doxygen/VectorTransforms_8cpp_source.html

 //===- VectorTransforms.cpp - Conversion within the Vector dialect --------===//

 //

 // 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 target-independent rewrites as 1->N patterns.

 //

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


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


 #include <cassert>

 #include <cstdint>

 #include <functional>

 #include <optional>

 #include <type_traits>


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

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

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

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

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

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

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

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

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

 #include "mlir/Dialect/Vector/IR/VectorOps.h"

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

 #include "mlir/Dialect/Vector/Utils/VectorUtils.h"

 #include "mlir/IR/BuiltinAttributeInterfaces.h"

 #include "mlir/IR/BuiltinTypes.h"

 #include "mlir/IR/ImplicitLocOpBuilder.h"

 #include "mlir/IR/Location.h"

 #include "mlir/IR/Matchers.h"

 #include "mlir/IR/PatternMatch.h"

 #include "mlir/IR/TypeUtilities.h"

 #include "mlir/Interfaces/VectorInterfaces.h"


 #include "llvm/ADT/DenseSet.h"

 #include "llvm/ADT/MapVector.h"

 #include "llvm/ADT/STLExtras.h"

 #include "llvm/Support/CommandLine.h"

 #include "llvm/Support/Debug.h"

 #include "llvm/Support/FormatVariadic.h"

 #include "llvm/Support/raw_ostream.h"


 #define DEBUG_TYPE "vector-to-vector"


 using namespace mlir;

 using namespace mlir::vector;


 template <typename IntType>

 static SmallVector<IntType> extractVector(ArrayAttr arrayAttr) {

   return llvm::to_vector<4>(llvm::map_range(

       arrayAttr.getAsRange<IntegerAttr>(),

       [](IntegerAttr attr) { return static_cast<IntType>(attr.getInt()); }));

 }


 // Helper to find an index in an affine map.

 static std::optional<int64_t> getResultIndex(AffineMap map, int64_t index) {

   for (int64_t i = 0, e = map.getNumResults(); i < e; ++i) {

     int64_t idx = map.getDimPosition(i);

     if (idx == index)

       return i;

   }

   return std::nullopt;

 }


 namespace {


 /// ShapeCastOpFolder folds cancelling ShapeCastOps away.

 //

 // Example:

 //

 //  The following MLIR with cancelling ShapeCastOps:

 //

 //   %0 = source : vector<5x4x2xf32>

 //   %1 = shape_cast %0 : vector<5x4x2xf32> to vector<20x2xf32>

 //   %2 = shape_cast %1 : vector<20x2xf32> to vector<5x4x2xf32>

 //   %3 = user %2 : vector<5x4x2xf32>

 //

 //  Should canonicalize to the following:

 //

 //   %0 = source : vector<5x4x2xf32>

 //   %1 = user %0 : vector<5x4x2xf32>

 //

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

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ShapeCastOp shapeCastOp,

                                 PatternRewriter &rewriter) const override {

     // Check if 'shapeCastOp' has vector source/result type.

     auto sourceVectorType =

         dyn_cast_or_null<VectorType>(shapeCastOp.getSource().getType());

     auto resultVectorType =

         dyn_cast_or_null<VectorType>(shapeCastOp.getResult().getType());

     if (!sourceVectorType || !resultVectorType)

       return failure();


     // Check if shape cast op source operand is also a shape cast op.

     auto sourceShapeCastOp = dyn_cast_or_null<vector::ShapeCastOp>(

         shapeCastOp.getSource().getDefiningOp());

     if (!sourceShapeCastOp)

       return failure();

     auto operandSourceVectorType =

         cast<VectorType>(sourceShapeCastOp.getSource().getType());

     auto operandResultVectorType = sourceShapeCastOp.getType();


     // Check if shape cast operations invert each other.

     if (operandSourceVectorType != resultVectorType ||

         operandResultVectorType != sourceVectorType)

       return failure();


     rewriter.replaceOp(shapeCastOp, sourceShapeCastOp.getSource());

     return success();

   }

 };


 /// Convert MulIOp/MulFOp + MultiDimReductionOp<add> into ContractionOp.

 /// Ex:

 /// ```

 ///   %0 = arith.mulf %arg0, %arg1 : vector<8x32x16xf32>

 ///   %1 = vector.multi_reduction add, %0 [1]

 ///     : vector<8x32x16xf32> to vector<8x16xf32>

 /// ```

 /// Gets converted to:

 /// ```

 ///   %1 = vector.contract {indexing_maps = [

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1)>],

 ///    iterator_types = ["parallel", "parallel", "reduction"],

 ///    kind = add} %0, %arg1, %cst_f0

 ///    : vector<8x32x16xf32>, vector<8x32x16xf32> into vector<8x32xf32>

 ///  ```

 struct MultiReduceToContract

     : public OpRewritePattern<vector::MultiDimReductionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::MultiDimReductionOp reduceOp,

                                 PatternRewriter &rewriter) const override {

     if (reduceOp.getKind() != vector::CombiningKind::ADD)

       return failure();

     Operation *mulOp = reduceOp.getSource().getDefiningOp();

     if (!mulOp || !isa<arith::MulIOp, arith::MulFOp>(mulOp))

       return failure();

     SmallVector<bool> reductionMask = reduceOp.getReductionMask();

     auto srcMap = rewriter.getMultiDimIdentityMap(reductionMask.size());

     SmallVector<AffineExpr> exprs;

     SmallVector<vector::IteratorType> iteratorTypes;

     for (const auto &isReduceDim : llvm::enumerate(reductionMask)) {

       if (!isReduceDim.value()) {

         iteratorTypes.push_back(vector::IteratorType::parallel);

         exprs.push_back(rewriter.getAffineDimExpr(isReduceDim.index()));

       } else {

         iteratorTypes.push_back(vector::IteratorType::reduction);

       }

     }

     auto dstMap =

         AffineMap::get(/*dimCount=*/reductionMask.size(),

                        /*symbolCount=*/0, exprs, reduceOp.getContext());

     rewriter.replaceOpWithNewOp<mlir::vector::ContractionOp>(

         reduceOp, mulOp->getOperand(0), mulOp->getOperand(1), reduceOp.getAcc(),

         rewriter.getAffineMapArrayAttr({srcMap, srcMap, dstMap}),

         rewriter.getArrayAttr(llvm::to_vector(llvm::map_range(

             iteratorTypes, [&](IteratorType t) -> mlir::Attribute {

               return IteratorTypeAttr::get(rewriter.getContext(), t);

             }))));

     return success();

   }

 };


 /// Merge LHS/RHS (A/B) TransposeOp into ContractionOp user.

 /// Ex:

 /// ```

 ///   %0 = vector.transpose %arg0, [2, 0, 1]

 ///     : vector<32x16x8xf32> to vector<8x32x16xf32>

 ///   %1 = vector.contract {indexing_maps = [

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1)>],

 ///    iterator_types = ["parallel", "parallel", "reduction"],

 ///    kind = add} %0, %arg1, %cst_f0

 ///    : vector<8x32x16xf32>, vector<8x32x16xf32> into vector<8x32xf32>

 /// ```

 /// Gets converted to:

 /// ```

 ///   %1 = vector.contract {indexing_maps = [

 ///         affine_map<(d0, d1, d2) -> (d1, d2, d0)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1)>],

 ///    iterator_types = ["parallel", "parallel", "reduction"],

 ///    kind = add} %arg0, %arg1, %cst_f0

 ///    : vector<8x32x16xf32>, vector<8x32x16xf32> into vector<8x32xf32>

 ///  ```

 struct CombineContractABTranspose final

     : public OpRewritePattern<vector::ContractionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ContractionOp contractOp,

                                 PatternRewriter &rewriter) const override {

     SmallVector<AffineMap> maps =

         llvm::to_vector<4>(contractOp.getIndexingMapsArray());

     Value lhs = contractOp.getLhs();

     Value rhs = contractOp.getRhs();

     size_t index = 0;

     bool changed = false;

     for (Value *operand : {&lhs, &rhs}) {

       AffineMap &map = maps[index++];

       auto transposeOp = operand->getDefiningOp<vector::TransposeOp>();

       if (!transposeOp)

         continue;

       AffineMap permutationMap = AffineMap::getPermutationMap(

           transposeOp.getPermutation(), contractOp.getContext());

       map = inversePermutation(permutationMap).compose(map);

       *operand = transposeOp.getVector();

       changed = true;

     }

     if (!changed)

       return failure();

     rewriter.replaceOpWithNewOp<vector::ContractionOp>(

         contractOp, lhs, rhs, contractOp.getAcc(),

         rewriter.getAffineMapArrayAttr(maps), contractOp.getIteratorTypes());

     return success();

   }

 };


 /// Merges accumulator and result transposes into contract.

 ///

 /// For example:

 /// ```mlir

 /// %accT = vector.transpose %acc, [0, 2, 1]

 ///   : vector<2x8x4xf32> to vector<2x4x8xf32>

 /// %contract = vector.contract {

 ///   indexing_maps = [

 ///     affine_map<(d0, d1, d2, d3) -> (d0, d3, d1)>,

 ///     affine_map<(d0, d1, d2, d3) -> (d3, d2)>,

 ///     affine_map<(d0, d1, d2, d3) -> (d0, d1, d2)>

 ///   ],

 ///   iterator_types = ["parallel", "parallel", "parallel", "reduction"],

 ///   kind = #vector.kind<add>

 /// } %lhs, %rhs, %accT

 ///   : vector<2x4x4xf32>, vector<4x8xf32> into vector<2x4x8xf32>

 /// %0 = vector.transpose %contract, [0, 2, 1]

 ///   : vector<2x4x8xf32> to vector<2x8x4>

 /// ```

 /// Becomes:

 /// ```mlir

 /// %0 = vector.contract {

 ///   indexing_maps = [

 ///     affine_map<(d0, d1, d2, d3) -> (d0, d3, d1)>,

 ///     affine_map<(d0, d1, d2, d3) -> (d3, d2)>,

 ///     affine_map<(d0, d1, d2, d3) -> (d0, d2, d1)>

 ///   ],

 ///   iterator_types = ["parallel", "parallel", "parallel", "reduction"],

 ///   kind = #vector.kind<add>

 /// } %lhs, %rhs, %acc

 ///   : vector<2x4x4xf32>, vector<4x8xf32> into vector<2x8x4xf32>

 /// ```

 struct CombineContractResultTranspose final

     : public OpRewritePattern<vector::TransposeOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::TransposeOp resTOp,

                                 PatternRewriter &rewriter) const override {

     auto contractOp = resTOp.getVector().getDefiningOp<vector::ContractionOp>();

     if (!contractOp || !contractOp->hasOneUse())

       return failure();


     auto accTOp = contractOp.getAcc().getDefiningOp<vector::TransposeOp>();

     if (!accTOp)

       return failure();


     MLIRContext *context = contractOp.getContext();

     auto maps = llvm::to_vector<3>(contractOp.getIndexingMapsArray());

     AffineMap contractMap = maps.back();


     // Accumulator transpose performs f(A) -> B. Contract performs g(C) -> B.

     // To index into A in contract, we need revert(f)(g(C)) -> A.

     auto accTMap =

         AffineMap::getPermutationMap(accTOp.getPermutation(), context);


     // Contract performs g(C) -> D. Result transpose performs h(D) -> E.

     // To index into E in contract, we need h(g(C)) -> E.

     auto resTMap =

         AffineMap::getPermutationMap(resTOp.getPermutation(), context);

     auto combinedResMap = resTMap.compose(contractMap);


     // The accumulator and result share the same indexing map. So they should be

     // the same to be able to merge. This means combinedResMap is the same as

     // inversePermutation(accTMap).compose(contractMap), which means

     if (inversePermutation(accTMap) != resTMap)

       return failure();

     maps.back() = combinedResMap;


     rewriter.replaceOpWithNewOp<vector::ContractionOp>(

         resTOp, contractOp.getLhs(), contractOp.getRhs(), accTOp.getVector(),

         rewriter.getAffineMapArrayAttr(maps), contractOp.getIteratorTypes());

     return success();

   }

 };


 /// Merge BroadcastOp into ContractionOp user.

