doxygen/NVGPUToNVVM_8cpp_source.html

 //===- NVGPUToNVVM.cpp - NVGPU to NVVM dialect conversion -----------------===//

 //

 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.

 // See https://llvm.org/LICENSE.txt for license information.

 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

 //

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


 #include "mlir/Conversion/NVGPUToNVVM/NVGPUToNVVM.h"


 #include "mlir/Conversion/GPUCommon/GPUCommonPass.h"

 #include "mlir/Conversion/LLVMCommon/ConversionTarget.h"

 #include "mlir/Conversion/LLVMCommon/Pattern.h"

 #include "mlir/Conversion/LLVMCommon/VectorPattern.h"

 #include "mlir/Dialect/Arith/IR/Arith.h"

 #include "mlir/Dialect/GPU/IR/GPUDialect.h"

 #include "mlir/Dialect/LLVMIR/LLVMDialect.h"

 #include "mlir/Dialect/LLVMIR/LLVMTypes.h"

 #include "mlir/Dialect/LLVMIR/NVVMDialect.h"

 #include "mlir/Dialect/MemRef/IR/MemRef.h"

 #include "mlir/Dialect/NVGPU/IR/NVGPUDialect.h"

 #include "mlir/Dialect/SCF/Transforms/Patterns.h"

 #include "mlir/IR/BuiltinTypes.h"

 #include "mlir/IR/ImplicitLocOpBuilder.h"

 #include "mlir/IR/PatternMatch.h"

 #include "mlir/IR/TypeUtilities.h"

 #include "mlir/IR/Value.h"

 #include "mlir/Pass/Pass.h"

 #include "llvm/Support/Debug.h"

 #include "llvm/Support/ErrorHandling.h"

 #include "llvm/Support/raw_ostream.h"

 #include <optional>


 #define DEBUG_TYPE "nvgpu-to-nvvm"

 #define DBGS() (llvm::dbgs() << '[' << DEBUG_TYPE << "] ")

 #define DBGSE() (llvm::dbgs())


 namespace mlir {

 #define GEN_PASS_DEF_CONVERTNVGPUTONVVMPASS

 #include "mlir/Conversion/Passes.h.inc"

 } // namespace mlir


 using namespace mlir;


 /// Number of bits that needs to be excluded when building matrix descriptor for

 /// wgmma operations.

 constexpr int exclude4LSB = 4;


 /// GPU has 32 bit registers, this function truncates values when larger width

 /// is not needed.

 static Value truncToI32(ImplicitLocOpBuilder &b, Value value) {

   Type type = value.getType();

   assert(llvm::isa<IntegerType>(type) && "expected an integer Value");

   if (type.getIntOrFloatBitWidth() <= 32)

     return value;

   return b.create<LLVM::TruncOp>(b.getI32Type(), value);

 }


 /// Returns the type for the intrinsic given the vectorResultType of the

 /// `gpu.mma.sync` operation.

 static Type inferIntrinsicResultType(Type vectorResultType) {

   MLIRContext *ctx = vectorResultType.getContext();

   auto a = cast<LLVM::LLVMArrayType>(vectorResultType);

   auto f16x2Ty = LLVM::getFixedVectorType(Float16Type::get(ctx), 2);

   auto i32Ty = IntegerType::get(ctx, 32);

   auto i32x2Ty = LLVM::getFixedVectorType(i32Ty, 2);

   Type f64Ty = Float64Type::get(ctx);

   Type f64x2Ty = LLVM::getFixedVectorType(f64Ty, 2);

   Type f32Ty = Float32Type::get(ctx);

   Type f32x2Ty = LLVM::getFixedVectorType(f32Ty, 2);

   if (a.getElementType() == f16x2Ty) {

     return LLVM::LLVMStructType::getLiteral(

         ctx, SmallVector<Type>(a.getNumElements(), f16x2Ty));

   }

   if (a.getElementType() == i32x2Ty) {

     return LLVM::LLVMStructType::getLiteral(

         ctx,

         SmallVector<Type>(static_cast<size_t>(a.getNumElements()) * 2, i32Ty));

   }

   if (a.getElementType() == f64x2Ty) {

     return LLVM::LLVMStructType::getLiteral(ctx, {f64Ty, f64Ty});

   }

   if (a.getElementType() == f32x2Ty) {

     return LLVM::LLVMStructType::getLiteral(

         ctx,

         SmallVector<Type>(static_cast<size_t>(a.getNumElements()) * 2, f32Ty));

   }

   if (a.getElementType() == LLVM::getFixedVectorType(f32Ty, 1)) {

     return LLVM::LLVMStructType::getLiteral(

         ctx, SmallVector<Type>(static_cast<size_t>(a.getNumElements()), f32Ty));

   }

   return vectorResultType;

 }


 /// Convert the SSA result of the NVVM intrinsic `nvvm.mma.sync` (which is

 /// always an LLVM struct) into a fragment that is compatible with the vector

 /// type of this operation. This involves extracting elements from the struct

 /// and inserting them into an LLVM array. These extra data-movement

 /// operations should be canonicalized away by the LLVM backend.

 static Value convertIntrinsicResult(Location loc, Type intrinsicResultType,

                                     Type resultType, Value intrinsicResult,

                                     RewriterBase &rewriter) {

   MLIRContext *ctx = rewriter.getContext();

   auto structType = dyn_cast<LLVM::LLVMStructType>(intrinsicResultType);

   auto arrayType = dyn_cast<LLVM::LLVMArrayType>(resultType);

   Type i32Ty = rewriter.getI32Type();

   Type f32Ty = rewriter.getF32Type();

   Type f64Ty = rewriter.getF64Type();

   Type f16x2Ty = LLVM::getFixedVectorType(rewriter.getF16Type(), 2);

   Type i32x2Ty = LLVM::getFixedVectorType(i32Ty, 2);

   Type f64x2Ty = LLVM::getFixedVectorType(f64Ty, 2);

   Type f32x2Ty = LLVM::getFixedVectorType(f32Ty, 2);

   Type f32x1Ty = LLVM::getFixedVectorType(f32Ty, 1);


   auto makeConst = [&](int32_t index) -> Value {

     return rewriter.create<LLVM::ConstantOp>(loc, IntegerType::get(ctx, 32),

                                              rewriter.getI32IntegerAttr(index));

   };


   if (arrayType) {

     SmallVector<Value, 4> elements;


     // The intrinsic returns 32-bit wide elements in a form which can be

     // directly bitcasted and inserted into the result vector.

     if (arrayType.getElementType() == f16x2Ty ||

         arrayType.getElementType() == f32x1Ty) {

       for (unsigned i = 0; i < structType.getBody().size(); i++) {

         Value el =

             rewriter.create<LLVM::ExtractValueOp>(loc, intrinsicResult, i);

         el = rewriter.createOrFold<LLVM::BitcastOp>(

             loc, arrayType.getElementType(), el);

         elements.push_back(el);

       }

     }


     // The intrinsic returns i32, f64, and f32 values as individual scalars,

     // even when the result is notionally a 64-bit wide element (e.g. f32x2). We

     // need to extract them from the struct and pack them into the 64-bit wide

     // rows of the vector result.

     if (arrayType.getElementType() == i32x2Ty ||

         arrayType.getElementType() == f64x2Ty ||

         arrayType.getElementType() == f32x2Ty) {


       for (unsigned i = 0, e = structType.getBody().size() / 2; i < e; i++) {

         Value vec =

             rewriter.create<LLVM::PoisonOp>(loc, arrayType.getElementType());

         Value x1 =

             rewriter.create<LLVM::ExtractValueOp>(loc, intrinsicResult, i * 2);

         Value x2 = rewriter.create<LLVM::ExtractValueOp>(loc, intrinsicResult,

                                                          i * 2 + 1);

         vec = rewriter.create<LLVM::InsertElementOp>(loc, vec.getType(), vec,

                                                      x1, makeConst(0));

         vec = rewriter.create<LLVM::InsertElementOp>(loc, vec.getType(), vec,

                                                      x2, makeConst(1));

         elements.push_back(vec);

       }

     }


     // Create the final vectorized result.

     Value result = rewriter.create<LLVM::PoisonOp>(loc, arrayType);

     for (const auto &el : llvm::enumerate(elements)) {

       result = rewriter.create<LLVM::InsertValueOp>(loc, result, el.value(),

                                                     el.index());

     }

     return result;

   }


   return intrinsicResult;

 }


 /// The `gpu.mma.sync` converter below expects matrix fragment operands to be

 /// given as 2D `vectors` where the rows are 32b or 64b wide. The

 /// `nvvm.mma.sync` op expects these argments to be a given in a long list of

 /// scalars of certain types. This function helps unpack the `vector` arguments

 /// and cast them to the types expected by `nvvm.mma.sync`.

 static SmallVector<Value> unpackOperandVector(ImplicitLocOpBuilder &b,

                                               Value operand,

                                               NVVM::MMATypes operandPtxType) {

   SmallVector<Value> result;

   Type i32Ty = b.getI32Type();

   Type f64Ty = b.getF64Type();

   Type f32Ty = b.getF32Type();

   Type i64Ty = b.getI64Type();

   Type i8x4Ty = LLVM::getFixedVectorType(b.getI8Type(), 4);

   Type i4x8Ty = LLVM::getFixedVectorType(b.getIntegerType(4), 8);

   Type f32x1Ty = LLVM::getFixedVectorType(f32Ty, 1);

   auto arrayTy = cast<LLVM::LLVMArrayType>(operand.getType());


   for (unsigned i = 0, e = arrayTy.getNumElements(); i < e; ++i) {

     Value toUse = b.create<LLVM::ExtractValueOp>(operand, i);


     // For 4xi8 vectors, the intrinsic expects these to be provided as i32

     // scalar types.

     if (arrayTy.getElementType() == i8x4Ty ||

         arrayTy.getElementType() == i4x8Ty ||

         (arrayTy.getElementType() == f32x1Ty &&

          operandPtxType == NVVM::MMATypes::tf32)) {

       result.push_back(b.create<LLVM::BitcastOp>(i32Ty, toUse));

       continue;

     }


     // For some element types (i32, f32, f64), we need to unpack the inner

     // vector/array type as well because the intrinsic expects individual

     // scalars to be provided.

     VectorType innerArrayTy = dyn_cast<VectorType>(arrayTy.getElementType());

     if (innerArrayTy && (innerArrayTy.getElementType() == i32Ty ||

                          innerArrayTy.getElementType() == f64Ty ||

                          innerArrayTy.getElementType() == f32Ty)) {

       for (unsigned idx = 0, innerSize = innerArrayTy.getNumElements();

            idx < innerSize; idx++) {

         result.push_back(b.create<LLVM::ExtractElementOp>(

             toUse,

             b.create<LLVM::ConstantOp>(i64Ty, b.getI64IntegerAttr(idx))));

       }

       continue;

     }

     result.push_back(toUse);

   }

   return result;

 }


 /// Returns whether mbarrier object has shared memory address space.

 static bool isMbarrierShared(nvgpu::MBarrierGroupType barrierType) {

   return (mlir::nvgpu::NVGPUDialect::isSharedMemoryAddressSpace(

       barrierType.getMemorySpace()));

 }


 /// Returns the memory space attribute of the mbarrier object.

 Attribute nvgpu::getMbarrierMemorySpace(MLIRContext *context,

                                         nvgpu::MBarrierGroupType barrierType) {

   Attribute memorySpace = {};

   if (isMbarrierShared(barrierType)) {

     memorySpace =

         IntegerAttr::get(IntegerType::get(context, 64),

                          nvgpu::NVGPUDialect::kSharedMemoryAddressSpace);

   }

   return memorySpace;

 }


 /// Returns memref type of the mbarrier object. The type is defined in the

 /// MBarrierGroupType.

