doxygen/XeGPUOps_8cpp_source.html

//===- XeGPUOps.cpp - MLIR XeGPU ops implementation -------------*- C++ -*-===//

//

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

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

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

//

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


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

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

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

#include "mlir/Dialect/Utils/IndexingUtils.h"

#include "mlir/Dialect/Utils/StaticValueUtils.h"

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

#include "mlir/IR/Builders.h"

#include "mlir/IR/TypeUtilities.h"

#include "mlir/Interfaces/ViewLikeInterface.h"


#include "llvm/Support/Debug.h"


#define DEBUG_TYPE "xegpu"


using namespace mlir;

using namespace mlir::xegpu;


static bool isSharedMemory(const MemRefType &memrefTy) {

  Attribute attr = memrefTy.getMemorySpace();

  if (auto intAttr = llvm::dyn_cast<IntegerAttr>(attr))

    return intAttr.getInt() == 3;

  if (auto memrefSpace = llvm::dyn_cast<MemorySpaceAttr>(attr))

    return memrefSpace.getValue() == MemorySpace::SLM;

  if (auto xevmSpace = llvm::dyn_cast<xevm::AddrSpaceAttr>(attr))

    return xevmSpace.getValue() == xevm::AddrSpace::SHARED;

  return gpu::GPUDialect::isWorkgroupMemoryAddressSpace(attr);

}


template <typename T>


static std::string makeString(T array, bool breakline = false) {

  std::string buf;

  buf.clear();

  llvm::raw_string_ostream os(buf);

  os << "[";

  for (size_t i = 1; i < array.size(); i++) {

    os << array[i - 1] << ", ";

    if (breakline)

      os << "\n\t\t";

  }

  os << array.back() << "]";

  return buf;

}


static SmallVector<int64_t> getShapeOf(Type type) {

  SmallVector<int64_t> shape;

  if (auto ty = llvm::dyn_cast<ShapedType>(type))

    shape = SmallVector<int64_t>(ty.getShape());

  else

    shape.push_back(1);

  return shape;

}


static bool isReadHintOrNone(const CachePolicyAttr &attr) {

  if (!attr)

    return true;

  auto kind = attr.getValue();

  return kind == CachePolicy::CACHED || kind == CachePolicy::UNCACHED ||

         kind == CachePolicy::STREAMING || kind == CachePolicy::READ_INVALIDATE;

}


static bool isWriteHintOrNone(const CachePolicyAttr &attr) {

  if (!attr)

    return true;

  auto kind = attr.getValue();

  return kind == CachePolicy::CACHED || kind == CachePolicy::UNCACHED ||

         kind == CachePolicy::WRITE_BACK || kind == CachePolicy::WRITE_THROUGH;

}


static LogicalResult


isValidGatherScatterParams(Type maskTy, VectorType valueTy,

                           TensorDescType tdescTy,

                           function_ref<InFlightDiagnostic()> emitError) {


  if (!tdescTy.isScattered())

    return emitError() << "Expects a scattered TensorDesc.";


  auto chunkSize = tdescTy.getChunkSizeAsInt();

  if (!valueTy) {

    if (chunkSize > 1)

      return emitError() << "Expecting chunk size == 1 for scalar result";

    if (dyn_cast<VectorType>(maskTy))

      return emitError() << "Expecting a vector type result.";

    return success();

  }


  auto maskShape = getShapeOf(maskTy);

  auto valueShape = getShapeOf(valueTy);

  auto tdescShape = getShapeOf(tdescTy);


  if (valueTy.getElementType() != tdescTy.getElementType())

    return emitError()

           << "Value should have the same element type as TensorDesc.";


  llvm::SmallVector<int64_t> expectedMaskShape(tdescShape);

  if (chunkSize > 1)

    expectedMaskShape.pop_back();

  if (expectedMaskShape != maskShape)

    return emitError()

           << "Mask should match TensorDesc except the chunk size dim.";


  // a valid shape for SIMT case

  if (valueTy.getRank() == 1 && valueTy.getNumElements() == chunkSize) {

    if (tdescTy.getLayoutAttr())

      return emitError() << "TensorDesc doesn't need LayoutAttr for SIMT code";

    return success();

  }


  if (tdescShape != valueShape)

    return emitError() << "Value shape " << makeString(valueShape)

                       << " is neither a valid distribution for SIMT nor "

                          "consistent with the tensor descriptor for SIMD "

                       << tdescTy;

  return success();

}


static LogicalResult


isValidGatherScatterBufferParams(Type offsetsTy, Type maskTy,

                                 VectorType valueTy, int64_t chunkSize,

                                 function_ref<InFlightDiagnostic()> emitError) {


  auto maskVecTy = dyn_cast<VectorType>(maskTy);

  auto offsetsVecTy = dyn_cast<VectorType>(offsetsTy);

  if (!valueTy) {

    if (chunkSize > 1)

      return emitError() << "Expecting chunk size == 1 for scalar result";

    if (maskVecTy || offsetsVecTy)

      return emitError() << "Expecting scalar mask and offsets.";

    else if (maskVecTy && offsetsVecTy)

      return emitError() << "Expecting a vector type result.";

    return success();

  }


  auto valueSize = valueTy.getNumElements();

  // SIMT mode with scalar mask and offsets.

  if (!maskVecTy && !offsetsVecTy) {

    if (valueSize != chunkSize)

      return emitError() << "value elements must match chunk size "

                         << chunkSize;

    return success();

  }

  auto maskShape = getShapeOf(maskTy);

  auto valueShape = getShapeOf(valueTy);


  if (!maskVecTy)

    return emitError() << "Expecting a vector type mask.";

  int64_t maskSize = maskVecTy.getNumElements();


  if (chunkSize > 1) {

    if ((valueTy.getRank() == 1) && (valueSize != chunkSize))

      return emitError() << "value elements must match chunk size "

                         << chunkSize;

  } else {

    if (valueSize != maskSize)

      return emitError()

             << "Mask should match value except the chunk size dim.";

  }

  llvm::SmallVector<int64_t> expectedMaskShape(valueShape);

  if (maskSize == 1)

    return success();

  if (chunkSize > 1)

    expectedMaskShape.pop_back();

  if (expectedMaskShape != maskShape)

    return emitError() << "Mask should match value except the chunk size dim.";


  return success();

}


LogicalResult


IsValidMatrixOpParams(VectorType dataTy, MemDescType mdescTy,

                      UnitAttr subgroup_block_io, DistributeLayoutAttr layout,

                      function_ref<InFlightDiagnostic()> emitError) {


  if (!dataTy) {

    if (subgroup_block_io)

      return emitError() << "subgroup_block_io "

                            "are only allowed when result is a VectorType.";

    else

      return success();

  }


  if (mdescTy.getRank() < 2)

    return emitError() << "mem_desc must be 2D or greater.";


