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/Utils/StaticValueUtils.h"

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

 #include "mlir/IR/Builders.h"

 #include "mlir/IR/TypeUtilities.h"


 #include "llvm/Support/Debug.h"


 #define DEBUG_TYPE "xegpu"


 namespace mlir {

 namespace xegpu {


 static void transpose(llvm::ArrayRef<int64_t> trans,

                       SmallVector<int64_t> &shape) {

   SmallVector<int64_t> old = shape;

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

     shape[i] = old[trans[i]];

 }


 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 int64_t getRankOf(Value val) {

   auto type = val.getType();

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

     return ty.getRank();

   return 0;

 }


 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, UnitAttr transposeAttr,

                            function_ref<InFlightDiagnostic()> emitError) {


   if (!tdescTy.isScattered())

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


   if (!valueTy)

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


   auto maskShape = getShapeOf(maskTy);

   auto valueShape = getShapeOf(valueTy);

   auto tdescShape = getShapeOf(tdescTy);

   auto chunkSize = tdescTy.getChunkSize();


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

     return emitError()

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


   if (tdescShape[0] != maskShape[0])

     return emitError()

            << "dim-0 of the Mask and TensorDesc should be the same.";


   // 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";

     if (transposeAttr)

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

     return success();

   }


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

     if (!transposeAttr)

       return emitError() << "rank-2 tensor has to be transposed.";

     transpose({1, 0}, tdescShape);

   }


   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();

 }


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

 // XeGPU_CreateNdDescOp

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

 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 */,

         staticOffsets /* const offsets */, {} /* empty const shape*/,

         {} /* empty const strides*/);

 }


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

                            Type tdesc, TypedValue<MemRefType> source,

                            llvm::ArrayRef<OpFoldResult> offsets,

                            llvm::ArrayRef<OpFoldResult> shape,

                            llvm::ArrayRef<OpFoldResult> strides) {

   assert(shape.size() && offsets.size() && strides.size() &&

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


   llvm::SmallVector<int64_t> staticOffsets;

   llvm::SmallVector<int64_t> staticShape;

   llvm::SmallVector<int64_t> staticStrides;

   llvm::SmallVector<Value> dynamicOffsets;

   llvm::SmallVector<Value> dynamicShape;

   llvm::SmallVector<Value> dynamicStrides;


   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);


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

         dynamicStrides, staticOffsetsAttr, staticShapeAttr, staticStridesAttr);

 }


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

                            Type tdesc, TypedValue<IntegerType> source,

                            llvm::ArrayRef<OpFoldResult> offsets,

                            llvm::ArrayRef<OpFoldResult> shape,

                            llvm::ArrayRef<OpFoldResult> strides) {

   assert(shape.size() && offsets.size() && strides.size() &&

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


   llvm::SmallVector<int64_t> staticOffsets;

   llvm::SmallVector<int64_t> staticShape;

   llvm::SmallVector<int64_t> staticStrides;

   llvm::SmallVector<Value> dynamicOffsets;

   llvm::SmallVector<Value> dynamicShape;

   llvm::SmallVector<Value> dynamicStrides;


   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);


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

         dynamicStrides, staticOffsetsAttr, staticShapeAttr, staticStridesAttr);

 }


 LogicalResult CreateNdDescOp::verify() {

   auto rank = (int64_t)getMixedOffsets().size();

   bool invalidRank = false;

   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;


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

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

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

   if (memrefTy) {

     invalidRank |= (memrefTy.getRank() != rank);

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

   }


   // mismatches among shape, strides, and offsets are

   // already handeled by OffsetSizeAndStrideOpInterface.

   // So they are not check here.

   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

   invalidRank = (getType().getRank() > 2 || getType().getRank() > rank);


   if (invalidRank)

     return emitOpError(

         "Expecting the TensorDesc rank is up to 2 and 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();

 }


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

 // XeGPU_PrefetchNdOp

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

 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();


   return success();

 }


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

 // XeGPU_LoadNdOp

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

 LogicalResult LoadNdOp::verify() {

   auto tdescTy = getTensorDescType();

   auto valueTy = getType();


   if (tdescTy.getRank() > 2)

     return emitOpError("Expecting a 1D/2D TensorDesc.\n");


   if (tdescTy.isScattered())

     return emitOpError("Expects a non-scattered 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.

     bool valid = std::all_of(trans.begin(), trans.end(), [&](int t) {

       return t >= 0 && t < tdescTy.getRank();

     });


     if (valid)

       transpose(trans, tdescShape);

     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;

   }


   return success();

 }


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

 // XeGPU_StoreNdOp

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

 LogicalResult StoreNdOp::verify() {

   auto dstTy = getTensorDescType(); // Tile

   auto valTy = getValueType();      // Vector


   if (dstTy.getRank() > 2)

     return emitOpError("Expecting a 1D/2D TensorDesc.\n");


   if (dstTy.isScattered())

     return emitOpError("Expects a non-scattered 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;

   }


   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 = builder.create<vector::FromElementsOp>(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 (getRankOf(getSource()) > 1)

     return emitOpError(

         "Expecting the source is a 1D memref or pointer (uint64_t).");


   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.getChunkSize();

   auto elemBits = tdescTy.getElementType().getIntOrFloatBitWidth();

   auto bitsPerLane = elemBits * chunkSize;

   if (chunkSize > 1 && bitsPerLane % 32) {

     // For 8-bit and 16-bit data, the hardware only supports chunk size of 1.