 /// Ex:

 /// ```

 ///   %0 = vector.broadcast %arg0 : vector<32x16xf32> to vector<8x32x16xf32>

 ///   %1 = vector.contract {indexing_maps = [

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1)>],

 ///    iterator_types = ["parallel", "parallel", "reduction"],

 ///    kind = add} %0, %arg1, %cst_f0

 ///    : vector<8x32x16xf32>, vector<8x32x16xf32> into vector<8x32xf32>

 /// ```

 /// Gets converted to:

 /// ```

 ///   %1 = vector.contract {indexing_maps = [

 ///         affine_map<(d0, d1, d2) -> (d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1, d2)>,

 ///         affine_map<(d0, d1, d2) -> (d0, d1)>],

 ///    iterator_types = ["parallel", "parallel", "reduction"],

 ///    kind = add} %arg0, %arg1, %cst_f0

 ///    : vector<32x16xf32>, vector<8x32x16xf32> into vector<8x32xf32>

 ///  ```

 struct CombineContractBroadcast

     : public OpRewritePattern<vector::ContractionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ContractionOp contractOp,

                                 PatternRewriter &rewriter) const override {

     SmallVector<AffineMap> maps =

         llvm::to_vector<4>(contractOp.getIndexingMapsArray());

     Value lhs = contractOp.getLhs();

     Value rhs = contractOp.getRhs();

     size_t index = 0;

     bool changed = false;

     for (Value *operand : {&lhs, &rhs}) {

       AffineMap &map = maps[index++];

       auto broadcast = operand->getDefiningOp<vector::BroadcastOp>();

       if (!broadcast)

         continue;

       // contractionOp can only take vector as operands.

       auto srcType = dyn_cast<VectorType>(broadcast.getSourceType());

       if (!srcType ||

           srcType.getRank() == broadcast.getResultVectorType().getRank())

         continue;

       int64_t rankDiff =

           broadcast.getResultVectorType().getRank() - srcType.getRank();

       bool innerDimBroadcast = false;

       SmallVector<AffineExpr> originalDims;

       for (const auto &dim : llvm::enumerate(srcType.getShape())) {

         if (dim.value() != broadcast.getResultVectorType().getDimSize(

                                rankDiff + dim.index())) {

           innerDimBroadcast = true;

           break;

         }

         originalDims.push_back(

             rewriter.getAffineDimExpr(dim.index() + rankDiff));

       }

       // Contract doesn't support inner dimension broadcast. Once this is

       // relaxed we can remove this case.

       if (innerDimBroadcast)

         continue;


       // It would be incorrect to fold a broadcast onto a reduction dimension

       // of non-unit size.

       bool nonUnitDimReductionBroadcast = false;

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

         if (broadcast.getResultVectorType().getDimSize(i) != 1 &&

             isReductionIterator(contractOp.getIteratorTypes()

                                     .getValue()[map.getDimPosition(i)])) {

           nonUnitDimReductionBroadcast = true;

           break;

         }

       }

       if (nonUnitDimReductionBroadcast)

         continue;


       AffineMap broadcastMap =

           AffineMap::get(broadcast.getResultVectorType().getRank(), 0,

                          originalDims, contractOp.getContext());

       map = broadcastMap.compose(map);

       *operand = broadcast.getSource();

       changed = true;

     }


     if (!changed)

       return failure();


     // Determine which dims are usused, now that the maps have been composed

     // with the broadcast maps.

     llvm::SmallBitVector unusedDimsBitVector = getUnusedDimsBitVector(maps);

     // Compress unused dims.

     for (auto &m : maps)

       m = compressDims(m, unusedDimsBitVector);

     // Compute the combined iterators.

     SmallVector<Attribute> iterators;

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

       if (!unusedDimsBitVector.test(i))

         iterators.push_back(contractOp.getIteratorTypes().getValue()[i]);

     }

     // Check that compressing unused dims isn't removing all reduction dimension

     // pairs. For example, if the vector.contract had only one reduction

     // iterator and that was a unit-dimension created by a broadcast,

     // then we should bail here, otherwise we would create a contract without

     // a reduction dimension pair.

     bool hasReductionIteratorApplyingOnBothSides = false;

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

       if (!isReductionIterator(iterators[i]))

         continue;

       if (getResultIndex(maps[0], i) && getResultIndex(maps[1], i)) {

         hasReductionIteratorApplyingOnBothSides = true;

         break;

       }

     }

     if (!hasReductionIteratorApplyingOnBothSides)

       return failure();


     // If the compressed maps have a dimension that is not used by either LHS or

     // RHS then the ContractionOp verifier would fail.

     if (getUnusedDimsBitVector({maps[0], maps[1]}).any())

       return failure();

     rewriter.replaceOpWithNewOp<vector::ContractionOp>(

         contractOp, lhs, rhs, contractOp.getAcc(),

         rewriter.getAffineMapArrayAttr(maps), rewriter.getArrayAttr(iterators));

     return success();

   }

 };


 /// Reorders cast(broadcast) to broadcast(cast). This makes broadcast ops and

 /// contraction ops closer, which kicks in CombineContractBroadcast pattern when

 /// casting ops are around these operations.

 /// Ex:

 /// ```

 ///   %0 = vector.broadcast %arg0 : vector<32x16xi8> to vector<8x32x16xi8>

 ///   %1 = arith.extsi %0 : vector<8x32x16xi8> to vector<8x32x16xi32>

 /// ```

 /// Gets converted to:

 /// ```

 ///   %0 = arith.extsi %0 : vector<32x16xi8> to vector<32x16xi32>

 ///   %1 = vector.broadcast %arg0 : vector<32x16xi32> to vector<8x32x16xi32>

 /// ```

 struct ReorderCastOpsOnBroadcast

     : public OpInterfaceRewritePattern<CastOpInterface> {

   using OpInterfaceRewritePattern<CastOpInterface>::OpInterfaceRewritePattern;


   LogicalResult matchAndRewrite(CastOpInterface op,

                                 PatternRewriter &rewriter) const override {

     if (op->getNumOperands() != 1)

       return failure();

     auto bcastOp = op->getOperand(0).getDefiningOp<vector::BroadcastOp>();

     if (!bcastOp)

       return failure();


     Type castResTy = getElementTypeOrSelf(op->getResult(0));

     if (auto vecTy = dyn_cast<VectorType>(bcastOp.getSourceType()))

       castResTy = vecTy.clone(castResTy);

     auto *castOp =

         rewriter.create(op->getLoc(), op->getName().getIdentifier(),

                         bcastOp.getSource(), castResTy, op->getAttrs());

     rewriter.replaceOpWithNewOp<vector::BroadcastOp>(

         op, op->getResult(0).getType(), castOp->getResult(0));

     return success();

   }

 };


 /// Reorders elementwise(transpose) to transpose(elementwise). This makes

 /// transpose ops and contraction ops closer, which kicks in

 /// CombineContractABTranspose pattern when elementwise ops are between these

 /// operations. Ex:

 /// ```

 /// %at = vector.transpose %a, [1, 0]: vector<4x2xf32> to vector<2x4xf32>

 /// %bt = vector.transpose %b, [1, 0]: vector<4x2xf32> to vector<2x4xf32>

 /// %r = arith.addf %at, %bt : vector<2x4xf32>

 /// ```

 /// Gets converted to:

 /// ```

 /// %0 = arith.addf %a, %b : vector<4x2xf32>

 /// %r = vector.transpose %0, [1, 0] : vector<2x4xf32>

 /// ```

 struct ReorderElementwiseOpsOnTranspose final

     : public OpTraitRewritePattern<OpTrait::Elementwise> {

   using OpTraitRewritePattern::OpTraitRewritePattern;

   LogicalResult matchAndRewrite(Operation *op,

                                 PatternRewriter &rewriter) const override {

     if (op->getNumResults() != 1 || op->getNumRegions() != 0)

       return failure();


     // Make sure all operands are transpose/constant ops and collect their

     // transposition maps.

     SmallVector<ArrayRef<int64_t>> transposeMaps;

     transposeMaps.reserve(op->getNumOperands());

     // Record the initial type before transposition. We'll use its shape later.

     // Any type will do here as we will check all transpose maps are the same.

     VectorType srcType;

     for (Value operand : op->getOperands()) {

       auto transposeOp = operand.getDefiningOp<vector::TransposeOp>();

       if (transposeOp) {

         transposeMaps.push_back(transposeOp.getPermutation());

         srcType = transposeOp.getSourceVectorType();

       } else if (!matchPattern(operand, m_Constant())) {

         return failure();

       }

     }

     if (transposeMaps.empty())

       return failure();

     // This is an elementwise op, so all transposed operands should have the

     // same type. We need to additionally check that all transposes uses the

     // same map.

     if (!llvm::all_equal(transposeMaps))

       return rewriter.notifyMatchFailure(op, "different transpose map");


     SmallVector<Value> srcValues;

     srcValues.reserve(op->getNumOperands());


     // If there are constant operands, we need to insert inverse transposes for

     // them. Calculate the inverse order first.

     auto order = transposeMaps.front();

     SmallVector<int64_t> invOrder(order.size());

     for (int i = 0, e = order.size(); i < e; ++i)

       invOrder[order[i]] = i;


     for (Value operand : op->getOperands()) {

       auto transposeOp = operand.getDefiningOp<vector::TransposeOp>();

       if (transposeOp) {

         srcValues.push_back(transposeOp.getVector());

       } else {

         // This is a constant. Create a reverse transpose op for it.

         auto vectorType =

             srcType.clone(cast<VectorType>(operand.getType()).getElementType());

         srcValues.push_back(rewriter.create<vector::TransposeOp>(

             operand.getLoc(), vectorType, operand, invOrder));

       }

     }


     auto vectorType = srcType.clone(

         cast<VectorType>(op->getResultTypes()[0]).getElementType());

     Operation *elementwiseOp =

         rewriter.create(op->getLoc(), op->getName().getIdentifier(), srcValues,

                         vectorType, op->getAttrs());

     rewriter.replaceOpWithNewOp<vector::TransposeOp>(

         op, op->getResultTypes()[0], elementwiseOp->getResult(0),

         transposeMaps.front());

     return success();

   }

 };


 // Returns the values in `arrayAttr` as an integer vector.

 static SmallVector<int64_t> getIntValueVector(ArrayAttr arrayAttr) {

   return llvm::to_vector<4>(

       llvm::map_range(arrayAttr.getAsRange<IntegerAttr>(),

                       [](IntegerAttr attr) { return attr.getInt(); }));

 }


 // Shuffles vector.bitcast op after vector.extract op.

 //

 // This transforms IR like:

 //   %0 = vector.bitcast %src : vector<4xf32> to vector<8xf16>

 //   %1 = vector.extract %0[3] : f16 from vector<8xf16>

 // Into:

 //   %0 = vector.extract %src[1] : f32 from vector<4xf32>

 //   %1 = vector.bitcast %0: vector<1xf32> to vector<2xf16>

 //   %2 = vector.extract %1[1] : f16 from vector<2xf16>

 struct BubbleDownVectorBitCastForExtract

     : public OpRewritePattern<vector::ExtractOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ExtractOp extractOp,

                                 PatternRewriter &rewriter) const override {

     // Only support extracting scalars for now.

     if (extractOp.getSourceVectorType().getRank() != 1)

       return failure();


     auto castOp = extractOp.getVector().getDefiningOp<vector::BitCastOp>();

     if (!castOp)

       return failure();


     VectorType castSrcType = castOp.getSourceVectorType();

     VectorType castDstType = castOp.getResultVectorType();

     assert(castSrcType.getRank() == castDstType.getRank());


     // Fail to match if we only have one element in the cast op source.

     // This is to avoid infinite loop given that this pattern can generate

     // such cases.

     if (castSrcType.getNumElements() == 1)

       return failure();


     // Only support casting to a larger number of elements or now.

     // E.g., vector<4xf32> -> vector<8xf16>.

     if (castSrcType.getNumElements() > castDstType.getNumElements())

       return failure();


     unsigned expandRatio =

         castDstType.getNumElements() / castSrcType.getNumElements();


     auto getFirstIntValue = [](ArrayRef<OpFoldResult> values) -> uint64_t {

       assert(values[0].is<Attribute>() && "Unexpected non-constant index");

       return cast<IntegerAttr>(values[0].get<Attribute>()).getInt();

     };


     uint64_t index = getFirstIntValue(extractOp.getMixedPosition());


     // Get the single scalar (as a vector) in the source value that packs the

     // desired scalar. E.g. extract vector<1xf32> from vector<4xf32>

     Location loc = extractOp.getLoc();

     Value packedValue = rewriter.create<vector::ExtractOp>(

         loc, castOp.getSource(), index / expandRatio);

     Type packedVecType = VectorType::get(/*shape=*/{1}, packedValue.getType());

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

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

     packedValue = rewriter.create<vector::InsertOp>(loc, packedValue, zero,

                                                     /*position=*/0);


     // Cast it to a vector with the desired scalar's type.

     // E.g. f32 -> vector<2xf16>

     VectorType packedType =

         VectorType::get({expandRatio}, castDstType.getElementType());

     Value castedValue =

         rewriter.create<vector::BitCastOp>(loc, packedType, packedValue);


     // Finally extract the desired scalar.

     rewriter.replaceOpWithNewOp<vector::ExtractOp>(extractOp, castedValue,

                                                    index % expandRatio);

     return success();

   }

 };


 // Shuffles vector.bitcast op after vector.extract_strided_slice op.