  ArrayRef<int64_t> dataShape = dataTy.getShape();

  ArrayRef<int64_t> mdescShape = mdescTy.getShape();


  SmallVector<int64_t> blockShape = mdescTy.getBlockShape();

  ArrayAttr strideAttr = mdescTy.getStrideAttr();

  SmallVector<int64_t> strides;

  for (Attribute attr : strideAttr.getValue()) {

    strides.push_back(cast<IntegerAttr>(attr).getInt());

  }

  if (subgroup_block_io && layout) {

    auto laneData = layout.getEffectiveLaneDataAsInt();

    auto laneLayout = layout.getEffectiveLaneLayoutAsInt();

    if (!laneData.empty()) {

      bool isLaneDataContiguous =

          std::all_of(laneData.begin(), std::prev(laneData.end()),

                      [](int x) { return x == 1; });

      if (!isLaneDataContiguous)

        return emitError() << "With subgroup_block_io, accessed data must be "

                              "contiguous and coalesced.";

      for (size_t i = 0; i < laneData.size(); ++i) {

        if (laneLayout[i] != blockShape[i])

          return emitError() << "With subgroup_block_io, the block shape must "

                                "match the lane layout.";

        if (laneLayout[i] != 1 && strides[i] != 1)

          return emitError() << "With subgroup_block_io, the distributed "

                                "dimensions must be contiguous.";

      }

    }

  }

  if (dataShape.size() == 2) {

    if (llvm::any_of(llvm::zip_equal(dataShape, mdescShape),

                     [](auto p) { return std::get<0>(p) > std::get<1>(p); }))

      return emitError() << "data shape must not exceed mem_desc shape.";

  } else {

    // if the subgroup_block_io attribute is set,  mdescTy must have block

    // attribute

    if (subgroup_block_io && !blockShape.size())

      return emitError() << "mem_desc must have block attribute when "

                            "subgroup_block_io is set.";

    // if the subgroup_block_io attribute is set, the memdesc should be row

    // major

    if (subgroup_block_io && mdescTy.isColMajor())

      return emitError() << "mem_desc should be row major when "

                            "subgroup_block_io is set.";

  }


  return success();

}


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

// XeGPU_CreateNdDescOp

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


void CreateNdDescOp::build(OpBuilder &builder, OperationState &state,

                           Type tdesc, TypedValue<MemRefType> source) {

  [[maybe_unused]] auto ty = source.getType();

  assert(ty.hasStaticShape() && "expecting a memref with static shape");


  build(builder, state, tdesc, source, ValueRange({}) /* dynamic offsets */,

        ValueRange({}) /* empty dynamic shape */,

        ValueRange({}) /* empty dynamic strides */,

        DenseI64ArrayAttr({}) /* const offsets */,

        DenseI64ArrayAttr({}) /* empty const shape*/,

        DenseI64ArrayAttr({}) /* empty const strides*/);

}


void CreateNdDescOp::build(OpBuilder &builder, OperationState &state,

                           Type tdesc, Value source,

                           llvm::ArrayRef<OpFoldResult> shape,

                           llvm::ArrayRef<OpFoldResult> strides) {

  Type srcTy = source.getType();

  assert((isa<IntegerType, MemRefType>(srcTy)) &&

         "Source has to be either int or memref.");


  llvm::SmallVector<Value> dynamicShape;

  llvm::SmallVector<Value> dynamicStrides;


  llvm::SmallVector<int64_t> staticShape;

  llvm::SmallVector<int64_t> staticStrides;


  dispatchIndexOpFoldResults(shape, dynamicShape, staticShape);

  dispatchIndexOpFoldResults(strides, dynamicStrides, staticStrides);


  auto staticShapeAttr = builder.getDenseI64ArrayAttr(staticShape);

  auto staticStridesAttr = builder.getDenseI64ArrayAttr(staticStrides);


  if (auto memrefTy = dyn_cast<MemRefType>(srcTy)) {

    auto memrefShape = memrefTy.getShape();

    auto [memrefStrides, _] = memrefTy.getStridesAndOffset();


    // if shape and strides are from Memref, we don't need attributes for them

    // to keep the IR print clean (only do so for full-static case, otherwise

    // printer would fail trying to print empty array-attr).

    if (staticShape == memrefShape && staticStrides == memrefStrides &&

        dynamicShape.empty() && dynamicStrides.empty()) {

      staticShapeAttr = DenseI64ArrayAttr();

      staticStridesAttr = DenseI64ArrayAttr();

    }

  }


  build(builder, state, tdesc, source, ValueRange({}), dynamicShape,

        dynamicStrides, builder.getDenseI64ArrayAttr({}), staticShapeAttr,

        staticStridesAttr);

}


void CreateNdDescOp::build(OpBuilder &builder, OperationState &state,

                           Type tdesc, TypedValue<MemRefType> source,

                           llvm::ArrayRef<OpFoldResult> offsets) {

  [[maybe_unused]] auto ty = source.getType();

  assert(ty.hasStaticShape() && offsets.size() == (size_t)ty.getRank());


  llvm::SmallVector<int64_t> staticOffsets;

  llvm::SmallVector<Value> dynamicOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);


  build(builder, state, tdesc, source, dynamicOffsets /* dynamic offsets */,

        ValueRange({}) /* empty dynamic shape */,

        ValueRange({}) /* empty dynamic strides */,

        builder.getDenseI64ArrayAttr(staticOffsets) /* const offsets */,

        {} /* empty const shape*/, {} /* empty const strides*/);

}


void CreateNdDescOp::build(OpBuilder &builder, OperationState &state,

                           Type tdesc, Value source,

                           llvm::ArrayRef<OpFoldResult> offsets,

                           llvm::ArrayRef<OpFoldResult> shape,

                           llvm::ArrayRef<OpFoldResult> strides) {

  assert(!shape.empty() && !offsets.empty() && !strides.empty() &&

         shape.size() == strides.size() && shape.size() == offsets.size());


  Type srcTy = source.getType();

  assert((isa<IntegerType, MemRefType>(srcTy)) &&

         "Source has to be either int or memref.");


  llvm::SmallVector<Value> dynamicOffsets;

  llvm::SmallVector<Value> dynamicShape;

  llvm::SmallVector<Value> dynamicStrides;


  llvm::SmallVector<int64_t> staticOffsets;

  llvm::SmallVector<int64_t> staticShape;

  llvm::SmallVector<int64_t> staticStrides;


  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);

  dispatchIndexOpFoldResults(shape, dynamicShape, staticShape);

  dispatchIndexOpFoldResults(strides, dynamicStrides, staticStrides);


