doxygen/VectorUnroll_8cpp_source.html

//===- VectorUnrollDistribute.cpp - patterns to do vector unrolling -------===//

//

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

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

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

//

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

//

// This file implements patterns to do vector unrolling and vector distribution.

//

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


#include "mlir/Dialect/Affine/IR/AffineOps.h"

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

#include "mlir/Dialect/Vector/Transforms/LoweringPatterns.h"

#include "mlir/Dialect/Vector/Transforms/VectorTransforms.h"

#include "mlir/Interfaces/VectorInterfaces.h"

#include "llvm/ADT/MapVector.h"

#include "llvm/ADT/STLExtras.h"

#include "llvm/Support/DebugLog.h"

#include "llvm/Support/InterleavedRange.h"

#include <optional>


#define DEBUG_TYPE "vector-unroll"


using namespace mlir;

using namespace mlir::vector;


SmallVector<Value> mlir::vector::sliceTransferIndices(

    ArrayRef<int64_t> elementOffsets, ArrayRef<Value> indices,

    AffineMap permutationMap, Location loc, OpBuilder &builder) {

  MLIRContext *ctx = builder.getContext();

  auto isBroadcast = [](AffineExpr expr) {

    if (auto constExpr = dyn_cast<AffineConstantExpr>(expr))

      return constExpr.getValue() == 0;

    return false;

  };

  // Compute 'sliceIndices' by adding 'sliceOffsets[i]' to 'indices[i]'.

  SmallVector<Value> slicedIndices(indices);

  for (const auto &dim : llvm::enumerate(permutationMap.getResults())) {

    int64_t elementOffset = elementOffsets[dim.index()];

    if (isBroadcast(dim.value()) || elementOffset == 0)

      continue;

    unsigned pos = cast<AffineDimExpr>(dim.value()).getPosition();

    auto expr = getAffineDimExpr(0, builder.getContext()) +

                getAffineConstantExpr(elementOffset, ctx);

    auto map = AffineMap::get(/*dimCount=*/1, /*symbolCount=*/0, expr);

    slicedIndices[pos] =

        affine::AffineApplyOp::create(builder, loc, map, indices[pos]);

  }

  return slicedIndices;

}


// Compute the new indices by adding `offsets` to `originalIndices`.

// If m < n (m = offsets.size(), n = originalIndices.size()),

// then only the trailing m values in `originalIndices` are updated.


static SmallVector<Value> sliceLoadStoreIndices(PatternRewriter &rewriter,

                                                Location loc,

                                                OperandRange originalIndices,

                                                ArrayRef<int64_t> offsets) {

  assert(offsets.size() <= originalIndices.size() &&

         "Offsets should not exceed the number of original indices");

  SmallVector<Value> indices(originalIndices);


  auto start = indices.size() - offsets.size();

  for (auto [i, offset] : llvm::enumerate(offsets)) {

    if (offset != 0) {

      indices[start + i] = arith::AddIOp::create(

          rewriter, loc, originalIndices[start + i],

          arith::ConstantIndexOp::create(rewriter, loc, offset));

    }

  }

  return indices;

}


// Clones `op` into a new operations that takes `operands` and returns

// `resultTypes`.


static Operation *cloneOpWithOperandsAndTypes(OpBuilder &builder, Location loc,

                                              Operation *op,

                                              ArrayRef<Value> operands,

                                              ArrayRef<Type> resultTypes) {

  return builder.create(loc, op->getName().getIdentifier(), operands,

                        resultTypes, op->getAttrs());

}


/// Return the target shape for unrolling for the given `op`. Return

/// std::nullopt if the op shouldn't be or cannot be unrolled.

static std::optional<SmallVector<int64_t>>


getTargetShape(const vector::UnrollVectorOptions &options, Operation *op) {

  LDBG() << "Get unroll shape for op " << op->getName().getStringRef();

  if (options.filterConstraint && failed(options.filterConstraint(op))) {

    LDBG() << "--no filter constraint -> BAIL";

    return std::nullopt;

  }

  assert(options.nativeShape &&

         "vector unrolling expects the native shape or native"

         "shape call back function to be set");

  auto unrollableVectorOp = dyn_cast<VectorUnrollOpInterface>(op);

  if (!unrollableVectorOp) {

    LDBG() << "--not an unrollable op -> BAIL";

    return std::nullopt;

  }

  auto maybeUnrollShape = unrollableVectorOp.getShapeForUnroll();

  if (!maybeUnrollShape) {

    LDBG() << "--could not get shape of op " << *op << " -> BAIL";

    return std::nullopt;

  }

  LDBG() << "--vector op shape: " << llvm::interleaved(*maybeUnrollShape);


  std::optional<SmallVector<int64_t>> targetShape = options.nativeShape(op);

  if (!targetShape) {

    LDBG() << "--no unrolling target shape defined " << *op << "-> SKIP";

    return std::nullopt;

  }

  LDBG() << "--target shape: " << llvm::interleaved(*targetShape);


  auto maybeShapeRatio = computeShapeRatio(*maybeUnrollShape, *targetShape);

  if (!maybeShapeRatio) {

    LDBG() << "--could not compute integral shape ratio -> BAIL";

    return std::nullopt;

  }

  if (llvm::all_of(*maybeShapeRatio, [](int64_t v) { return v == 1; })) {

    LDBG() << "--no unrolling needed -> SKIP";

    return std::nullopt;

  }

  LDBG() << "--found an integral shape ratio to unroll to -> SUCCESS";

  return targetShape;

}


static SmallVector<int64_t>


getUnrollOrder(unsigned numLoops, Operation *op,

               const vector::UnrollVectorOptions &options) {

  SmallVector<int64_t> loopOrder =

      llvm::to_vector(llvm::seq<int64_t>(0, static_cast<int64_t>(numLoops)));

  if (options.traversalOrderCallback != nullptr) {

    std::optional<SmallVector<int64_t>> order =

        options.traversalOrderCallback(op);

    if (order) {

      loopOrder = std::move(*order);

    }

  }

  return loopOrder;

}


namespace {


struct UnrollTransferReadPattern

    : public OpRewritePattern<vector::TransferReadOp> {

  UnrollTransferReadPattern(MLIRContext *context,

                            const vector::UnrollVectorOptions &options,

                            PatternBenefit benefit = 1)

      : OpRewritePattern<vector::TransferReadOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::TransferReadOp readOp,

                                PatternRewriter &rewriter) const override {

    // TODO: support 0-d corner case.

    if (readOp.getTransferRank() == 0)

      return failure();

    if (readOp.getMask())

      return failure();

    auto targetShape = getTargetShape(options, readOp);

    if (!targetShape)

      return failure();

    auto sourceVectorType = readOp.getVectorType();

    SmallVector<int64_t> strides(targetShape->size(), 1);

    Location loc = readOp.getLoc();

    ArrayRef<int64_t> originalSize = sourceVectorType.getShape();


    // Prepare the result vector;

    Value result =

        arith::ConstantOp::create(rewriter, loc, sourceVectorType,

                                  rewriter.getZeroAttr(sourceVectorType));

    auto targetType =

        VectorType::get(*targetShape, sourceVectorType.getElementType());

    SmallVector<Value> originalIndices(readOp.getIndices().begin(),

                                       readOp.getIndices().end());

    SmallVector<int64_t> loopOrder =

        getUnrollOrder(originalSize.size(), readOp, options);

    for (SmallVector<int64_t> elementOffsets :

         StaticTileOffsetRange(originalSize, *targetShape, loopOrder)) {

      SmallVector<Value> indices =

          sliceTransferIndices(elementOffsets, originalIndices,

                               readOp.getPermutationMap(), loc, rewriter);

      auto slicedRead = vector::TransferReadOp::create(

          rewriter, loc, targetType, readOp.getBase(), indices,

          readOp.getPermutationMapAttr(), readOp.getPadding(), readOp.getMask(),

          readOp.getInBoundsAttr());


      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, slicedRead, result, elementOffsets, strides);

    }

    rewriter.replaceOp(readOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollTransferWritePattern

    : public OpRewritePattern<vector::TransferWriteOp> {

  UnrollTransferWritePattern(MLIRContext *context,

                             const vector::UnrollVectorOptions &options,

                             PatternBenefit benefit = 1)

      : OpRewritePattern<vector::TransferWriteOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::TransferWriteOp writeOp,

                                PatternRewriter &rewriter) const override {

    // TODO: support 0-d corner case.

    if (writeOp.getTransferRank() == 0)

      return failure();


    if (writeOp.getMask())

      return failure();

    auto targetShape = getTargetShape(options, writeOp);

    if (!targetShape)

      return failure();

    auto sourceVectorType = writeOp.getVectorType();

    SmallVector<int64_t> strides(targetShape->size(), 1);

    Location loc = writeOp.getLoc();

    ArrayRef<int64_t> originalSize = sourceVectorType.getShape();

    // Bail-out if rank(source) != rank(target). The main limitation here is the

    // fact that `ExtractStridedSlice` requires the rank for the input and

    // output to match. If needed, we can relax this later.

    if (originalSize.size() != targetShape->size())

      return rewriter.notifyMatchFailure(

          writeOp,

          "expected source input vector rank to match target shape rank");


    SmallVector<Value> originalIndices(writeOp.getIndices().begin(),

                                       writeOp.getIndices().end());