 //

 // This transforms IR like:

 //    %cast = vector.bitcast %arg0: vector<4xf32> to vector<8xf16>

 //     %0 = vector.extract_strided_slice %cast {

 //            offsets = [4], sizes = [4], strides = [1]

 //          } : vector<8xf16> to vector<4xf16>

 // Into:

 //   %0 = vector.extract_strided_slice %src {

 //          offsets = [2], sizes = [2], strides = [1]

 //        } : vector<4xf32> to vector<2xf32>

 //   %1 = vector.bitcast %0 : vector<2xf32> to vector<4xf16>

 struct BubbleDownBitCastForStridedSliceExtract

     : public OpRewritePattern<vector::ExtractStridedSliceOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ExtractStridedSliceOp extractOp,

                                 PatternRewriter &rewriter) const override {

     auto castOp = extractOp.getVector().getDefiningOp<vector::BitCastOp>();

     if (!castOp)

       return failure();


     VectorType castSrcType = castOp.getSourceVectorType();

     VectorType castDstType = castOp.getResultVectorType();

     assert(castSrcType.getRank() == castDstType.getRank());


     int64_t castSrcLastDim = castSrcType.getShape().back();

     int64_t castDstLastDim = castDstType.getShape().back();

     // Require casting to more elements for now; other cases to be implemented.

     if (castSrcLastDim > castDstLastDim)

       return failure();


     // Only accept all one strides for now.

     if (llvm::any_of(extractOp.getStrides().getAsValueRange<IntegerAttr>(),

                      [](const APInt &val) { return !val.isOne(); }))

       return failure();


     unsigned rank = extractOp.getSourceVectorType().getRank();

     assert(castDstLastDim % castSrcLastDim == 0);

     int64_t expandRatio = castDstLastDim / castSrcLastDim;


     // If we have a less number of offsets than the rank, then implicitly we

     // are selecting the full range for the last bitcasted dimension; other

     // dimensions aren't affected. Otherwise, we need to scale down the last

     // dimension's offset given we are extracting from less elements now.

     ArrayAttr newOffsets = extractOp.getOffsets();

     if (newOffsets.size() == rank) {

       SmallVector<int64_t> offsets = getIntValueVector(newOffsets);

       if (offsets.back() % expandRatio != 0)

         return failure();

       offsets.back() = offsets.back() / expandRatio;

       newOffsets = rewriter.getI64ArrayAttr(offsets);

     }


     // Similarly for sizes.

     ArrayAttr newSizes = extractOp.getSizes();

     if (newSizes.size() == rank) {

       SmallVector<int64_t> sizes = getIntValueVector(newSizes);

       if (sizes.back() % expandRatio != 0)

         return failure();

       sizes.back() = sizes.back() / expandRatio;

       newSizes = rewriter.getI64ArrayAttr(sizes);

     }


     SmallVector<int64_t> dims =

         llvm::to_vector<4>(cast<VectorType>(extractOp.getType()).getShape());

     dims.back() = dims.back() / expandRatio;

     VectorType newExtractType =

         VectorType::get(dims, castSrcType.getElementType());


     auto newExtractOp = rewriter.create<vector::ExtractStridedSliceOp>(

         extractOp.getLoc(), newExtractType, castOp.getSource(), newOffsets,

         newSizes, extractOp.getStrides());


     rewriter.replaceOpWithNewOp<vector::BitCastOp>(

         extractOp, extractOp.getType(), newExtractOp);


     return success();

   }

 };


 // Shuffles vector.bitcast op before vector.insert_strided_slice op.

 //

 // This transforms IR like:

 //   %0 = vector.insert %val, %dst[4] : vector<32xi4> into vector<8x32xi4>

 //   %1 = vector.bitcast %0 : vector<8x32xi4> to vector<8x16xi8>

 // Into:

 //   %0 = vector.bitcast %val : vector<32xi4> to vector<16xi8>

 //   %1 = vector.bitcast %dst : vector<8x32xi4> to vector<8x16xi8>

 //   %2 = vector.insert %0, %1 [4] : vector<16xi8> into vector<8x16xi8>

 //

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

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::BitCastOp bitcastOp,

                                 PatternRewriter &rewriter) const override {

     VectorType castSrcType = bitcastOp.getSourceVectorType();

     VectorType castDstType = bitcastOp.getResultVectorType();


     // 0-D and scalable vectors are not supported yet.

     if (castSrcType.getRank() == 0 || castSrcType.isScalable() ||

         castDstType.isScalable())

       return failure();


     int64_t castSrcLastDim = castSrcType.getShape().back();

     int64_t castDstLastDim = castDstType.getShape().back();

     bool isNumElemsShrink = castSrcLastDim >= castDstLastDim;

     int64_t ratio;

     if (isNumElemsShrink) {

       assert(castSrcLastDim % castDstLastDim == 0);

       ratio = castSrcLastDim / castDstLastDim;

     } else {

       assert(castDstLastDim % castSrcLastDim == 0);

       ratio = castDstLastDim / castSrcLastDim;

     }


     auto insertOp = bitcastOp.getSource().getDefiningOp<vector::InsertOp>();

     if (!insertOp)

       return failure();


     // Only vector sources are supported for now.

     auto insertSrcType = dyn_cast<VectorType>(insertOp.getSourceType());

     if (!insertSrcType)

       return failure();


     // Bitcast the source.

     SmallVector<int64_t> srcDims(insertSrcType.getShape());

     srcDims.back() =

         isNumElemsShrink ? srcDims.back() / ratio : srcDims.back() * ratio;

     VectorType newCastSrcType =

         VectorType::get(srcDims, castDstType.getElementType());

     auto newCastSrcOp = rewriter.create<vector::BitCastOp>(

         bitcastOp.getLoc(), newCastSrcType, insertOp.getSource());


     SmallVector<int64_t> dstDims(insertOp.getDestVectorType().getShape());

     dstDims.back() =

         isNumElemsShrink ? dstDims.back() / ratio : dstDims.back() * ratio;

     VectorType newCastDstType =

         VectorType::get(dstDims, castDstType.getElementType());


     // Bitcast the destination.

     auto newCastDstOp = rewriter.create<vector::BitCastOp>(

         bitcastOp.getLoc(), newCastDstType, insertOp.getDest());


     // Generate new insert.

     rewriter.replaceOpWithNewOp<vector::InsertOp>(

         bitcastOp, newCastSrcOp, newCastDstOp, insertOp.getMixedPosition());

     return success();

   }

 };


 // Shuffles vector.bitcast op before vector.insert_strided_slice op.

 //

 // This transforms IR like:

 //   %0 = vector.insert_strided_slice %src, %dst {

 //          offsets = [0], strides = [1]} : vector<4xf16> into vector<8xf16>

 //   %1 = vector.bitcast %0: vector<8xf16> to vector<4xf32>

 // Into:

 //   %0 = vector.bitcast %src : vector<4xf16> to vector<2xf32>

 //   %1 = vector.bitcast %dst : vector<8xf16> to vector<4xf32>

 //   %2 = vector.insert_strided_slice %src, %dst {

 //          offsets = [0], strides = [1]} : vector<2xf32> into vector<4xf32>

 struct BubbleUpBitCastForStridedSliceInsert

     : public OpRewritePattern<vector::BitCastOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::BitCastOp bitcastOp,

                                 PatternRewriter &rewriter) const override {

     VectorType castSrcType = bitcastOp.getSourceVectorType();

     VectorType castDstType = bitcastOp.getResultVectorType();

     assert(castSrcType.getRank() == castDstType.getRank());

     // Skip 0-D vector which will not from InsertStridedSliceOp.

     if (castSrcType.getRank() == 0)

       return failure();


     int64_t castSrcLastDim = castSrcType.getShape().back();

     int64_t castDstLastDim = castDstType.getShape().back();

     // Require casting to less elements for now; other cases to be implemented.

     if (castSrcLastDim < castDstLastDim)

       return failure();


     assert(castSrcLastDim % castDstLastDim == 0);

     int64_t shrinkRatio = castSrcLastDim / castDstLastDim;


     auto insertOp =

         bitcastOp.getSource().getDefiningOp<vector::InsertStridedSliceOp>();

     if (!insertOp)

       return failure();


     // Only accept all one strides for now.

     if (llvm::any_of(insertOp.getStrides().getAsValueRange<IntegerAttr>(),

                      [](const APInt &val) { return !val.isOne(); }))

       return failure();


     unsigned rank = insertOp.getSourceVectorType().getRank();

     // Require insert op to have the same rank for the source and destination

     // vector; other cases to be implemented.

     if (rank != insertOp.getDestVectorType().getRank())

       return failure();


     // Requires that shape of insert op src is castable to dstType.

     unsigned sourceWidth = castSrcType.getElementType().getIntOrFloatBitWidth();

     unsigned destinationWidth =

         castDstType.getElementType().getIntOrFloatBitWidth();

     unsigned numElements = destinationWidth / sourceWidth;

     if (insertOp.getSourceVectorType().getNumElements() % numElements != 0)

       return failure();


     ArrayAttr newOffsets = insertOp.getOffsets();

     assert(newOffsets.size() == rank);

     SmallVector<int64_t> offsets = getIntValueVector(newOffsets);

     if (offsets.back() % shrinkRatio != 0)

       return failure();

     offsets.back() = offsets.back() / shrinkRatio;

     newOffsets = rewriter.getI64ArrayAttr(offsets);


     SmallVector<int64_t> srcDims =

         llvm::to_vector<4>(insertOp.getSourceVectorType().getShape());

     srcDims.back() = srcDims.back() / shrinkRatio;

     VectorType newCastSrcType =

         VectorType::get(srcDims, castDstType.getElementType());


     auto newCastSrcOp = rewriter.create<vector::BitCastOp>(

         bitcastOp.getLoc(), newCastSrcType, insertOp.getSource());


     SmallVector<int64_t> dstDims =

         llvm::to_vector<4>(insertOp.getDestVectorType().getShape());

     dstDims.back() = dstDims.back() / shrinkRatio;

     VectorType newCastDstType =

         VectorType::get(dstDims, castDstType.getElementType());


     auto newCastDstOp = rewriter.create<vector::BitCastOp>(

         bitcastOp.getLoc(), newCastDstType, insertOp.getDest());


     rewriter.replaceOpWithNewOp<vector::InsertStridedSliceOp>(

         bitcastOp, bitcastOp.getType(), newCastSrcOp, newCastDstOp, newOffsets,

         insertOp.getStrides());


     return success();

   }

 };


 // Breaks down vector.bitcast op

 //

 // This transforms IR like:

 //   %1 = vector.bitcast %0: vector<8xf16> to vector<4xf32>

 // Into:

 //   %cst = vector.splat %c0_f32 : vector<4xf32>

 //   %1 = vector.extract_strided_slice %0 {

 //          offsets = [0], sizes = [4], strides = [1]

 //        } : vector<8xf16> to vector<4xf16>

 //   %2 = vector.bitcast %1 : vector<4xf16> to vector<2xf32>

 //   %4 = vector.insert_strided_slice %2, %cst {

 //          offsets = [0], strides = [1]} : vector<2xf32> into vector<4xf32>

 //   %5 = vector.extract_strided_slice %0 {

 //          offsets = [4], sizes = [4], strides = [1]

 //        } : vector<8xf16> to vector<4xf16>

 //   %6 = vector.bitcast %5 : vector<4xf16> to vector<2xf32>

 //   %7 = vector.insert_strided_slice %6, %cst {

 //          offsets = [2], strides = [1]} : vector<2xf32> into vector<4xf32>

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

   using OpRewritePattern::OpRewritePattern;


 public:

   BreakDownVectorBitCast(MLIRContext *context,

                          std::function<bool(vector::BitCastOp)> controlFn,

                          PatternBenefit benefit)

       : OpRewritePattern(context, benefit), controlFn(std::move(controlFn)) {}


   LogicalResult matchAndRewrite(vector::BitCastOp bitcastOp,

                                 PatternRewriter &rewriter) const override {


     if (controlFn && !controlFn(bitcastOp))

       return failure();


     VectorType castSrcType = bitcastOp.getSourceVectorType();

     VectorType castDstType = bitcastOp.getResultVectorType();

     assert(castSrcType.getRank() == castDstType.getRank());


     // Only support rank 1 case for now.

     if (castSrcType.getRank() != 1)

       return failure();


     int64_t castSrcLastDim = castSrcType.getShape().back();

     int64_t castDstLastDim = castDstType.getShape().back();

     // Require casting to less elements for now; other cases to be implemented.

     if (castSrcLastDim < castDstLastDim)

       return failure();


     assert(castSrcLastDim % castDstLastDim == 0);

     int64_t shrinkRatio = castSrcLastDim / castDstLastDim;

     // Nothing to do if it is already bitcasting to a single element.

     if (castSrcLastDim == shrinkRatio)

       return failure();


     Location loc = bitcastOp.getLoc();

     Type elemType = castDstType.getElementType();

     assert(elemType.isSignlessIntOrIndexOrFloat());


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

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

     Value res = rewriter.create<SplatOp>(loc, castDstType, zero);


     SmallVector<int64_t> sliceShape{castDstLastDim};

     SmallVector<int64_t> strides{1};

     VectorType newCastDstType =

         VectorType::get(SmallVector<int64_t>{castDstLastDim / shrinkRatio},

                         castDstType.getElementType());


     for (int i = 0, e = shrinkRatio; i < e; ++i) {

       Value extracted = rewriter.create<ExtractStridedSliceOp>(

           loc, bitcastOp.getSource(), ArrayRef<int64_t>{i * castDstLastDim},

           sliceShape, strides);

       Value bitcast =

           rewriter.create<BitCastOp>(loc, newCastDstType, extracted);

       res = rewriter.create<InsertStridedSliceOp>(

           loc, bitcast, res,

           ArrayRef<int64_t>{i * castDstLastDim / shrinkRatio}, strides);

     }

     rewriter.replaceOp(bitcastOp, res);

     return success();

   }


 private:

   std::function<bool(BitCastOp)> controlFn;

 };


 /// Reorders elementwise(broadcast/splat) to broadcast(elementwise). Ex:

 /// ```

 /// %a = vector.broadcast %arg1 : index to vector<1x4xindex>

 /// %b = vector.broadcast %arg2 : index to vector<1x4xindex>

 /// %r = arith.addi %a, %b : vector<1x4xindex>

 /// ```

 /// Gets converted to:

 /// ```

 /// %r = arith.addi %arg0, %arg1 : index

 /// %b = vector.broadcast %r : index to vector<1x4xindex>

 /// ```

 ///

 /// Both `vector.broadcast` and `vector.splat` are supported as broadcasting

 /// ops.

 struct ReorderElementwiseOpsOnBroadcast final

     : public OpTraitRewritePattern<OpTrait::Elementwise> {

   using OpTraitRewritePattern::OpTraitRewritePattern;

   LogicalResult matchAndRewrite(Operation *op,

                                 PatternRewriter &rewriter) const override {

     if (op->getNumResults() != 1)

       return failure();

     if (!llvm::isa<ShapedType>(op->getResults()[0].getType()))

       return failure();

     if (!OpTrait::hasElementwiseMappableTraits(op))

       return rewriter.notifyMatchFailure(

           op, "Op doesn't have ElementwiseMappableTraits");

     if (op->getNumOperands() == 0)

       return failure();

     if (op->getResults()[0].getType() != op->getOperand(0).getType())

       return rewriter.notifyMatchFailure(op,

                                          "result and operand type mismatch");

     if (isa<vector::FMAOp>(op)) {

       return rewriter.notifyMatchFailure(

           op,

           "Op only accepts vector types - not supported as broadcast source "

           "might be a scalar");

     }


     // Get the type of the lhs operand

     auto *lhsBcastOrSplat = op->getOperand(0).getDefiningOp();

     if (!lhsBcastOrSplat ||

         !isa<vector::BroadcastOp, vector::SplatOp>(*lhsBcastOrSplat))

       return failure();

     auto lhsBcastOrSplatType = lhsBcastOrSplat->getOperand(0).getType();


     // Make sure that all operands are broadcast from identical types:

     //  * scalar (`vector.broadcast` + `vector.splat`), or

     //  * vector (`vector.broadcast`).