  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);

  auto staticShapeAttr = builder.getDenseI64ArrayAttr(staticShape);

  auto staticStridesAttr = builder.getDenseI64ArrayAttr(staticStrides);


  if (auto memrefTy = dyn_cast<MemRefType>(srcTy)) {

    auto memrefShape = memrefTy.getShape();

    auto [memrefStrides, _] = memrefTy.getStridesAndOffset();


    // if shape and strides are from Memref, we don't need attributes for them

    // to keep the IR print clean (only do so for full-static case, otherwise

    // printer would fail trying to print empty array-attr).

    if (staticShape == memrefShape && staticStrides == memrefStrides &&

        dynamicShape.empty() && dynamicStrides.empty()) {

      staticShapeAttr = DenseI64ArrayAttr();

      staticStridesAttr = DenseI64ArrayAttr();

    }

  }


  build(builder, state, tdesc, source, dynamicOffsets, dynamicShape,

        dynamicStrides, staticOffsetsAttr, staticShapeAttr, staticStridesAttr);

}


LogicalResult CreateNdDescOp::verify() {

  size_t rank = getMixedSizes().size();

  bool invalidRank = rank != getMixedStrides().size();

  bool invalidElemTy = false;


  // Memory space of created TensorDesc should match with the source.

  // Both source and TensorDesc are considered for global memory by default,

  // if the memory scope attr is not specified. If source is an integer,

  // it is considered as ptr to global memory.

  auto srcMemorySpace = getSourceMemorySpace();

  auto tdescMemorySpace = static_cast<unsigned>(getType().getMemorySpace());

  if (srcMemorySpace != tdescMemorySpace)

    return emitOpError("Memory space mismatch.")

           << " Source: " << srcMemorySpace

           << ", TensorDesc: " << tdescMemorySpace;


  if (size_t offsetRank = getMixedOffsets().size())

    invalidRank |= (offsetRank != rank);


  // check source type matches the rank if it is a memref.

  // It also should have the same ElementType as TensorDesc.

  if (auto memrefTy = dyn_cast<MemRefType>(getSourceType()))

    invalidElemTy |= memrefTy.getElementType() != getElementType();


  if (llvm::isa<IntegerType>(getSourceType())) {

    // strides and shape must present for integer source.

    if (getMixedStrides().empty() || getMixedSizes().empty())

      return emitOpError("expecting strides and shape to be present for "

                         "integer source.");

  }


  if (invalidRank)

    return emitOpError(

        "Expecting the rank of shape, strides, offsets, and source (if source "

        "is a memref) should match with each other.");


  // check result TensorDesc rank

  if (getType().getRank() > (int64_t)rank)

    return emitOpError(

        "Expecting the TensorDesc rank is not greater than the "

        "ranks of shape, strides, offsets or the memref source.");


  if (invalidElemTy)

    return emitOpError("TensorDesc should have the same element "

                       "type with the source if it is a memref.\n");


  if (getType().isScattered())

    return emitOpError("Expects a non-scattered TensorDesc.\n");


  return success();

}


static ParseResult parseOptionalDynamicIndexList(

    OpAsmParser &parser,

    SmallVectorImpl<OpAsmParser::UnresolvedOperand> &values,

    DenseI64ArrayAttr &integers, SmallVectorImpl<Type> *valueTypes = nullptr,

    AsmParser::Delimiter delimiter = AsmParser::Delimiter::Square) {


  SmallVector<int64_t, 4> integerVals;

  auto parseIntegerOrValue = [&]() {

    OpAsmParser::UnresolvedOperand operand;

    auto res = parser.parseOptionalOperand(operand);


    if (res.has_value() && succeeded(res.value())) {

      values.push_back(operand);

      integerVals.push_back(ShapedType::kDynamic);

      if (valueTypes && parser.parseColonType(valueTypes->emplace_back()))

        return failure();

    } else {

      int64_t integer;

      if (failed(parser.parseInteger(integer)))

        return failure();

      integerVals.push_back(integer);

    }

    return success();

  };


  // If the optional values are given there must be left bracket

  if (parser.parseOptionalLSquare().succeeded()) {

    if (parser.parseCommaSeparatedList(parseIntegerOrValue) ||

        parser.parseRSquare())

      return parser.emitError(parser.getNameLoc())

             << "expected a list of SSA values or integers";

    integers = parser.getBuilder().getDenseI64ArrayAttr(integerVals);

    return success();

  }


  return success();

}


static void printOptionalDynamicIndexList(OpAsmPrinter &printer, Operation *op,

                                          OperandRange values,

                                          DenseI64ArrayAttr integers) {

  if (!integers || integers.empty())

    return;

  printDynamicIndexList(printer, op, values, integers,

                        /*scalableFlags=*/{}, {}, AsmParser::Delimiter::Square);

}


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

// XeGPU_PrefetchNdOp

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


void PrefetchNdOp::build(OpBuilder &builder, OperationState &state,

                         Value tensorDesc, xegpu::CachePolicyAttr l1_hint,

                         xegpu::CachePolicyAttr l2_hint,

                         xegpu::CachePolicyAttr l3_hint) {


  return build(builder, state, tensorDesc, ValueRange(), DenseI64ArrayAttr(),

               l1_hint, l2_hint, l3_hint, /*anchor_layout=*/nullptr);

}


void PrefetchNdOp::build(OpBuilder &builder, OperationState &state,

                         Value tensorDesc, ArrayRef<OpFoldResult> offsets,

                         xegpu::CachePolicyAttr l1_hint,

                         xegpu::CachePolicyAttr l2_hint,

                         xegpu::CachePolicyAttr l3_hint,

                         xegpu::DistributeLayoutAttr layout) {

  SmallVector<Value> dynamicOffsets;

  SmallVector<int64_t> staticOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);


  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);


  build(builder, state, tensorDesc, dynamicOffsets, staticOffsetsAttr, l1_hint,

        l2_hint, l3_hint, /*anchor_layout=*/layout);

}


LogicalResult PrefetchNdOp::verify() {

  auto tdescTy = getTensorDescType();

  if (tdescTy.isScattered())

    return emitOpError("Expects a non-scattered TensorDesc.\n");


  if (!isReadHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isReadHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isReadHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  int64_t tDescRank = tdescTy.getRank();

  int64_t offsetSize = getMixedOffsets().size();

  if (offsetSize != 0 && offsetSize != tDescRank)

    return emitOpError(

        "Mismatched ranks between offsets and tensor descriptor");


  return success();

}


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

// XeGPU_LoadNdOp

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


void LoadNdOp::build(OpBuilder &builder, OperationState &state, Type retType,

                     Value tensorDesc, UnitAttr packed,

                     DenseI64ArrayAttr transpose,

                     xegpu::CachePolicyAttr l1_hint,

                     xegpu::CachePolicyAttr l2_hint,

                     xegpu::CachePolicyAttr l3_hint) {


  return build(builder, state, retType, tensorDesc, ValueRange(),

               DenseI64ArrayAttr(), packed, transpose, l1_hint, l2_hint,

               l3_hint, /*anchor_layout=*/nullptr);