    SmallVector<int64_t> loopOrder =

        getUnrollOrder(originalSize.size(), writeOp, options);

    Value resultTensor;

    for (SmallVector<int64_t> elementOffsets :

         StaticTileOffsetRange(originalSize, *targetShape, loopOrder)) {

      Value slicedVector = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, writeOp.getVector(), elementOffsets, *targetShape, strides);

      SmallVector<Value> indices =

          sliceTransferIndices(elementOffsets, originalIndices,

                               writeOp.getPermutationMap(), loc, rewriter);

      Operation *slicedWrite = vector::TransferWriteOp::create(

          rewriter, loc, slicedVector,

          resultTensor ? resultTensor : writeOp.getBase(), indices,

          writeOp.getPermutationMapAttr(), writeOp.getInBoundsAttr());

      // For the tensor case update the destination for the next transfer write.

      if (!slicedWrite->getResults().empty())

        resultTensor = slicedWrite->getResult(0);

    }

    if (resultTensor)

      rewriter.replaceOp(writeOp, resultTensor);

    else

      rewriter.eraseOp(writeOp);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct OffsetMapInfo {

  static SmallVector<int64_t> getEmptyKey() { return {int64_t(-1)}; }


  static SmallVector<int64_t> getTombstoneKey() { return {int64_t(-2)}; }


  static unsigned getHashValue(const SmallVector<int64_t> &v) {

    return static_cast<unsigned>(llvm::hash_combine_range(v));

  }


  static bool isEqual(const SmallVector<int64_t> &lhs,

                      const SmallVector<int64_t> &rhs) {

    return lhs == rhs;

  }

};


struct UnrollContractionPattern

    : public OpRewritePattern<vector::ContractionOp> {

  UnrollContractionPattern(MLIRContext *context,

                           const vector::UnrollVectorOptions &options,

                           PatternBenefit benefit = 1)

      : OpRewritePattern<vector::ContractionOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::ContractionOp contractOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, contractOp);

    if (!targetShape)

      return failure();

    auto dstVecType = cast<VectorType>(contractOp.getResultType());

    SmallVector<int64_t> originalSize = *contractOp.getShapeForUnroll();


    Location loc = contractOp.getLoc();

    unsigned accIndex = vector::ContractionOp::getAccOperandIndex();

    AffineMap dstAffineMap = contractOp.getIndexingMapsArray()[accIndex];

    llvm::MapVector<

        SmallVector<int64_t>, Value,

        llvm::DenseMap<SmallVector<int64_t>, unsigned, OffsetMapInfo>>

        accCache;


    SmallVector<int64_t> loopOrder = getUnrollOrder(

        contractOp.getIteratorTypes().size(), contractOp, options);


    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalSize, *targetShape, loopOrder)) {

      SmallVector<Value> slicesOperands(contractOp.getNumOperands());


      // Helper to compute the new shape of each operand and extract the slice.

      auto extractOperand = [&](unsigned index, Value operand,

                                AffineMap permutationMap,

                                ArrayRef<int64_t> operandOffets) {

        SmallVector<int64_t> operandShape = applyPermutationMap(

            permutationMap, ArrayRef<int64_t>(*targetShape));

        SmallVector<int64_t> operandStrides(operandOffets.size(), 1);

        slicesOperands[index] =

            rewriter.createOrFold<vector::ExtractStridedSliceOp>(

                loc, operand, operandOffets, operandShape, operandStrides);

      };


      // Extract the new lhs operand.

      AffineMap lhsPermutationMap = contractOp.getIndexingMapsArray()[0];

      SmallVector<int64_t> lhsOffets =

          applyPermutationMap(lhsPermutationMap, ArrayRef<int64_t>(offsets));

      extractOperand(0, contractOp.getLhs(), lhsPermutationMap, lhsOffets);


      // Extract the new rhs operand.

      AffineMap rhsPermutationMap = contractOp.getIndexingMapsArray()[1];

      SmallVector<int64_t> rhsOffets =

          applyPermutationMap(rhsPermutationMap, ArrayRef<int64_t>(offsets));

      extractOperand(1, contractOp.getRhs(), rhsPermutationMap, rhsOffets);


      AffineMap accPermutationMap = contractOp.getIndexingMapsArray()[2];

      SmallVector<int64_t> accOffets =

          applyPermutationMap(accPermutationMap, ArrayRef<int64_t>(offsets));

      // If a version of the accumulator has already been computed, use it

      // otherwise extract the first version from the original operand.

      auto *accIt = accCache.find(accOffets);

      if (accIt != accCache.end())

        slicesOperands[2] = accIt->second;

      else

        extractOperand(2, contractOp.getAcc(), accPermutationMap, accOffets);


      SmallVector<int64_t> dstShape =

          applyPermutationMap(dstAffineMap, ArrayRef<int64_t>(*targetShape));

      auto targetType = VectorType::get(dstShape, dstVecType.getElementType());

      Operation *newOp = cloneOpWithOperandsAndTypes(

          rewriter, loc, contractOp, slicesOperands, targetType);


      SmallVector<int64_t> dstOffets =

          applyPermutationMap(dstAffineMap, ArrayRef<int64_t>(offsets));

      // Save the accumulated value untill all the loops are unrolled since

      // reduction loop keep updating the accumulator.

      accCache[dstOffets] = newOp->getResult(0);

    }

    // Assemble back the accumulator into a single vector.

    Value result = arith::ConstantOp::create(rewriter, loc, dstVecType,

                                             rewriter.getZeroAttr(dstVecType));

    for (const auto &it : accCache) {

      SmallVector<int64_t> dstStrides(it.first.size(), 1);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, it.second, result, it.first, dstStrides);

    }

    rewriter.replaceOp(contractOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollMultiReductionPattern

    : public OpRewritePattern<vector::MultiDimReductionOp> {

  UnrollMultiReductionPattern(MLIRContext *context,

                              const vector::UnrollVectorOptions &options,

                              PatternBenefit benefit = 1)

      : OpRewritePattern<vector::MultiDimReductionOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::MultiDimReductionOp reductionOp,

                                PatternRewriter &rewriter) const override {

    std::optional<SmallVector<int64_t>> targetShape =

        getTargetShape(options, reductionOp);

    if (!targetShape)

      return failure();

    SmallVector<int64_t> originalSize = *reductionOp.getShapeForUnroll();

    Location loc = reductionOp.getLoc();

    auto resultType = reductionOp->getResult(0).getType();


    // Handle scalar result case: all dimensions are reduced.

    // Each source tile is reduced to a scalar, and partial results are

    // chained through the accumulator operand.

    if (resultType.isIntOrFloat()) {

      Value accumulator = reductionOp.getAcc();

      for (SmallVector<int64_t> offsets :

           StaticTileOffsetRange(originalSize, *targetShape)) {

        SmallVector<int64_t> operandStrides(offsets.size(), 1);

        Value slicedOperand =

            rewriter.createOrFold<vector::ExtractStridedSliceOp>(

                loc, reductionOp.getSource(), offsets, *targetShape,

                operandStrides);

        Operation *newOp = cloneOpWithOperandsAndTypes(

            rewriter, loc, reductionOp, {slicedOperand, accumulator},

            resultType);

        accumulator = newOp->getResult(0);

      }

      rewriter.replaceOp(reductionOp, accumulator);

      return success();

    }


    // Vector result case.

    llvm::MapVector<

        SmallVector<int64_t>, Value,

        llvm::DenseMap<SmallVector<int64_t>, unsigned, OffsetMapInfo>>

        accCache;


    // Stride of the ratios, this gives us the offsets of sliceCount in a basis

    // of multiples of the targetShape.

    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalSize, *targetShape)) {

      SmallVector<Value> operands;

      SmallVector<int64_t> operandStrides(offsets.size(), 1);

      Value slicedOperand =

          rewriter.createOrFold<vector::ExtractStridedSliceOp>(

              loc, reductionOp.getSource(), offsets, *targetShape,

              operandStrides);

      operands.push_back(slicedOperand);

      SmallVector<int64_t> dstShape;

      SmallVector<int64_t> destOffset;

      for (size_t i : llvm::seq(size_t(0), targetShape->size())) {

        if (!reductionOp.isReducedDim(i)) {

          destOffset.push_back(offsets[i]);

          dstShape.push_back((*targetShape)[i]);

        }

      }

      Value acc;

      SmallVector<int64_t> accStrides(destOffset.size(), 1);

      // If a version of the accumulator has already been computed, use it

      // otherwise extract the first version from the original operand.

      auto *accIt = accCache.find(destOffset);

      if (accIt != accCache.end())

        acc = accIt->second;

      else

        acc = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

            loc, reductionOp.getAcc(), destOffset, dstShape, accStrides);

      operands.push_back(acc);

      auto targetType = VectorType::get(

          dstShape, reductionOp.getSourceVectorType().getElementType());

      Operation *newOp = cloneOpWithOperandsAndTypes(rewriter, loc, reductionOp,

                                                     operands, targetType);

      Value result = newOp->getResult(0);

      accCache[destOffset] = result;

    }

    // Assemble back the accumulator into a single vector.