     // Otherwise the re-ordering wouldn't be safe.

     if (!llvm::all_of(op->getOperands(), [&lhsBcastOrSplatType](Value val) {

           auto bcast = val.getDefiningOp<vector::BroadcastOp>();

           if (bcast)

             return (bcast.getOperand().getType() == lhsBcastOrSplatType);

           auto splat = val.getDefiningOp<vector::SplatOp>();

           if (splat)

             return (splat.getOperand().getType() == lhsBcastOrSplatType);

           return false;

         })) {

       return failure();

     }


     // Collect the source values before broadcasting

     SmallVector<Value> srcValues;

     srcValues.reserve(op->getNumOperands());

     for (Value operand : op->getOperands()) {

       srcValues.push_back(operand.getDefiningOp()->getOperand(0));

     }


     // Create the "elementwise" Op

     Operation *elementwiseOp =

         rewriter.create(op->getLoc(), op->getName().getIdentifier(), srcValues,

                         lhsBcastOrSplatType, op->getAttrs());


     // Replace the original Op with the elementwise Op

     auto vectorType = op->getResultTypes()[0];

     rewriter.replaceOpWithNewOp<vector::BroadcastOp>(

         op, vectorType, elementwiseOp->getResults());


     return success();

   }

 };


 // Helper that returns a vector comparison that constructs a mask:

 //     mask = [0,1,..,n-1] + [o,o,..,o] < [b,b,..,b]

 //

 // If `dim == 0` then the result will be a 0-D vector.

 //

 // NOTE: The LLVM::GetActiveLaneMaskOp intrinsic would provide an alternative,

 //       much more compact, IR for this operation, but LLVM eventually

 //       generates more elaborate instructions for this intrinsic since it

 //       is very conservative on the boundary conditions.

 static Value buildVectorComparison(PatternRewriter &rewriter, Operation *op,

                                    bool force32BitVectorIndices, int64_t dim,

                                    Value b, Value *off = nullptr) {

   auto loc = op->getLoc();

   // If we can assume all indices fit in 32-bit, we perform the vector

   // comparison in 32-bit to get a higher degree of SIMD parallelism.

   // Otherwise we perform the vector comparison using 64-bit indices.

   Type idxType =

       force32BitVectorIndices ? rewriter.getI32Type() : rewriter.getI64Type();

   DenseIntElementsAttr indicesAttr;

   if (dim == 0 && force32BitVectorIndices) {

     indicesAttr = DenseIntElementsAttr::get(

         VectorType::get(ArrayRef<int64_t>{}, idxType), ArrayRef<int32_t>{0});

   } else if (dim == 0) {

     indicesAttr = DenseIntElementsAttr::get(

         VectorType::get(ArrayRef<int64_t>{}, idxType), ArrayRef<int64_t>{0});

   } else if (force32BitVectorIndices) {

     indicesAttr = rewriter.getI32VectorAttr(

         llvm::to_vector<4>(llvm::seq<int32_t>(0, dim)));

   } else {

     indicesAttr = rewriter.getI64VectorAttr(

         llvm::to_vector<4>(llvm::seq<int64_t>(0, dim)));

   }

   Value indices = rewriter.create<arith::ConstantOp>(loc, indicesAttr);

   // Add in an offset if requested.

   if (off) {

     Value o = getValueOrCreateCastToIndexLike(rewriter, loc, idxType, *off);

     Value ov = rewriter.create<vector::SplatOp>(loc, indices.getType(), o);

     indices = rewriter.create<arith::AddIOp>(loc, ov, indices);

   }

   // Construct the vector comparison.

   Value bound = getValueOrCreateCastToIndexLike(rewriter, loc, idxType, b);

   Value bounds =

       rewriter.create<vector::SplatOp>(loc, indices.getType(), bound);

   return rewriter.create<arith::CmpIOp>(loc, arith::CmpIPredicate::slt, indices,

                                         bounds);

 }


 template <typename ConcreteOp>

 struct MaterializeTransferMask : public OpRewritePattern<ConcreteOp> {

 public:

   explicit MaterializeTransferMask(MLIRContext *context, bool enableIndexOpt,

                                    PatternBenefit benefit = 1)

       : mlir::OpRewritePattern<ConcreteOp>(context, benefit),

         force32BitVectorIndices(enableIndexOpt) {}


   LogicalResult matchAndRewrite(ConcreteOp xferOp,

                                 PatternRewriter &rewriter) const override {

     if (!xferOp.hasOutOfBoundsDim())

       return failure();


     if (xferOp.getVectorType().getRank() > 1 || xferOp.getIndices().empty())

       return failure();


     Location loc = xferOp->getLoc();

     VectorType vtp = xferOp.getVectorType();


     // Create the in-bounds mask with all elements between [0 .. dim - offset)

     // set and [dim - offset .. vector_length) unset.

     //

     // TODO: when the leaf transfer rank is k > 1, we need the last `k`

     //       dimensions here.

     unsigned lastIndex = llvm::size(xferOp.getIndices()) - 1;

     Value off = xferOp.getIndices()[lastIndex];

     Value dim =

         vector::createOrFoldDimOp(rewriter, loc, xferOp.getSource(), lastIndex);

     Value b = rewriter.create<arith::SubIOp>(loc, dim.getType(), dim, off);

     Value mask = rewriter.create<vector::CreateMaskOp>(

         loc,

         VectorType::get(vtp.getShape(), rewriter.getI1Type(),

                         vtp.getScalableDims()),

         b);

     if (xferOp.getMask()) {

       // Intersect the in-bounds with the mask specified as an op parameter.

       mask = rewriter.create<arith::AndIOp>(loc, mask, xferOp.getMask());

     }


     rewriter.modifyOpInPlace(xferOp, [&]() {

       xferOp.getMaskMutable().assign(mask);

       xferOp.setInBoundsAttr(rewriter.getBoolArrayAttr({true}));

     });


     return success();

   }


 private:

   const bool force32BitVectorIndices;

 };


 /// Conversion pattern for a `vector.create_mask` (0-D and 1-D only).

 class VectorCreateMaskOpConversion

     : public OpRewritePattern<vector::CreateMaskOp> {

 public:

   explicit VectorCreateMaskOpConversion(MLIRContext *context,

                                         bool enableIndexOpt,

                                         PatternBenefit benefit = 1)

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

         force32BitVectorIndices(enableIndexOpt) {}


   LogicalResult matchAndRewrite(vector::CreateMaskOp op,

                                 PatternRewriter &rewriter) const override {

     auto dstType = op.getType();

     if (cast<VectorType>(dstType).isScalable())

       return failure();

     int64_t rank = dstType.getRank();

     if (rank > 1)

       return failure();

     rewriter.replaceOp(

         op, buildVectorComparison(rewriter, op, force32BitVectorIndices,

                                   rank == 0 ? 0 : dstType.getDimSize(0),

                                   op.getOperand(0)));

     return success();

   }


 private:

   const bool force32BitVectorIndices;

 };


 /// Returns true if all the `i1` elements of `constantOp` are set to `value`.

 static bool allI1ConstantValuesSetTo(arith::ConstantOp constantOp, bool value) {

   auto denseAttr = dyn_cast<DenseIntElementsAttr>(constantOp.getValue());

   // TODO: Support non-dense constant.

   if (!denseAttr)

     return false;


   assert(denseAttr.getElementType().isInteger(1) && "Unexpected type");

   return denseAttr.isSplat() && denseAttr.getSplatValue<bool>() == value;

 }


 /// Folds a select operation between an all-true and all-false vector. For now,

 /// only single element vectors (i.e., vector<1xi1>) are supported. That is:

 ///

 ///   %true = arith.constant dense<true> : vector<1xi1>

 ///   %false = arith.constant dense<false> : vector<1xi1>

 ///   %result = arith.select %cond, %true, %false : i1, vector<1xi1>

 ///   =>

 ///   %result = vector.broadcast %cond : i1 to vector<1xi1>

 ///

 /// InstCombine seems to handle vectors with multiple elements but not the

 /// single element ones.

 struct FoldI1Select : public OpRewritePattern<arith::SelectOp> {

   using OpRewritePattern<arith::SelectOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(arith::SelectOp selectOp,

                                 PatternRewriter &rewriter) const override {

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

     if (!vecType || !vecType.getElementType().isInteger(1))

       return failure();


     // Only scalar conditions can be folded.

     Value cond = selectOp.getCondition();

     if (isa<VectorType>(cond.getType()))

       return failure();


     // TODO: Support n-D and scalable vectors.

     if (vecType.getRank() != 1 || vecType.isScalable())

       return failure();


     // TODO: Support vectors with multiple elements.

     if (vecType.getShape()[0] != 1)

       return failure();


     auto trueConst = selectOp.getTrueValue().getDefiningOp<arith::ConstantOp>();

     if (!trueConst || !allI1ConstantValuesSetTo(trueConst, true))

       return failure();


     auto falseConst =

         selectOp.getFalseValue().getDefiningOp<arith::ConstantOp>();

     if (!falseConst || !allI1ConstantValuesSetTo(falseConst, false))

       return failure();


     // Replace select with its condition broadcasted to single element vector.

     auto elemType = rewriter.getIntegerType(vecType.getNumElements());

     auto bcastType = VectorType::get(/*shape=*/{1}, elemType);

     rewriter.replaceOpWithNewOp<vector::BroadcastOp>(selectOp, bcastType, cond);

     return success();

   }

 };


 /// Returns the number of dims can be folded away from transfer ops. It returns

 /// a failure if it can not determine the number of dims to be folded.

 ///

 /// Ex 1: returns "2" if `srcType` is memref<512x16x1x1xf32> and

 /// `vectorType` is vector<16x16x1x1xf32>

 /// (there two inner most dims can be dropped by memref.subview ops)

 ///

 /// Ex 2: returns "1" if `srcType` is memref<512x16x1x1xf32> with

 /// [8192, 16, 8, 1] strides and `vectorType` is vector<16x16x1x1xf32>

 /// (only the inner most unit dim of `srcType` can be dropped)

 ///

 /// Ex 3: return "0" if `srcType` is memref<512x16x1x1xf32> and

 /// `vectorType` is vector<16x16x1x[1]xf32>

 /// (the most inner dim in `vectorType` is not a unit dim (it's a "scalable

 /// unit")

 static FailureOr<size_t>

 getTransferFoldableInnerUnitDims(MemRefType srcType, VectorType vectorType) {

   SmallVector<int64_t> srcStrides;

   int64_t srcOffset;

   if (failed(getStridesAndOffset(srcType, srcStrides, srcOffset)))

     return failure();


   auto isUnitDim = [](VectorType type, int dim) {

     return type.getDimSize(dim) == 1 && !type.getScalableDims()[dim];

   };


   // According to vector.transfer_read/write semantics, the vector can be a

   // slice. Thus, we have to offset the check index with `rankDiff` in

   // `srcStrides` and source dim sizes.

   size_t result = 0;

   int rankDiff = srcType.getRank() - vectorType.getRank();

   for (int64_t i = 0, e = vectorType.getRank(); i < e; ++i) {

     // Check that the inner dim size is 1 for both memref type and vector slice.