 MemRefType nvgpu::getMBarrierMemrefType(MLIRContext *context,

                                         nvgpu::MBarrierGroupType barrierType) {

   Attribute memorySpace = nvgpu::getMbarrierMemorySpace(context, barrierType);

   MemRefLayoutAttrInterface layout;

   return MemRefType::get({barrierType.getNumBarriers()},

                          IntegerType::get(context, 64), layout, memorySpace);

 }


 namespace {


 struct MmaLdMatrixOpToNVVM : public ConvertOpToLLVMPattern<nvgpu::LdMatrixOp> {

   using ConvertOpToLLVMPattern<nvgpu::LdMatrixOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::LdMatrixOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     MLIRContext *ctx = getContext();

     ImplicitLocOpBuilder b(op.getLoc(), rewriter);


     // The result type of ldmatrix will always be a struct of 32bit integer

     // registers if more than one 32bit value is returned. Otherwise, the result

     // is a single i32. The result type of the GPU operation is always a vector

     // of shape (NumRegisters, VectorRegister) where VectorRegister is the

     // vector type of the result and always 32 bits long. We bitcast the result

     // of the NVVM::LdMatrix to this vector type.

     auto vectorResultType = dyn_cast<VectorType>(op->getResultTypes()[0]);

     if (!vectorResultType) {

       return failure();

     }

     Type innerVectorType = LLVM::getFixedVectorType(

         vectorResultType.getElementType(), vectorResultType.getDimSize(1));


     int64_t num32BitRegs = vectorResultType.getDimSize(0);


     Type ldMatrixResultType;

     if (num32BitRegs > 1) {

       ldMatrixResultType = LLVM::LLVMStructType::getLiteral(

           ctx, SmallVector<Type>(num32BitRegs, rewriter.getI32Type()));

     } else {

       ldMatrixResultType = rewriter.getI32Type();

     }


     auto srcMemrefType = cast<MemRefType>(op.getSrcMemref().getType());

     Value srcPtr =

         getStridedElementPtr(b.getLoc(), srcMemrefType, adaptor.getSrcMemref(),

                              adaptor.getIndices(), rewriter);

     Value ldMatrixResult = b.create<NVVM::LdMatrixOp>(

         ldMatrixResultType, srcPtr,

         /*num=*/op.getNumTiles(),

         /*layout=*/op.getTranspose() ? NVVM::MMALayout::col

                                      : NVVM::MMALayout::row);


     // The ldmatrix operation returns either a single i32 value or a struct of

     // i32 values. Here we unpack those values and cast them back to their

     // actual vector type (still of width 32b) and repack them into a result

     // struct.

     Type finalResultType = typeConverter->convertType(vectorResultType);

     Value result = b.create<LLVM::PoisonOp>(finalResultType);

     for (int64_t i = 0, e = vectorResultType.getDimSize(0); i < e; i++) {

       Value i32Register =

           num32BitRegs > 1 ? b.create<LLVM::ExtractValueOp>(ldMatrixResult, i)

                            : ldMatrixResult;

       Value casted = b.create<LLVM::BitcastOp>(innerVectorType, i32Register);

       result = b.create<LLVM::InsertValueOp>(result, casted, i);

     }


     rewriter.replaceOp(op, result);

     return success();

   }

 };


 /// Convert the given type into the corresponding PTX type (NVVM::MMATypes

 /// enum).

 static FailureOr<NVVM::MMATypes> getNvvmMmaType(Type t) {

   Type elType = getElementTypeOrSelf(t);

   if (elType.isInteger(8))

     return NVVM::MMATypes::s8;

   if (elType.isInteger(4))

     return NVVM::MMATypes::s4;

   if (elType.isF16())

     return NVVM::MMATypes::f16;

   if (elType.isF64())

     return NVVM::MMATypes::f64;

   if (elType.isF32())

     return NVVM::MMATypes::tf32;

   return failure();

 }


 struct MmaSyncOptoNVVM : public ConvertOpToLLVMPattern<nvgpu::MmaSyncOp> {

   using ConvertOpToLLVMPattern<nvgpu::MmaSyncOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::MmaSyncOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op.getLoc(), rewriter);

     // Get the shapes of the MMAMatrix type being used. The shapes will

     // choose which intrinsic this op will be lowered to.

     VectorType aType = op.getMatrixA().getType();

     VectorType bType = op.getMatrixA().getType();

     VectorType cType = op.getMatrixC().getType();


     std::array<int64_t, 3> gemmShape = op.getMmaShapeAsArray();


     // Tensor Cores (mma.sync) on F32 works only with TensorFloat32 (TF32).

     bool tf32Enabled = op->hasAttr(op.getTf32EnabledAttrName());

     if (aType.getElementType().isF32() && !tf32Enabled)

       return failure();


     FailureOr<NVVM::MMATypes> ptxTypeA = getNvvmMmaType(aType);

     if (failed(ptxTypeA))

       return op->emitOpError("failed to deduce operand PTX types");

     FailureOr<NVVM::MMATypes> ptxTypeB = getNvvmMmaType(bType);

     if (failed(ptxTypeB))

       return op->emitOpError("failed to deduce operand PTX types");

     std::optional<NVVM::MMATypes> ptxTypeC =

         NVVM::MmaOp::inferOperandMMAType(cType.getElementType(),

                                          /*isAccumulator=*/true);

     if (!ptxTypeC)

       return op->emitError(

           "could not infer the PTX type for the accumulator/result");


     // TODO: add an attribute to the op to customize this behavior.

     std::optional<NVVM::MMAIntOverflow> overflow(std::nullopt);

     if (isa<IntegerType>(aType.getElementType()))

       overflow = NVVM::MMAIntOverflow::satfinite;


     SmallVector<Value> matA =

         unpackOperandVector(b, adaptor.getMatrixA(), *ptxTypeA);

     SmallVector<Value> matB =

         unpackOperandVector(b, adaptor.getMatrixB(), *ptxTypeB);

     SmallVector<Value> matC =

         unpackOperandVector(b, adaptor.getMatrixC(), *ptxTypeC);


     Type desiredRetTy = typeConverter->convertType(op->getResultTypes()[0]);

     Type intrinsicResTy = inferIntrinsicResultType(

         typeConverter->convertType(op->getResultTypes()[0]));

     Value intrinsicResult = b.create<NVVM::MmaOp>(

         intrinsicResTy, matA, matB, matC,

         /*shape=*/gemmShape,

         /*b1Op=*/std::nullopt,

         /*intOverflow=*/overflow,

         /*multiplicandPtxTypes=*/

         std::array<NVVM::MMATypes, 2>{*ptxTypeA, *ptxTypeB},

         /*multiplicandLayouts=*/

         std::array<NVVM::MMALayout, 2>{NVVM::MMALayout::row,

                                        NVVM::MMALayout::col});

     rewriter.replaceOp(op, convertIntrinsicResult(op.getLoc(), intrinsicResTy,

                                                   desiredRetTy, intrinsicResult,

                                                   rewriter));

     return success();

   }

 };


 struct ConvertNVGPUToNVVMPass

     : public impl::ConvertNVGPUToNVVMPassBase<ConvertNVGPUToNVVMPass> {

   using Base::Base;


   void getDependentDialects(DialectRegistry &registry) const override {

     registry.insert<memref::MemRefDialect, LLVM::LLVMDialect, NVVM::NVVMDialect,

                     arith::ArithDialect>();

   }


   void runOnOperation() override {

     LowerToLLVMOptions options(&getContext());

     RewritePatternSet patterns(&getContext());

     LLVMTypeConverter converter(&getContext(), options);

     IRRewriter rewriter(&getContext());

     populateGpuMemorySpaceAttributeConversions(

         converter, [](gpu::AddressSpace space) -> unsigned {

           switch (space) {

           case gpu::AddressSpace::Global:

             return static_cast<unsigned>(

                 NVVM::NVVMMemorySpace::kGlobalMemorySpace);

           case gpu::AddressSpace::Workgroup:

             return static_cast<unsigned>(

                 NVVM::NVVMMemorySpace::kSharedMemorySpace);

           case gpu::AddressSpace::Private:

             return 0;

           }

           llvm_unreachable("unknown address space enum value");

           return 0;

         });

     /// device-side async tokens cannot be materialized in nvvm. We just

     /// convert them to a dummy i32 type in order to easily drop them during

     /// conversion.

     converter.addConversion([&](nvgpu::DeviceAsyncTokenType type) -> Type {

       return converter.convertType(IntegerType::get(type.getContext(), 32));

     });

     converter.addConversion([&](nvgpu::WarpgroupAccumulatorType type) -> Type {

       Type elemType = type.getFragmented().getElementType();

       int64_t sizeM = type.getFragmented().getDimSize(0);

       int64_t sizeN = type.getFragmented().getDimSize(1);


       unsigned numMembers;

       if (elemType.isF32() || elemType.isInteger(32))

         numMembers = sizeN / 2;

       else if (elemType.isF16())

         numMembers = sizeN / 4;

       else

         llvm_unreachable("unsupported type for warpgroup accumulator");


       SmallVector<Type> innerStructBody;

       for (unsigned i = 0; i < numMembers; i++)

         innerStructBody.push_back(elemType);

       auto innerStructType =

           LLVM::LLVMStructType::getLiteral(type.getContext(), innerStructBody);


       SmallVector<Type> structBody;

       for (int i = 0; i < sizeM; i += kWgmmaSizeM)

         structBody.push_back(innerStructType);


       auto convertedType =

           LLVM::LLVMStructType::getLiteral(type.getContext(), structBody);

       return converter.convertType(convertedType);

     });

     converter.addConversion([&](nvgpu::MBarrierTokenType type) -> Type {

       return converter.convertType(IntegerType::get(type.getContext(), 64));

     });

     converter.addConversion(

         [&](nvgpu::WarpgroupMatrixDescriptorType type) -> Type {

           return converter.convertType(IntegerType::get(type.getContext(), 64));

         });

     converter.addConversion([&](nvgpu::MBarrierGroupType type) -> Type {

       return converter.convertType(

           nvgpu::getMBarrierMemrefType(rewriter.getContext(), type));

     });

     converter.addConversion([&](nvgpu::TensorMapDescriptorType type) -> Type {

       return LLVM::LLVMPointerType::get(type.getContext());

     });

     populateNVGPUToNVVMConversionPatterns(converter, patterns);

     LLVMConversionTarget target(getContext());

     target.addLegalDialect<::mlir::LLVM::LLVMDialect>();

     target.addLegalDialect<::mlir::arith::ArithDialect>();

     target.addLegalDialect<::mlir::memref::MemRefDialect>();

     target.addLegalDialect<::mlir::NVVM::NVVMDialect>();

     mlir::scf::populateSCFStructuralTypeConversionsAndLegality(

         converter, patterns, target);

     if (failed(applyPartialConversion(getOperation(), target,

                                       std::move(patterns))))

       signalPassFailure();

   }

 };


 /// Returns the constraints for the sparse MMA inline assembly instruction.

 static std::string buildMmaSparseAsmConstraintString(unsigned matASize,

                                                      unsigned matBSize,

                                                      unsigned matCSize) {

   std::string str;

   llvm::raw_string_ostream ss(str);

   for (unsigned i = 0; i < matCSize; i++)

     ss << "=r,";

   for (unsigned i = 0; i < matASize + matBSize + matCSize; i++)

     ss << "r,";

   // The final operand is for the sparsity metadata.

   // The sparsity selector appears as direct literal.

   ss << "r";

   return str;

 }


 /// Returns the string for the `mma.sp.sync` instruction that corresponds to

 /// the given parameters. Note that this function doesn't do any validation,

 /// it's expected that the provided parameters correspond to a valid

 /// instruction.

 static std::string buildMmaSparseAsmString(

     const std::array<int64_t, 3> &shape, unsigned matASize, unsigned matBSize,

     unsigned matCSize, NVVM::MMATypes ptxTypeA, NVVM::MMATypes ptxTypeB,

     NVVM::MMATypes ptxTypeC, NVVM::MMATypes ptxTypeD,

     std::optional<NVVM::MMAIntOverflow> overflow, unsigned metaDataSelector) {

   auto ptxTypeStr = [](NVVM::MMATypes ptxType) {

     return NVVM::stringifyMMATypes(ptxType);

   };


   std::string asmStr;

   llvm::raw_string_ostream ss(asmStr);

   ss << "mma.sp.sync.aligned.m" << shape[0] << "n" << shape[1] << "k"

      << shape[2] << ".row.col.";


   if (overflow)

     ss << NVVM::stringifyMMAIntOverflow(*overflow) << ".";


   ss << ptxTypeStr(ptxTypeD) << "." << ptxTypeStr(ptxTypeA) << "."