    Value result = arith::ConstantOp::create(

        rewriter, loc, reductionOp.getDestType(),

        rewriter.getZeroAttr(reductionOp.getDestType()));

    for (const auto &it : accCache) {

      SmallVector<int64_t> dstStrides(it.first.size(), 1);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, it.second, result, it.first, dstStrides);

    }

    rewriter.replaceOp(reductionOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollElementwisePattern : public RewritePattern {

  UnrollElementwisePattern(MLIRContext *context,

                           const vector::UnrollVectorOptions &options,

                           PatternBenefit benefit = 1)

      : RewritePattern(MatchAnyOpTypeTag(), benefit, context),

        options(options) {}


  LogicalResult matchAndRewrite(Operation *op,

                                PatternRewriter &rewriter) const override {

    if (!OpTrait::hasElementwiseMappableTraits(op) || op->getNumResults() != 1)

      return failure();

    auto targetShape = getTargetShape(options, op);

    if (!targetShape)

      return failure();

    int64_t targetShapeRank = targetShape->size();

    auto dstVecType = cast<VectorType>(op->getResult(0).getType());

    SmallVector<int64_t> originalSize =

        *cast<VectorUnrollOpInterface>(op).getShapeForUnroll();

    int64_t originalShapeRank = originalSize.size();


    Location loc = op->getLoc();


    // Handle rank mismatch by adding leading unit dimensions to targetShape

    SmallVector<int64_t> adjustedTargetShape(originalShapeRank);

    int64_t rankDiff = originalShapeRank - targetShapeRank;

    std::fill(adjustedTargetShape.begin(),

              adjustedTargetShape.begin() + rankDiff, 1);

    std::copy(targetShape->begin(), targetShape->end(),

              adjustedTargetShape.begin() + rankDiff);


    int64_t adjustedTargetShapeRank = adjustedTargetShape.size();

    // Prepare the result vector.

    Value result = arith::ConstantOp::create(rewriter, loc, dstVecType,

                                             rewriter.getZeroAttr(dstVecType));

    SmallVector<int64_t> strides(adjustedTargetShapeRank, 1);

    VectorType unrolledVecType =

        VectorType::get(*targetShape, dstVecType.getElementType());


    // Create the unrolled computation.

    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalSize, adjustedTargetShape)) {

      SmallVector<Value> extractOperands;

      for (OpOperand &operand : op->getOpOperands()) {

        auto vecType = dyn_cast<VectorType>(operand.get().getType());

        if (!vecType) {

          extractOperands.push_back(operand.get());

          continue;

        }

        Value extracted = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

            loc, operand.get(), offsets, adjustedTargetShape, strides);


        // Reshape to remove leading unit dims if needed

        if (adjustedTargetShapeRank > targetShapeRank) {

          extracted = rewriter.createOrFold<vector::ShapeCastOp>(

              loc, VectorType::get(*targetShape, vecType.getElementType()),

              extracted);

        }

        extractOperands.push_back(extracted);

      }


      Operation *newOp = cloneOpWithOperandsAndTypes(

          rewriter, loc, op, extractOperands, unrolledVecType);


      Value computeResult = newOp->getResult(0);


      // Use strides sized to targetShape for proper insertion

      SmallVector<int64_t> insertStrides =

          (adjustedTargetShapeRank > targetShapeRank)

              ? SmallVector<int64_t>(targetShapeRank, 1)

              : strides;


      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, computeResult, result, offsets, insertStrides);

    }

    rewriter.replaceOp(op, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollReductionPattern : public OpRewritePattern<vector::ReductionOp> {

  UnrollReductionPattern(MLIRContext *context,

                         const vector::UnrollVectorOptions &options,

                         PatternBenefit benefit = 1)

      : OpRewritePattern<vector::ReductionOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::ReductionOp reductionOp,

                                PatternRewriter &rewriter) const override {

    std::optional<SmallVector<int64_t>> targetShape =

        getTargetShape(options, reductionOp);

    if (!targetShape)

      return failure();

    SmallVector<int64_t> originalSize = *reductionOp.getShapeForUnroll();


    // Create unrolled vector reduction.

    Location loc = reductionOp.getLoc();

    Value accumulator = nullptr;

    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalSize, *targetShape)) {

      SmallVector<int64_t> strides(offsets.size(), 1);

      Value slicedOperand =

          rewriter.createOrFold<vector::ExtractStridedSliceOp>(

              loc, reductionOp.getVector(), offsets, *targetShape, strides);

      Operation *newOp = cloneOpWithOperandsAndTypes(

          rewriter, loc, reductionOp, slicedOperand, reductionOp.getType());

      Value result = newOp->getResult(0);


      if (!accumulator) {

        // This is the first reduction.

        accumulator = result;

      } else {

        // On subsequent reduction, combine with the accumulator.

        accumulator = makeArithReduction(rewriter, loc, reductionOp.getKind(),

                                         accumulator, result);

      }

    }


    rewriter.replaceOp(reductionOp, accumulator);

    return success();

  }


private:

  const vector::UnrollVectorOptions options;

};


struct UnrollTransposePattern : public OpRewritePattern<vector::TransposeOp> {

  UnrollTransposePattern(MLIRContext *context,

                         const vector::UnrollVectorOptions &options,

                         PatternBenefit benefit = 1)

      : OpRewritePattern<vector::TransposeOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::TransposeOp transposeOp,

                                PatternRewriter &rewriter) const override {

    if (transposeOp.getResultVectorType().getRank() == 0)

      return failure();

    auto targetShape = getTargetShape(options, transposeOp);

    if (!targetShape)

      return failure();

    auto originalVectorType = transposeOp.getResultVectorType();

    SmallVector<int64_t> strides(targetShape->size(), 1);

    Location loc = transposeOp.getLoc();

    ArrayRef<int64_t> originalSize = originalVectorType.getShape();


    // Prepare the result vector;

    Value result =

        arith::ConstantOp::create(rewriter, loc, originalVectorType,

                                  rewriter.getZeroAttr(originalVectorType));

    ArrayRef<int64_t> permutation = transposeOp.getPermutation();


    // Unroll the computation.

    for (SmallVector<int64_t> elementOffsets :

         StaticTileOffsetRange(originalSize, *targetShape)) {

      SmallVector<int64_t> permutedOffsets(elementOffsets.size());

      SmallVector<int64_t> permutedShape(elementOffsets.size());

      // Compute the source offsets and shape.

      for (auto indices : llvm::enumerate(permutation)) {

        permutedOffsets[indices.value()] = elementOffsets[indices.index()];

        permutedShape[indices.value()] = (*targetShape)[indices.index()];

      }

      Value slicedOperand =

          rewriter.createOrFold<vector::ExtractStridedSliceOp>(

              loc, transposeOp.getVector(), permutedOffsets, permutedShape,

              strides);

      Value transposedSlice = rewriter.createOrFold<vector::TransposeOp>(

          loc, slicedOperand, permutation);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, transposedSlice, result, elementOffsets, strides);

    }

    rewriter.replaceOp(transposeOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollGatherPattern : public OpRewritePattern<vector::GatherOp> {

  UnrollGatherPattern(MLIRContext *context,

                      const vector::UnrollVectorOptions &options,

                      PatternBenefit benefit = 1)

      : OpRewritePattern<vector::GatherOp>(context, benefit), options(options) {

  }


  LogicalResult matchAndRewrite(vector::GatherOp gatherOp,

                                PatternRewriter &rewriter) const override {

    VectorType sourceVectorType = gatherOp.getVectorType();

    if (sourceVectorType.getRank() == 0)

      return failure();

    auto targetShape = getTargetShape(options, gatherOp);

    if (!targetShape)

      return failure();

    SmallVector<int64_t> strides(targetShape->size(), 1);

    Location loc = gatherOp.getLoc();

    ArrayRef<int64_t> originalSize = gatherOp.getVectorType().getShape();


    // Prepare the result vector;

    Value result =

        arith::ConstantOp::create(rewriter, loc, sourceVectorType,

                                  rewriter.getZeroAttr(sourceVectorType));

    auto targetType =

        VectorType::get(*targetShape, sourceVectorType.getElementType());


    SmallVector<int64_t> loopOrder =

        getUnrollOrder(originalSize.size(), gatherOp, options);

    for (SmallVector<int64_t> elementOffsets :

         StaticTileOffsetRange(originalSize, *targetShape, loopOrder)) {

      // To get the unrolled gather, extract the same slice based on the

      // decomposed shape from each of the index, mask, and pass-through

      // vectors.