     // It can be folded only if they are 1 and the stride is 1.

     int dim = vectorType.getRank() - i - 1;

     if (srcStrides[dim + rankDiff] != 1 ||

         srcType.getDimSize(dim + rankDiff) != 1 || !isUnitDim(vectorType, dim))

       break;

     result++;

   }

   return result;

 }


 /// Drop inner most contiguous unit dimensions from transfer_read operand.

 class DropInnerMostUnitDimsTransferRead

     : public OpRewritePattern<vector::TransferReadOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::TransferReadOp readOp,

                                 PatternRewriter &rewriter) const override {

     // TODO: support 0-d corner case.

     if (readOp.getTransferRank() == 0)

       return failure();


     // TODO: support mask.

     if (readOp.getMask())

       return failure();


     auto srcType = dyn_cast<MemRefType>(readOp.getSource().getType());

     if (!srcType)

       return failure();


     if (!readOp.getPermutationMap().isMinorIdentity())

       return failure();


     auto targetType = readOp.getVectorType();

     if (targetType.getRank() <= 1)

       return failure();


     FailureOr<size_t> maybeDimsToDrop =

         getTransferFoldableInnerUnitDims(srcType, targetType);

     if (failed(maybeDimsToDrop))

       return failure();


     size_t dimsToDrop = maybeDimsToDrop.value();

     if (dimsToDrop == 0)

       return failure();


     auto inBounds = readOp.getInBoundsValues();

     auto droppedInBounds = ArrayRef<bool>(inBounds).take_back(dimsToDrop);

     if (llvm::is_contained(droppedInBounds, false))

       return failure();


     auto resultTargetVecType =

         VectorType::get(targetType.getShape().drop_back(dimsToDrop),

                         targetType.getElementType(),

                         targetType.getScalableDims().drop_back(dimsToDrop));


     auto loc = readOp.getLoc();

     SmallVector<OpFoldResult> sizes =

         memref::getMixedSizes(rewriter, loc, readOp.getSource());

     SmallVector<OpFoldResult> offsets(srcType.getRank(),

                                       rewriter.getIndexAttr(0));

     SmallVector<OpFoldResult> strides(srcType.getRank(),

                                       rewriter.getIndexAttr(1));

     auto resultMemrefType =

         cast<MemRefType>(memref::SubViewOp::inferRankReducedResultType(

             srcType.getShape().drop_back(dimsToDrop), srcType, offsets, sizes,

             strides));

     ArrayAttr inBoundsAttr = rewriter.getArrayAttr(

         readOp.getInBoundsAttr().getValue().drop_back(dimsToDrop));

     Value rankedReducedView = rewriter.create<memref::SubViewOp>(

         loc, resultMemrefType, readOp.getSource(), offsets, sizes, strides);

     auto permMap = getTransferMinorIdentityMap(

         cast<ShapedType>(rankedReducedView.getType()), resultTargetVecType);

     Value result = rewriter.create<vector::TransferReadOp>(

         loc, resultTargetVecType, rankedReducedView,

         readOp.getIndices().drop_back(dimsToDrop), AffineMapAttr::get(permMap),

         readOp.getPadding(),

         // TODO: support mask.

         /*mask=*/Value(), inBoundsAttr);

     rewriter.replaceOpWithNewOp<vector::ShapeCastOp>(readOp, targetType,

                                                      result);

     return success();

   }

 };


 /// Drop inner most contiguous unit dimensions from transfer_write operand.

 /// E.g.,

 ///    vector.transfer_write %arg1, %arg0[%c0, %arg2, %c0, %c0, %c0]

 ///      {in_bounds = [true, true, true, true, true]}

 ///      : vector<1x16x16x1x1xf32>, memref<1x512x16x1x1xf32>

 ///

 /// will be replaced with

 ///

 ///    %subview = memref.subview %arg0

 ///      [0, 0, 0, 0, 0] [1, 512, 16, 1, 1] [1, 1, 1, 1, 1]

 ///      : memref<1x512x16x1x1xf32> to memref<1x512x16xf32>

 ///    %0 = vector.shape_cast %arg1 : vector<1x16x16x1x1xf32>

 ///      to vector<1x16x16xf32>

 ///    vector.transfer_write %0, %subview[%c0, %arg2, %c0]

 ///      {in_bounds = [true, true, true]}

 ///      : vector<1x16x16xf32>, memref<1x512x16xf32>

 ///

 /// Note, this pattern will not collapse "scalable unit" dims (i.e. `[1]`).

 class DropInnerMostUnitDimsTransferWrite

     : public OpRewritePattern<vector::TransferWriteOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::TransferWriteOp writeOp,

                                 PatternRewriter &rewriter) const override {

     // TODO: support 0-d corner case.

     if (writeOp.getTransferRank() == 0)

       return failure();


     // TODO: support mask.

     if (writeOp.getMask())

       return failure();


     auto srcType = dyn_cast<MemRefType>(writeOp.getSource().getType());

     if (!srcType)

       return failure();


     if (!writeOp.getPermutationMap().isMinorIdentity())

       return failure();


     auto targetType = writeOp.getVectorType();

     if (targetType.getRank() <= 1)

       return failure();


     FailureOr<size_t> maybeDimsToDrop =

         getTransferFoldableInnerUnitDims(srcType, targetType);

     if (failed(maybeDimsToDrop))

       return failure();


     size_t dimsToDrop = maybeDimsToDrop.value();

     if (dimsToDrop == 0)

       return failure();


     auto inBounds = writeOp.getInBoundsValues();

     auto droppedInBounds = ArrayRef<bool>(inBounds).take_back(dimsToDrop);

     if (llvm::is_contained(droppedInBounds, false))

       return failure();


     auto resultTargetVecType =

         VectorType::get(targetType.getShape().drop_back(dimsToDrop),

                         targetType.getElementType(),

                         targetType.getScalableDims().drop_back(dimsToDrop));


     Location loc = writeOp.getLoc();

     SmallVector<OpFoldResult> sizes =

         memref::getMixedSizes(rewriter, loc, writeOp.getSource());

     SmallVector<OpFoldResult> offsets(srcType.getRank(),

                                       rewriter.getIndexAttr(0));

     SmallVector<OpFoldResult> strides(srcType.getRank(),

                                       rewriter.getIndexAttr(1));

     auto resultMemrefType =

         cast<MemRefType>(memref::SubViewOp::inferRankReducedResultType(

             srcType.getShape().drop_back(dimsToDrop), srcType, offsets, sizes,

             strides));

     ArrayAttr inBoundsAttr = rewriter.getArrayAttr(

         writeOp.getInBoundsAttr().getValue().drop_back(dimsToDrop));


     Value rankedReducedView = rewriter.create<memref::SubViewOp>(

         loc, resultMemrefType, writeOp.getSource(), offsets, sizes, strides);

     auto permMap = getTransferMinorIdentityMap(

         cast<ShapedType>(rankedReducedView.getType()), resultTargetVecType);


     auto shapeCast = rewriter.createOrFold<vector::ShapeCastOp>(

         loc, resultTargetVecType, writeOp.getVector());

     rewriter.replaceOpWithNewOp<vector::TransferWriteOp>(

         writeOp, shapeCast, rankedReducedView,

         writeOp.getIndices().drop_back(dimsToDrop), AffineMapAttr::get(permMap),

         // TODO: support mask.

         /*mask=*/Value(), inBoundsAttr);

     return success();

   }

 };


 /// Canonicalization of a `vector.contraction %a, %b, %c` with row-major matmul

 /// semantics to a contraction suitable for MMT (matrix matrix multiplication

 /// with the RHS transposed) lowering.

 struct CanonicalizeContractMatmulToMMT final

     : OpRewritePattern<vector::ContractionOp> {

   using OpRewritePattern::OpRewritePattern;


   using FilterConstraintType =

       std::function<LogicalResult(vector::ContractionOp op)>;


   CanonicalizeContractMatmulToMMT(MLIRContext *context, PatternBenefit benefit,

                                   FilterConstraintType constraint)

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

         filter(std::move(constraint)) {}


   LogicalResult matchAndRewrite(vector::ContractionOp op,

                                 PatternRewriter &rewriter) const override {

     if (failed(filter(op)))

       return failure();


     Location loc = op.getLoc();

     Value lhs = op.getLhs();

     Value rhs = op.getRhs();

     Value res = op.getAcc();


     // Set up the parallel/reduction structure in right form.

     using MapList = ArrayRef<ArrayRef<AffineExpr>>;

     auto infer = [&](MapList m) {

       return AffineMap::inferFromExprList(m, op.getContext());

     };

     AffineExpr m;

     AffineExpr n;

     AffineExpr k;

     bindDims(rewriter.getContext(), m, n, k);

     static constexpr std::array<int64_t, 2> perm = {1, 0};

     auto iteratorTypes = op.getIteratorTypes().getValue();

     SmallVector<AffineMap, 4> maps = op.getIndexingMapsArray();

     if (iteratorTypes.size() != 3 ||

         !vector::isParallelIterator(iteratorTypes[0]) ||

         !vector::isParallelIterator(iteratorTypes[1]) ||

         !vector::isReductionIterator(iteratorTypes[2]))

       return rewriter.notifyMatchFailure(op, "contraction is not a gemm");


     // The canonical form is "TNT" = A row-major, B col-major, C row-major.

     const auto canonicalForm = infer({{m, k}, {n, k}, {m, n}});

     if (maps == canonicalForm)

       return rewriter.notifyMatchFailure(op, "already in the canonical form");


     // Create a vector transpose making sure to emit zero/sign-extend at the

     // end.

     auto createTranspose = [&rewriter, loc](Value mat) -> Value {

       if (auto sext = mat.getDefiningOp<arith::ExtSIOp>()) {

         Value trans =

             rewriter.create<vector::TransposeOp>(loc, sext.getIn(), perm);

         VectorType newType =

             cast<VectorType>(trans.getType())

                 .clone(cast<VectorType>(mat.getType()).getElementType());

         return rewriter.create<arith::ExtSIOp>(loc, newType, trans);

       }

       if (auto zext = mat.getDefiningOp<arith::ExtUIOp>()) {

         Value trans =

             rewriter.create<vector::TransposeOp>(loc, zext.getIn(), perm);

         VectorType newType =

             VectorType::get(cast<VectorType>(trans.getType()).getShape(),

                             cast<VectorType>(mat.getType()).getElementType());

         return rewriter.create<arith::ExtUIOp>(loc, newType, trans);

       }

       return rewriter.create<vector::TransposeOp>(loc, mat, perm);

     };


     if (maps == infer({{m, k}, {k, n}, {m, n}})) {

       rhs = createTranspose(rhs);

     } else if (maps == infer({{k, m}, {n, k}, {m, n}})) {

       lhs = createTranspose(lhs);

     } else if (maps == infer({{k, m}, {k, n}, {m, n}})) {

       rhs = createTranspose(rhs);

       lhs = createTranspose(lhs);

     } else if (maps == infer({{k, m}, {k, n}, {n, m}})) {

       std::swap(rhs, lhs);

       rhs = createTranspose(rhs);

       lhs = createTranspose(lhs);

     } else if (maps == infer({{k, m}, {n, k}, {n, m}})) {

       std::swap(rhs, lhs);

       rhs = createTranspose(rhs);

     } else if (maps == infer({{m, k}, {k, n}, {n, m}})) {

       std::swap(lhs, rhs);

       lhs = createTranspose(lhs);

     } else if (maps == infer({{m, k}, {n, k}, {n, m}})) {

       std::swap(lhs, rhs);

     } else {

       return rewriter.notifyMatchFailure(op, "unhandled contraction form");

     }

     rewriter.replaceOpWithNewOp<vector::ContractionOp>(

         op, lhs, rhs, res, rewriter.getAffineMapArrayAttr(canonicalForm),

         op.getIteratorTypes());

     return success();

   };


 private:

   FilterConstraintType filter;

 };


 /// Pattern to fold arithmetic extensions on floating point data types into

 /// vector contraction operations. linalg.matmul introduces arithmetic

 /// extensions on its operands. Please mlir snippets below for more details.

 /// ```mlir

 ///   "linalg.matmul"(%lhs, %rhs, %acc) ({

 ///      ^bb0(%arg1: f16, %arg2: f16, %arg3: f32):

 ///        %lhs_f32 = "arith.extf"(%arg1) : (f16) -> f32

 ///        %rhs_f32 = "arith.extf"(%arg2) : (f16) -> f32

 ///        %mul = "arith.mulf"(%lhs_f32, %rhs_f32) : (f32, f32) -> f32

 ///        %acc = "arith.addf"(%arg3, %mul) : (f32, f32) -> f32

 ///        "linalg.yield"(%acc) : (f32) -> ()

 ///     })

 /// ```

 /// This restricts the native usage of mixed precision NVIDIA Ampere Tensor

 /// Cores, i.e, `mma.sync.*.f32.f16.f16.f32` and `mma.sync.*.f32.bf16.bf16.f32`.

 /// This pattern folds the arithmetic extensions into the vector contraction and

 /// enables the usage of native mixed precision Tensor Core instructions.

 template <typename ExtOp>

 struct FoldArithExtIntoContractionOp

     : public OpRewritePattern<vector::ContractionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ContractionOp contractOp,

                                 PatternRewriter &rewriter) const override {


     auto lhsDefOp = contractOp.getLhs().getDefiningOp<ExtOp>();

     auto rhsDefOp = contractOp.getRhs().getDefiningOp<ExtOp>();


     if (!lhsDefOp || !rhsDefOp) {

       return rewriter.notifyMatchFailure(contractOp,

                                          "no defining op on contract operands");

     }


     rewriter.replaceOpWithNewOp<vector::ContractionOp>(

         contractOp, lhsDefOp->getOperand(0), rhsDefOp->getOperand(0),

         contractOp.getAcc(), contractOp.getIndexingMapsAttr(),

         contractOp.getIteratorTypesAttr());


     return success();

   }

 };


 /// Pattern to fold chained reduction to a series of vector additions and a

 /// final reduction. This form should require fewer subgroup operations.