     // For 32-bit data, the hardware can support larger larger chunk size. So

     // we can bitcast 8-bit/16-bit data to 32-bit data for better performance.

     // But this requires the total size is 32 bit aligned to make the

     // optimization work.

     return emitOpError(

         "access size (chunk_size * sizeof(elemTy)) should be 32-bit aligned.");

   }


   auto lscConstraints = 512 * 8; // each access is upto 512 bytes.

   if (elemBits * tdescTy.getNumElements() > lscConstraints)

     return emitOpError("total access size (simd_lanes * chunk_size * "

                        "sizeof(elemTy)) is upto 512 bytes.");


   SmallVector<int64_t> shape({(int64_t)getNumOffsets()});

   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.isScattered())

     return emitOpError("Expects a 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();


   return success();

 }


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

 // XeGPU_LoadGatherOp

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

 LogicalResult LoadGatherOp::verify() {

   auto tdescTy = getTensorDescType();

   auto maskTy = getMaskType();

   auto valueTy = getValueType();


   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();


   return isValidGatherScatterParams(maskTy, valueTy, tdescTy,

                                     getTransposeAttr(),

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

 }


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

 // XeGPU_StoreScatterOp

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

 LogicalResult StoreScatterOp::verify() {

   auto tdescTy = getTensorDescType();

   auto maskTy = getMaskType();

   auto valueTy = getValueType();


   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();


   return isValidGatherScatterParams(maskTy, valueTy, tdescTy,

                                     getTransposeAttr(),

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

 }


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

 // 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 = builder.create<vector::FromElementsOp>(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);

 }


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

 // 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 srcMap = getSrcMapAttr();

   auto resMap = getResMapAttr();

   if (!srcMap)

     return emitOpError("expected srcMap.");

   if (!resMap)

     return emitOpError("expected resMap.");


   if (srcMap == resMap)

     return emitOpError("expected different srcMap and resMap.");


   // both srcMap and resMap should be WgLayout or SgLayout at the same time.

   if ((!srcMap.isWgLayout() || !resMap.isWgLayout()) &&

       (!srcMap.isSgLayout() || !resMap.isSgLayout()))

     return emitOpError(

         "expected srcMap and resMap be WgLayout or SgLayout at the same time.");


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

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

     return emitOpError("invalid srcMap, data cannot be evenly distributed.");


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

     return emitOpError("invalid resMap, data cannot be evenly distributed.");


   return mlir::success();

 }


 } // namespace xegpu

 } // namespace mlir


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

 #define GET_OP_CLASSES

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

Builders.h

Utils.h

kind
union mlir::linalg::@1192::ArityGroupAndKind::Kind kind

getElementType
static Type getElementType(Type type, ArrayRef< int32_t > indices, function_ref< InFlightDiagnostic(StringRef)> emitErrorFn)
Walks the given type hierarchy with the given indices, potentially down to component granularity,...
Definition: SPIRVOps.cpp:188

StaticValueUtils.h

TypeUtilities.h

XeGPU.h

llvm::ArrayRef< int64_t >

llvm::SmallVector
Definition: LLVM.h:72

llvm::function_ref
Definition: LLVM.h:90

mlir::InFlightDiagnostic
This class represents a diagnostic that is inflight and set to be reported.
Definition: Diagnostics.h:314

mlir::OpBuilder
This class helps build Operations.
Definition: Builders.h:205

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

mlir::ValueRange
This class provides an abstraction over the different types of ranges over Values.
Definition: ValueRange.h:387

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:26

mlir::xegpu::makeString
static std::string makeString(T array, bool breakline=false)
Definition: XeGPUOps.cpp:30

mlir::xegpu::isValidGatherScatterParams
static LogicalResult isValidGatherScatterParams(Type maskTy, VectorType valueTy, TensorDescType tdescTy, UnitAttr transposeAttr, function_ref< InFlightDiagnostic()> emitError)
Definition: XeGPUOps.cpp:77

mlir::xegpu::getRankOf
static int64_t getRankOf(Value val)
Definition: XeGPUOps.cpp:53

mlir::xegpu::isWriteHintOrNone
static bool isWriteHintOrNone(const CachePolicyAttr &attr)
Definition: XeGPUOps.cpp:68

mlir::xegpu::isReadHintOrNone
static bool isReadHintOrNone(const CachePolicyAttr &attr)
Definition: XeGPUOps.cpp:60

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

mlir::xegpu::getShapeOf
static SmallVector< int64_t > getShapeOf(Type type)
Definition: XeGPUOps.cpp:44

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

mlir::emitWarning
InFlightDiagnostic emitWarning(Location loc)
Utility method to emit a warning message using this location.
Definition: Diagnostics.cpp:334

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:109

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

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:474

mlir::emitError
InFlightDiagnostic emitError(Location loc)
Utility method to emit an error message using this location.
Definition: Diagnostics.cpp:328

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:75

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

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::verify
LogicalResult verify(Operation *op, bool verifyRecursively=true)
Perform (potentially expensive) checks of invariants, used to detect compiler bugs,...
Definition: Verifier.cpp:424

mlir::OperationState
This represents an operation in an abstracted form, suitable for use with the builder APIs.
Definition: OperationSupport.h:947