      << ptxTypeStr(ptxTypeB) << "." << ptxTypeStr(ptxTypeC) << " ";

   unsigned asmArgIdx = 0;


   // The operand string is structured into sections `{matC elements...},

   // {matA elements...}, {matB elements...}, {matC elements}`.

   for (const auto arrSize : {matCSize, matASize, matBSize, matCSize}) {

     ss << "{";

     for (unsigned i = 0; i < arrSize; i++)

       ss << "$" << asmArgIdx++ << (i < arrSize - 1 ? "," : "");

     ss << "},";

   }

   ss << "$" << asmArgIdx++ << ",";

   assert(metaDataSelector <= 1);

   ss << "0x" << metaDataSelector << ";";

   return asmStr;

 }


 /// Builds an inline assembly operation corresponding to the specified MMA

 /// sparse sync operation.

 static FailureOr<LLVM::InlineAsmOp> emitMmaSparseSyncOpAsm(

     ImplicitLocOpBuilder &b, NVVM::MMATypes ptxTypeA, NVVM::MMATypes ptxTypeB,

     NVVM::MMATypes ptxTypeC, NVVM::MMATypes ptxTypeD,

     std::optional<NVVM::MMAIntOverflow> overflow, ArrayRef<Value> unpackedAData,

     ArrayRef<Value> unpackedB, ArrayRef<Value> unpackedC, Value indexData,

     int64_t metadataSelector, const std::array<int64_t, 3> &shape,

     Type intrinsicResultType) {

   auto asmDialectAttr =

       LLVM::AsmDialectAttr::get(b.getContext(), LLVM::AsmDialect::AD_ATT);


   const unsigned matASize = unpackedAData.size();

   const unsigned matBSize = unpackedB.size();

   const unsigned matCSize = unpackedC.size();


   std::string asmStr = buildMmaSparseAsmString(

       shape, matASize, matBSize, matCSize, ptxTypeA, ptxTypeB, ptxTypeC,

       ptxTypeD, overflow, metadataSelector);

   std::string constraintStr =

       buildMmaSparseAsmConstraintString(matASize, matBSize, matCSize);


   SmallVector<Value> asmVals;

   asmVals.reserve(matASize + matBSize + matCSize + 1);

   for (ArrayRef<Value> args : {unpackedAData, unpackedB, unpackedC})

     llvm::append_range(asmVals, args);

   asmVals.push_back(indexData);


   return b.create<LLVM::InlineAsmOp>(

       /*resultTypes=*/intrinsicResultType,

       /*operands=*/asmVals,

       /*asm_string=*/asmStr,

       /*constraints=*/constraintStr,

       /*has_side_effects=*/true,

       /*is_align_stack=*/false,

       /*asm_dialect=*/asmDialectAttr,

       /*operand_attrs=*/ArrayAttr());

 }


 /// Lowers `nvgpu.mma.sp.sync` to inline assembly.

 struct NVGPUMmaSparseSyncLowering

     : public ConvertOpToLLVMPattern<nvgpu::MmaSparseSyncOp> {

   using ConvertOpToLLVMPattern<nvgpu::MmaSparseSyncOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::MmaSparseSyncOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op.getLoc(), rewriter);

     // Get the shapes of the MMAMatrix type being used. The shapes will

     // choose which intrinsic this op will be lowered to.

     VectorType aType = op.getMatrixA().getType();

     VectorType bType = op.getMatrixB().getType();

     VectorType cType = op.getMatrixC().getType();


     FailureOr<NVVM::MMATypes> ptxTypeA = getNvvmMmaType(aType);

     if (failed(ptxTypeA))

       return op->emitOpError("failed to deduce operand PTX types");

     FailureOr<NVVM::MMATypes> ptxTypeB = getNvvmMmaType(bType);

     if (failed(ptxTypeB))

       return op->emitOpError("failed to deduce operand PTX types");

     std::optional<NVVM::MMATypes> ptxTypeC =

         NVVM::MmaOp::inferOperandMMAType(cType.getElementType(),

                                          /*isAccumulator=*/true);

     if (!ptxTypeC)

       return op->emitError(

           "could not infer the PTX type for the accumulator/result");


     // Same as `mma.sync`, F32 works only with TensorFloat32 (TF32).

     bool tf32Enabled = op->hasAttr(op.getTf32EnabledAttrName());

     if (aType.getElementType().isF32() && !tf32Enabled)

       return failure();


     // TODO: add an attribute to the op to customize this behavior.

     std::optional<NVVM::MMAIntOverflow> overflow(std::nullopt);

     if (isa<IntegerType>(aType.getElementType()))

       overflow = NVVM::MMAIntOverflow::satfinite;


     SmallVector<Value> matA =

         unpackOperandVector(b, adaptor.getMatrixA(), *ptxTypeA);

     SmallVector<Value> matB =

         unpackOperandVector(b, adaptor.getMatrixB(), *ptxTypeB);

     SmallVector<Value> matC =

         unpackOperandVector(b, adaptor.getMatrixC(), *ptxTypeC);


     Type desiredRetTy = typeConverter->convertType(op->getResultTypes()[0]);

     Type intrinsicResTy = inferIntrinsicResultType(

         typeConverter->convertType(op->getResultTypes()[0]));


     // Bitcast the sparse metadata from vector<2xf16> to an i32.

     Value sparseMetadata = adaptor.getSparseMetadata();

     if (sparseMetadata.getType() !=

         LLVM::getFixedVectorType(rewriter.getI16Type(), 2))

       return op->emitOpError() << "Expected metadata type to be LLVM "

                                   "VectorType of 2 i16 elements";

     sparseMetadata =

         b.create<LLVM::BitcastOp>(rewriter.getI32Type(), sparseMetadata);


     FailureOr<LLVM::InlineAsmOp> intrinsicResult = emitMmaSparseSyncOpAsm(

         b, *ptxTypeA, *ptxTypeB, *ptxTypeC, *ptxTypeC, overflow, matA, matB,

         matC, sparseMetadata, op.getSparsitySelector(), op.getMmaShapeAsArray(),

         intrinsicResTy);

     if (failed(intrinsicResult))

       return failure();


     assert((*intrinsicResult).getNumResults() == 1 &&

            "expected inline asm op returns a single LLVM struct type");

     rewriter.replaceOp(

         op, convertIntrinsicResult(op.getLoc(), intrinsicResTy, desiredRetTy,

                                    (*intrinsicResult)->getResult(0), rewriter));

     return success();

   }

 };


 struct NVGPUAsyncCopyLowering

     : public ConvertOpToLLVMPattern<nvgpu::DeviceAsyncCopyOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::DeviceAsyncCopyOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::DeviceAsyncCopyOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op.getLoc(), rewriter);

     Location loc = op.getLoc();

     auto dstMemrefType = cast<MemRefType>(op.getDst().getType());

     Value dstPtr =

         getStridedElementPtr(b.getLoc(), dstMemrefType, adaptor.getDst(),

                              adaptor.getDstIndices(), rewriter);

     FailureOr<unsigned> dstAddressSpace =

         getTypeConverter()->getMemRefAddressSpace(dstMemrefType);

     if (failed(dstAddressSpace))

       return rewriter.notifyMatchFailure(

           loc, "destination memref address space not convertible to integer");


     auto srcMemrefType = cast<MemRefType>(op.getSrc().getType());

     FailureOr<unsigned> srcAddressSpace =

         getTypeConverter()->getMemRefAddressSpace(srcMemrefType);

     if (failed(srcAddressSpace))

       return rewriter.notifyMatchFailure(

           loc, "source memref address space not convertible to integer");


     Value scrPtr = getStridedElementPtr(loc, srcMemrefType, adaptor.getSrc(),

                                         adaptor.getSrcIndices(), rewriter);

     // Intrinsics takes a global pointer so we need an address space cast.

     auto srcPointerGlobalType = LLVM::LLVMPointerType::get(

         op->getContext(), NVVM::NVVMMemorySpace::kGlobalMemorySpace);

     scrPtr = b.create<LLVM::AddrSpaceCastOp>(srcPointerGlobalType, scrPtr);

     int64_t dstElements = adaptor.getDstElements().getZExtValue();

     int64_t sizeInBytes =

         (dstMemrefType.getElementTypeBitWidth() * dstElements) / 8;

     // When the optional SrcElements argument is *not* present, the regular

     // CpAsyncOp is generated. CopyAsyncOp reads bytes from source (global

     // memory) to fill DstElements number of elements in the destination

     // (shared memory).

     Value srcBytes = adaptor.getSrcElements();

     if (srcBytes) {

       // When the optional SrcElements argument is present, the source (global

       // memory) of CpAsyncOp is read only for SrcElements number of elements.

       // The rest of the DstElements in the destination (shared memory) are

       // filled with zeros.

       Value c3I32 =

           b.create<LLVM::ConstantOp>(b.getI32Type(), b.getI32IntegerAttr(3));

       Value bitwidth = b.create<LLVM::ConstantOp>(

           b.getI32Type(),

           b.getI32IntegerAttr(srcMemrefType.getElementTypeBitWidth()));

       Value srcElementsI32 = b.create<LLVM::TruncOp>(b.getI32Type(), srcBytes);

       srcBytes = b.create<LLVM::LShrOp>(

           b.create<LLVM::MulOp>(bitwidth, srcElementsI32), c3I32);

     }

     // Cache global (.cg) for 16 dst bytes, Cache all (.ca) for sizes other than

     // 16 dst bytes.

     NVVM::LoadCacheModifierKind cacheModifier =

         (op.getBypassL1().value_or(false) && sizeInBytes == 16)

             ? NVVM::LoadCacheModifierKind::CG

             : NVVM::LoadCacheModifierKind::CA;


     b.create<NVVM::CpAsyncOp>(

         dstPtr, scrPtr, rewriter.getI32IntegerAttr(sizeInBytes),

         NVVM::LoadCacheModifierKindAttr::get(op->getContext(), cacheModifier),

         srcBytes);


     // Drop the result token.

     Value zero = b.create<LLVM::ConstantOp>(

         IntegerType::get(op.getContext(), 32), rewriter.getI32IntegerAttr(0));

     rewriter.replaceOp(op, zero);

     return success();

   }

 };


 struct NVGPUAsyncCreateGroupLowering

     : public ConvertOpToLLVMPattern<nvgpu::DeviceAsyncCreateGroupOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::DeviceAsyncCreateGroupOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::DeviceAsyncCreateGroupOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     rewriter.create<NVVM::CpAsyncCommitGroupOp>(op.getLoc());

     // Drop the result token.