 ///

 /// ```mlir

 /// %a = vector.reduction <add> %x, %acc

 /// %b = vector.reduction <add> %y, %a

 ///  ==>

 /// %a = arith.addf %x, %y

 /// %b = vector.reduction <add> %a, %acc

 /// ```

 struct ChainedReduction final : OpRewritePattern<vector::ReductionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ReductionOp op,

                                 PatternRewriter &rewriter) const override {

     // TODO: Handle other combining kinds.

     if (op.getKind() != vector::CombiningKind::ADD)

       return failure();


     // Accumulator is optional.

     Value acc = op.getAcc();

     if (!acc)

       return failure();


     if (!acc.getType().isIntOrFloat())

       return failure();


     auto parentReduction = acc.getDefiningOp<vector::ReductionOp>();

     if (!parentReduction)

       return failure();


     Location loc = op.getLoc();

     Value vAdd;

     if (isa<IntegerType>(acc.getType())) {

       vAdd = rewriter.createOrFold<arith::AddIOp>(

           loc, parentReduction.getVector(), op.getVector());

     } else {

       vAdd = rewriter.create<arith::AddFOp>(loc, parentReduction.getVector(),

                                             op.getVector());

     }

     rewriter.replaceOpWithNewOp<vector::ReductionOp>(op, op.getKind(), vAdd,

                                                      parentReduction.getAcc());

     return success();

   }

 };


 // Helper function dropping unit non-scalable dimension from a VectorType

 // keeping at least 1 dimension to avoid generating 0-D vectors. Scalable unit

 // dimensions are not dropped. Folding such dimensions would require "shifting"

 // the scalable flag onto some other fixed-width dim (e.g. vector<[1]x4xf32> ->

 // vector<[4]xf32>). This could be implemented in the future.

 static VectorType dropNonScalableUnitDimFromType(VectorType inVecTy) {

   auto inVecShape = inVecTy.getShape();

   SmallVector<int64_t> newShape;

   SmallVector<bool> newScalableDims;

   for (auto [dim, isScalable] :

        llvm::zip_equal(inVecShape, inVecTy.getScalableDims())) {

     if (dim == 1 && !isScalable)

       continue;


     newShape.push_back(dim);

     newScalableDims.push_back(isScalable);

   }

   // All dims have been dropped, return vector<1xeType>.

   if (newShape.empty()) {

     newShape.push_back(1);

     newScalableDims.push_back(false);

   }


   return VectorType::get(newShape, inVecTy.getElementType(), newScalableDims);

 }


 /// For vectors with at least one unit dim, replaces:

 ///   elementwise(a, b)

 /// with:

 ///   sc_a = shape_cast(a)

 ///   sc_b = shape_cast(b)

 ///   res = elementwise(sc_a, sc_b)

 ///   return shape_cast(res)

 /// The newly inserted shape_cast Ops fold (before elementwise Op) and then

 /// restore (after elementwise Op) the unit dim. Vectors `a` and `b` are

 /// required to be rank > 1.

 ///

 /// Ex:

 ///  %mul = arith.mulf %B_row, %A_row : vector<1x[4]xf32>

 ///  %cast = vector.shape_cast %mul : vector<1x[4]xf32> to vector<[4]xf32>

 ///

 /// gets converted to:

 ///

 ///  %B_row_sc = vector.shape_cast %B_row : vector<1x[4]xf32> to vector<[4]xf32>

 ///  %A_row_sc = vector.shape_cast %A_row : vector<1x[4]xf32> to vector<[4]xf32>

 ///  %mul = arith.mulf %B_row_sc, %A_row_sc : vector<[4]xf32>

 ///  %cast_new = vector.shape_cast %mul : vector<[4]xf32> to vector<1x[4]xf32>

 ///  %cast = vector.shape_cast %cast_new : vector<1x[4]xf32> to vector<[4]xf32>

 ///

 /// Patterns for folding shape_casts should instantly eliminate `%cast_new` and

 /// `%cast`.

 struct DropUnitDimFromElementwiseOps final

     : public OpTraitRewritePattern<OpTrait::Elementwise> {

   using OpTraitRewritePattern::OpTraitRewritePattern;

   LogicalResult matchAndRewrite(Operation *op,

                                 PatternRewriter &rewriter) const override {

     if (op->getNumResults() != 1 || op->getNumRegions() != 0)

       return failure();


     auto resultVectorType = dyn_cast<VectorType>(op->getResult(0).getType());

     if (!resultVectorType)

       return failure();


     // Check the operand pre-conditions. For `Elementwise` ops all operands are

     // guaranteed to have identical shapes (with some exceptions such as

     // `arith.select`) and it suffices to only check one of them.

     auto sourceVectorType = dyn_cast<VectorType>(op->getOperand(0).getType());

     if (!sourceVectorType)

       return failure();

     if (sourceVectorType.getRank() < 2)

       return failure();


     SmallVector<Value> newOperands;

     auto loc = op->getLoc();

     for (auto operand : op->getOperands()) {

       auto opVectorType = cast<VectorType>(operand.getType());

       auto newVType = dropNonScalableUnitDimFromType(opVectorType);

       if (newVType == opVectorType)

         return rewriter.notifyMatchFailure(op, "No unit dimension to remove.");


       auto opSC = rewriter.create<vector::ShapeCastOp>(loc, newVType, operand);

       newOperands.push_back(opSC);

     }


     VectorType newResultVectorType =

         dropNonScalableUnitDimFromType(resultVectorType);

     // Create an updated elementwise Op without unit dim.

     Operation *elementwiseOp =

         rewriter.create(loc, op->getName().getIdentifier(), newOperands,

                         newResultVectorType, op->getAttrs());


     // Restore the unit dim by applying vector.shape_cast to the result.

     rewriter.replaceOpWithNewOp<ShapeCastOp>(op, resultVectorType,

                                              elementwiseOp->getResult(0));


     return success();

   }

 };


 /// A pattern to drop unit dims from vector.transpose.

 ///

 /// Example:

 ///

 ///  BEFORE:

 ///  ```mlir

 ///  %transpose = vector.transpose %vector, [3, 0, 1, 2]

 ///    : vector<1x1x4x[4]xf32> to vector<[4]x1x1x4xf32>

 ///  ```

 ///

 ///  AFTER:

 ///  ```mlir

 ///  %dropDims = vector.shape_cast %vector

 ///    : vector<1x1x4x[4]xf32> to vector<4x[4]xf32>

 ///  %transpose = vector.transpose %0, [1, 0]

 ///    : vector<4x[4]xf32> to vector<[4]x4xf32>

 ///  %restoreDims = vector.shape_cast %transpose

 ///    : vector<[4]x4xf32> to vector<[4]x1x1x4xf32>

 ///  ```

 struct DropUnitDimsFromTransposeOp final

     : OpRewritePattern<vector::TransposeOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::TransposeOp op,

                                 PatternRewriter &rewriter) const override {

     VectorType sourceType = op.getSourceVectorType();

     VectorType sourceTypeWithoutUnitDims =

         dropNonScalableUnitDimFromType(sourceType);


     if (sourceType == sourceTypeWithoutUnitDims)

       return failure();


     // Construct a map from dimIdx -> number of dims dropped before dimIdx.

     auto sourceDims = llvm::to_vector(vector::getDims(sourceType));

     SmallVector<int64_t> droppedDimsBefore(sourceType.getRank());

     int64_t droppedDims = 0;

     for (auto [i, dim] : llvm::enumerate(sourceDims)) {

       droppedDimsBefore[i] = droppedDims;

       if (dim == std::make_tuple(1, false))

         ++droppedDims;

     }


     // Drop unit dims from transpose permutation.

     ArrayRef<int64_t> perm = op.getPermutation();

     SmallVector<int64_t> newPerm;

     for (int64_t idx : perm) {

       if (sourceDims[idx] == std::make_tuple(1, false))

         continue;

       newPerm.push_back(idx - droppedDimsBefore[idx]);

     }


     // Fixup for `newPerm`. The `sourceTypeWithoutUnitDims` could be vector<1xT>

     // type when the dimensions are unit dimensions. In this case, the newPerm

     // should be [0].

     if (newPerm.empty()) {

       newPerm.push_back(0);

     }


     Location loc = op.getLoc();

     // Drop the unit dims via shape_cast.

     auto dropDimsShapeCast = rewriter.create<vector::ShapeCastOp>(

         loc, sourceTypeWithoutUnitDims, op.getVector());

     // Create the new transpose.

     auto tranposeWithoutUnitDims =

         rewriter.create<vector::TransposeOp>(loc, dropDimsShapeCast, newPerm);

     // Restore the unit dims via shape cast.

     rewriter.replaceOpWithNewOp<vector::ShapeCastOp>(

         op, op.getResultVectorType(), tranposeWithoutUnitDims);


     return success();

   }

 };


 /// A pattern to drop unit dims from the iter_args of an scf.for.

 ///

 /// Example:

 ///

 ///  BEFORE:

 ///  ```mlir

 ///  %res = scf.for ... iter_args(%iter = %init) -> vector<[4]x1x1x4xf32> {

 ///    ...

 ///    scf.yield %

 ///  }

 ///  ```

 ///

 ///  AFTER:

 ///  ```mlir

 ///  %drop = vector.shape_cast %init

 ///    : vector<4x1x1x[4]xf32> to vector<4x[4]xf32>

 ///  %new_loop = scf.for ... iter_args(%iter = %drop) -> vector<[4]x4xf32> {

 ///    %new_iter = vector.shape_cast %iter

 ///      : vector<[4]x4xf32> to vector<[4]x1x1x4xf32>

 ///    ...

 ///  }

 ///  %res = vector.shape_cast %new_loop

 ///    : vector<[4]x4xf32> to vector<[4]x1x1x4xf32>

 ///  ```

 struct DropUnitDimsFromScfForOp final : OpRewritePattern<scf::ForOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(scf::ForOp forOp,

                                 PatternRewriter &rewriter) const override {

     /// Find the first iter_arg with droppable unit dims. Further applications

     /// of this pattern will apply to later arguments.

     for (OpOperand &operand : forOp.getInitArgsMutable()) {

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

       if (!vectorType)

         continue;


       VectorType newVectorType = dropNonScalableUnitDimFromType(vectorType);

       if (vectorType == newVectorType)

         continue;


       // Create a new ForOp with that iter operand replaced.

       auto castFn = [](OpBuilder &b, Location loc, Type type, Value source) {

         return b.create<vector::ShapeCastOp>(loc, type, source);

       };


       Value replacement =

           castFn(rewriter, forOp.getLoc(), newVectorType, operand.get());

       rewriter.replaceOp(forOp,

                          replaceAndCastForOpIterArg(rewriter, forOp, operand,

                                                     replacement, castFn));

       return success();

     }

     return failure();

   }

 };


 /// Pattern to eliminate redundant zero-constants added to reduction operands.

 /// It's enough for there to be one initial zero value, so we can eliminate the

 /// extra ones that feed into `vector.reduction <add>`. These get created by the

 /// `ChainedReduction` pattern.

