...
Definition CommandLine.h:712

llvm::cl::init
initializer< Ty > init(const Ty &Val)
Definition CommandLine.h:444

llvm::codeview::PublicSymFlags::Function
@ Function
Definition CodeView.h:408

llvm::dxil::OpCode
OpCode
Definition DXILConstants.h:18

llvm::logicalview::LVAttributeKind::Inserted
@ Inserted
Definition LVOptions.h:109

llvm::mdconst::extract
std::enable_if_t< detail::IsValidPointer< X, Y >::value, X * > extract(Y &&MD)
Extract a Value from Metadata.
Definition Metadata.h:668

llvm::objcopy::AdjustKind::Set
@ Set
Definition CommonConfig.h:155

llvm::pdb::PDB_SymType::Exe
@ Exe
Definition PDBTypes.h:245

llvm::rdf::Instr
NodeAddr< InstrNode * > Instr
Definition RDFGraph.h:389

llvm
This is an optimization pass for GlobalISel generic memory operations.
Definition Types.h:26

llvm::buildOpName
void buildOpName(Register Target, const StringRef &Name, MachineIRBuilder &MIRBuilder)
Definition SPIRVUtils.cpp:185

llvm::Value
FunctionAddr VTableAddr Value
Definition InstrProf.h:137

llvm::getStringImm
std::string getStringImm(const MachineInstr &MI, unsigned StartIndex)
Definition SPIRVUtils.cpp:142

llvm::all_of
bool all_of(R &&range, UnaryPredicate P)
Provide wrappers to std::all_of which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1737

llvm::hash_value
hash_code hash_value(const FixedPointSemantics &Val)
Definition APFixedPoint.h:137

llvm::getSymbolicOperandExtensions
ExtensionList getSymbolicOperandExtensions(SPIRV::OperandCategory::OperandCategory Category, uint32_t Value)
Definition SPIRVBaseInfo.cpp:184

llvm::getSymbolicOperandCapabilities
CapabilityList getSymbolicOperandCapabilities(SPIRV::OperandCategory::OperandCategory Category, uint32_t Value)
Definition SPIRVBaseInfo.cpp:128

llvm::ExtensionList
SmallVector< SPIRV::Extension::Extension, 8 > ExtensionList
Definition SPIRVBaseInfo.h:256

llvm::dyn_cast
decltype(auto) dyn_cast(const From &Val)
dyn_cast<X> - Return the argument parameter cast to the specified type.
Definition Casting.h:643

llvm::InstrSignature
SmallVector< size_t > InstrSignature
Definition SPIRVModuleAnalysis.h:217

llvm::getSymbolicOperandMaxVersion
VersionTuple getSymbolicOperandMaxVersion(SPIRV::OperandCategory::OperandCategory Category, uint32_t Value)
Definition SPIRVBaseInfo.cpp:116

llvm::buildOpDecorate
void buildOpDecorate(Register Reg, MachineIRBuilder &MIRBuilder, SPIRV::Decoration::Decoration Dec, const std::vector< uint32_t > &DecArgs, StringRef StrImm)
Definition SPIRVUtils.cpp:212

llvm::getImm
MachineInstr * getImm(const MachineOperand &MO, const MachineRegisterInfo *MRI)
Definition SPIRVUtils.cpp:1070

llvm::getCapabilitiesEnabledByExtension
CapabilityList getCapabilitiesEnabledByExtension(SPIRV::Extension::Extension Extension)
Definition SPIRVBaseInfo.cpp:163

llvm::dbgs
LLVM_ABI raw_ostream & dbgs()
dbgs() - This returns a reference to a raw_ostream for debugging messages.
Definition Debug.cpp:207

llvm::report_fatal_error
LLVM_ABI void report_fatal_error(Error Err, bool gen_crash_diag=true)
Definition Error.cpp:163