      Value indexSubVec = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, gatherOp.getIndices(), elementOffsets, *targetShape, strides);

      Value maskSubVec = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, gatherOp.getMask(), elementOffsets, *targetShape, strides);

      Value passThruSubVec =

          rewriter.createOrFold<vector::ExtractStridedSliceOp>(

              loc, gatherOp.getPassThru(), elementOffsets, *targetShape,

              strides);

      auto slicedGather = vector::GatherOp::create(

          rewriter, loc, targetType, gatherOp.getBase(), gatherOp.getOffsets(),

          indexSubVec, maskSubVec, passThruSubVec);


      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, slicedGather, result, elementOffsets, strides);

    }

    rewriter.replaceOp(gatherOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollLoadPattern : public OpRewritePattern<vector::LoadOp> {

  UnrollLoadPattern(MLIRContext *context,

                    const vector::UnrollVectorOptions &options,

                    PatternBenefit benefit = 1)

      : OpRewritePattern<vector::LoadOp>(context, benefit), options(options) {}


  LogicalResult matchAndRewrite(vector::LoadOp loadOp,

                                PatternRewriter &rewriter) const override {

    VectorType vecType = loadOp.getVectorType();


    auto targetShape = getTargetShape(options, loadOp);

    if (!targetShape)

      return failure();


    Location loc = loadOp.getLoc();

    ArrayRef<int64_t> originalShape = vecType.getShape();

    SmallVector<int64_t> strides(targetShape->size(), 1);


    Value result = arith::ConstantOp::create(rewriter, loc, vecType,

                                             rewriter.getZeroAttr(vecType));


    SmallVector<int64_t> loopOrder =

        getUnrollOrder(originalShape.size(), loadOp, options);


    auto targetVecType =

        VectorType::get(*targetShape, vecType.getElementType());


    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalShape, *targetShape, loopOrder)) {

      SmallVector<Value> indices =

          sliceLoadStoreIndices(rewriter, loc, loadOp.getIndices(), offsets);

      Value slicedLoad = vector::LoadOp::create(rewriter, loc, targetVecType,

                                                loadOp.getBase(), indices);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, slicedLoad, result, offsets, strides);

    }

    rewriter.replaceOp(loadOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollStorePattern : public OpRewritePattern<vector::StoreOp> {

  UnrollStorePattern(MLIRContext *context,

                     const vector::UnrollVectorOptions &options,

                     PatternBenefit benefit = 1)

      : OpRewritePattern<vector::StoreOp>(context, benefit), options(options) {}


  LogicalResult matchAndRewrite(vector::StoreOp storeOp,

                                PatternRewriter &rewriter) const override {

    VectorType vecType = storeOp.getVectorType();


    auto targetShape = getTargetShape(options, storeOp);

    if (!targetShape)

      return failure();


    Location loc = storeOp.getLoc();

    ArrayRef<int64_t> originalShape = vecType.getShape();

    SmallVector<int64_t> strides(targetShape->size(), 1);


    Value base = storeOp.getBase();

    Value vector = storeOp.getValueToStore();


    SmallVector<int64_t> loopOrder =

        getUnrollOrder(originalShape.size(), storeOp, options);


    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalShape, *targetShape, loopOrder)) {

      SmallVector<Value> indices =

          sliceLoadStoreIndices(rewriter, loc, storeOp.getIndices(), offsets);

      Value slice = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, vector, offsets, *targetShape, strides);

      vector::StoreOp::create(rewriter, loc, slice, base, indices);

    }

    rewriter.eraseOp(storeOp);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


struct UnrollBroadcastPattern : public OpRewritePattern<vector::BroadcastOp> {

  UnrollBroadcastPattern(MLIRContext *context,

                         const vector::UnrollVectorOptions &options,

                         PatternBenefit benefit = 1)

      : OpRewritePattern<vector::BroadcastOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::BroadcastOp broadcastOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, broadcastOp);

    if (!targetShape)

      return failure();


    Location loc = broadcastOp.getLoc();

    VectorType srcType = dyn_cast<VectorType>(broadcastOp.getSourceType());

    VectorType resType = broadcastOp.getResultVectorType();

    VectorType targetType =

        resType.cloneWith(*targetShape, resType.getElementType());

    Value result = arith::ConstantOp::create(rewriter, loc, resType,

                                             rewriter.getZeroAttr(resType));


    SmallVector<int64_t> originalShape = *broadcastOp.getShapeForUnroll();

    SmallVector<int64_t> strides(originalShape.size(), 1);


    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalShape, *targetShape)) {

      Value newSrc;

      if (!srcType) {

        // Scalar to vector broadcast.

        newSrc = broadcastOp.getSource();

      } else {

        // Vector to vector broadcast.

        int64_t rank = srcType.getRank();

        SmallVector<int64_t> srcOffsets(offsets.end() - rank, offsets.end());

        SmallVector<int64_t> srcShape(targetShape->end() - rank,

                                      targetShape->end());

        SmallVector<int64_t> srcStrides(strides.end() - rank, strides.end());

        // adjust the offset and shape for src if the corresponding dim is 1.

        for (int64_t i = 0; i < rank; ++i) {

          if (srcType.getDimSize(i) == 1) {

            srcOffsets[i] = 0;

            srcShape[i] = 1;

          }

        }

        newSrc = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

            loc, broadcastOp.getSource(), srcOffsets, srcShape, srcStrides);

      }


      Operation *newOp = cloneOpWithOperandsAndTypes(rewriter, loc, broadcastOp,

                                                     newSrc, targetType);


      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, newOp->getResult(0), result, offsets, strides);

    }


    rewriter.replaceOp(broadcastOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// Unrolls 2 or more dimensional `vector.to_elements` ops by unrolling the

/// outermost dimension of the operand. For example:

///

/// ```

/// %0:4 = vector.to_elements %v : vector<2x2xf32>

///

/// ==>

///

/// %v0 = vector.extract %v[0] : vector<2x2xf32> from vector<2x2x2xf32>

/// %v1 = vector.extract %v[1] : vector<2x2xf32> from vector<2x2x2xf32>

/// %0:4 = vector.to_elements %v0 : vector<2x2xf32>

/// %1:4 = vector.to_elements %v1 : vector<2x2xf32>

/// ```

///

/// When this pattern is applied until a fixed-point is reached,

/// this will produce a sequence of 1-d from_elements

/// ops.

struct UnrollToElements final : public OpRewritePattern<vector::ToElementsOp> {

  UnrollToElements(MLIRContext *context,

                   const vector::UnrollVectorOptions &options,

                   PatternBenefit benefit = 1)

      : OpRewritePattern<vector::ToElementsOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::ToElementsOp op,

                                PatternRewriter &rewriter) const override {


    TypedValue<VectorType> source = op.getSource();

    FailureOr<SmallVector<Value>> result =

        vector::unrollVectorValue(source, rewriter);

    if (failed(result)) {

      return failure();

    }

    SmallVector<Value> vectors = *result;


    SmallVector<Value> results;

    for (Value vector : vectors) {

      auto subElements =

          vector::ToElementsOp::create(rewriter, op.getLoc(), vector);

      llvm::append_range(results, subElements.getResults());

    }

    rewriter.replaceOp(op, results);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// This pattern unrolls `vector.step` operations according to the provided

/// target unroll shape. It decomposes a large step vector into smaller step

/// vectors (segments) and assembles the result by inserting each computed

/// segment into the appropriate offset of the original vector.

///

/// The pattern does not support scalable vectors and will fail to match them.

///

/// For each segment, it adds the base step vector and the segment's offset,

/// then inserts the result into the output vector at the corresponding

/// position.

///

/// Example:

///   Given a step operation:

///     %0 = vector.step : vector<8xindex>

///

///   and a target unroll shape of <4>, the pattern produces:

///

///     %base = vector.step : vector<4xindex>

///     %zero = arith.constant dense<0> : vector<8xindex>

///     %result0 = vector.insert_strided_slice %base, %zero

///       {offsets = [0], strides = [1]} : vector<4xindex> into vector<8xindex>

///     %offset = arith.constant dense<4> : vector<4xindex>

///     %segment1 = arith.addi %base, %offset : vector<4xindex>

///     %result1 = vector.insert_strided_slice %segment1, %result0

///       {offsets = [4], strides = [1]} : vector<4xindex> into vector<8xindex>

///

struct UnrollStepPattern : public OpRewritePattern<vector::StepOp> {

  UnrollStepPattern(MLIRContext *context,

                    const vector::UnrollVectorOptions &options,

                    PatternBenefit benefit = 1)

      : OpRewritePattern<vector::StepOp>(context, benefit), options(options) {}


  LogicalResult matchAndRewrite(vector::StepOp stepOp,

                                PatternRewriter &rewriter) const override {

    std::optional<SmallVector<int64_t>> targetShape =

        getTargetShape(options, stepOp);

    if (!targetShape)

      return failure();


    VectorType vecType = stepOp.getType();

    if (vecType.isScalable()) {

      // Scalable vectors are not supported by this pattern.

      return failure();

    }

    int64_t originalSize = vecType.getShape()[0];

    Location loc = stepOp.getLoc();

    SmallVector<int64_t> strides(1, 1);


    Value result = arith::ConstantOp::create(rewriter, loc, vecType,

                                             rewriter.getZeroAttr(vecType));


    auto targetVecType =

        VectorType::get(*targetShape, vecType.getElementType());

    Value baseStep = vector::StepOp::create(rewriter, loc, targetVecType);

    for (const SmallVector<int64_t> &offsets :

         StaticTileOffsetRange({originalSize}, *targetShape)) {

      Value bcastOffset = arith::ConstantOp::create(

          rewriter, loc, targetVecType,

          DenseElementsAttr::get(

              targetVecType,

              IntegerAttr::get(targetVecType.getElementType(), offsets[0])));

      Value tileStep =

          arith::AddIOp::create(rewriter, loc, baseStep, bcastOffset);


      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, tileStep, result, offsets, strides);

    }

    rewriter.replaceOp(stepOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// Unrolls 2 or more dimensional `vector.from_elements` ops by unrolling the

/// outermost dimension. For example:

/// ```

/// %v = vector.from_elements %e0, %e1, %e2, %e3, %e4, %e5 : vector<2x3xf32>

///

/// ==>

///

/// %0   = ub.poison : vector<2x3xf32>

/// %v0  = vector.from_elements %e0, %e1, %e2 : vector<3xf32>

/// %1   = vector.insert %v0, %0 [0] : vector<3xf32> into vector<2x3xf32>

/// %v1  = vector.from_elements %e3, %e4, %e5 : vector<3xf32>

/// %v   = vector.insert %v1, %1 [1] : vector<3xf32> into vector<2x3xf32>

/// ```

///

/// When this pattern is applied until a fixed-point is reached,

/// this will produce a sequence of 1-d from_elements

/// ops.

struct UnrollFromElements : OpRewritePattern<vector::FromElementsOp> {

  UnrollFromElements(MLIRContext *context,

                     const vector::UnrollVectorOptions &options,

                     PatternBenefit benefit = 1)

      : OpRewritePattern<vector::FromElementsOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::FromElementsOp op,

                                PatternRewriter &rewriter) const override {

    ValueRange allElements = op.getElements();


    auto unrollFromElementsFn = [&](PatternRewriter &rewriter, Location loc,

                                    VectorType subTy, int64_t index) {

      size_t subTyNumElements = subTy.getNumElements();

      assert((index + 1) * subTyNumElements <= allElements.size() &&

             "out of bounds");

      ValueRange subElements =

          allElements.slice(index * subTyNumElements, subTyNumElements);

      return vector::FromElementsOp::create(rewriter, loc, subTy, subElements);

    };


    return unrollVectorOp(op, rewriter, unrollFromElementsFn);

  }


private:

  vector::UnrollVectorOptions options;

};


/// This pattern unrolls `vector.create_mask` operations into smaller mask

/// operations based on the target unroll shape. Each unrolled slice computes

/// its local mask size in each dimension (d) as:

/// min(max(originalMaskSize[d] - offset[d], 0), unrolledDimSize[d]).

/// Example:

///   Given a create_mask operation:

///     %0 = vector.create_mask %c6, %c10 : vector<8x16xi1>  // mask first 6x10

///     elements

///

///   and a target unroll shape of <4x8>, the pattern produces:

///

///     %false = arith.constant dense<false> : vector<8x16xi1>

///

///     Slice [0,0]:

///     mask size = min(max(6-0, 0), 4) x min(max(10-0, 0), 8) = 4x8

///     %mask00 = vector.create_mask %c4, %c8 : vector<4x8xi1>

///     %r0 = vector.insert_strided_slice %mask00, %false [0, 0], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///     Slice [0,8]:

///     mask size = min(max(6-0, 0), 4) x min(max(10-8, 0), 8) = 4x2

///     %mask01 = vector.create_mask %c4, %c2 : vector<4x8xi1>

///     %r1 = vector.insert_strided_slice %mask01, %r0 [0, 8], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///     Slice [4,0]:

///     mask size = min(max(6-4, 0), 4) x min(max(10-0, 0), 8) = 2x8

///     %mask10 = vector.create_mask %c2, %c8 : vector<4x8xi1>

///     %r2 = vector.insert_strided_slice %mask10, %r1 [4, 0], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///     Slice [4,8]:

///     mask size = min(max(6-4, 0), 4) x min(max(10-8, 0), 8) = 2x2

///     %mask11 = vector.create_mask %c2, %c2 : vector<4x8xi1>

///     %result = vector.insert_strided_slice %mask11, %r2 [4, 8], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

struct UnrollCreateMaskPattern : public OpRewritePattern<vector::CreateMaskOp> {

  UnrollCreateMaskPattern(MLIRContext *context,

                          const vector::UnrollVectorOptions &options,

                          PatternBenefit benefit = 1)

      : OpRewritePattern<vector::CreateMaskOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::CreateMaskOp createMaskOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, createMaskOp);

    if (!targetShape)

      return failure();


    VectorType resultType = createMaskOp.getVectorType();

    SmallVector<int64_t> originalSize = *createMaskOp.getShapeForUnroll();

    Location loc = createMaskOp.getLoc();


    Value result = arith::ConstantOp::create(rewriter, loc, resultType,

                                             rewriter.getZeroAttr(resultType));

    VectorType targetVectorType =

        VectorType::get(*targetShape, rewriter.getI1Type());

    SmallVector<int64_t> strides(targetShape->size(), 1);


    // In each dimension (d), each unrolled vector computes its mask size as:

    // min(max(originalMaskOperands[d] - offset[d], 0), unrolledDimSize[d]).

    for (SmallVector<int64_t> offsets :

         StaticTileOffsetRange(originalSize, *targetShape)) {

      SmallVector<Value> unrolledOperands;


      for (auto [i, originalMaskOperand] :

           llvm::enumerate(createMaskOp.getOperands())) {

        Value offsetVal =

            arith::ConstantIndexOp::create(rewriter, loc, offsets[i]);

        Value adjustedMaskSize = rewriter.createOrFold<arith::SubIOp>(

            loc, originalMaskOperand, offsetVal);

        Value zero = arith::ConstantIndexOp::create(rewriter, loc, 0);

        Value unrolledDimSize =

            arith::ConstantIndexOp::create(rewriter, loc, (*targetShape)[i]);

        Value nonNegative =

            rewriter.createOrFold<arith::MaxSIOp>(loc, adjustedMaskSize, zero);

        Value unrolledOperand = rewriter.createOrFold<arith::MinSIOp>(

            loc, nonNegative, unrolledDimSize);

        unrolledOperands.push_back(unrolledOperand);

      }


      auto unrolledMask = rewriter.createOrFold<vector::CreateMaskOp>(

          loc, targetVectorType, unrolledOperands);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, unrolledMask, result, offsets, strides);

    }

    rewriter.replaceOp(createMaskOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// This pattern unrolls `vector.constant_mask` operations into smaller mask

/// operations based on the target unroll shape. Each unrolled slice computes

/// whether its elements should be masked based on the original mask dimensions

/// and the slice's offset position.

///

/// Example:

///   Given a constant_mask operation:

///     %0 = vector.constant_mask [6, 10] : vector<8x16xi1>

///

///   and a target unroll shape of <4x8>, the pattern produces:

///

///     %false = arith.constant dense<false> : vector<8x16xi1>

///

///     Slice [0,0]: elements [0:4, 0:8] - fully within [6, 10] bounds

///     %mask00 = vector.constant_mask [4, 8] : vector<4x8xi1>

///     %r0 = vector.insert_strided_slice %mask00, %false [0, 0], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///

///     Slice [0,8]: elements [0:4, 8:16] - partially within bounds

///     %mask01 = vector.constant_mask [4, 2] : vector<4x8xi1>

///     %r1 = vector.insert_strided_slice %mask01, %r0 [0, 8], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///

///     Slice [4,0]: elements [4:8, 0:8] - partially within bounds

///     %mask10 = vector.constant_mask [2, 8] : vector<4x8xi1>

///     %r2 = vector.insert_strided_slice %mask10, %r1 [4, 0], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

///

///     Slice [4,8]: elements [4:8, 8:16] - partially within bounds

///     %mask11 = vector.constant_mask [2, 2] : vector<4x8xi1>

///     %result = vector.insert_strided_slice %mask11, %r2 [4, 8], [1, 1]

///       : vector<4x8xi1> into vector<8x16xi1>

struct UnrollConstantMaskPattern

    : public OpRewritePattern<vector::ConstantMaskOp> {

  UnrollConstantMaskPattern(MLIRContext *context,

                            const vector::UnrollVectorOptions &options,

                            PatternBenefit benefit = 1)

      : OpRewritePattern<vector::ConstantMaskOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::ConstantMaskOp constantMaskOp,

                                PatternRewriter &rewriter) const override {

    std::optional<SmallVector<int64_t>> targetShape =

        getTargetShape(options, constantMaskOp);

    if (!targetShape)

      return failure();


    VectorType resultType = constantMaskOp.getVectorType();

    SmallVector<int64_t> originalSize = *constantMaskOp.getShapeForUnroll();

    Location loc = constantMaskOp.getLoc();


    Value result = arith::ConstantOp::create(rewriter, loc, resultType,

                                             rewriter.getZeroAttr(resultType));

    VectorType targetVectorType =

        VectorType::get(*targetShape, rewriter.getI1Type());

    SmallVector<int64_t> strides(targetShape->size(), 1);


    // In each dimension (d), each unrolled vector computes its mask size as:

    // min(max(originalMaskDim[d] - offset[d], 0), unrolledDimSize[d]).

    for (const SmallVector<int64_t> &offsets :

         StaticTileOffsetRange(originalSize, *targetShape)) {

      SmallVector<int64_t> unrolledMaskDims;


      for (auto [i, originalMaskDim] :

           llvm::enumerate(constantMaskOp.getMaskDimSizes())) {

        // Calculate how many elements in this dimension should be masked

        // for this particular slice

        int64_t adjustedMaskSize =

            std::max(originalMaskDim - offsets[i], static_cast<int64_t>(0));

        int64_t unrolledMaskDim =

            std::min(adjustedMaskSize, static_cast<int64_t>((*targetShape)[i]));

        unrolledMaskDims.push_back(unrolledMaskDim);

      }


      auto unrolledMask = rewriter.createOrFold<vector::ConstantMaskOp>(

          loc, targetVectorType, unrolledMaskDims);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, unrolledMask, result, offsets, strides);

    }

    rewriter.replaceOp(constantMaskOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// Checks whether extractShape is a contiguous slice of shape.