 ///

 /// ```mlir

 /// %a = arith.addf %x, %zero

 /// %b = arith.addf %a, %y

 /// %c = vector.reduction <add> %b, %acc

 ///  ==>

 /// %b = arith.addf %a, %y

 /// %c = vector.reduction <add> %b, %acc

 /// ```

 struct ReduceRedundantZero final : OpRewritePattern<vector::ReductionOp> {

   using OpRewritePattern::OpRewritePattern;


   LogicalResult matchAndRewrite(vector::ReductionOp op,

                                 PatternRewriter &rewriter) const override {

     // TODO: Handle other reduction kinds and their identity values.

     if (op.getKind() != vector::CombiningKind::ADD)

       return failure();


     Type elemType = op.getSourceVectorType().getElementType();

     // The integer case should be handled by `arith.addi` folders, only check

     // for floats here.

     if (!isa<FloatType>(elemType))

       return failure();


     auto vAdd = op.getVector().getDefiningOp<arith::AddFOp>();

     if (!vAdd)

       return failure();

     auto addLhs = vAdd.getLhs().getDefiningOp<arith::AddFOp>();

     if (!addLhs)

       return failure();


     if (!matchPattern(addLhs.getRhs(), m_AnyZeroFloat()))

       return failure();


     auto newAdd = rewriter.create<arith::AddFOp>(vAdd.getLoc(), addLhs.getLhs(),

                                                  vAdd.getRhs());

     rewriter.replaceOpWithNewOp<vector::ReductionOp>(op, op.getKind(), newAdd,

                                                      op.getAcc());

     return success();

   }

 };


 /// Example:

 /// ```

 /// %a = vector.reduction <add> %x : vector<2xf32> into f32

 /// ```

 /// is transformed into:

 /// ```

 /// %y = vector.extract %x[0] : f32 from vector<2xf32>

 /// %z = vector.extract %x[1] : f32 from vector<2xf32>

 /// %a = arith.addf %y, %z : f32

 /// ```

 struct BreakDownVectorReduction final : OpRewritePattern<vector::ReductionOp> {

   BreakDownVectorReduction(MLIRContext *context,

                            unsigned maxNumElementsToExtract,

                            PatternBenefit benefit)

       : OpRewritePattern(context, benefit),

         maxNumElementsToExtract(maxNumElementsToExtract) {}


   LogicalResult matchAndRewrite(vector::ReductionOp op,

                                 PatternRewriter &rewriter) const override {

     VectorType type = op.getSourceVectorType();

     if (type.isScalable() || op.isMasked())

       return failure();

     assert(type.getRank() == 1 && "Expected a 1-d vector");


     int64_t numElems = type.getNumElements();

     if (numElems > maxNumElementsToExtract) {

       return rewriter.notifyMatchFailure(

           op, llvm::formatv("has too many vector elements ({0}) to break down "

                             "(max allowed: {1})",

                             numElems, maxNumElementsToExtract));

     }


     Location loc = op.getLoc();

     SmallVector<Value> extracted(numElems, nullptr);

     for (auto [idx, extractedElem] : llvm::enumerate(extracted))

       extractedElem = rewriter.create<vector::ExtractOp>(

           loc, op.getVector(), static_cast<int64_t>(idx));


     Value res = extracted.front();

     for (auto extractedElem : llvm::drop_begin(extracted))

       res = vector::makeArithReduction(rewriter, loc, op.getKind(), res,

                                        extractedElem, op.getFastmathAttr());

     if (Value acc = op.getAcc())

       res = vector::makeArithReduction(rewriter, loc, op.getKind(), res, acc,

                                        op.getFastmathAttr());


     rewriter.replaceOp(op, res);

     return success();

   }


 private:

   unsigned maxNumElementsToExtract = 0;

 };


 /// Fold `mulf(tr(broadcast(A)), broadcast(B))` into `vector.outerproduct(A,

 /// B)`.

 /// Example:

 ///  %lhsBcast = vector.broadcast %lhs : vector<4xi32> to vector<4x4xi32>

 ///  %lhsT = vector.transpose %lhsBcast, [1, 0] : vector<4x4xi32> to

 ///  vector<4x4xi32> %rhsBcast = vector.broadcast %rhs : vector<4xi32> to

 ///  vector<4x4xi32> %mul = arith.muli %lhsT, %rhsBcast : vector<4x4xi32>

 ///

 /// Becomes :

 ///

 ///  %res = vector.outerproduct %lhs, %rhs : vector<4xi32>, vector<4xi32>

 ///

 /// Supports only 1D-to-2D broadcasts. The following cases are not supported.

 /// %ex1 = vector.broadcast %lhsCast : vector<1x4xf32> to vector<4x4xf32>

 /// %ex2 = vector.broadcast %lhsCast : f32 to vector<4x4xf32>

 /// %ex3 = vector.broadcast %lhsCast : vector<1x1xf32> to vector<4x4xf32>

 template <typename MulOpType>

 struct FoldArithToVectorOuterProduct : public OpRewritePattern<MulOpType> {

   using OpRewritePattern<MulOpType>::OpRewritePattern;

   // Returns whether a vector.broadcast matches requirements for an outerproduct

   // pattern. aka a 1D-to-2D broadcastOp without broadcasted unit dimension.

   bool isValidBroadcastSource(vector::BroadcastOp broadcastOp) const {

     // Fail if it is not a 1-to-2 dimension to broadcast to avoid generating

     // shape_casts/broadcasts which does not belong in this pattern.

     if (!broadcastOp.computeBroadcastedUnitDims().empty())

       return false;

     // Avoid broadcast like f32 or vector<f32> -> ResType

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

     return srcType && srcType.getRank() != 2;

   }


   LogicalResult matchAndRewrite(MulOpType mulOp,

                                 PatternRewriter &rewriter) const override {

     auto resType = llvm::cast<VectorType>(mulOp.getResult().getType());

     if (!resType)

       return failure();

     if (resType.getRank() != 2)

       return failure();

     /// If operandA can be written as tr(broadcast(A)) and operandB as

     /// broadcast(B) where broadcasts are 1D-to-2D, create and return

     /// vector.outerproduct(A, B). Returns failure() otherwise.

     auto matchOuterProduct =

         [&](Value operandA,

             Value operandB) -> FailureOr<vector::OuterProductOp> {

       auto transposedLhs = operandA.getDefiningOp<vector::TransposeOp>();

       if (!transposedLhs)

         return failure();

       // Fail unless this is a true 2-D matrix transpose.

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

       if (permutation.size() != 2 || permutation[0] != 1 || permutation[1] != 0)

         return failure();


       auto broadcastedLhs =

           transposedLhs.getVector().getDefiningOp<vector::BroadcastOp>();

       if (!broadcastedLhs || !isValidBroadcastSource(broadcastedLhs))

         return failure();


       auto broadcastedRhs = operandB.getDefiningOp<vector::BroadcastOp>();

       if (!broadcastedRhs || !isValidBroadcastSource(broadcastedRhs))

         return failure();


       return rewriter.create<vector::OuterProductOp>(

           mulOp->getLoc(), resType, broadcastedLhs.getSource(),

           broadcastedRhs.getSource(), Value(), vector::CombiningKind::ADD);

     };


     Value lhs = mulOp->getOperand(0), rhs = mulOp->getOperand(1);

     auto maybeOuterP = matchOuterProduct(lhs, rhs);

     // Handle commutativity, the transposed op is the outerproduct LHS.

     if (failed(maybeOuterP))

       maybeOuterP = matchOuterProduct(rhs, lhs);

     if (failed(maybeOuterP))

       return failure();

     rewriter.replaceOp(mulOp, maybeOuterP->getResult());

     return success();

   }

 };


 } // namespace


 void mlir::vector::populateFoldArithExtensionPatterns(

     RewritePatternSet &patterns) {

   patterns.add<FoldArithExtIntoContractionOp<arith::ExtFOp>,

                FoldArithExtIntoContractionOp<arith::ExtSIOp>>(

       patterns.getContext());

 }


 void mlir::vector::populateVectorMaskMaterializationPatterns(

     RewritePatternSet &patterns, bool force32BitVectorIndices,

     PatternBenefit benefit) {

   patterns.add<VectorCreateMaskOpConversion,

                MaterializeTransferMask<vector::TransferReadOp>,

                MaterializeTransferMask<vector::TransferWriteOp>>(

       patterns.getContext(), force32BitVectorIndices, benefit);

   patterns.add<FoldI1Select>(patterns.getContext(), benefit);

 }


 void mlir::vector::populateShapeCastFoldingPatterns(RewritePatternSet &patterns,

                                                     PatternBenefit benefit) {

   patterns.add<ShapeCastOpFolder>(patterns.getContext(), benefit);

 }


 void mlir::vector::populateDropUnitDimWithShapeCastPatterns(

     RewritePatternSet &patterns, PatternBenefit benefit) {

   // TODO: Consider either:

   //  * including DropInnerMostUnitDimsTransferRead and

   //    DropInnerMostUnitDimsTransferWrite, or

   //  * better naming to distinguish this and

   //    populateVectorTransferCollapseInnerMostContiguousDimsPatterns.

   patterns.add<DropUnitDimFromElementwiseOps, DropUnitDimsFromScfForOp,

                DropUnitDimsFromTransposeOp, ShapeCastOpFolder>(

       patterns.getContext(), benefit);

 }


 void mlir::vector::populateBubbleVectorBitCastOpPatterns(

     RewritePatternSet &patterns, PatternBenefit benefit) {

   patterns.add<BubbleDownVectorBitCastForExtract,

                BubbleDownBitCastForStridedSliceExtract,

                BubbleUpBitCastForInsert, BubbleUpBitCastForStridedSliceInsert>(

       patterns.getContext(), benefit);

 }


 void mlir::vector::populateBreakDownVectorBitCastOpPatterns(

     RewritePatternSet &patterns,

     std::function<bool(vector::BitCastOp)> controlFn, PatternBenefit benefit) {

   patterns.add<BreakDownVectorBitCast>(patterns.getContext(),

                                        std::move(controlFn), benefit);

 }


 void mlir::vector::populateVectorContractCanonicalizeMatmulToMMT(

     RewritePatternSet &patterns,

     std::function<LogicalResult(vector::ContractionOp)> constraint,

     PatternBenefit benefit) {

   patterns.add<CanonicalizeContractMatmulToMMT>(patterns.getContext(), benefit,

                                                 std::move(constraint));

 }


 void mlir::vector::populateVectorReductionToContractPatterns(

     RewritePatternSet &patterns, PatternBenefit benefit) {

   patterns.add<MultiReduceToContract, CombineContractBroadcast,

                CombineContractABTranspose, CombineContractResultTranspose>(

       patterns.getContext(), benefit);

 }


 void mlir::vector::

     populateVectorTransferCollapseInnerMostContiguousDimsPatterns(

         RewritePatternSet &patterns, PatternBenefit benefit) {

   patterns.add<DropInnerMostUnitDimsTransferRead,

                DropInnerMostUnitDimsTransferWrite>(patterns.getContext(),

                                                    benefit);

 }


 void mlir::vector::populateSinkVectorOpsPatterns(RewritePatternSet &patterns,

                                                  PatternBenefit benefit) {

   patterns.add<ReorderElementwiseOpsOnTranspose, ReorderCastOpsOnBroadcast,

                ReorderElementwiseOpsOnBroadcast>(patterns.getContext(),

                                                  benefit);

 }


 void mlir::vector::populateChainedVectorReductionFoldingPatterns(

     RewritePatternSet &patterns, PatternBenefit benefit) {

   patterns.add<ChainedReduction>(patterns.getContext(), benefit);

   patterns.add<ReduceRedundantZero>(patterns.getContext(),

                                     PatternBenefit(benefit.getBenefit() + 1));

 }


 void mlir::vector::populateBreakDownVectorReductionPatterns(

     RewritePatternSet &patterns, unsigned maxNumElementsToExtract,

     PatternBenefit benefit) {

   patterns.add<BreakDownVectorReduction>(patterns.getContext(),

                                          maxNumElementsToExtract, benefit);

 }


 void mlir::vector::populateElementwiseToVectorOpsPatterns(

     RewritePatternSet &patterns) {

   patterns.add<FoldArithToVectorOuterProduct<arith::MulFOp>,

                FoldArithToVectorOuterProduct<arith::MulIOp>>(

       patterns.getContext());

 }


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

 // TableGen'd enum attribute definitions

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


 #include "mlir/Dialect/Vector/Transforms/VectorTransformsEnums.cpp.inc"

AffineOps.h

BuiltinAttributeInterfaces.h

Utils.h

zext
static uint64_t zext(uint32_t arg)
Definition: InferIntRangeInterfaceImpls.cpp:56

ImplicitLocOpBuilder.h

IndexingUtils.h

Location.h

Matchers.h

PatternMatch.h

broadcast
static Value broadcast(Location loc, Value toBroadcast, unsigned numElements, const TypeConverter &typeConverter, ConversionPatternRewriter &rewriter)
Broadcasts the value to vector with numElements number of elements.
Definition: SPIRVToLLVM.cpp:151

StructuredOpsUtils.h

TypeUtilities.h

VectorInterfaces.h

VectorOps.h

VectorRewritePatterns.h

getFirstIntValue
static uint64_t getFirstIntValue(ValueRange values)
Returns the integer value from the first valid input element, assuming Value inputs are defined by a ...
Definition: VectorToSPIRV.cpp:43

getResultIndex
static std::optional< int64_t > getResultIndex(AffineMap map, int64_t index)
Definition: VectorTransforms.cpp:63

extractVector
static SmallVector< IntType > extractVector(ArrayAttr arrayAttr)
Definition: VectorTransforms.cpp:56

VectorTransforms.h

VectorUtils.h

llvm::ArrayRef
Definition: LLVM.h:48

llvm::SmallVector
Definition: LLVM.h:72

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::getDimPosition
unsigned getDimPosition(unsigned idx) const
Extracts the position of the dimensional expression at the given result, when the caller knows it is ...
Definition: AffineMap.cpp:415

mlir::AffineMap::get
static AffineMap get(MLIRContext *context)
Returns a zero result affine map with no dimensions or symbols: () -> ().
Definition: MLIRContext.cpp:1264

mlir::AffineMap::getNumResults
unsigned getNumResults() const
Definition: AffineMap.cpp:402

mlir::AffineMap::getPermutationMap
static AffineMap getPermutationMap(ArrayRef< unsigned > permutation, MLIRContext *context)
Returns an AffineMap representing a permutation.
Definition: AffineMap.cpp:264

mlir::AffineMap::compose
AffineMap compose(AffineMap map) const
Returns the AffineMap resulting from composing this with map.
Definition: AffineMap.cpp:556

mlir::AffineMap::inferFromExprList
static SmallVector< AffineMap, 4 > inferFromExprList(ArrayRef< ArrayRef< AffineExpr >> exprsList, MLIRContext *context)
Returns a vector of AffineMaps; each with as many results as exprs.size(), as many dims as the larges...
Definition: AffineMap.cpp:312