llvm::SPIRVType
const MachineInstr SPIRVType
Definition SPIRVGlobalRegistry.h:28

llvm::getSymbolicOperandMnemonic
std::string getSymbolicOperandMnemonic(SPIRV::OperandCategory::OperandCategory Category, int32_t Value)
Definition SPIRVBaseInfo.cpp:66

llvm::errs
LLVM_ABI raw_fd_ostream & errs()
This returns a reference to a raw_ostream for standard error.
Definition raw_ostream.cpp:904

llvm::Op
DWARFExpression::Operation Op
Definition DWARFExpressionPrinter.cpp:22

llvm::getSymbolicOperandMinVersion
VersionTuple getSymbolicOperandMinVersion(SPIRV::OperandCategory::OperandCategory Category, uint32_t Value)
Definition SPIRVBaseInfo.cpp:104

llvm::BitWidth
constexpr unsigned BitWidth
Definition BitmaskEnum.h:219

llvm::cast
decltype(auto) cast(const From &Val)
cast<X> - Return the argument parameter cast to the specified type.
Definition Casting.h:559

llvm::is_contained
bool is_contained(R &&Range, const E &Element)
Returns true if Element is found in Range.
Definition STLExtras.h:1945

llvm::CapabilityList
SmallVector< SPIRV::Capability::Capability, 8 > CapabilityList
Definition SPIRVBaseInfo.h:255

llvm::InstrTraces
std::set< InstrSignature > InstrTraces
Definition SPIRVModuleAnalysis.h:218

llvm::hash_combine
hash_code hash_combine(const Ts &...args)
Combine values into a single hash_code.
Definition Hashing.h:592

llvm::InstrGRegsMap
std::map< SmallVector< size_t >, unsigned > InstrGRegsMap
Definition SPIRVModuleAnalysis.h:219

llvm::reportFatalUsageError
LLVM_ABI void reportFatalUsageError(Error Err)
Report a fatal error that does not indicate a bug in LLVM.
Definition Error.cpp:177

N
#define N

AvoidCapabilitiesSet
Definition SPIRVModuleAnalysis.cpp:49

AvoidCapabilitiesSet::AvoidCapabilitiesSet
AvoidCapabilitiesSet()
Definition SPIRVModuleAnalysis.cpp:51

AvoidCapabilitiesSet::S
SmallSet< SPIRV::Capability::Capability, 4 > S
Definition SPIRVModuleAnalysis.cpp:50

llvm::SPIRVModuleAnalysis
Definition SPIRVModuleAnalysis.h:221

llvm::SPIRVModuleAnalysis::MAI
static struct SPIRV::ModuleAnalysisInfo MAI
Definition SPIRVModuleAnalysis.h:230

llvm::SPIRVModuleAnalysis::ID
static char ID
Definition SPIRVModuleAnalysis.h:222

llvm::SPIRVModuleAnalysis::runOnModule
bool runOnModule(Module &M) override
runOnModule - Virtual method overriden by subclasses to process the module being operated on.
Definition SPIRVModuleAnalysis.cpp:2782

llvm::SPIRVModuleAnalysis::getAnalysisUsage
void getAnalysisUsage(AnalysisUsage &AU) const override
getAnalysisUsage - This function should be overriden by passes that need analysis information to do t...
Definition SPIRVModuleAnalysis.cpp:2777

llvm::SPIRV::FPFastMathDefaultInfoVector
Definition SPIRVUtils.h:145

llvm::SPIRV::FPFastMathDefaultInfoVector::computeFPFastMathDefaultInfoVecIndex
static size_t computeFPFastMathDefaultInfoVecIndex(size_t BitWidth)
Definition SPIRVUtils.h:146

llvm::SPIRV::FPFastMathDefaultInfo
Definition SPIRVUtils.h:117

llvm::SPIRV::ModuleAnalysisInfo
Definition SPIRVModuleAnalysis.h:136

llvm::SPIRV::ModuleAnalysisInfo::Reqs
RequirementHandler Reqs
Definition SPIRVModuleAnalysis.h:137