}


void LoadNdOp::build(OpBuilder &builder, OperationState &state, Type retType,

                     Value tensorDesc, ArrayRef<OpFoldResult> offsets,

                     UnitAttr packed, DenseI64ArrayAttr transpose,

                     xegpu::CachePolicyAttr l1_hint,

                     xegpu::CachePolicyAttr l2_hint,

                     xegpu::CachePolicyAttr l3_hint,

                     xegpu::DistributeLayoutAttr layout) {

  SmallVector<Value> dynamicOffsets;

  SmallVector<int64_t> staticOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);


  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);


  build(builder, state, retType, tensorDesc, dynamicOffsets, staticOffsetsAttr,

        packed, transpose, l1_hint, l2_hint, l3_hint,

        /*anchor_layout=*/layout);

}


LogicalResult LoadNdOp::verify() {

  auto tdescTy = getTensorDescType();

  auto valueTy = getType();


  if (tdescTy.isScattered())

    return emitOpError("Expects a non-scattered TensorDesc.\n");


  if (tdescTy.getRank() > 2)

    return emitOpError("Expects a 1D or 2D TensorDesc.\n");


  if (!valueTy)

    return emitOpError("Invalid result, it should be a VectorType.\n");


  if (!isReadHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isReadHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isReadHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  int tdescElems = tdescTy.getNumElements() * tdescTy.getArrayLength();

  int valueElems = valueTy.getNumElements();


  // If the result vector is 1D and has less elements than the tensor

  // descriptor, it is supposed to be a SIMT op. The layout attribute in

  // tensor_desc is not needed.

  if (valueElems < tdescElems && valueTy.getRank() == 1) {

    // SIMT mode doesn't need LayoutAttr.

    if (tdescTy.getLayoutAttr())

      return emitOpError()

             << "TensorDesc doesn't need LayoutAttr for SIMT code";


    // For SIMT code, the load is evenly distributed across all lanes in a

    // subgroup. Since subgroup size is arch dependent, we only check even

    // distribution here.

    if (tdescElems % valueElems)

      return emitOpError()

             << "Result shape " << makeString(getShapeOf(valueTy))

             << " is not a valid distribution for tensor descriptor "

             << tdescTy;


    return success();

  }


  // Check SIMD mode.

  auto tdescShape = getShapeOf(tdescTy);

  auto valueShape = getShapeOf(valueTy);


  if (getTranspose()) {

    auto trans = getTranspose().value();

    // Make sure the transpose value is valid, and apply it

    if (llvm::all_of(trans, [&](size_t s) { return s < tdescShape.size(); }))

      tdescShape = applyPermutation(tdescShape, trans);

    else

      mlir::emitWarning(getLoc()) << "Invalid transpose attr. It is ignored.";

  }


  if (getPacked()) {

    if (tdescTy.getRank() == 2) {

      const int axis = 0;

      auto vnni_factor = valueShape.back();

      tdescShape[axis] /= vnni_factor;

      tdescShape.push_back(vnni_factor);

    } else {

      mlir::emitWarning(getLoc())

          << "Invalid Packed Attr. It is ignored (available for 2D "

             "TensorDesc only).";

    }

  }


  auto array_len = tdescTy.getArrayLength();

  if (array_len > 1)

    tdescShape.insert(tdescShape.begin(), array_len);


  if (tdescShape != valueShape)

    return emitOpError() << "Result shape " << makeString(valueShape)

                         << " is not consistent with tensor descriptor "

                         << tdescTy;


  int64_t tDescRank = tdescTy.getRank();

  int64_t offsetSize = getMixedOffsets().size();

  if (offsetSize != 0 && offsetSize != tDescRank)

    return emitOpError(

        "Mismatched ranks between offsets and tensor descriptor");


  return success();

}


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

// XeGPU_StoreNdOp

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


void StoreNdOp::build(OpBuilder &builder, OperationState &state, Value value,

                      Value tensorDesc, xegpu::CachePolicyAttr l1_hint,

                      xegpu::CachePolicyAttr l2_hint,

                      xegpu::CachePolicyAttr l3_hint) {


  return build(builder, state, value, tensorDesc, ValueRange(),

               DenseI64ArrayAttr(), l1_hint, l2_hint, l3_hint,

               /*anchor_layout=*/nullptr);

}


void StoreNdOp::build(OpBuilder &builder, OperationState &state, Value value,

                      Value tensorDesc, ArrayRef<OpFoldResult> offsets,

                      xegpu::CachePolicyAttr l1_hint,

                      xegpu::CachePolicyAttr l2_hint,

                      xegpu::CachePolicyAttr l3_hint,

                      xegpu::DistributeLayoutAttr layout) {

  SmallVector<Value> dynamicOffsets;

  SmallVector<int64_t> staticOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);


  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);


  build(builder, state, value, tensorDesc, dynamicOffsets, staticOffsetsAttr,

        l1_hint, l2_hint, l3_hint, /*anchor_layout=*/layout);

}


LogicalResult StoreNdOp::verify() {

  auto dstTy = getTensorDescType(); // Tile

  auto valTy = getValueType();      // Vector


  if (dstTy.isScattered())

    return emitOpError("Expects a non-scattered TensorDesc.\n");


  if (dstTy.getRank() > 2)

    return emitOpError("Expects a 1D or 2D TensorDesc.\n");


  if (!valTy)

    return emitOpError("Expecting a VectorType result.\n");


  if (!isWriteHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isWriteHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isWriteHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  auto array_len = dstTy.getArrayLength();

  if (array_len > 1)

    return emitOpError("array length is not supported by store_nd.\n");


  auto tdescElems = dstTy.getNumElements();

  auto valueElems = valTy.getNumElements();


  // Similar to LoadNdOp, if the value vector is 1D and has less elements than

  // the tensor descriptor, it is supposed to be a SIMT op. The layout attribute

  // in tensor_desc is not needed.

  if (valTy.getRank() == 1 && valueElems < tdescElems) {

    // SIMT mode doesn't need LayoutAttr.

    if (dstTy.getLayoutAttr())

      return emitOpError()

             << "TensorDesc doesn't need LayoutAttr for SIMT code";


    if (tdescElems % valueElems)

      return emitOpError()

             << "Value shape " << makeString(getShapeOf(valTy))

             << " is not a valid distribution for tensor descriptor " << dstTy;


    return success();

  }


  // SIMD code should have the same shape as the tensor descriptor.

  auto tdescShape = getShapeOf(dstTy);

  auto valueShape = getShapeOf(valTy);

  if (tdescShape != valueShape)

    return emitOpError() << "Value shape " << makeString(valueShape)