     Value zero = rewriter.create<LLVM::ConstantOp>(

         op->getLoc(), IntegerType::get(op.getContext(), 32),

         rewriter.getI32IntegerAttr(0));

     rewriter.replaceOp(op, zero);

     return success();

   }

 };


 struct NVGPUAsyncWaitLowering

     : public ConvertOpToLLVMPattern<nvgpu::DeviceAsyncWaitOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::DeviceAsyncWaitOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::DeviceAsyncWaitOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     // If numGroup is not present pick 0 as a conservative correct value.

     int32_t numGroups = adaptor.getNumGroups().value_or(0);

     rewriter.create<NVVM::CpAsyncWaitGroupOp>(op.getLoc(), numGroups);

     rewriter.eraseOp(op);

     return success();

   }

 };


 /// Creates mbarrier object in shared memory

 struct NVGPUMBarrierCreateLowering

     : public ConvertOpToLLVMPattern<nvgpu::MBarrierCreateOp> {

   using ConvertOpToLLVMPattern<nvgpu::MBarrierCreateOp>::ConvertOpToLLVMPattern;


   template <typename moduleT>

   memref::GlobalOp generateGlobalBarrier(ConversionPatternRewriter &rewriter,

                                          Operation *funcOp, moduleT moduleOp,

                                          MemRefType barrierType) const {

     SymbolTable symbolTable(moduleOp);

     OpBuilder::InsertionGuard guard(rewriter);

     rewriter.setInsertionPoint(&moduleOp.front());

     auto global = rewriter.create<memref::GlobalOp>(

         funcOp->getLoc(), "__mbarrier",

         /*sym_visibility=*/rewriter.getStringAttr("private"),

         /*type=*/barrierType,

         /*initial_value=*/ElementsAttr(),

         /*constant=*/false,

         /*alignment=*/rewriter.getI64IntegerAttr(8));

     symbolTable.insert(global);

     return global;

   }


   LogicalResult

   matchAndRewrite(nvgpu::MBarrierCreateOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     Operation *funcOp = op->getParentOp();

     MemRefType barrierType = nvgpu::getMBarrierMemrefType(

         rewriter.getContext(), op.getBarriers().getType());


     memref::GlobalOp global;

     if (auto moduleOp = funcOp->getParentOfType<gpu::GPUModuleOp>())

       global = generateGlobalBarrier(rewriter, funcOp, moduleOp, barrierType);

     else if (auto moduleOp = funcOp->getParentOfType<ModuleOp>())

       global = generateGlobalBarrier(rewriter, funcOp, moduleOp, barrierType);


     rewriter.setInsertionPoint(op);

     rewriter.replaceOpWithNewOp<memref::GetGlobalOp>(op, barrierType,

                                                      global.getName());

     return success();

   }

 };


 /// Base class for lowering mbarrier operations to nvvm intrinsics.

 template <typename SourceOp>

 struct MBarrierBasePattern : public ConvertOpToLLVMPattern<SourceOp> {

 public:

   using ConvertOpToLLVMPattern<SourceOp>::ConvertOpToLLVMPattern;

   /// Returns the base pointer of the mbarrier object.

   Value getMbarrierPtr(ImplicitLocOpBuilder &b,

                        nvgpu::MBarrierGroupType mbarType, Value memrefDesc,

                        Value mbarId,

                        ConversionPatternRewriter &rewriter) const {

     MemRefType mbarrierMemrefType =

         nvgpu::getMBarrierMemrefType(rewriter.getContext(), mbarType);

     return ConvertToLLVMPattern::getStridedElementPtr(

         b.getLoc(), mbarrierMemrefType, memrefDesc, {mbarId}, rewriter);

   }

 };


 struct NVGPUMBarrierGetLowering

     : public MBarrierBasePattern<nvgpu::MBarrierGetOp> {

   using MBarrierBasePattern<nvgpu::MBarrierGetOp>::MBarrierBasePattern;


   LogicalResult

   matchAndRewrite(nvgpu::MBarrierGetOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     nvgpu::MBarrierGroupType mbarrierType = op.getBarriers().getType();

     rewriter.setInsertionPoint(op);

     Value barrier = getMbarrierPtr(b, mbarrierType, adaptor.getBarriers(),

                                    adaptor.getMbarId(), rewriter);

     Type resType = op.getMbarrierPointer().getType();

     rewriter.replaceOpWithNewOp<LLVM::PtrToIntOp>(op, resType, barrier);

     return success();

   }

 };


 /// Lowers `nvgpu.mbarrier.init` to `nvvm.mbarrier.init`

 struct NVGPUMBarrierInitLowering

     : public MBarrierBasePattern<nvgpu::MBarrierInitOp> {

   using MBarrierBasePattern<nvgpu::MBarrierInitOp>::MBarrierBasePattern;


   LogicalResult

   matchAndRewrite(nvgpu::MBarrierInitOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     nvgpu::MBarrierGroupType mbarrierType = op.getBarriers().getType();

     rewriter.setInsertionPoint(op);

     Value barrier = getMbarrierPtr(b, mbarrierType, adaptor.getBarriers(),

                                    adaptor.getMbarId(), rewriter);

     Value count = truncToI32(b, adaptor.getCount());

     if (isMbarrierShared(mbarrierType)) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierInitSharedOp>(

           op, barrier, count, adaptor.getPredicate());

     } else {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierInitOp>(op, barrier, count,

                                                         adaptor.getPredicate());

     }

     return success();

   }

 };


 /// Lowers `nvgpu.mbarrier.arrive` to `nvvm.mbarrier.arrive`

 struct NVGPUMBarrierArriveLowering

     : public MBarrierBasePattern<nvgpu::MBarrierArriveOp> {

   using MBarrierBasePattern<nvgpu::MBarrierArriveOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::MBarrierArriveOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);

     Type tokenType = getTypeConverter()->convertType(

         nvgpu::MBarrierTokenType::get(op->getContext()));

     if (isMbarrierShared(op.getBarriers().getType())) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveSharedOp>(op, tokenType,

                                                                 barrier);

     } else {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveOp>(op, tokenType,

                                                           barrier);

     }

     return success();

   }

 };


 /// Lowers `nvgpu.mbarrier.arrive.nocomplete` to

 /// `nvvm.mbarrier.arrive.nocomplete`

 struct NVGPUMBarrierArriveNoCompleteLowering

     : public MBarrierBasePattern<nvgpu::MBarrierArriveNoCompleteOp> {

   using MBarrierBasePattern<

       nvgpu::MBarrierArriveNoCompleteOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::MBarrierArriveNoCompleteOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);

     Type tokenType = getTypeConverter()->convertType(

         nvgpu::MBarrierTokenType::get(op->getContext()));

     Value count = truncToI32(b, adaptor.getCount());

     if (isMbarrierShared(op.getBarriers().getType())) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveNocompleteSharedOp>(

           op, tokenType, barrier, count);

     } else {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveNocompleteOp>(

           op, tokenType, barrier, count);

     }

     return success();

   }

 };


 /// Lowers `nvgpu.mbarrier.test.wait` to `nvvm.mbarrier.test.wait`

 struct NVGPUMBarrierTestWaitLowering

     : public MBarrierBasePattern<nvgpu::MBarrierTestWaitOp> {

   using MBarrierBasePattern<nvgpu::MBarrierTestWaitOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::MBarrierTestWaitOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);

     Type retType = rewriter.getI1Type();

     if (isMbarrierShared(op.getBarriers().getType())) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierTestWaitSharedOp>(

           op, retType, barrier, adaptor.getToken());

     } else {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierTestWaitOp>(

           op, retType, barrier, adaptor.getToken());

     }

     return success();

   }

 };


 struct NVGPUMBarrierArriveExpectTxLowering

     : public MBarrierBasePattern<nvgpu::MBarrierArriveExpectTxOp> {

   using MBarrierBasePattern<

       nvgpu::MBarrierArriveExpectTxOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::MBarrierArriveExpectTxOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);

     Value txcount = truncToI32(b, adaptor.getTxcount());


     if (isMbarrierShared(op.getBarriers().getType())) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveExpectTxSharedOp>(

           op, barrier, txcount, adaptor.getPredicate());

       return success();

     }


     rewriter.replaceOpWithNewOp<NVVM::MBarrierArriveExpectTxOp>(

         op, barrier, txcount, adaptor.getPredicate());

     return success();

   }

 };


 struct NVGPUMBarrierTryWaitParityLowering

     : public MBarrierBasePattern<nvgpu::MBarrierTryWaitParityOp> {

   using MBarrierBasePattern<

       nvgpu::MBarrierTryWaitParityOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::MBarrierTryWaitParityOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);

     Value ticks = truncToI32(b, adaptor.getTicks());

     Value phase =

         b.create<LLVM::ZExtOp>(b.getI32Type(), adaptor.getPhaseParity());


     if (isMbarrierShared(op.getBarriers().getType())) {

       rewriter.replaceOpWithNewOp<NVVM::MBarrierTryWaitParitySharedOp>(

           op, barrier, phase, ticks);

       return success();

     }


     rewriter.replaceOpWithNewOp<NVVM::MBarrierTryWaitParityOp>(op, barrier,

                                                                phase, ticks);

     return success();

   }

 };


 struct NVGPUTmaAsyncLoadOpLowering

     : public MBarrierBasePattern<nvgpu::TmaAsyncLoadOp> {

   using MBarrierBasePattern<nvgpu::TmaAsyncLoadOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::TmaAsyncLoadOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     auto srcMemrefType = cast<MemRefType>(op.getDst().getType());

     Value dest = getStridedElementPtr(op->getLoc(), srcMemrefType,

                                       adaptor.getDst(), {}, rewriter);

     Value barrier =

         getMbarrierPtr(b, op.getBarriers().getType(), adaptor.getBarriers(),

                        adaptor.getMbarId(), rewriter);


     SmallVector<Value> coords = adaptor.getCoordinates();

     for (auto [index, value] : llvm::enumerate(coords)) {

       coords[index] = truncToI32(b, value);

     }

     rewriter.replaceOpWithNewOp<NVVM::CpAsyncBulkTensorGlobalToSharedClusterOp>(

         op, dest, adaptor.getTensorMapDescriptor(), coords, barrier,

         ValueRange{}, adaptor.getMulticastMask(), Value{},

         adaptor.getPredicate());

     return success();

   }

 };


 struct NVGPUTmaAsyncStoreOpLowering

     : public MBarrierBasePattern<nvgpu::TmaAsyncStoreOp> {

   using MBarrierBasePattern<nvgpu::TmaAsyncStoreOp>::MBarrierBasePattern;

   LogicalResult

   matchAndRewrite(nvgpu::TmaAsyncStoreOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     auto srcMemrefType = cast<MemRefType>(op.getSrc().getType());

     Value dest = getStridedElementPtr(op->getLoc(), srcMemrefType,

                                       adaptor.getSrc(), {}, rewriter);

     SmallVector<Value> coords = adaptor.getCoordinates();

     for (auto [index, value] : llvm::enumerate(coords)) {

       coords[index] = truncToI32(b, value);

     }


     rewriter.replaceOpWithNewOp<NVVM::CpAsyncBulkTensorSharedCTAToGlobalOp>(

         op, adaptor.getTensorMapDescriptor(), dest, coords,

         adaptor.getPredicate());

     return success();

   }

 };


 struct NVGPUGenerateWarpgroupDescriptorLowering

     : public ConvertOpToLLVMPattern<nvgpu::WarpgroupGenerateDescriptorOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::WarpgroupGenerateDescriptorOp>::ConvertOpToLLVMPattern;


   LogicalResult

   matchAndRewrite(nvgpu::WarpgroupGenerateDescriptorOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {


     ImplicitLocOpBuilder b(op->getLoc(), rewriter);


     nvgpu::TensorMapSwizzleKind swizzleKind =

         op.getTensorMap().getType().getSwizzle();


     unsigned layout =

         (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_128B)  ? 128

         : (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_64B) ? 64

         : (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_32B) ? 32

                                                                     : 1;

     unsigned swizzle =

         (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_128B)  ? 1

         : (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_64B) ? 2

         : (swizzleKind == nvgpu::TensorMapSwizzleKind::SWIZZLE_32B) ? 3

                                                                     : 0;


     auto ti64 = b.getIntegerType(64);

     auto makeConst = [&](uint64_t index) -> Value {

       return b.create<LLVM::ConstantOp>(ti64, b.getI64IntegerAttr(index));

     };

     auto shiftLeft = [&](Value value, unsigned shift) -> Value {

       return b.create<LLVM::ShlOp>(ti64, value, makeConst(shift));

     };

     auto shiftRight = [&](Value value, unsigned shift) -> Value {

       return b.create<LLVM::LShrOp>(ti64, value, makeConst(shift));

     };

     auto insertBit = [&](Value desc, Value val, int startBit) {

       return b.create<LLVM::OrOp>(ti64, desc, shiftLeft(val, startBit));

     };


     int64_t sizeN = op.getTensorMap().getType().getTensor().getDimSize(0);

     uint64_t strideDimVal = (layout << 3) >> exclude4LSB;

     uint64_t leadDimVal = (sizeN * layout) >> exclude4LSB;

     uint64_t offsetVal = 0;


     Value strideDim = makeConst(strideDimVal);

     Value leadDim = makeConst(leadDimVal);


     Value baseAddr = getStridedElementPtr(

         op->getLoc(), cast<MemRefType>(op.getTensor().getType()),

         adaptor.getTensor(), {}, rewriter);

     Value basePtr = b.create<LLVM::PtrToIntOp>(ti64, baseAddr);