llvm::SPIRV::ModuleAnalysisInfo::setSkipEmission
void setSkipEmission(const MachineInstr *MI)
Definition SPIRVModuleAnalysis.h:176

llvm::SPIRV::ModuleAnalysisInfo::getRegisterAlias
MCRegister getRegisterAlias(const MachineFunction *MF, Register Reg)
Definition SPIRVModuleAnalysis.h:184

llvm::SPIRV::ModuleAnalysisInfo::getOrCreateMBBRegister
MCRegister getOrCreateMBBRegister(const MachineBasicBlock &MBB)
Definition SPIRVModuleAnalysis.h:207

llvm::SPIRV::ModuleAnalysisInfo::MS
InstrList MS[NUM_MODULE_SECTIONS]
Definition SPIRVModuleAnalysis.h:159

llvm::SPIRV::ModuleAnalysisInfo::Addr
AddressingModel::AddressingModel Addr
Definition SPIRVModuleAnalysis.h:139

llvm::SPIRV::ModuleAnalysisInfo::setRegisterAlias
void setRegisterAlias(const MachineFunction *MF, Register Reg, MCRegister AliasReg)
Definition SPIRVModuleAnalysis.h:180

llvm::SPIRV::ModuleAnalysisInfo::FPFastMathDefaultInfoMap
DenseMap< const Function *, SPIRV::FPFastMathDefaultInfoVector > FPFastMathDefaultInfoMap
Definition SPIRVModuleAnalysis.h:168

llvm::SPIRV::RequirementHandler
Definition SPIRVModuleAnalysis.h:62

llvm::SPIRV::RequirementHandler::addCapabilities
void addCapabilities(const CapabilityList &ToAdd)

llvm::SPIRV::RequirementHandler::isCapabilityAvailable
bool isCapabilityAvailable(Capability::Capability Cap) const
Definition SPIRVModuleAnalysis.h:119

llvm::SPIRV::RequirementHandler::checkSatisfiable
void checkSatisfiable(const SPIRVSubtarget &ST) const

llvm::SPIRV::RequirementHandler::getAndAddRequirements
void getAndAddRequirements(SPIRV::OperandCategory::OperandCategory Category, uint32_t i, const SPIRVSubtarget &ST)

llvm::SPIRV::RequirementHandler::addExtension
void addExtension(Extension::Extension ToAdd)
Definition SPIRVModuleAnalysis.h:105

llvm::SPIRV::RequirementHandler::initAvailableCapabilities
void initAvailableCapabilities(const SPIRVSubtarget &ST)

llvm::SPIRV::RequirementHandler::removeCapabilityIf
void removeCapabilityIf(const Capability::Capability ToRemove, const Capability::Capability IfPresent)

llvm::SPIRV::RequirementHandler::addCapability
void addCapability(Capability::Capability ToAdd)
Definition SPIRVModuleAnalysis.h:101

llvm::SPIRV::RequirementHandler::addAvailableCaps
void addAvailableCaps(const CapabilityList &ToAdd)

llvm::SPIRV::RequirementHandler::addRequirements
void addRequirements(const Requirements &Req)

llvm::SPIRV::Requirements
Definition SPIRVModuleAnalysis.h:46

llvm::SPIRV::Requirements::IsSatisfiable
const bool IsSatisfiable
Definition SPIRVModuleAnalysis.h:47

llvm::SPIRV::Requirements::Cap
const std::optional< Capability::Capability > Cap
Definition SPIRVModuleAnalysis.h:48

llvm::SPIRV::Requirements::MinVer
const VersionTuple MinVer
Definition SPIRVModuleAnalysis.h:50

llvm::SPIRV::Requirements::MaxVer
const VersionTuple MaxVer
Definition SPIRVModuleAnalysis.h:51

llvm::SPIRV::Requirements::Exts
const ExtensionList Exts
Definition SPIRVModuleAnalysis.h:49

llvm::cl::desc
Definition CommandLine.h:410