                         << " is not consistent with tensor descriptor "

                         << dstTy;


  int64_t tDescRank = dstTy.getRank();

  int64_t offsetSize = getMixedOffsets().size();

  if (offsetSize != 0 && offsetSize != tDescRank)

    return emitOpError(

        "Mismatched ranks between offsets and tensor descriptor");


  return success();

}


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

// XeGPU_UpdateNDOffsetOp

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

LogicalResult UpdateNdOffsetOp::verify() {

  auto ty = getTensorDescType();

  if (ty.isScattered())

    return emitOpError("Expects a non-scattered TensorDesc.\n");


  // number of offsets specified must match the rank of the tensor descriptor

  if (ty.getRank() != (int64_t)getNumOffsets()) {

    return emitOpError("Invalid number of offsets.");

  }

  return success();

}


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

// XeGPU_CreateDescOp

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


void CreateDescOp::build(OpBuilder &builder, OperationState &state,

                         TensorDescType TensorDesc, Value source,

                         llvm::ArrayRef<OpFoldResult> offsets) {

  auto loc = source.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get(size, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);

  build(builder, state, TensorDesc, source, offset);

}


void CreateDescOp::build(OpBuilder &builder, OperationState &state,

                         TensorDescType TensorDesc, Value source,

                         llvm::ArrayRef<int64_t> offsets) {

  auto ofrs = getAsIndexOpFoldResult(builder.getContext(), offsets);

  build(builder, state, TensorDesc, source, ofrs);

}


LogicalResult CreateDescOp::verify() {

  auto tdescTy = getTensorDescType();


  if (!tdescTy.isScattered())

    return emitOpError("Expects a scattered TensorDesc.\n");


  // Memory space of created TensorDesc should match with the source.

  // Both source and TensorDesc are considered for global memory by default,

  // if the memory scope attr is not specified. If source is an integer,

  // it is considered as ptr to global memory.

  auto srcMemorySpace = getSourceMemorySpace();

  auto tdescMemorySpace = static_cast<unsigned>(tdescTy.getMemorySpace());

  if (srcMemorySpace != tdescMemorySpace)

    return emitOpError("Memory space mismatch.")

           << " Source: " << srcMemorySpace

           << ", TensorDesc: " << tdescMemorySpace;


  // check total size

  auto chunkSize = tdescTy.getChunkSizeAsInt();

  SmallVector<int64_t> shape(getOffsetsType().getShape());

  if (chunkSize != 1)

    shape.push_back(chunkSize);


  auto tdescShape = getShapeOf(tdescTy);

  if (shape != tdescShape)

    return emitOpError("Incorrect TensorDesc shape. ")

           << "Expected is " << makeString(shape) << "\n";


  return success();

}


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

// XeGPU_PrefetchOp

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

LogicalResult PrefetchOp::verify() {

  auto tdescTy = getTensorDescType();


  if (!tdescTy && !getOffsets())

    return emitOpError("Expects offsets.");


  if (tdescTy && getOffsets())

    return emitOpError("offsets not allowed.");


  if (tdescTy && !tdescTy.isScattered())

    return emitOpError("Expects a scattered TensorDesc.");


  if (!isReadHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isReadHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isReadHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  auto srcTy = getSourceType();

  if (srcTy.isInteger() && !getOffsetAlignByteAttr())

    return emitOpError("offset_align_byte is required with integer source.");


  if (getOffsetAlignByteAttr() && !srcTy.isInteger())

    return emitOpError("offset_align_byte only allowed with integer source.");


  return success();

}


void PrefetchOp::build(OpBuilder &builder, OperationState &state, Value source,

                       xegpu::CachePolicyAttr l1_hint,

                       xegpu::CachePolicyAttr l2_hint,

                       xegpu::CachePolicyAttr l3_hint) {

  build(builder, state, source, Value(), l1_hint, l2_hint, l3_hint,

        IntegerAttr{}, /*anchor_layout=*/nullptr);

}


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

// XeGPU_LoadGatherOp

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

LogicalResult LoadGatherOp::verify() {

  auto tdescTy = getTensorDescType();

  auto maskTy = getMaskType();

  auto valueTy = getValueType();


  if (!tdescTy && !getOffsets())

    return emitOpError("Expects offsets.");


  if (tdescTy && getOffsets())

    return emitOpError("offsets not allowed.");


  if (tdescTy && !tdescTy.isScattered())

    return emitOpError("Expects a scattered TensorDesc.");


  if (!isReadHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isReadHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isReadHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  if (tdescTy)

    return isValidGatherScatterParams(maskTy, valueTy, tdescTy,

                                      [&]() { return emitOpError(); });

  auto srcTy = getSourceType();

  uint64_t chunkSize = static_cast<int64_t>(getChunkSize().value_or(1));

  auto memTy = dyn_cast<MemRefType>(srcTy);


  if (memTy && (getElementType() != memTy.getElementType()))

    return emitError() << "Value should have the same element type as MemRef.";


  auto offsetsTy = getOffsets().getType();

  return isValidGatherScatterBufferParams(offsetsTy, maskTy, valueTy, chunkSize,

                                          [&]() { return emitOpError(); });

}


void LoadGatherOp::build(OpBuilder &builder, OperationState &state,

                         Type valueType, Value source, Value mask,

                         xegpu::CachePolicyAttr l1_hint,

                         xegpu::CachePolicyAttr l2_hint,

                         xegpu::CachePolicyAttr l3_hint) {

  build(builder, state, valueType, source, Value(), mask, IntegerAttr(),

        l1_hint, l2_hint, l3_hint, /*anchor_layout=*/nullptr);

}


void LoadGatherOp::build(OpBuilder &builder, OperationState &state,

                         Type valueType, Value source,

                         ArrayRef<OpFoldResult> offsets, Value mask,

                         IntegerAttr chunk_size, xegpu::CachePolicyAttr l1_hint,

                         xegpu::CachePolicyAttr l2_hint,

                         xegpu::CachePolicyAttr l3_hint) {

  auto loc = source.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get(size, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);


  build(builder, state, valueType, source, offset, mask, chunk_size, l1_hint,

        l2_hint, l3_hint, /*anchor_layout=*/nullptr);

}


void LoadGatherOp::build(OpBuilder &builder, OperationState &state,

                         Type valueType, Value source,

                         ArrayRef<OpFoldResult> offsets, Value mask,

                         IntegerAttr chunk_size, xegpu::CachePolicyAttr l1_hint,

                         xegpu::CachePolicyAttr l2_hint,

                         xegpu::CachePolicyAttr l3_hint,

                         DistributeLayoutAttr layout) {

  auto loc = source.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get(size, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);


  build(builder, state, valueType, source, offset, mask, chunk_size, l1_hint,

        l2_hint, l3_hint, layout);