     // Just use 14 bits for base address

     Value basePtr14bit = shiftRight(shiftLeft(basePtr, 46), 50);


     int startSwizzleBit = 62, startOffsetBit = 49, startStrideBit = 32,

         startLeadBit = 16, startBaseAddrBit = 0;

     Value dsc = makeConst(0);

     // // [62,64)  swizzle type

     dsc = insertBit(dsc, makeConst(swizzle), startSwizzleBit);

     // // [49,52)  base_offset

     dsc = insertBit(dsc, makeConst(offsetVal), startOffsetBit);

     // // [32,46)  stride

     dsc = insertBit(dsc, strideDim, startStrideBit);

     // // [16,30)  leading dimension

     dsc = insertBit(dsc, leadDim, startLeadBit);

     // // [0,14)   start_address

     dsc = insertBit(dsc, basePtr14bit, startBaseAddrBit);


     LLVM_DEBUG(DBGS() << "Generating warpgroup.descriptor: "

                       << "leading_off:" << leadDimVal << "\t"

                       << "stride_off :" << strideDimVal << "\t"

                       << "base_offset:" << offsetVal << "\t"

                       << "layout_type:" << swizzle << " ("

                       << nvgpu::stringifyTensorMapSwizzleKind(swizzleKind)

                       << ")\n start_addr :  " << baseAddr << "\n");


     rewriter.replaceOp(op, dsc);

     return success();

   }

 };


 static Value makeI64Const(ImplicitLocOpBuilder &b, int32_t index) {

   return b.create<LLVM::ConstantOp>(b.getIntegerType(64),

                                     b.getI32IntegerAttr(index));

 }


 /// Returns a Value that holds data type enum that is expected by CUDA driver.

 static Value elementTypeAsLLVMConstant(ImplicitLocOpBuilder &b, Type type) {

   // Enum is from CUDA driver API

   // https://docs.nvidia.com/cuda/cuda-driver-api/group__CUDA__TYPES.html

   enum CUtensorMapDataTypeEnum {

     CU_TENSOR_MAP_DATA_TYPE_UINT8 = 0,

     CU_TENSOR_MAP_DATA_TYPE_UINT16,

     CU_TENSOR_MAP_DATA_TYPE_UINT32,

     CU_TENSOR_MAP_DATA_TYPE_INT32,

     CU_TENSOR_MAP_DATA_TYPE_UINT64,

     CU_TENSOR_MAP_DATA_TYPE_INT64,

     CU_TENSOR_MAP_DATA_TYPE_FLOAT16,

     CU_TENSOR_MAP_DATA_TYPE_FLOAT32,

     CU_TENSOR_MAP_DATA_TYPE_FLOAT64,

     CU_TENSOR_MAP_DATA_TYPE_BFLOAT16,

     CU_TENSOR_MAP_DATA_TYPE_FLOAT32_FTZ,

     CU_TENSOR_MAP_DATA_TYPE_TFLOAT32,

     CU_TENSOR_MAP_DATA_TYPE_TFLOAT32_FTZ

   };


   if (type.isUnsignedInteger(8))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_UINT8);

   if (type.isUnsignedInteger(16))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_UINT16);

   if (type.isUnsignedInteger(32))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_UINT32);

   if (type.isUnsignedInteger(64))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_UINT64);

   if (type.isSignlessInteger(32))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_INT32);

   if (type.isSignlessInteger(64))

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_INT64);

   if (type.isF16())

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_FLOAT16);

   if (type.isF32())

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_FLOAT32);

   if (type.isF64())

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_FLOAT64);

   if (type.isBF16())

     return makeI64Const(b, CU_TENSOR_MAP_DATA_TYPE_BFLOAT16);


   llvm_unreachable("Not supported data type");

 }


 struct NVGPUTmaCreateDescriptorOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::TmaCreateDescriptorOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::TmaCreateDescriptorOp>::ConvertOpToLLVMPattern;

   LogicalResult

   matchAndRewrite(nvgpu::TmaCreateDescriptorOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     auto llvmPointerType = LLVM::LLVMPointerType::get(op->getContext());

     Type llvmInt64Type = IntegerType::get(op->getContext(), 64);


     Value tensorElementType =

         elementTypeAsLLVMConstant(b, op.getTensor().getType().getElementType());

     auto promotedOperands = getTypeConverter()->promoteOperands(

         b.getLoc(), op->getOperands(), adaptor.getOperands(), b);


     Value boxArrayPtr = b.create<LLVM::AllocaOp>(llvmPointerType, llvmInt64Type,

                                                  makeI64Const(b, 5));

     for (auto [index, value] : llvm::enumerate(adaptor.getBoxDimensions())) {

       Value gep = b.create<LLVM::GEPOp>(llvmPointerType, llvmPointerType,

                                         boxArrayPtr, makeI64Const(b, index));

       b.create<LLVM::StoreOp>(value, gep);

     }


     nvgpu::TensorMapDescriptorType desc = op.getTensorMap().getType();

     // Set Arguments for the function call

     SmallVector<Value> arguments;

     arguments.push_back(promotedOperands[0]); // rank

     arguments.push_back(promotedOperands[1]); // descriptor

     arguments.push_back(tensorElementType);   // data type

     arguments.push_back(

         makeI64Const(b, (int)desc.getInterleave()));              // interleave

     arguments.push_back(makeI64Const(b, (int)desc.getSwizzle())); // swizzle

     arguments.push_back(makeI64Const(b, (int)desc.getL2promo())); // l2promo

     arguments.push_back(makeI64Const(b, (int)desc.getOob()));     // oob

     arguments.push_back(boxArrayPtr); // box dimensions


     // Set data types of the arguments

     SmallVector<Type> argTypes = {

         llvmInt64Type,   /* int64_t tensorRank */

         llvmPointerType, /* ptr */

         llvmInt64Type,   /* int64_t */

         llvmInt64Type,   /* int64_t */

         llvmInt64Type,   /* int64_t */

         llvmInt64Type,   /* int64_t */

         llvmInt64Type,   /* int64_t */

         llvmPointerType  /* ptr  */

     };

     FunctionCallBuilder hostRegisterCallBuilder = {

         "mgpuTensorMapEncodeTiledMemref", llvmPointerType, argTypes};

     Value tensorMap =

         hostRegisterCallBuilder.create(b.getLoc(), b, arguments).getResult();


     rewriter.replaceOp(op, tensorMap);

     return success();

   }

 };


 struct NVGPUWarpgroupMmaOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::WarpgroupMmaOp> {

   using ConvertOpToLLVMPattern<nvgpu::WarpgroupMmaOp>::ConvertOpToLLVMPattern;


   /// This is a helper class to generate required NVVM Ops for warp-group level

   /// matrix multiplication.

   /// When the given GEMM shape is larger than the shape of

   /// a wgmma instrution in PTX, it can generate multiple NVVM::WgmmaMmaAsyncOp

   /// Op(s), group and execute them asynchronously. The class also handles

   /// waiting for completion and iterates through WarpgroupMatrixDescriptor to

   /// create descriptors for each instruction.

   ///

   /// For example this is the case when the shape of GEMM is 128x128x128

   ///

   ///    nvvm.wgmma.fence.aligned

   ///

   ///    nvvm.wgmma.mma.async descA, descB

   ///    iterate(descA, descB)

   ///    nvvm.wgmma.mma.async descA, descB

   ///    [6x times more]

   ///

   ///    nvvm.wgmma.group.sync.aligned

   ///    nvvm.wgmma.wait.group.sync [groupId]

   ///

   class WarpgroupGemm {

     nvgpu::WarpgroupMmaOp op;

     ImplicitLocOpBuilder b;

     OpAdaptor adaptor;


     // Entire shape of the given Op

     int64_t totalM, totalN, totalK;


     // Shape of one wgmma instruction

     int wgmmaM = 0, wgmmaN = 0, wgmmaK = 0;


     // Iteration counts for GEMM

     int iterationM = 0, iterationN = 0, iterationK = 0;


     /// The function returns the shape of wgmma instruction that is defined in

     /// PTX programming guide.

     /// https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#asynchronous-warpgroup-level-matrix-shape

     void findWgmmaShape(int64_t sizeM, int64_t sizeN, Type inputElemType) {

       wgmmaM = 64;

       wgmmaN = sizeN;

       if (inputElemType.isTF32()) {

         wgmmaK = 8;

       } else if (inputElemType.isF16() || inputElemType.isBF16()) {

         wgmmaK = 16;

       } else if (isa<Float8E4M3FNType, Float8E5M2Type>(inputElemType) ||

                  inputElemType.isInteger(16)) {

         wgmmaK = 32;

       } else if (inputElemType.isInteger(1)) {

         wgmmaK = 256;

       } else {

         llvm_unreachable("msg: not supported K shape");

       }

       LLVM_DEBUG(DBGS() << "Generating WgmmaMmaAsyncOp shape[m = " << wgmmaM

                         << ", n = " << wgmmaN << ", k = " << wgmmaK << "]\n");

     }


     /// Generates WGMMATypesAttr from MLIR Type

     NVVM::WGMMATypesAttr generateWgmmaType(Type type,

                                            bool useF32 = false) const {

       auto getWgmmaType = [=](Type elemType) {

         if (elemType.isF32() || elemType.isTF32())

           return useF32 ? NVVM::WGMMATypes::f32 : NVVM::WGMMATypes::tf32;

         if (elemType.isF16())

           return NVVM::WGMMATypes::f16;

         if (elemType.isBF16())

           return NVVM::WGMMATypes::bf16;

         if (isa<Float8E4M3FNType>(elemType))

           return NVVM::WGMMATypes::e4m3;

         if (isa<Float8E5M2Type>(elemType))

           return NVVM::WGMMATypes::e5m2;

         if (elemType.isInteger(1))

           return NVVM::WGMMATypes::b1;

         if (elemType.isInteger(8))

           return NVVM::WGMMATypes::s8;

         if (elemType.isUnsignedInteger(8))

           return NVVM::WGMMATypes::u8;

         if (elemType.isInteger(32))

           return NVVM::WGMMATypes::s32;

         llvm_unreachable("unsupported type");

       };

       return NVVM::WGMMATypesAttr::get(op->getContext(), getWgmmaType(type));

     }


     /// Generates layout attribute for the input matrix for wgmma instruction

     NVVM::MMALayoutAttr

     generateWgmmaLayout(std::optional<bool> transpose) const {

       if (transpose.value_or(false))

         return NVVM::MMALayoutAttr::get(op->getContext(), NVVM::MMALayout::col);

       return NVVM::MMALayoutAttr::get(op->getContext(), NVVM::MMALayout::row);

     }


     /// Generates shape attribute for wgmma instruction

     NVVM::MMAShapeAttr generateWgmmaShape() const {

       return NVVM::MMAShapeAttr::get(op->getContext(), wgmmaM, wgmmaN, wgmmaK);

     }


     /// Generates scale attributes of output matrix for wgmma instruction

     NVVM::WGMMAScaleOutAttr generateScaleOut() const {

       return NVVM::WGMMAScaleOutAttr::get(op->getContext(),

                                           NVVM::WGMMAScaleOut::one);

     }

     /// Generates scale attributes of input matrix for wgmma instruction

     NVVM::WGMMAScaleInAttr generateScaleIn() const {

       return NVVM::WGMMAScaleInAttr::get(op->getContext(),

                                          NVVM::WGMMAScaleIn::one);

     }


     /// Basic function to generate Add

     Value makeAdd(Value lhs, Value rhs) {

       return b.create<LLVM::AddOp>(lhs.getType(), lhs, rhs);

     };


     /// Moves the descriptor pointer of matrix-A for the next wgmma instruction.

     /// Currently, it only handles row-major.