/// For extractShape to be contiguous in shape:

/// 1) All but the leading dimension of extractShape and shape must match

/// exactly. 2) The total number of elements in shape must be evenly divisible

/// by

///    the total number of elements in extractShape.

/// Examples:

///   isContiguous([4, 4], [8, 4]) == true

///   isContiguous([2, 4], [8, 4]) == true

///   isContiguous([2, 2], [8, 4]) == false

/// Removes leading unit dimensions to handle cases like:

///   isContiguous([1, 16], [1, 32]) == true

static bool isContiguous(ArrayRef<int64_t> extractShape,

                         ArrayRef<int64_t> shape) {


  if (extractShape.empty() || shape.empty() ||

      extractShape.size() > shape.size())

    return false;


  while (extractShape.size() > 1 && extractShape.front() == 1)

    extractShape = extractShape.drop_front();


  while (shape.size() > 1 && shape.front() == 1) {

    shape = shape.drop_front();

  }


  size_t rankDiff = shape.size() - extractShape.size();

  if (!llvm::equal(extractShape.drop_front(), shape.drop_front(rankDiff + 1)))

    return false;


  int64_t extractElements = ShapedType::getNumElements(extractShape);

  int64_t shapeElements = ShapedType::getNumElements(shape);

  return shapeElements % extractElements == 0;

}


/// Determines what shape to use with `vector.extract_strided_slice` to extract

/// a contiguous memory region from a source vector. The extraction must be

/// contiguous and contain exactly the specified number of elements. If such an

/// extraction shape cannot be determined, returns std::nullopt.

/// EXAMPLE 1:

///   sourceShape = [16], targetElements = 8

///   Working right-to-left:

///   - Take min(8, 16) = 8 from only dim → extractShape = [8],

///     remaining = 8/8 = 1

///     Result: [8]

///

///  EXAMPLE 2:

///   sourceShape = [4, 4], targetElements = 8

///   Working right-to-left:

///   - Take min(8, 4) = 4 from last dim → extractShape = [4],

///     remaining = 8/4 = 2

///   - Take min(2, 4) = 2 from first dim → extractShape = [2, 4],

///     remaining = 2/2 = 1

///     Result: [2, 4]

static std::optional<SmallVector<int64_t>>

calculateSourceExtractShape(ArrayRef<int64_t> sourceShape,

                            int64_t targetElements) {

  SmallVector<int64_t> extractShape;

  int64_t remainingElements = targetElements;


  // Build extract shape from innermost dimension outward to ensure contiguity.

  for (int i = sourceShape.size() - 1; i >= 0 && remainingElements > 1; --i) {

    int64_t takeFromDim = std::min(remainingElements, sourceShape[i]);

    extractShape.insert(extractShape.begin(), takeFromDim);


    if (remainingElements % takeFromDim != 0)

      return std::nullopt; // Not evenly divisible.

    remainingElements /= takeFromDim;

  }


  // Fill remaining dimensions with 1.

  while (extractShape.size() < sourceShape.size())

    extractShape.insert(extractShape.begin(), 1);


  if (ShapedType::getNumElements(extractShape) != targetElements)

    return std::nullopt;


  return extractShape;

}


// Convert result offsets to source offsets via linear position.

static SmallVector<int64_t>

calculateSourceOffsets(ArrayRef<int64_t> resultOffsets,

                       ArrayRef<int64_t> sourceShape,

                       ArrayRef<int64_t> resultShape) {

  // Convert result offsets to linear position.

  int64_t linearIndex = linearize(resultOffsets, computeStrides(resultShape));

  // Convert linear position to source offsets.

  return delinearize(linearIndex, computeStrides(sourceShape));

}


/// This pattern unrolls `vector.shape_cast` operations according to the

/// provided target unroll shape. It unrolls a large shape cast into smaller

/// shape casts by extracting contiguous slices from the source vector, casting

/// each slice to the target shape, and assembling the result by inserting each

/// computed segment into the appropriate offset of the result vector.

///

/// This pattern only applies when contiguous slices can be extracted from the

/// source vector and inserted into the result vector such that each slice

/// remains a valid vector (and not decompose to scalars). In these cases, the

/// unrolling proceeds as:

/// vector.extract_strided_slice -> vector.shape_cast (on the slice) ->

/// vector.insert_strided_slice.

///

/// Example:

///   Given a shape cast operation:

///     %0 = vector.shape_cast %src : vector<8x2xf32> to vector<4x4xf32>

///

///   and a target unroll shape of <2x4>, the pattern produces:

///

///     %zero = arith.constant dense<0.0> : vector<4x4xf32>

///     %s0 = vector.extract_strided_slice %src [0, 0], [4, 2], [1, 1]

///       : vector<8x2xf32> to vector<4x2xf32>

///     %sc0 = vector.shape_cast %s0 : vector<4x2xf32> to vector<2x4xf32>

///     %i0 = vector.insert_strided_slice %sc0, %zero [0, 0], [1, 1]

///       : vector<2x4xf32> into vector<4x4xf32>

///     %s1 = vector.extract_strided_slice %src [4, 0], [4, 2], [1, 1]

///       : vector<8x2xf32> to vector<4x2xf32>

///     %sc1 = vector.shape_cast %s1 : vector<4x2xf32> to vector<2x4xf32>

///     %i1 = vector.insert_strided_slice %sc1, %i0 [2, 0], [1, 1]

///       : vector<2x4xf32> into vector<4x4xf32>

///

struct UnrollShapeCastPattern : public OpRewritePattern<vector::ShapeCastOp> {

  UnrollShapeCastPattern(MLIRContext *context,

                         const vector::UnrollVectorOptions &options,

                         PatternBenefit benefit = 1)

      : OpRewritePattern<vector::ShapeCastOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::ShapeCastOp shapeCastOp,

                                PatternRewriter &rewriter) const override {

    std::optional<SmallVector<int64_t>> targetShape =

        getTargetShape(options, shapeCastOp);

    if (!targetShape)

      return failure();


    VectorType sourceType = shapeCastOp.getSourceVectorType();

    VectorType resultType = shapeCastOp.getResultVectorType();

    ArrayRef<int64_t> sourceShape = sourceType.getShape();

    ArrayRef<int64_t> resultShape = resultType.getShape();


    if (!isContiguous(*targetShape, resultShape))

      return rewriter.notifyMatchFailure(

          shapeCastOp, "Only supports cases where target shape is "

                       "contiguous in result vector shape");


    int64_t targetElements = ShapedType::getNumElements(*targetShape);


    // Calculate the shape to extract from source.

    std::optional<SmallVector<int64_t>> extractShape =

        calculateSourceExtractShape(sourceShape, targetElements);

    if (!extractShape)

      return rewriter.notifyMatchFailure(

          shapeCastOp,

          "cannot extract target number of elements contiguously from source");


    Location loc = shapeCastOp.getLoc();


    // Create result vector initialized to zero.

    Value result = arith::ConstantOp::create(rewriter, loc, resultType,

                                             rewriter.getZeroAttr(resultType));


    VectorType targetType =

        VectorType::get(*targetShape, sourceType.getElementType());


    SmallVector<int64_t> extractStrides(extractShape->size(), 1);

    SmallVector<int64_t> insertStrides(targetShape->size(), 1);


    for (SmallVector<int64_t> resultOffsets :

         StaticTileOffsetRange(resultShape, *targetShape)) {

      SmallVector<int64_t> sourceOffsets =

          calculateSourceOffsets(resultOffsets, sourceShape, resultShape);

      Value sourceChunk = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, shapeCastOp.getSource(), sourceOffsets, *extractShape,

          extractStrides);

      Value targetChunk = rewriter.createOrFold<vector::ShapeCastOp>(

          loc, targetType, sourceChunk);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, targetChunk, result, resultOffsets, insertStrides);

    }


    rewriter.replaceOp(shapeCastOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


// Unroll vector::BitCastOp into smaller slice-based bitcast operations.

// Decomposes the result vector into target shape chunks and bitcasts

// corresponding source slices, accounting for element bitwidth ratios.