}


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

// XeGPU_StoreScatterOp

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

LogicalResult StoreScatterOp::verify() {

  auto tdescTy = getTensorDescType();

  auto maskTy = getMaskType();

  auto valueTy = getValueType();


  if (!tdescTy && !getOffsets())

    return emitOpError("Expects offsets.");


  if (tdescTy && getOffsets())

    return emitOpError("offsets not allowed.");


  if (tdescTy && !tdescTy.isScattered())

    return emitOpError("Expects a scattered TensorDesc.");


  if (!isWriteHintOrNone(getL1HintAttr()))

    return emitOpError("invalid l1_hint: ") << getL1HintAttr();


  if (!isWriteHintOrNone(getL2HintAttr()))

    return emitOpError("invalid l2_hint: ") << getL2HintAttr();


  if (!isWriteHintOrNone(getL3HintAttr()))

    return emitOpError("invalid l3_hint: ") << getL3HintAttr();


  if (tdescTy)

    return isValidGatherScatterParams(maskTy, valueTy, tdescTy,

                                      [&]() { return emitOpError(); });


  auto destTy = getDestType();

  uint64_t chunkSize = static_cast<int64_t>(getChunkSize().value_or(1));

  auto memTy = dyn_cast<MemRefType>(destTy);


  if (memTy && (getElementType() != memTy.getElementType()))

    return emitError() << "Value should have the same element type as MemRef.";


  auto offsetsTy = getOffsets().getType();

  return isValidGatherScatterBufferParams(offsetsTy, maskTy, valueTy, chunkSize,

                                          [&]() { return emitOpError(); });

}


void StoreScatterOp::build(OpBuilder &builder, OperationState &state,

                           Value value, Value dest, Value mask,

                           xegpu::CachePolicyAttr l1_hint,

                           xegpu::CachePolicyAttr l2_hint,

                           xegpu::CachePolicyAttr l3_hint) {

  build(builder, state, value, dest, Value(), mask, IntegerAttr(), l1_hint,

        l2_hint, l3_hint, /*anchor_layout=*/nullptr);

}


void StoreScatterOp::build(OpBuilder &builder, OperationState &state,

                           Value value, Value dest,

                           ArrayRef<OpFoldResult> offsets, Value mask,

                           IntegerAttr chunk_size,

                           xegpu::CachePolicyAttr l1_hint,

                           xegpu::CachePolicyAttr l2_hint,

                           xegpu::CachePolicyAttr l3_hint) {

  auto loc = dest.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get(size, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);


  // Call the correct builder overload that does not expect result types.

  build(builder, state, value, dest, offset, mask, chunk_size, l1_hint, l2_hint,

        l3_hint, /*anchor_layout=*/nullptr);

}


void StoreScatterOp::build(

    OpBuilder &builder, OperationState &state, Value value, Value dest,

    ArrayRef<OpFoldResult> offsets, Value mask, IntegerAttr chunk_size,

    xegpu::CachePolicyAttr l1_hint, xegpu::CachePolicyAttr l2_hint,

    xegpu::CachePolicyAttr l3_hint, DistributeLayoutAttr layout) {

  auto loc = dest.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get(size, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);


  // Call the correct builder overload that does not expect result types.

  build(builder, state, value, dest, offset, mask, chunk_size, l1_hint, l2_hint,

        l3_hint, layout);

}


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

// XeGPU_UpdateOffsetOp

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

void UpdateOffsetOp::build(OpBuilder &builder, OperationState &state,

                           mlir::Value tensorDesc,

                           llvm::ArrayRef<OpFoldResult> offsets) {

  auto tdescTy = mlir::dyn_cast<TensorDescType>(tensorDesc.getType());

  assert(tdescTy && "Expecting the source is a TensorDescType value.");

  auto loc = tensorDesc.getLoc();

  int64_t size = static_cast<int64_t>(offsets.size());

  auto type = VectorType::get({size}, builder.getIndexType());

  auto values = getValueOrCreateConstantIndexOp(builder, loc, offsets);

  auto offset = vector::FromElementsOp::create(builder, loc, type, values);

  build(builder, state, tdescTy, tensorDesc, offset);

}


void UpdateOffsetOp::build(OpBuilder &builder, OperationState &state,

                           Value tensorDesc, llvm::ArrayRef<int64_t> offsets) {

  auto ofrs = getAsIndexOpFoldResult(builder.getContext(), offsets);

  build(builder, state, tensorDesc, ofrs);

}


LogicalResult UpdateOffsetOp::verify() {

  auto tdescTy = getTensorDescType();

  if (!tdescTy.isScattered())

    return emitOpError("Expects a scattered TensorDesc.\n");


  SmallVector<int64_t> expectedOffsetShape = getShapeOf(tdescTy);

  SmallVector<int64_t> offsetShape = getShapeOf(getOffsetsType());

  if (tdescTy.getChunkSizeAsInt() > 1)

    expectedOffsetShape.pop_back();


  if (expectedOffsetShape != offsetShape)

    return emitOpError(

        "Offsets should match TensorDesc except the chunk size dim.");


  return success();

}


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

// XeGPU_DpasOp

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

LogicalResult DpasOp::verify() {

  int64_t lhsRank = getLhsType().getRank();

  int64_t rhsRank = getRhsType().getRank();

  int64_t resRank = getResultType().getRank();

  auto lhsShape = getLhsType().getShape();

  auto rhsShape = getRhsType().getShape();

  auto resShape = getResultType().getShape();


  if (getAcc() && getAcc().getType() != getResultType())

    return emitOpError("Expecting the acc type to be the same as result.");


  // SIMT code: the size of the B operand has to be a multiple of 32 bits.

  // It skips the semantic check since lack of architecture information.

  // Users need to ensure the correctness.

  if (lhsRank == 1 && rhsRank == 1 && resRank == 1) {

    auto numElems = getRhsType().getNumElements();

    auto elemTy = getRhsType().getElementType();

    auto factor = 32 / elemTy.getIntOrFloatBitWidth();

    if (numElems % factor != 0)

      return emitOpError("Expecting B operand to be a multiple of 32 bits.");

    return success();

  }


  // SIMD code

  if (lhsRank != 2 || (rhsRank != 2 && rhsRank != 3) || resRank != 2)

    return emitOpError(

        "expecting lhs and result to be a 2D vector, and rhs to be either "

        "2D or 3D (packed) vector.");

  auto bK = rhsRank == 3 ? rhsShape[0] * rhsShape[2] : rhsShape[0];

  if (bK != lhsShape[1])

    return emitOpError("K-dimension mismatch.");

  if (lhsShape[0] != resShape[0])

    return emitOpError("M-dimension mismatch.");

  if (rhsShape[1] != resShape[1])

    return emitOpError("N-dimension mismatch.");


  return success();