     ///

     /// It moves the pointer like below for [128][64] size:

     ///                 +2 +4 +6

     ///                  ↓  ↓  ↓

     /// descA    ---> +--+--+--+--+

     ///               |->|->|->|->|

     ///               |  |  |  |  |

     ///               |  |  |  |  |

     ///               |  |  |  |  |

     /// descA+512---> +-----------+

     ///               |  |  |  |  |

     ///               |  |  |  |  |

     ///               |  |  |  |  |

     ///               |  |  |  |  |

     ///               +-----------+

     ///

     Value iterateDescriptorA(Value desc, int i, int j, int k) {

       MemRefType matrixTypeA = op.getDescriptorA().getType().getTensor();

       Type elemA = matrixTypeA.getElementType();

       int byte = elemA.getIntOrFloatBitWidth() / 8;

       int tileShapeA = matrixTypeA.getDimSize(1);

       int incrementVal = ((wgmmaK * k) + (totalK * tileShapeA * i)) * byte;

       incrementVal = incrementVal >> exclude4LSB;

       LLVM_DEBUG(DBGS() << "\t\t[m: " << i << " n: " << j << " k: " << k

                         << "] [wgmma descriptors] Descriptor A + "

                         << incrementVal << " | \t ");

       if (!incrementVal)

         return desc;

       return makeAdd(desc, makeI64Const(b, incrementVal));

     }


     /// Moves the descriptor pointer of matrix-B for the next wgmma instruction.

     /// Currently, it only handles column-major.

     ///

     /// It moves the pointer like below for [128][64] size:

     /// descB     ---> +--+--+--+--+--+--+--+--+

     ///                |↓ |  |  |  |  |  |  |  |

     ///                |↓ |  |  |  |  |  |  |  |

     ///                |↓ |  |  |  |  |  |  |  |

     ///                |↓ |  |  |  |  |  |  |  |

     ///                +--+--+--+--+--+--+--+--+

     ///

     Value iterateDescriptorB(Value desc, int i, int j, int k) {

       MemRefType matrixTypeB = op.getDescriptorB().getType().getTensor();

       Type elemB = matrixTypeB.getElementType();

       int byte = elemB.getIntOrFloatBitWidth() / 8;

       int incrementVal = matrixTypeB.getDimSize(0) * wgmmaK * k * byte;

       incrementVal = incrementVal >> exclude4LSB;

       LLVM_DEBUG(DBGSE() << "Descriptor B + " << incrementVal << "\n");

       if (!incrementVal)

         return desc;

       return makeAdd(desc, makeI64Const(b, incrementVal));

     }


     /// This function generates a WgmmaMmaAsyncOp using provided GMMA matrix

     /// descriptors and arranges them based on induction variables: i, j, and k.

     Value generateWgmma(int i, int j, int k, Value matrixC) {

       LLVM_DEBUG(DBGS() << "\t wgmma."

                         << "m" << wgmmaM << "n" << wgmmaN << "k" << wgmmaK

                         << "(A[" << (iterationM * wgmmaM) << ":"

                         << (iterationM * wgmmaM) + wgmmaM << "]["

                         << (iterationK * wgmmaK) << ":"

                         << (iterationK * wgmmaK + wgmmaK) << "] * "

                         << " B[" << (iterationK * wgmmaK) << ":"

                         << (iterationK * wgmmaK + wgmmaK) << "][" << 0 << ":"

                         << wgmmaN << "])\n");


       Value descriptorA = iterateDescriptorA(adaptor.getDescriptorA(), i, j, k);

       Value descriptorB = iterateDescriptorB(adaptor.getDescriptorB(), i, j, k);


       Type elemA = op.getDescriptorA().getType().getTensor().getElementType();

       NVVM::WGMMATypesAttr itypeA = generateWgmmaType(elemA);


       Type elemB = op.getDescriptorB().getType().getTensor().getElementType();

       NVVM::WGMMATypesAttr itypeB = generateWgmmaType(elemB);


       Type elemD = op.getMatrixC().getType().getFragmented().getElementType();

       NVVM::WGMMATypesAttr itypeD = generateWgmmaType(elemD, true);


       NVVM::MMAShapeAttr shape = generateWgmmaShape();

       NVVM::WGMMAScaleOutAttr scaleOut = generateScaleOut();

       NVVM::WGMMAScaleInAttr scaleIn = generateScaleIn();

       NVVM::MMALayoutAttr layoutA = generateWgmmaLayout(op.getTransposeA());

       NVVM::MMALayoutAttr layoutB = generateWgmmaLayout(!op.getTransposeB());


       auto overflow = NVVM::MMAIntOverflowAttr::get(

           op->getContext(), NVVM::MMAIntOverflow::wrapped);


       return b.create<NVVM::WgmmaMmaAsyncOp>(

           matrixC.getType(), matrixC, descriptorA, descriptorB, shape, itypeA,

           itypeB, itypeD, scaleOut, scaleIn, scaleIn, layoutA, layoutB,

           overflow);

     }


     /// Generates multiple wgmma instructions to complete the given GEMM shape

     Value generateWgmmaGroup() {

       Value wgmmaResult =

           b.create<LLVM::PoisonOp>(adaptor.getMatrixC().getType());


       // Perform GEMM

       SmallVector<Value> wgmmaResults;

       for (int i = 0; i < iterationM; ++i) {

         Value matrixC = b.create<LLVM::ExtractValueOp>(adaptor.getMatrixC(), i);

         for (int j = 0; j < iterationN; ++j)

           for (int k = 0; k < iterationK; ++k)

             matrixC = generateWgmma(i, j, k, matrixC);

         wgmmaResults.push_back(matrixC);

       }

       for (auto [idx, matrix] : llvm::enumerate(wgmmaResults)) {

         wgmmaResult = b.create<LLVM::InsertValueOp>(wgmmaResult.getType(),

                                                     wgmmaResult, matrix, idx);

       }

       return wgmmaResult;

     }


   public:

     WarpgroupGemm(nvgpu::WarpgroupMmaOp op, ImplicitLocOpBuilder &b,

                   OpAdaptor adaptor)

         : op(op), b(b), adaptor(adaptor) {

       // Find the entire GEMM Shape

       totalM = op.getDescriptorA().getType().getTensor().getDimSize(0);

       totalN = op.getDescriptorB().getType().getTensor().getDimSize(1);

       totalK = op.getDescriptorA().getType().getTensor().getDimSize(1);

       LLVM_DEBUG(DBGS() << "===--- GEMM D[" << totalM << "][" << totalN

                         << "] += A[" << totalM << "][" << totalK << "] * B["

                         << totalK << "][" << totalN << "] ---===\n");


       // Find the shape for one wgmma instruction

       findWgmmaShape(

           totalM, totalN,

           op.getDescriptorA().getType().getTensor().getElementType());


       // Iterations counts to complete the given shape with wgmma shape

       iterationM = totalM / wgmmaM;

       iterationN = totalN / wgmmaN;

       iterationK = totalK / wgmmaK;

     }


     /// Generates WgmmaMmaAsync Ops to complete the specified GEMM  shape. It

     /// includes generating a fence Op (WgmmaFenceAlignedOp) before the

     /// instructions and group synchronization, as well as waiting

     /// (WgmmaGroupSyncAlignedOp) for group synchronization

     /// (WgmmaWaitGroupSyncOp) after the instructions.

     Value generateWarpgroupMma() {

       b.create<NVVM::WgmmaFenceAlignedOp>();

       Value wgmmaResult = generateWgmmaGroup();

       b.create<NVVM::WgmmaGroupSyncAlignedOp>();

       b.create<NVVM::WgmmaWaitGroupSyncOp>(op.getWaitGroup());

       return wgmmaResult;

     }

   };

   LogicalResult

   matchAndRewrite(nvgpu::WarpgroupMmaOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);


     // Step 1. Build a helper class

     WarpgroupGemm warpgroupGemm(op, b, adaptor);


     // Step 2. Get the entire GEMM Shape

     Value wgmmaResult = warpgroupGemm.generateWarpgroupMma();


     // Step 3. Replace fragmented result struct with the op results

     rewriter.replaceOp(op, wgmmaResult);

     return success();

   }

 };


 struct NVGPUWarpgroupMmaStoreOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::WarpgroupMmaStoreOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::WarpgroupMmaStoreOp>::ConvertOpToLLVMPattern;


   /// This function stores a fragmented register matrix owned by a warp group

   /// (128 threads) into a memref. Each thread has 64 registers, each the size

   /// of a struct.

   /// Here is what each threads (T) holds, each `d` is struct value with a

   /// number.

   ///

   /// Threads in warp-group (128 threads) and what they owns in the matrixD:

   /// 0-31    Warp-0  -> MatrixD[0:15 ][0:N]

   /// 32-63   Warp-1  -> MatrixD[16:31][0:N]

   /// 64-95   Warp-2  -> MatrixD[32:47][0:N]

   /// 96-127  Warp-3  -> MatrixD[48:64][0:N]

   ///

   /// Matrix-D:

   ///   +______________________________________________________________________+

   ///   |     0-1  |    2-3  |    4-5  |    6-7  |   8-9  |   10-11|..|N-8,N-7 |

   /// 0 | T0:d0-d1 |T1:d0-d1 |T2:d0-d1 |T3:d0-d1 |T0:d4-d5| T1:d4-d5..|T0:dX-dY|

   /// 1 | T4:d0-d1 |T5:d0-d1 |T6:d0-d1 |T7:d0-d1 |T4:d4-d5| T5:d4-d5..|T4:dX-dY|

   /// ..| .........|.........|.........|.........|........|...........|........|

   /// 8 | T0:d2-d3 |T1:d2-d3 |T2:d2-d3 |T3:d2-d3 |T0:d6-d7|T1:d6-d7,..|T0:dZ-dW|

   /// 9 | T4:d2-d3 |T5:d2-d3 |T6:d2-d3 |T7:d2-d3 |T4:d6-d7| T5:d6-d7..|T4:dZ-dW|

   /// ..| .........|.........|.........|.........|........|...........|........|

   /// 15| T28:d2-d3|T29:d2-d3|T30:d2-d3|T31:d2-d3|........|...........|........|

   /// 16| T32:d2-d3|T33:d2-d3|T34:d2-d3|T35:d2-d3|........|...........|........|

   /// ..| .........|.........|.........|.........|........|...........|........|

   /// 32| T64:d2-d3|T65:d2-d3|T66:d2-d3|T67:d2-d3|........|...........|........|

   /// ..| .........|.........|.........|.........|........|...........|........|

   /// 48| T96:d2-d3|T97:d2-d3|T98:d2-d3|T99:d2-d3|........|...........|........|

   /// ..| .........|.........|.........|.........|........|...........|........|

   ///   +______________________________________________________________________+

   ///

   /// \param rewriter: The pattern rewriter.

   /// \param matrixD: Result of the warp-group MMA operation (fragmented

   /// matrix). It is holded by a thread and a struct with 64 elements.

   /// \param dstMemref: The memref where the registers will be stored.