/// Example:

///   Given a bitcast Op:

///

///     vector.bitcast %src : vector<4x8xf32>

///

///   and a target unroll shape of <2x4>, the pattern produces:

///

///     %slice_0 = vector.extract_strided_slice %lhs[0, 0] : vector<2x4xf32>

///     %slice_0 = vector.bitcast %slice_0 : vector<2x4xf32>

///     %result = vector.insert_strided_slice %slice_0, %init[0, 0]

///     // ... repeat for remaining slices

struct UnrollBitCastPattern : public OpRewritePattern<vector::BitCastOp> {

  UnrollBitCastPattern(MLIRContext *context,

                       const vector::UnrollVectorOptions &options,

                       PatternBenefit benefit = 1)

      : OpRewritePattern<vector::BitCastOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::BitCastOp bitCastOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, bitCastOp);

    if (!targetShape)

      return rewriter.notifyMatchFailure(bitCastOp,

                                         "failed to get target shape");


    VectorType sourceType = bitCastOp.getSourceVectorType();

    VectorType resultType = bitCastOp.getResultVectorType();

    ArrayRef<int64_t> resultShape = resultType.getShape();

    Location loc = bitCastOp.getLoc();


    if (targetShape->size() != resultShape.size())

      return rewriter.notifyMatchFailure(

          bitCastOp, "target shape rank must match result rank");


    unsigned sourceElementBits = sourceType.getElementTypeBitWidth();

    unsigned resultElementBits = resultType.getElementTypeBitWidth();


    SmallVector<int64_t> sourceSliceShape(targetShape->begin(),

                                          targetShape->end());

    int64_t lastDim = sourceSliceShape.size() - 1;


    sourceSliceShape[lastDim] =

        ((*targetShape)[lastDim] * resultElementBits) / sourceElementBits;


    Value result = arith::ConstantOp::create(rewriter, loc, resultType,

                                             rewriter.getZeroAttr(resultType));

    SmallVector<int64_t> resultStrides(targetShape->size(), 1);

    SmallVector<int64_t> sourceStrides(sourceSliceShape.size(), 1);


    VectorType targetType =

        VectorType::get(*targetShape, resultType.getElementType());


    for (SmallVector<int64_t> resultOffsets :

         StaticTileOffsetRange(resultShape, *targetShape)) {

      SmallVector<int64_t> sourceOffsets = resultOffsets;

      sourceOffsets[lastDim] =

          (resultOffsets[lastDim] * resultElementBits) / sourceElementBits;


      Value sourceSlice = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, bitCastOp.getSource(), sourceOffsets, sourceSliceShape,

          sourceStrides);

      Value bitcastSlice = rewriter.createOrFold<vector::BitCastOp>(

          loc, targetType, sourceSlice);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, bitcastSlice, result, resultOffsets, resultStrides);

    }


    rewriter.replaceOp(bitCastOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// Pattern to unroll vector.interleave into smaller slice-sized operations.

/// Decomposes a large interleave into slices by extracting slices from both

/// input vectors, interleaving them, and inserting back into the result.

///

/// Example:

///   Given an interleave Op:

///

///     vector.interleave %lhs, %rhs : vector<4x8xf32>

///

///   and a target unroll shape of <2x4>, the pattern produces:

///

///     %slice_lhs_0 = vector.extract_strided_slice %lhs[0, 0] : vector<2x2xf32>

///     %slice_rhs_0 = vector.extract_strided_slice %rhs[0, 0] : vector<2x2xf32>

///     %slice_0 = vector.interleave %slice_lhs_0, %slice_rhs_0

///       : vector<2x4xf32>

///     %result = vector.insert_strided_slice %slice_0, %init[0, 0]

///     // ... repeat for remaining slices

struct UnrollInterleavePattern : public OpRewritePattern<vector::InterleaveOp> {

  UnrollInterleavePattern(MLIRContext *context,

                          const vector::UnrollVectorOptions &options,

                          PatternBenefit benefit = 1)

      : OpRewritePattern<vector::InterleaveOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::InterleaveOp interleaveOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, interleaveOp);

    if (!targetShape)

      return rewriter.notifyMatchFailure(interleaveOp,

                                         "failed to get target shape");


    VectorType resultType = interleaveOp.getResultVectorType();

    ArrayRef<int64_t> resultShape = resultType.getShape();

    Location loc = interleaveOp.getLoc();


    if (targetShape->size() != resultShape.size())

      return rewriter.notifyMatchFailure(

          interleaveOp, "target shape rank must match result rank");


    SmallVector<int64_t> sourceSliceShape(targetShape->begin(),

                                          targetShape->end());

    int64_t lastDim = sourceSliceShape.size() - 1;

    sourceSliceShape[lastDim] = (*targetShape)[lastDim] / 2;


    Value result = arith::ConstantOp::create(rewriter, loc, resultType,

                                             rewriter.getZeroAttr(resultType));

    SmallVector<int64_t> resultStrides(targetShape->size(), 1);

    SmallVector<int64_t> sourceStrides(sourceSliceShape.size(), 1);


    VectorType targetType =

        VectorType::get(*targetShape, resultType.getElementType());


    for (SmallVector<int64_t> resultOffsets :

         StaticTileOffsetRange(resultShape, *targetShape)) {

      SmallVector<int64_t> sourceOffsets = resultOffsets;

      sourceOffsets[lastDim] = resultOffsets[lastDim] / 2;


      Value lhsSlice = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, interleaveOp.getLhs(), sourceOffsets, sourceSliceShape,

          sourceStrides);

      Value rhsSlice = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, interleaveOp.getRhs(), sourceOffsets, sourceSliceShape,

          sourceStrides);

      Value interleaveSlice = rewriter.createOrFold<vector::InterleaveOp>(

          loc, targetType, lhsSlice, rhsSlice);

      result = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, interleaveSlice, result, resultOffsets, resultStrides);

    }


    rewriter.replaceOp(interleaveOp, result);

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


/// Pattern to unroll vector.deinterleave into smaller slice-sized operations.

/// Decomposes a large deinterleave (which splits a vector into even/odd halves)

/// by extracting source slices, deinterleaving them, and inserting into two

/// result vectors.

///

/// Example:

///   Given a deinterleave Op:

///

///     vector.deinterleave %src : vector<4x8xf32>

///

///   and a target unroll shape of <2x4>, the pattern produces:

///

///   %slice_0 = vector.extract_strided_slice %src[0, 0] : vector<2x4xf32>

///   %slice_lhs_0, %slice_rhs_0 = vector.deinterleave %slice_0 :

///   vector<2x4xf32> %result1 = vector.insert_strided_slice %slice_lhs_0,

///   %init1[0, 0] %result2 = vector.insert_strided_slice %slice_rhs_0,

///   %init2[0, 0]

///   // ... repeat for remaining slices

struct UnrollDeinterleavePattern

    : public OpRewritePattern<vector::DeinterleaveOp> {

  UnrollDeinterleavePattern(MLIRContext *context,

                            const vector::UnrollVectorOptions &options,

                            PatternBenefit benefit = 1)

      : OpRewritePattern<vector::DeinterleaveOp>(context, benefit),

        options(options) {}


  LogicalResult matchAndRewrite(vector::DeinterleaveOp deinterleaveOp,

                                PatternRewriter &rewriter) const override {

    auto targetShape = getTargetShape(options, deinterleaveOp);

    if (!targetShape)

      return rewriter.notifyMatchFailure(deinterleaveOp,

                                         "failed to get target shape");


    VectorType resultType = deinterleaveOp.getResultVectorType();

    ArrayRef<int64_t> resultShape = resultType.getShape();

    Location loc = deinterleaveOp.getLoc();


    if (targetShape->size() != resultShape.size())

      return rewriter.notifyMatchFailure(

          deinterleaveOp, "target shape rank must match result rank");


    SmallVector<int64_t> sourceSliceShape(targetShape->begin(),

                                          targetShape->end());

    int64_t lastDim = sourceSliceShape.size() - 1;

    sourceSliceShape[lastDim] = (*targetShape)[lastDim] * 2;


    Value resultOdd = arith::ConstantOp::create(

        rewriter, loc, resultType, rewriter.getZeroAttr(resultType));

    Value resultEven = arith::ConstantOp::create(

        rewriter, loc, resultType, rewriter.getZeroAttr(resultType));

    SmallVector<int64_t> resultStrides(targetShape->size(), 1);

    SmallVector<int64_t> sourceStrides(sourceSliceShape.size(), 1);


    for (SmallVector<int64_t> resultOffsets :

         StaticTileOffsetRange(resultShape, *targetShape)) {

      SmallVector<int64_t> sourceOffsets = resultOffsets;

      sourceOffsets[lastDim] = resultOffsets[lastDim] * 2;


      Value sourceSlice = rewriter.createOrFold<vector::ExtractStridedSliceOp>(

          loc, deinterleaveOp.getSource(), sourceOffsets, sourceSliceShape,

          sourceStrides);


      auto deinterleaveSlice =

          vector::DeinterleaveOp::create(rewriter, loc, sourceSlice);


      resultOdd = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, deinterleaveSlice.getRes1(), resultOdd, resultOffsets,

          resultStrides);

      resultEven = rewriter.createOrFold<vector::InsertStridedSliceOp>(

          loc, deinterleaveSlice.getRes2(), resultEven, resultOffsets,

          resultStrides);

    }


    rewriter.replaceOp(deinterleaveOp, ValueRange{resultOdd, resultEven});

    return success();

  }


private:

  vector::UnrollVectorOptions options;

};


} // namespace


void mlir::vector::populateVectorUnrollPatterns(

    RewritePatternSet &patterns, const UnrollVectorOptions &options,

    PatternBenefit benefit) {

  patterns.add<UnrollTransferReadPattern, UnrollTransferWritePattern,

               UnrollContractionPattern, UnrollElementwisePattern,

               UnrollReductionPattern, UnrollMultiReductionPattern,

               UnrollTransposePattern, UnrollGatherPattern, UnrollLoadPattern,

               UnrollStorePattern, UnrollBroadcastPattern, UnrollFromElements,

               UnrollToElements, UnrollStepPattern, UnrollShapeCastPattern,

               UnrollCreateMaskPattern, UnrollConstantMaskPattern,

               UnrollBitCastPattern, UnrollInterleavePattern,

               UnrollDeinterleavePattern>(patterns.getContext(), options,

                                          benefit);

}


void mlir::vector::populateVectorToElementsUnrollPatterns(

    RewritePatternSet &patterns, PatternBenefit benefit) {

  patterns.add<UnrollToElements>(patterns.getContext(), UnrollVectorOptions(),

                                 benefit);