}


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

// XeGPU_ConvertLayoutOp

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

LogicalResult ConvertLayoutOp::verify() {

  auto srcLayout = getInputLayout();

  auto resLayout = getTargetLayout();

  if (!srcLayout)

    return emitOpError("expected input layout.");

  if (!resLayout)

    return emitOpError("expected target layout.");


  // both input and target layouts should be WgLayout or SgLayout at the same

  // time.

  if ((!srcLayout.isForWorkgroup() || !resLayout.isForWorkgroup()) &&

      (!srcLayout.isForSubgroup() || !resLayout.isForSubgroup()))

    return emitOpError("expected input layout and target layout be WgLayout or "

                       "SgLayout at the same time.");


  auto shape = getSource().getType().getShape();

  if (!XeGPUDialect::isEvenlyDistributable(shape, srcLayout))

    return emitOpError(

        "invalid input layout, data cannot be evenly distributed.");


  if (!XeGPUDialect::isEvenlyDistributable(shape, resLayout))

    return emitOpError(

        "invalid target layout, data cannot be evenly distributed.");


  return mlir::success();

}


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

// XeGPU_LoadMatrixOp

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

void LoadMatrixOp::build(OpBuilder &builder, OperationState &state, Type res,

                         TypedValue<MemDescType> memDesc,

                         llvm::ArrayRef<OpFoldResult> offsets,

                         DistributeLayoutAttr layout) {

  llvm::SmallVector<Value> dynamicOffsets;

  llvm::SmallVector<int64_t> staticOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);

  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);

  // Call the generated builder with all parameters (including optional ones as

  // nullptr/empty)

  build(builder, state, res, memDesc, dynamicOffsets, staticOffsetsAttr,

        /*subgroup_block_io=*/nullptr, layout);

}


LogicalResult LoadMatrixOp::verify() {


  auto resTy = dyn_cast<VectorType>(getRes().getType());

  UnitAttr subgroup_block_io = getSubgroupBlockIoAttr();

  MemDescType mdescTy = getMemDesc().getType();


  return IsValidMatrixOpParams(resTy, mdescTy, subgroup_block_io,

                               getLayoutAttr(), [&]() { return emitError(); });

}


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

// XeGPU_StoreMatrixOp

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

void StoreMatrixOp::build(OpBuilder &builder, OperationState &state, Value data,

                          TypedValue<MemDescType> memDesc,

                          llvm::ArrayRef<OpFoldResult> offsets,

                          DistributeLayoutAttr layout) {

  llvm::SmallVector<Value> dynamicOffsets;

  llvm::SmallVector<int64_t> staticOffsets;

  dispatchIndexOpFoldResults(offsets, dynamicOffsets, staticOffsets);

  auto staticOffsetsAttr = builder.getDenseI64ArrayAttr(staticOffsets);

  build(builder, state, data, memDesc, dynamicOffsets, staticOffsetsAttr,

        /*subgroup_block_io=*/nullptr, layout);

}


LogicalResult StoreMatrixOp::verify() {


  auto dataTy = dyn_cast<VectorType>(getData().getType());

  UnitAttr subgroup_block_io = getSubgroupBlockIoAttr();

  MemDescType mdescTy = getMemDesc().getType();

  return IsValidMatrixOpParams(dataTy, mdescTy, subgroup_block_io,

                               getLayoutAttr(), [&]() { return emitError(); });

}


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

// XeGPU_TruncfOp

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


LogicalResult TruncfOp::verify() {

  auto sourceVecType = dyn_cast<VectorType>(getSource().getType());

  auto resultVecType = dyn_cast<VectorType>(getResult().getType());


  if (sourceVecType.getElementTypeBitWidth() <=

      resultVecType.getElementTypeBitWidth())

    return emitOpError("input type must be wider than result type.");


  return success();

}


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

// XeGPU_DpasMxOp

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


LogicalResult DpasMxOp::verify() {

  if (getAcc() && getAcc().getType() != getResultType())

    return emitOpError("Expecting the acc type to be the same as result.");


  return success();

}


namespace mlir {

#include <mlir/Dialect/XeGPU/IR/XeGPUAttrInterface.cpp.inc>

} // namespace mlir

#include <mlir/Dialect/XeGPU/IR/XeGPUEnums.cpp.inc>

#define GET_OP_CLASSES

#include <mlir/Dialect/XeGPU/IR/XeGPU.cpp.inc>

success
return success()

emitOpError
p<< " : "<< getMemRefType()<< ", "<< getType();}static LogicalResult verifyVectorMemoryOp(Operation *op, MemRefType memrefType, VectorType vectorType) { if(memrefType.getElementType() !=vectorType.getElementType()) return op-> emitOpError("requires memref and vector types of the same elemental type")
Given a list of lists of parsed operands, populates uniqueOperands with unique operands.

Builders.h

GPUDialect.h

IndexingUtils.h

getElementType
static Type getElementType(Type type)
Determine the element type of type.
Definition LLVMDialect.cpp:3391

ValueRange
b ValueRange
Definition LinalgTransformOps.cpp:2125

ArrayAttr
ArrayAttr()

getValueType
static Type getValueType(Attribute attr)
Definition SPIRVOps.cpp:773

StaticValueUtils.h

getShape
static ArrayRef< int64_t > getShape(Type type)
Returns the shape of the given type.
Definition Traits.cpp:117

TypeUtilities.h

ViewLikeInterface.h

getShapeOf
static SmallVector< int64_t > getShapeOf(Type type)
Definition XeGPUOps.cpp:52

IsValidMatrixOpParams
LogicalResult IsValidMatrixOpParams(VectorType dataTy, MemDescType mdescTy, UnitAttr subgroup_block_io, DistributeLayoutAttr layout, function_ref< InFlightDiagnostic()> emitError)
Definition XeGPUOps.cpp:177

makeString
static std::string makeString(T array, bool breakline=false)
Definition XeGPUOps.cpp:38

isWriteHintOrNone
static bool isWriteHintOrNone(const CachePolicyAttr &attr)
Definition XeGPUOps.cpp:69

isReadHintOrNone
static bool isReadHintOrNone(const CachePolicyAttr &attr)
Definition XeGPUOps.cpp:61

isValidGatherScatterBufferParams
static LogicalResult isValidGatherScatterBufferParams(Type offsetsTy, Type maskTy, VectorType valueTy, int64_t chunkSize, function_ref< InFlightDiagnostic()> emitError)
Definition XeGPUOps.cpp:125

printOptionalDynamicIndexList
static void printOptionalDynamicIndexList(OpAsmPrinter &printer, Operation *op, OperandRange values, DenseI64ArrayAttr integers)
Definition XeGPUOps.cpp:450

isSharedMemory
static bool isSharedMemory(const MemRefType &memrefTy)
Definition XeGPUOps.cpp:26

parseOptionalDynamicIndexList
static ParseResult parseOptionalDynamicIndexList(OpAsmParser &parser, SmallVectorImpl< OpAsmParser::UnresolvedOperand > &values, DenseI64ArrayAttr &integers, SmallVectorImpl< Type > *valueTypes=nullptr, AsmParser::Delimiter delimiter=AsmParser::Delimiter::Square)
Definition XeGPUOps.cpp:412

isValidGatherScatterParams
static LogicalResult isValidGatherScatterParams(Type maskTy, VectorType valueTy, TensorDescType tdescTy, function_ref< InFlightDiagnostic()> emitError)
Definition XeGPUOps.cpp:78