   /// \param offset: the offset within the memref where the registers will be

   /// stored.

   void storeFragmentedMatrix(ImplicitLocOpBuilder &b, Value matrixD,

                              TypedValue<MemRefType> dstMemref,

                              int offset) const {

     Type i32 = b.getI32Type();


     auto makeConst = [&](int32_t index) -> Value {

       return b.create<LLVM::ConstantOp>(i32, b.getI32IntegerAttr(index));

     };

     Value c1 = makeConst(1);

     Value c2 = makeConst(2);

     Value c4 = makeConst(4);

     Value c8 = makeConst(8);

     Value c16 = makeConst(16);

     Value warpSize = makeConst(kWarpSize);


     auto makeMul = [&](Value lhs, Value rhs) -> Value {

       return b.create<LLVM::MulOp>(lhs.getType(), lhs, rhs);

     };

     auto makeAdd = [&](Value lhs, Value rhs) -> Value {

       return b.create<LLVM::AddOp>(lhs.getType(), lhs, rhs);

     };


     auto makeExtractAndStore = [&](int i, Value wgmmaResult, Value x, Value y,

                                    TypedValue<::mlir::MemRefType> memref) {

       Type it = b.getIndexType();

       Value idx = b.create<arith::IndexCastOp>(it, x);

       Value idy0 = b.create<arith::IndexCastOp>(it, y);

       Value idy1 = b.create<arith::IndexCastOp>(it, makeAdd(y, c1));

       Value d0 = b.create<LLVM::ExtractValueOp>(wgmmaResult, i);

       Value d1 = b.create<LLVM::ExtractValueOp>(wgmmaResult, i + 1);

       b.create<memref::StoreOp>(d0, memref, ValueRange{idx, idy0});

       b.create<memref::StoreOp>(d1, memref, ValueRange{idx, idy1});

     };


     Value tidx = b.create<NVVM::ThreadIdXOp>(i32);

     Value laneId = b.create<LLVM::URemOp>(i32, tidx, warpSize);

     Value warpId = b.create<LLVM::UDivOp>(i32, tidx, warpSize);

     Value lane4Id = b.create<LLVM::UDivOp>(i32, laneId, c4);

     Value lane4modId = b.create<LLVM::URemOp>(i32, laneId, c4);


     Value tj = makeMul(lane4modId, c2);

     Value ti = makeAdd(lane4Id, makeMul(warpId, c16));

     if (offset)

       ti = makeAdd(ti, makeConst(offset));


     auto structType = cast<LLVM::LLVMStructType>(matrixD.getType());


     // Number of 32-bit registers owns per thread

     constexpr unsigned numAdjacentRegisters = 2;

     // Number of 8x8 matrices one below another per warp

     constexpr unsigned numStackedMatrices = 2;


     size_t storeCount = (structType.getBody().size() /

                          (numStackedMatrices * numAdjacentRegisters));


     for (size_t i = 0; i < numStackedMatrices; ++i) {

       Value idx = makeAdd(ti, makeMul(makeConst(i), c8));

       for (size_t j = 0; j < storeCount; ++j) {

         Value idy = makeAdd(tj, makeMul(makeConst(j), c8));

         size_t structIndex = (i * numAdjacentRegisters) +

                              (j * (numStackedMatrices * numAdjacentRegisters));

         makeExtractAndStore(structIndex, matrixD, idx, idy, dstMemref);

       }

     }

   }


   LogicalResult

   matchAndRewrite(nvgpu::WarpgroupMmaStoreOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     int offset = 0;

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     Value matriDValue = adaptor.getMatrixD();

     auto stype = cast<LLVM::LLVMStructType>(matriDValue.getType());

     for (auto [idx, matrixD] : llvm::enumerate(stype.getBody())) {

       auto structType = cast<LLVM::LLVMStructType>(matrixD);

       Value innerStructValue = b.create<LLVM::ExtractValueOp>(matriDValue, idx);

       storeFragmentedMatrix(b, innerStructValue, op.getDstMemref(), offset);

       offset += structType.getBody().size();

     }

     rewriter.eraseOp(op);

     return success();

   }

 };


 struct NVGPUWarpgroupMmaInitAccumulatorOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::WarpgroupMmaInitAccumulatorOp> {

   using ConvertOpToLLVMPattern<

       nvgpu::WarpgroupMmaInitAccumulatorOp>::ConvertOpToLLVMPattern;

   LogicalResult

   matchAndRewrite(nvgpu::WarpgroupMmaInitAccumulatorOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     LLVM::LLVMStructType packStructType = cast<LLVM::LLVMStructType>(

         getTypeConverter()->convertType(op.getMatrixC().getType()));

     Type elemType = cast<LLVM::LLVMStructType>(packStructType.getBody().front())

                         .getBody()

                         .front();

     Value zero = b.create<LLVM::ConstantOp>(elemType, b.getZeroAttr(elemType));

     Value packStruct = b.create<LLVM::PoisonOp>(packStructType);

     SmallVector<Value> innerStructs;

     // Unpack the structs and set all values to zero

     for (auto [idx, s] : llvm::enumerate(packStructType.getBody())) {

       auto structType = cast<LLVM::LLVMStructType>(s);

       Value structValue = b.create<LLVM::ExtractValueOp>(packStruct, idx);

       for (unsigned i = 0; i < structType.getBody().size(); ++i) {

         structValue = b.create<LLVM::InsertValueOp>(

             structType, structValue, zero, ArrayRef<int64_t>({i}));

       }

       innerStructs.push_back(structValue);

     }

     // Pack the inner structs into a single struct

     for (auto [idx, matrix] : llvm::enumerate(innerStructs)) {

       packStruct = b.create<LLVM::InsertValueOp>(packStruct.getType(),

                                                  packStruct, matrix, idx);

     }

     rewriter.replaceOp(op, packStruct);

     return success();

   }

 };


 struct NVGPUTmaFenceOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::TmaFenceOp> {

   using ConvertOpToLLVMPattern<nvgpu::TmaFenceOp>::ConvertOpToLLVMPattern;

   LogicalResult

   matchAndRewrite(nvgpu::TmaFenceOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     MLIRContext *ctx = op.getContext();

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     auto i32Ty = b.getI32Type();

     Value tensormapSize =

         b.create<LLVM::ConstantOp>(i32Ty, rewriter.getI32IntegerAttr(128));


     auto memscope =

         NVVM::MemScopeKindAttr::get(ctx, ::mlir::NVVM::MemScopeKind::SYS);


     rewriter.replaceOpWithNewOp<NVVM::FenceProxyAcquireOp>(

         op, memscope, adaptor.getTensorMapDescriptor(), tensormapSize);


     return success();

   }

 };


 struct NVGPUTmaPrefetchOpLowering

     : public ConvertOpToLLVMPattern<nvgpu::TmaPrefetchOp> {

   using ConvertOpToLLVMPattern<nvgpu::TmaPrefetchOp>::ConvertOpToLLVMPattern;

   LogicalResult

   matchAndRewrite(nvgpu::TmaPrefetchOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     rewriter.replaceOpWithNewOp<NVVM::PrefetchTensorMapOp>(

         op, adaptor.getTensorMapDescriptor(), adaptor.getPredicate());

     return success();

   }

 };


 struct NVGPURcpOpLowering : public ConvertOpToLLVMPattern<nvgpu::RcpOp> {

   using ConvertOpToLLVMPattern<nvgpu::RcpOp>::ConvertOpToLLVMPattern;

   LogicalResult

   matchAndRewrite(nvgpu::RcpOp op, OpAdaptor adaptor,

                   ConversionPatternRewriter &rewriter) const override {

     ImplicitLocOpBuilder b(op->getLoc(), rewriter);

     auto i64Ty = b.getI64Type();

     auto f32Ty = b.getF32Type();

     VectorType inTy = op.getIn().getType();

     // apply rcp.approx.ftz.f on each element in vector.

     auto convert1DVec = [&](Type llvm1DVectorTy, Value inVec) {

       Value ret1DVec = b.create<LLVM::PoisonOp>(llvm1DVectorTy);

       int numElems = llvm::cast<VectorType>(llvm1DVectorTy).getNumElements();

       for (int i = 0; i < numElems; i++) {

         Value idx = b.create<LLVM::ConstantOp>(i64Ty, b.getI64IntegerAttr(i));

         Value elem = b.create<LLVM::ExtractElementOp>(inVec, idx);

         Value dst = b.create<NVVM::RcpApproxFtzF32Op>(f32Ty, elem);

         ret1DVec = b.create<LLVM::InsertElementOp>(ret1DVec, dst, idx);

       }

       return ret1DVec;

     };

     if (inTy.getRank() == 1) {

       rewriter.replaceOp(op, convert1DVec(inTy, adaptor.getIn()));

       return success();

     }

     return LLVM::detail::handleMultidimensionalVectors(

         op.getOperation(), adaptor.getOperands(), *(this->getTypeConverter()),

         [&](Type llvm1DVectorTy, ValueRange operands) -> Value {

           OpAdaptor adaptor(operands);

           return convert1DVec(llvm1DVectorTy, adaptor.getIn());

         },

         rewriter);

   }

 };

 } // namespace


 void mlir::populateNVGPUToNVVMConversionPatterns(

     const LLVMTypeConverter &converter, RewritePatternSet &patterns) {

   patterns.add<

       NVGPUMBarrierCreateLowering,           // nvgpu.mbarrier.create

       NVGPUMBarrierInitLowering,             // nvgpu.mbarrier.init

       NVGPUMBarrierGetLowering,              // nvgpu.mbarrier.get

       NVGPUMBarrierArriveLowering,           // nvgpu.mbarrier.arrive

       NVGPUMBarrierArriveNoCompleteLowering, // nvgpu.mbarrier.arrive.no_complete

       NVGPUMBarrierTestWaitLowering,         // nvgpu.mbarrier.test_wait_parity

       NVGPUMBarrierTryWaitParityLowering,    // nvgpu.mbarrier.try_wait_parity

       NVGPUTmaAsyncLoadOpLowering,           // nvgpu.tma.async.load

       NVGPUTmaAsyncStoreOpLowering,          // nvgpu.tma.async.store

       NVGPUTmaCreateDescriptorOpLowering,    // nvgpu.tma.create.descriptor

       NVGPUTmaPrefetchOpLowering,            // nvgpu.tma.prefetch.descriptor

       NVGPUTmaFenceOpLowering,               // nvgpu.tma.fence.descriptor

       NVGPUMBarrierArriveExpectTxLowering,   // nvgpu.mbarrier.arrive.expect_tx

       NVGPUGenerateWarpgroupDescriptorLowering, // nvgpu.warpgroup.generate.descriptor

       NVGPUWarpgroupMmaOpLowering,              // nvgpu.warpgroup.mma

       NVGPUWarpgroupMmaStoreOpLowering,         // nvgpu.warpgroup.mma.store

       NVGPUWarpgroupMmaInitAccumulatorOpLowering, // nvgpu.warpgroup.mma.init.accumulator

       MmaSyncOptoNVVM, MmaLdMatrixOpToNVVM, NVGPUAsyncCopyLowering,

       NVGPUAsyncCreateGroupLowering, NVGPUAsyncWaitLowering,

       NVGPUMmaSparseSyncLowering, NVGPURcpOpLowering>(converter);

 }

kSharedMemorySpace
static constexpr int64_t kSharedMemorySpace
Definition: BasicPtxBuilderInterface.cpp:29

ConversionTarget.h

GPUCommonPass.h

GPUDialect.h

ImplicitLocOpBuilder.h

getContext
static MLIRContext * getContext(OpFoldResult val)
Definition: IndexingUtils.cpp:295

LLVMDialect.h

LLVMTypes.h

NVGPUDialect.h

kWgmmaSizeM
constexpr int kWgmmaSizeM
M size of wgmma.mma_async instruction.
Definition: NVGPUDialect.h:40

kWarpSize
constexpr int kWarpSize
Definition: NVGPUDialect.h:26

unpackOperandVector
static SmallVector< Value > unpackOperandVector(ImplicitLocOpBuilder &b, Value operand, NVVM::MMATypes operandPtxType)
The gpu.mma.sync converter below expects matrix fragment operands to be given as 2D vectors where the...
Definition: NVGPUToNVVM.cpp:176

truncToI32
static Value truncToI32(ImplicitLocOpBuilder &b, Value value)
GPU has 32 bit registers, this function truncates values when larger width is not needed.
Definition: NVGPUToNVVM.cpp:51

DBGSE
#define DBGSE()
Definition: NVGPUToNVVM.cpp:36

inferIntrinsicResultType
static Type inferIntrinsicResultType(Type vectorResultType)
Returns the type for the intrinsic given the vectorResultType of the gpu.mma.sync operation.
Definition: NVGPUToNVVM.cpp:61

exclude4LSB
constexpr int exclude4LSB
Number of bits that needs to be excluded when building matrix descriptor for wgmma operations.
Definition: NVGPUToNVVM.cpp:47

isMbarrierShared
static bool isMbarrierShared(nvgpu::MBarrierGroupType barrierType)
Returns whether mbarrier object has shared memory address space.
Definition: NVGPUToNVVM.cpp:223

DBGS
#define DBGS()
Definition: NVGPUToNVVM.cpp:35

convertIntrinsicResult
static Value convertIntrinsicResult(Location loc, Type intrinsicResultType, Type resultType, Value intrinsicResult, RewriterBase &rewriter)
Convert the SSA result of the NVVM intrinsic nvvm.mma.sync (which is always an LLVM struct) into a fr...
Definition: NVGPUToNVVM.cpp:100

NVGPUToNVVM.h

NVVMDialect.h

options
static llvm::ManagedStatic< PassManagerOptions > options
Definition: PassManagerOptions.cpp:89