}


void mlir::vector::populateVectorFromElementsUnrollPatterns(

    RewritePatternSet &patterns, PatternBenefit benefit) {

  patterns.add<UnrollFromElements>(patterns.getContext(), UnrollVectorOptions(),

                                   benefit);

}

indices
indices
Definition AffineAnalysis.cpp:262

success
return success()

AffineOps.h

extractStrides
static LogicalResult extractStrides(AffineExpr e, AffineExpr multiplicativeFactor, MutableArrayRef< AffineExpr > strides, AffineExpr &offset)
Takes a single AffineExpr e and populates the strides array with the strides expressions for each dim...
Definition BuiltinAttributeInterfaces.cpp:104

lhs
lhs
Definition AffineExpr.cpp:833

IndexingUtils.h

ValueRange
b ValueRange
Definition LinalgTransformOps.cpp:2142

result
result
Definition LinalgTransformOps.cpp:2137

LoweringPatterns.h

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

VectorInterfaces.h

rhs
*B rhs
Definition VectorTransforms.cpp:2272

VectorTransforms.h

sliceLoadStoreIndices
static SmallVector< Value > sliceLoadStoreIndices(PatternRewriter &rewriter, Location loc, OperandRange originalIndices, ArrayRef< int64_t > offsets)
Definition VectorUnroll.cpp:57

getTargetShape
static std::optional< SmallVector< int64_t > > getTargetShape(const vector::UnrollVectorOptions &options, Operation *op)
Return the target shape for unrolling for the given op.
Definition VectorUnroll.cpp:89

getUnrollOrder
static SmallVector< int64_t > getUnrollOrder(unsigned numLoops, Operation *op, const vector::UnrollVectorOptions &options)
Definition VectorUnroll.cpp:131

cloneOpWithOperandsAndTypes
static Operation * cloneOpWithOperandsAndTypes(OpBuilder &builder, Location loc, Operation *op, ArrayRef< Value > operands, ArrayRef< Type > resultTypes)
Definition VectorUnroll.cpp:78

int64_t

llvm::ArrayRef
Definition LLVM.h:40

llvm::SmallVector
Definition LLVM.h:64

mlir::AffineExpr
Base type for affine expression.
Definition AffineExpr.h:68

mlir::AffineMap
A multi-dimensional affine map Affine map's are immutable like Type's, and they are uniqued.
Definition AffineMap.h:46

mlir::AffineMap::get
static AffineMap get(MLIRContext *context)
Returns a zero result affine map with no dimensions or symbols: () -> ().
Definition MLIRContext.cpp:1225

mlir::AffineMap::getResults
ArrayRef< AffineExpr > getResults() const
Definition AffineMap.cpp:405

mlir::Builder::getZeroAttr
TypedAttr getZeroAttr(Type type)
Definition Builders.cpp:328

mlir::Builder::getI1Type
IntegerType getI1Type()
Definition Builders.cpp:57

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

mlir::DenseElementsAttr::get
static DenseElementsAttr get(ShapedType type, ArrayRef< Attribute > values)
Constructs a dense elements attribute from an array of element values.
Definition BuiltinAttributes.cpp:870

mlir::Location
This class defines the main interface for locations in MLIR and acts as a non-nullable wrapper around...
Definition Location.h:76

mlir::MLIRContext
MLIRContext is the top-level object for a collection of MLIR operations.
Definition MLIRContext.h:63

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

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:528

mlir::OpBuilder::create
Operation * create(const OperationState &state)
Creates an operation given the fields represented as an OperationState.
Definition Builders.cpp:461

mlir::OperandRange
This class implements the operand iterators for the Operation class.
Definition ValueRange.h:44

mlir::OperationName::getStringRef
StringRef getStringRef() const
Return the name of this operation. This always succeeds.
Definition OperationSupport.h:497

mlir::OperationName::getIdentifier
StringAttr getIdentifier() const
Return the name of this operation as a StringAttr.
Definition OperationSupport.h:500

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

mlir::Operation::getAttrs
ArrayRef< NamedAttribute > getAttrs()
Return all of the attributes on this operation.
Definition Operation.h:538

mlir::Operation::getResult
OpResult getResult(unsigned idx)
Get the 'idx'th result of this operation.
Definition Operation.h:433

mlir::Operation::getLoc
Location getLoc()
The source location the operation was defined or derived from.
Definition Operation.h:241

mlir::Operation::getOpOperands
MutableArrayRef< OpOperand > getOpOperands()
Definition Operation.h:409

mlir::Operation::getName
OperationName getName()
The name of an operation is the key identifier for it.
Definition Operation.h:116

mlir::Operation::getResults
result_range getResults()
Definition Operation.h:441

mlir::Operation::getNumResults
unsigned getNumResults()
Return the number of results held by this operation.
Definition Operation.h:430

mlir::PatternBenefit
This class represents the benefit of a pattern match in a unitless scheme that ranges from 0 (very li...
Definition PatternMatch.h:34

mlir::PatternRewriter
A special type of RewriterBase that coordinates the application of a rewrite pattern on the current I...
Definition PatternMatch.h:799

mlir::RewritePatternSet
Definition PatternMatch.h:822

mlir::RewritePatternSet::getContext
MLIRContext * getContext() const
Definition PatternMatch.h:837

mlir::RewritePatternSet::add
RewritePatternSet & add(ConstructorArg &&arg, ConstructorArgs &&...args)
Add an instance of each of the pattern types 'Ts' to the pattern list with the given arguments.
Definition PatternMatch.h:861

mlir::RewritePattern
RewritePattern is the common base class for all DAG to DAG replacements.
Definition PatternMatch.h:238

mlir::RewriterBase::replaceOp
virtual void replaceOp(Operation *op, ValueRange newValues)
Replace the results of the given (original) operation with the specified list of values (replacements...
Definition PatternMatch.cpp:127

mlir::RewriterBase::eraseOp
virtual void eraseOp(Operation *op)
This method erases an operation that is known to have no uses.
Definition PatternMatch.cpp:155

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:732

mlir::Value::getType
Type getType() const
Return the type of this value.
Definition Value.h:105

mlir::arith::ConstantIndexOp::create
static ConstantIndexOp create(OpBuilder &builder, Location location, int64_t value)
Definition ArithOps.cpp:369

mlir::OpTrait::hasElementwiseMappableTraits
bool hasElementwiseMappableTraits(Operation *op)
Together, Elementwise, Scalarizable, Vectorizable, and Tensorizable provide an easy way for scalar op...
Definition Operation.cpp:1400

mlir::remark::failed
detail::InFlightRemark failed(Location loc, RemarkOpts opts)
Report an optimization remark that failed.
Definition Remarks.h:717

mlir::shape
Definition ShapeMappingAnalysis.h:20

mlir::vector
Definition ConvertVectorToLLVM.h:22

mlir::vector::makeArithReduction
Value makeArithReduction(OpBuilder &b, Location loc, CombiningKind kind, Value v1, Value acc, arith::FastMathFlagsAttr fastmath=nullptr, Value mask=nullptr)
Returns the result value of reducing two scalar/vector values with the corresponding arith operation.

mlir::vector::unrollVectorValue
FailureOr< SmallVector< Value > > unrollVectorValue(TypedValue< VectorType >, RewriterBase &)
Generic utility for unrolling values of type vector<NxAxBx...> to N values of type vector<AxBx....
Definition VectorUtils.cpp:606

mlir::vector::unrollVectorOp
LogicalResult unrollVectorOp(Operation *op, PatternRewriter &rewriter, UnrollVectorOpFn unrollFn)
Definition VectorUtils.cpp:626

mlir
Include the generated interface declarations.
Definition ABIRewriteContext.h:29

mlir::computeStrides
SmallVector< int64_t > computeStrides(ArrayRef< int64_t > sizes)
Definition IndexingUtils.h:47

mlir::delinearize
SmallVector< int64_t > delinearize(int64_t linearIndex, ArrayRef< int64_t > strides)
Given the strides together with a linear index in the dimension space, return the vector-space offset...
Definition IndexingUtils.cpp:97

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:494

mlir::getAffineConstantExpr
AffineExpr getAffineConstantExpr(int64_t constant, MLIRContext *context)

mlir::applyPermutationMap
SmallVector< T > applyPermutationMap(AffineMap map, llvm::ArrayRef< T > source)
Apply a permutation from map to source and return the result.
Definition AffineMap.h:675

mlir::linearize
int64_t linearize(ArrayRef< int64_t > offsets, ArrayRef< int64_t > basis)
Return the linearized index of 'offsets' w.r.t.
Definition IndexingUtils.cpp:90

mlir::computeShapeRatio
std::optional< SmallVector< int64_t > > computeShapeRatio(ArrayRef< int64_t > shape, ArrayRef< int64_t > subShape)
Return the multi-dimensional integral ratio of subShape to the trailing dimensions of shape.
Definition IndexingUtils.cpp:106

mlir::getAffineDimExpr
AffineExpr getAffineDimExpr(unsigned position, MLIRContext *context)
These free functions allow clients of the API to not use classes in detail.

mlir::OpRewritePattern
OpRewritePattern is a wrapper around RewritePattern that allows for matching and rewriting against an...
Definition PatternMatch.h:314

mlir::vector::UnrollVectorOptions
Options that control the vector unrolling.
Definition VectorRewritePatterns.h:36