XeVMDialect.h

int64_t

llvm::ArrayRef
Definition LLVM.h:40

llvm::SmallVectorImpl
Definition LLVM.h:66

llvm::SmallVector
Definition LLVM.h:64

mlir::AsmParser::Delimiter
Delimiter
These are the supported delimiters around operand lists and region argument lists,...
Definition OpImplementation.h:814

mlir::AsmParser::Delimiter::Square
@ Square
Square brackets surrounding zero or more operands.
Definition OpImplementation.h:820

mlir::AsmParser::getBuilder
virtual Builder & getBuilder() const =0
Return a builder which provides useful access to MLIRContext, global objects like types and attribute...

mlir::AsmParser::parseCommaSeparatedList
virtual ParseResult parseCommaSeparatedList(Delimiter delimiter, function_ref< ParseResult()> parseElementFn, StringRef contextMessage=StringRef())=0
Parse a list of comma-separated items with an optional delimiter.

mlir::AsmParser::emitError
virtual InFlightDiagnostic emitError(SMLoc loc, const Twine &message={})=0
Emit a diagnostic at the specified location and return failure.

mlir::AsmParser::parseRSquare
virtual ParseResult parseRSquare()=0
Parse a ] token.

mlir::AsmParser::parseInteger
ParseResult parseInteger(IntT &result)
Parse an integer value from the stream.
Definition OpImplementation.h:754

mlir::AsmParser::parseColonType
virtual ParseResult parseColonType(Type &result)=0
Parse a colon followed by a type.

mlir::AsmParser::getNameLoc
virtual SMLoc getNameLoc() const =0
Return the location of the original name token.

mlir::AsmParser::parseOptionalLSquare
virtual ParseResult parseOptionalLSquare()=0
Parse a [ token if present.

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

mlir::Builder::getDenseI64ArrayAttr
DenseI64ArrayAttr getDenseI64ArrayAttr(ArrayRef< int64_t > values)
Definition Builders.cpp:171

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

mlir::Builder::getIndexType
IndexType getIndexType()
Definition Builders.cpp:55

mlir::InFlightDiagnostic
This class represents a diagnostic that is inflight and set to be reported.
Definition Diagnostics.h:327

mlir::OpAsmParser
The OpAsmParser has methods for interacting with the asm parser: parsing things from it,...
Definition OpImplementation.h:1516

mlir::OpAsmParser::parseOptionalOperand
virtual OptionalParseResult parseOptionalOperand(UnresolvedOperand &result, bool allowResultNumber=true)=0
Parse a single operand if present.

mlir::OpAsmPrinter
This is a pure-virtual base class that exposes the asmprinter hooks necessary to implement a custom p...
Definition OpImplementation.h:455

mlir::OpBuilder
This class helps build Operations.
Definition Builders.h:209

mlir::OperandRange
This class implements the operand iterators for the Operation class.
Definition ValueRange.h:43

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

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

mlir::Type::isInteger
bool isInteger() const
Return true if this is an integer type (with the specified width).
Definition Types.cpp:58

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:105

mlir::Value::getLoc
Location getLoc() const
Return the location of this value.
Definition Value.cpp:24

Utils.h

XeGPU.h

mlir::memref::getMixedSizes
SmallVector< OpFoldResult > getMixedSizes(OpBuilder &builder, Location loc, Value value)
Return the dimensions of the given memref value.
Definition MemRefOps.cpp:79

mlir::shape
Definition ShapeMappingAnalysis.h:20

mlir::xegpu
Definition XeGPU.h:25

mlir
Include the generated interface declarations.
Definition AliasAnalysis.h:19

mlir::emitWarning
InFlightDiagnostic emitWarning(Location loc)
Utility method to emit a warning message using this location.
Definition Diagnostics.cpp:338

mlir::getAsIndexOpFoldResult
OpFoldResult getAsIndexOpFoldResult(MLIRContext *ctx, int64_t val)
Convert int64_t to integer attributes of index type and return them as OpFoldResult.
Definition StaticValueUtils.cpp:120

mlir::DenseI64ArrayAttr
detail::DenseArrayAttrImpl< int64_t > DenseI64ArrayAttr
Definition BuiltinAttributes.h:757

mlir::getType
Type getType(OpFoldResult ofr)
Returns the int type of the integer in ofr.
Definition Utils.cpp:305

mlir::applyPermutation
SmallVector< T > applyPermutation(ArrayRef< T > input, ArrayRef< int64_t > permutation)
Definition IndexingUtils.h:201

mlir::emitError
InFlightDiagnostic emitError(Location loc)
Utility method to emit an error message using this location.
Definition Diagnostics.cpp:332

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:497

mlir::dispatchIndexOpFoldResults
void dispatchIndexOpFoldResults(ArrayRef< OpFoldResult > ofrs, SmallVectorImpl< Value > &dynamicVec, SmallVectorImpl< int64_t > &staticVec)
Helper function to dispatch multiple OpFoldResults according to the behavior of dispatchIndexOpFoldRe...
Definition StaticValueUtils.cpp:86

mlir::getValueOrCreateConstantIndexOp
Value getValueOrCreateConstantIndexOp(OpBuilder &b, Location loc, OpFoldResult ofr)
Converts an OpFoldResult to a Value.
Definition Utils.cpp:112

mlir::function_ref
llvm::function_ref< Fn > function_ref
Definition LLVM.h:144

mlir::printDynamicIndexList
void printDynamicIndexList(OpAsmPrinter &printer, Operation *op, OperandRange values, ArrayRef< int64_t > integers, ArrayRef< bool > scalableFlags, TypeRange valueTypes=TypeRange(), AsmParser::Delimiter delimiter=AsmParser::Delimiter::Square)
Printer hooks for custom directive in assemblyFormat.
Definition ViewLikeInterface.cpp:195

mlir::OpAsmParser::UnresolvedOperand
This is the representation of an operand reference.
Definition OpImplementation.h:1567

mlir::OperationState
This represents an operation in an abstracted form, suitable for use with the builder APIs.
Definition OperationSupport.h:941