PatternMatch.h

Patterns.h

TypeUtilities.h

Value.h

VectorPattern.h

llvm::ArrayRef
Definition: LLVM.h:48

llvm::SmallVector
Definition: LLVM.h:72

mlir::Attribute
Attributes are known-constant values of operations.
Definition: Attributes.h:25

mlir::Builder::getI16Type
IntegerType getI16Type()
Definition: Builders.cpp:61

mlir::Builder::getI32IntegerAttr
IntegerAttr getI32IntegerAttr(int32_t value)
Definition: Builders.cpp:196

mlir::Builder::getF32Type
FloatType getF32Type()
Definition: Builders.cpp:43

mlir::Builder::getI64Type
IntegerType getI64Type()
Definition: Builders.cpp:65

mlir::Builder::getI32Type
IntegerType getI32Type()
Definition: Builders.cpp:63

mlir::Builder::getI64IntegerAttr
IntegerAttr getI64IntegerAttr(int64_t value)
Definition: Builders.cpp:108

mlir::Builder::getIntegerType
IntegerType getIntegerType(unsigned width)
Definition: Builders.cpp:67

mlir::Builder::getType
Ty getType(Args &&...args)
Get or construct an instance of the type Ty with provided arguments.
Definition: Builders.h:89

mlir::Builder::getStringAttr
StringAttr getStringAttr(const Twine &bytes)
Definition: Builders.cpp:258

mlir::Builder::getZeroAttr
TypedAttr getZeroAttr(Type type)
Definition: Builders.cpp:320

mlir::Builder::getF16Type
FloatType getF16Type()
Definition: Builders.cpp:39

mlir::Builder::getContext
MLIRContext * getContext() const
Definition: Builders.h:56

mlir::Builder::getI1Type
IntegerType getI1Type()
Definition: Builders.cpp:53

mlir::Builder::getIndexType
IndexType getIndexType()
Definition: Builders.cpp:51

mlir::Builder::getI8Type
IntegerType getI8Type()
Definition: Builders.cpp:59

mlir::Builder::getF64Type
FloatType getF64Type()
Definition: Builders.cpp:45

mlir::ConversionPatternRewriter
This class implements a pattern rewriter for use with ConversionPatterns.
Definition: DialectConversion.h:821

mlir::ConversionPatternRewriter::replaceOp
void replaceOp(Operation *op, ValueRange newValues) override
Replace the given operation with the new values.
Definition: DialectConversion.cpp:1640

mlir::ConversionPatternRewriter::eraseOp
void eraseOp(Operation *op) override
PatternRewriter hook for erasing a dead operation.
Definition: DialectConversion.cpp:1665

mlir::ConvertOpToLLVMPattern
Utility class for operation conversions targeting the LLVM dialect that match exactly one source oper...
Definition: Pattern.h:148

mlir::ConvertToLLVMPattern::getStridedElementPtr
Value getStridedElementPtr(Location loc, MemRefType type, Value memRefDesc, ValueRange indices, ConversionPatternRewriter &rewriter) const
Definition: Pattern.cpp:61

mlir::DialectRegistry
The DialectRegistry maps a dialect namespace to a constructor for the matching dialect.
Definition: DialectRegistry.h:139

mlir::DialectRegistry::insert
void insert()
Definition: DialectRegistry.h:148

mlir::IRRewriter
This class coordinates rewriting a piece of IR outside of a pattern rewrite, providing a way to keep ...
Definition: PatternMatch.h:784

mlir::ImplicitLocOpBuilder
ImplicitLocOpBuilder maintains a 'current location', allowing use of the create<> method without spec...
Definition: ImplicitLocOpBuilder.h:23

mlir::ImplicitLocOpBuilder::getLoc
Location getLoc() const
Accessors for the implied location.
Definition: ImplicitLocOpBuilder.h:56

mlir::ImplicitLocOpBuilder::create
OpTy create(Args &&...args)
Create an operation of specific op type at the current insertion point and location.
Definition: ImplicitLocOpBuilder.h:66

mlir::LLVMConversionTarget
Derived class that automatically populates legalization information for different LLVM ops.
Definition: ConversionTarget.h:17

mlir::LLVMTypeConverter
Conversion from types to the LLVM IR dialect.
Definition: TypeConverter.h:35

mlir::Location
This class defines the main interface for locations in MLIR and acts as a non-nullable wrapper around...
Definition: Location.h:66

mlir::LowerToLLVMOptions
Options to control the LLVM lowering.
Definition: LoweringOptions.h:30

mlir::MLIRContext
MLIRContext is the top-level object for a collection of MLIR operations.
Definition: MLIRContext.h:60

mlir::OpBuilder::InsertionGuard
RAII guard to reset the insertion point of the builder when destroyed.
Definition: Builders.h:346

mlir::OpBuilder::setInsertionPoint
void setInsertionPoint(Block *block, Block::iterator insertPoint)
Set the insertion point to the specified location.
Definition: Builders.h:396

mlir::OpBuilder::createOrFold
void createOrFold(SmallVectorImpl< Value > &results, Location location, Args &&...args)
Create an operation of specific op type at the current insertion point, and immediately try to fold i...
Definition: Builders.h:518

mlir::OpBuilder::create
Operation * create(const OperationState &state)
Creates an operation given the fields represented as an OperationState.
Definition: Builders.cpp:453

mlir::Operation
Operation is the basic unit of execution within MLIR.
Definition: Operation.h:88

mlir::Operation::getLoc
Location getLoc()
The source location the operation was defined or derived from.
Definition: Operation.h:223

mlir::Operation::getParentOp
Operation * getParentOp()
Returns the closest surrounding operation that contains this operation or nullptr if this is a top-le...
Definition: Operation.h:234

mlir::Operation::getParentOfType
OpTy getParentOfType()
Return the closest surrounding parent operation that is of type 'OpTy'.
Definition: Operation.h:238

mlir::RewritePatternSet
Definition: PatternMatch.h:826

mlir::RewriterBase
This class coordinates the application of a rewrite on a set of IR, providing a way for clients to tr...
Definition: PatternMatch.h:412

mlir::RewriterBase::notifyMatchFailure
std::enable_if_t<!std::is_convertible< CallbackT, Twine >::value, LogicalResult > notifyMatchFailure(Location loc, CallbackT &&reasonCallback)
Used to notify the listener that the IR failed to be rewritten because of a match failure,...
Definition: PatternMatch.h:736

mlir::RewriterBase::replaceOpWithNewOp
OpTy replaceOpWithNewOp(Operation *op, Args &&...args)
Replace the results of the given (original) op with a new op that is created without verification (re...
Definition: PatternMatch.h:554

mlir::SymbolTable
This class allows for representing and managing the symbol table used by operations with the 'SymbolT...
Definition: SymbolTable.h:24

mlir::Type
Instances of the Type class are uniqued, have an immutable identifier and an optional mutable compone...
Definition: Types.h:74

mlir::Type::isF64
bool isF64() const
Definition: Types.cpp:41

mlir::Type::isTF32
bool isTF32() const
Definition: Types.cpp:39

mlir::Type::getContext
MLIRContext * getContext() const
Return the MLIRContext in which this type was uniqued.
Definition: Types.cpp:35

mlir::Type::isSignlessInteger
bool isSignlessInteger() const
Return true if this is a signless integer type (with the specified width).
Definition: Types.cpp:64

mlir::Type::isF32
bool isF32() const
Definition: Types.cpp:40

mlir::Type::isUnsignedInteger
bool isUnsignedInteger() const
Return true if this is an unsigned integer type (with the specified width).
Definition: Types.cpp:88

mlir::Type::isInteger
bool isInteger() const
Return true if this is an integer type (with the specified width).
Definition: Types.cpp:56

mlir::Type::isF16
bool isF16() const
Definition: Types.cpp:38

mlir::Type::getIntOrFloatBitWidth
unsigned getIntOrFloatBitWidth() const
Return the bit width of an integer or a float type, assert failure on other types.
Definition: Types.cpp:122

mlir::Type::isBF16
bool isBF16() const
Definition: Types.cpp:37

mlir::ValueRange
This class provides an abstraction over the different types of ranges over Values.
Definition: ValueRange.h:381

mlir::Value
This class represents an instance of an SSA value in the MLIR system, representing a computable value...
Definition: Value.h:96

mlir::Value::getType
Type getType() const
Return the type of this value.
Definition: Value.h:129

Pattern.h

Pass.h

Arith.h

MemRef.h

BuiltinTypes.h

mlir::LLVM::detail::handleMultidimensionalVectors
LogicalResult handleMultidimensionalVectors(Operation *op, ValueRange operands, const LLVMTypeConverter &typeConverter, std::function< Value(Type, ValueRange)> createOperand, ConversionPatternRewriter &rewriter)
Definition: VectorPattern.cpp:80

mlir::LLVM::getFixedVectorType
Type getFixedVectorType(Type elementType, unsigned numElements)
Creates an LLVM dialect-compatible type with the given element type and length.
Definition: LLVMTypes.cpp:961

mlir::NVVM::kGlobalMemorySpace
@ kGlobalMemorySpace
Global memory space identifier.
Definition: NVVMDialect.h:38

mlir::detail::enumerate
constexpr void enumerate(std::tuple< Tys... > &tuple, CallbackT &&callback)
Definition: Matchers.h:344

mlir::nvgpu::getMBarrierMemrefType
MemRefType getMBarrierMemrefType(MLIRContext *context, MBarrierGroupType barrierType)
Return the memref type that can be used to represent an mbarrier object.

mlir::nvgpu::getMbarrierMemorySpace
Attribute getMbarrierMemorySpace(MLIRContext *context, MBarrierGroupType barrierType)
Returns the memory space attribute of the mbarrier object.

mlir::scf::populateSCFStructuralTypeConversionsAndLegality
void populateSCFStructuralTypeConversionsAndLegality(const TypeConverter &typeConverter, RewritePatternSet &patterns, ConversionTarget &target)
Populates patterns for SCF structural type conversions and sets up the provided ConversionTarget with...
Definition: StructuralTypeConversions.cpp:242

mlir::xegpu::transpose
static void transpose(llvm::ArrayRef< int64_t > trans, SmallVector< int64_t > &shape)
Definition: XeGPUOps.cpp:22

mlir
Include the generated interface declarations.
Definition: LocalAliasAnalysis.h:20

mlir::TypedValue
std::conditional_t< std::is_same_v< Ty, mlir::Type >, mlir::Value, detail::TypedValue< Ty > > TypedValue
If Ty is mlir::Type this will select Value instead of having a wrapper around it.
Definition: Value.h:498

mlir::populateNVGPUToNVVMConversionPatterns
void populateNVGPUToNVVMConversionPatterns(const LLVMTypeConverter &converter, RewritePatternSet &patterns)
Definition: NVGPUToNVVM.cpp:1744

mlir::getElementTypeOrSelf
Type getElementTypeOrSelf(Type type)
Return the element type or return the type itself.
Definition: TypeUtilities.cpp:23

mlir::patterns
const FrozenRewritePatternSet & patterns
Definition: GreedyPatternRewriteDriver.h:233

mlir::populateGpuMemorySpaceAttributeConversions
void populateGpuMemorySpaceAttributeConversions(TypeConverter &typeConverter, const MemorySpaceMapping &mapping)
Populates memory space attribute conversion rules for lowering gpu.address_space to integer values.
Definition: GPUOpsLowering.cpp:801

mlir::get
auto get(MLIRContext *context, Ts &&...params)
Helper method that injects context only if needed, this helps unify some of the attribute constructio...
Definition: BytecodeImplementation.h:509

mlir::applyPartialConversion
LogicalResult applyPartialConversion(ArrayRef< Operation * > ops, const ConversionTarget &target, const FrozenRewritePatternSet &patterns, ConversionConfig config=ConversionConfig())
Below we define several entry points for operation conversion.
Definition: DialectConversion.cpp:3359

mlir::FunctionCallBuilder
Definition: GPUCommonPass.h:51

mlir::FunctionCallBuilder::create
LLVM::CallOp create(Location loc, OpBuilder &builder, ArrayRef< Value > arguments) const
Definition: GPUToLLVMConversion.cpp:580

j
Eliminates variable at the specified position using Fourier-Motzkin variable elimination.