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

mlir::Builder::getIndexAttr
IntegerAttr getIndexAttr(int64_t value)
Definition: Builders.cpp:148

mlir::Builder::getMultiDimIdentityMap
AffineMap getMultiDimIdentityMap(unsigned rank)
Definition: Builders.cpp:427

mlir::Builder::getI64Type
IntegerType getI64Type()
Definition: Builders.cpp:109

mlir::Builder::getI32Type
IntegerType getI32Type()
Definition: Builders.cpp:107

mlir::Builder::getIntegerType
IntegerType getIntegerType(unsigned width)
Definition: Builders.cpp:111

mlir::Builder::getZeroAttr
TypedAttr getZeroAttr(Type type)
Definition: Builders.cpp:364

mlir::Builder::getAffineDimExpr
AffineExpr getAffineDimExpr(unsigned position)
Definition: Builders.cpp:404

mlir::Builder::getContext
MLIRContext * getContext() const
Definition: Builders.h:55

mlir::Builder::getI32VectorAttr
DenseIntElementsAttr getI32VectorAttr(ArrayRef< int32_t > values)
Definition: Builders.cpp:162

mlir::Builder::getI64VectorAttr
DenseIntElementsAttr getI64VectorAttr(ArrayRef< int64_t > values)
Definition: Builders.cpp:168

mlir::Builder::getI1Type
IntegerType getI1Type()
Definition: Builders.cpp:97

mlir::Builder::getArrayAttr
ArrayAttr getArrayAttr(ArrayRef< Attribute > value)
Definition: Builders.cpp:306

mlir::Builder::getI64ArrayAttr
ArrayAttr getI64ArrayAttr(ArrayRef< int64_t > values)
Definition: Builders.cpp:321

mlir::Builder::getBoolArrayAttr
ArrayAttr getBoolArrayAttr(ArrayRef< bool > values)
Definition: Builders.cpp:310

mlir::Builder::getAffineMapArrayAttr
ArrayAttr getAffineMapArrayAttr(ArrayRef< AffineMap > values)
Definition: Builders.cpp:358

mlir::DenseIntElementsAttr
An attribute that represents a reference to a dense integer vector or tensor object.
Definition: BuiltinAttributes.h:950

mlir::DenseIntElementsAttr::get
static DenseIntElementsAttr get(const ShapedType &type, Arg &&arg)
Get an instance of a DenseIntElementsAttr with the given arguments.
Definition: BuiltinAttributes.h:961

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

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

mlir::OpBuilder
This class helps build Operations.
Definition: Builders.h:215

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:497

mlir::OpOperand
This class represents an operand of an operation.
Definition: Value.h:267

mlir::OpTraitRewritePattern
OpTraitRewritePattern is a wrapper around RewritePattern that allows for matching and rewriting again...
Definition: PatternMatch.h:384

mlir::OpTraitRewritePattern::OpTraitRewritePattern
OpTraitRewritePattern(MLIRContext *context, PatternBenefit benefit=1)
Definition: PatternMatch.h:386

mlir::OperationName::getIdentifier
StringAttr getIdentifier() const
Return the name of this operation as a StringAttr.
Definition: OperationSupport.h:478

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

mlir::Operation::getOperand
Value getOperand(unsigned idx)
Definition: Operation.h:345

mlir::Operation::clone
Operation * clone(IRMapping &mapper, CloneOptions options=CloneOptions::all())
Create a deep copy of this operation, remapping any operands that use values outside of the operation...
Definition: Operation.cpp:717

mlir::Operation::getResult
OpResult getResult(unsigned idx)
Get the 'idx'th result of this operation.
Definition: Operation.h:402

mlir::Operation::getContext
MLIRContext * getContext()
Return the context this operation is associated with.
Definition: Operation.h:216

mlir::Operation::getNumRegions
unsigned getNumRegions()
Returns the number of regions held by this operation.
Definition: Operation.h:669

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

mlir::Operation::getNumOperands
unsigned getNumOperands()
Definition: Operation.h:341

mlir::Operation::getAttrs
ArrayRef< NamedAttribute > getAttrs()
Return all of the attributes on this operation.
Definition: Operation.h:507

mlir::Operation::getName
OperationName getName()
The name of an operation is the key identifier for it.
Definition: Operation.h:119

mlir::Operation::getResultTypes
result_type_range getResultTypes()
Definition: Operation.h:423

mlir::Operation::getOperands
operand_range getOperands()
Returns an iterator on the underlying Value's.
Definition: Operation.h:373

mlir::Operation::getResults
result_range getResults()
Definition: Operation.h:410

mlir::Operation::getNumResults
unsigned getNumResults()
Return the number of results held by this operation.
Definition: Operation.h:399

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::PatternBenefit::getBenefit
unsigned short getBenefit() const
If the corresponding pattern can match, return its benefit. If the.
Definition: PatternMatch.cpp:27

mlir::PatternRewriter
A special type of RewriterBase that coordinates the application of a rewrite pattern on the current I...
Definition: PatternMatch.h:785

mlir::ResultRange::getType
type_range getType() const
Definition: ValueRange.cpp:39

mlir::RewritePatternSet
Definition: PatternMatch.h:808

mlir::RewritePatternSet::getContext
MLIRContext * getContext() const
Definition: PatternMatch.h:823

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:847

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:718

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:133

mlir::RewriterBase::modifyOpInPlace
void modifyOpInPlace(Operation *root, CallableT &&callable)
This method is a utility wrapper around an in-place modification of an operation.
Definition: PatternMatch.h:630

mlir::RewriterBase::replaceOpWithNewOp
OpTy replaceOpWithNewOp(Operation *op, Args &&...args)
Replace the results of the given (original) op with a new op that is created without verification (re...
Definition: PatternMatch.h:536

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

mlir::Type::isIntOrFloat
bool isIntOrFloat() const
Return true if this is an integer (of any signedness) or a float type.
Definition: Types.cpp:127

mlir::Type::isSignlessIntOrIndexOrFloat
bool isSignlessIntOrIndexOrFloat() const
Return true if this is a signless integer, index, or float type.
Definition: Types.cpp:115

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::getContext
MLIRContext * getContext() const
Utility to get the associated MLIRContext that this value is defined in.
Definition: Value.h:132

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

mlir::Value::getLoc
Location getLoc() const
Return the location of this value.
Definition: Value.cpp:26

mlir::Value::getDefiningOp
Operation * getDefiningOp() const
If this value is the result of an operation, return the operation that defines it.
Definition: Value.cpp:20

Arith.h

Linalg.h

MemRef.h

SCF.h

Tensor.h

BuiltinTypes.h

mlir::OpTrait::hasElementwiseMappableTraits
bool hasElementwiseMappableTraits(Operation *op)
Together, Elementwise, Scalarizable, Vectorizable, and Tensorizable provide an easy way for scalar op...
Definition: Operation.cpp:1393

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

mlir::memref::getMixedSizes
SmallVector< OpFoldResult > getMixedSizes(OpBuilder &builder, Location loc, Value value)
Return the dimensions of the given memref value.
Definition: MemRefOps.cpp:77

mlir::scf::replaceAndCastForOpIterArg
SmallVector< Value > replaceAndCastForOpIterArg(RewriterBase &rewriter, scf::ForOp forOp, OpOperand &operand, Value replacement, const ValueTypeCastFnTy &castFn)
Definition: SCF.cpp:776

mlir::vector
Definition: Passes.h:35

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::populateDropUnitDimWithShapeCastPatterns
void populateDropUnitDimWithShapeCastPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Collect a set of patterns that use vector.shape_cast to help fold unit dims.
Definition: VectorTransforms.cpp:2057

mlir::vector::isReductionIterator
bool isReductionIterator(Attribute attr)
Returns true if attr has "reduction" iterator type semantics.
Definition: VectorOps.h:152

mlir::vector::populateBreakDownVectorBitCastOpPatterns
void populateBreakDownVectorBitCastOpPatterns(RewritePatternSet &patterns, std::function< bool(BitCastOp)> controlFn=nullptr, PatternBenefit benefit=1)
Populate patterns with a pattern to break down 1-D vector.bitcast ops based on the destination vector...

mlir::vector::getDims
auto getDims(VectorType vType)
Returns a range over the dims (size and scalability) of a VectorType.
Definition: VectorUtils.h:124

mlir::vector::populateElementwiseToVectorOpsPatterns
void populateElementwiseToVectorOpsPatterns(RewritePatternSet &patterns)
Collect a set of patterns that fold elementwise op on vectors to the vector dialect.
Definition: VectorTransforms.cpp:2128

mlir::vector::getTransferMinorIdentityMap
AffineMap getTransferMinorIdentityMap(ShapedType shapedType, VectorType vectorType)
Build the default minor identity map suitable for a vector transfer.
Definition: VectorOps.cpp:153

mlir::vector::populateShapeCastFoldingPatterns
void populateShapeCastFoldingPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Collect a set of vector.shape_cast folding patterns.
Definition: VectorTransforms.cpp:2052

mlir::vector::populateChainedVectorReductionFoldingPatterns
void populateChainedVectorReductionFoldingPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Patterns that fold chained vector reductions.
Definition: VectorTransforms.cpp:2114

mlir::vector::populateBubbleVectorBitCastOpPatterns
void populateBubbleVectorBitCastOpPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Collect a set of patterns that bubble up/down bitcast ops.
Definition: VectorTransforms.cpp:2069

mlir::vector::isParallelIterator
bool isParallelIterator(Attribute attr)
Returns true if attr has "parallel" iterator type semantics.
Definition: VectorOps.h:147

mlir::vector::populateFoldArithExtensionPatterns
void populateFoldArithExtensionPatterns(RewritePatternSet &patterns)
Collect a set of patterns that fold arithmetic extension on floating point into vector contract for t...
Definition: VectorTransforms.cpp:2035

mlir::vector::populateVectorContractCanonicalizeMatmulToMMT
void populateVectorContractCanonicalizeMatmulToMMT(RewritePatternSet &patterns, std::function< LogicalResult(vector::ContractionOp)> constraint=[](vector::ContractionOp) { return success();}, PatternBenefit=1)
Canonicalization of a vector.contraction a, b, c with row-major matmul semantics to a contraction wit...
Definition: VectorTransforms.cpp:2084

mlir::vector::populateSinkVectorOpsPatterns
void populateSinkVectorOpsPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Patterns that remove redundant Vector Ops by re-ordering them with e.g.
Definition: VectorTransforms.cpp:2107

mlir::vector::populateVectorMaskMaterializationPatterns
void populateVectorMaskMaterializationPatterns(RewritePatternSet &patterns, bool force32BitVectorIndices, PatternBenefit benefit=1)
These patterns materialize masks for various vector ops such as transfers.
Definition: VectorTransforms.cpp:2042

mlir::vector::populateVectorTransferCollapseInnerMostContiguousDimsPatterns
void populateVectorTransferCollapseInnerMostContiguousDimsPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Collect a set of patterns to reduce the rank of the operands of vector transfer ops to operate on the...
Definition: VectorTransforms.cpp:2100

mlir::vector::populateVectorReductionToContractPatterns
void populateVectorReductionToContractPatterns(RewritePatternSet &patterns, PatternBenefit benefit=1)
Collect patterns to convert reduction op to vector.contract and fold transpose/broadcast ops into the...
Definition: VectorTransforms.cpp:2092

mlir::vector::createOrFoldDimOp
Value createOrFoldDimOp(OpBuilder &b, Location loc, Value source, int64_t dim)
Helper function that creates a memref::DimOp or tensor::DimOp depending on the type of source.
Definition: VectorUtils.cpp:41

mlir::vector::populateBreakDownVectorReductionPatterns
void populateBreakDownVectorReductionPatterns(RewritePatternSet &patterns, unsigned maxNumElementsToExtract=2, PatternBenefit benefit=1)
Patterns to break down vector reductions into a series of arith reductions over vector elements.
Definition: VectorTransforms.cpp:2121

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

mlir::matchPattern
bool matchPattern(Value value, const Pattern &pattern)
Entry point for matching a pattern over a Value.
Definition: Matchers.h:485

mlir::bindDims
void bindDims(MLIRContext *ctx, AffineExprTy &...exprs)
Bind a list of AffineExpr references to DimExpr at positions: [0 .
Definition: AffineExpr.h:348

mlir::getStridesAndOffset
LogicalResult getStridesAndOffset(MemRefType t, SmallVectorImpl< int64_t > &strides, int64_t &offset)
Returns the strides of the MemRef if the layout map is in strided form.
Definition: BuiltinTypes.cpp:823

mlir::inversePermutation
AffineMap inversePermutation(AffineMap map)
Returns a map of codomain to domain dimensions such that the first codomain dimension for a particula...
Definition: AffineMap.cpp:791

mlir::getValueOrCreateCastToIndexLike
Value getValueOrCreateCastToIndexLike(OpBuilder &b, Location loc, Type targetType, Value value)
Create a cast from an index-like value (index or integer) to another index-like value.
Definition: Utils.cpp:120

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

mlir::m_AnyZeroFloat
detail::constant_float_predicate_matcher m_AnyZeroFloat()
Matches a constant scalar / vector splat / tensor splat float (both positive and negative) zero.
Definition: Matchers.h:399

mlir::compressDims
AffineMap compressDims(AffineMap map, const llvm::SmallBitVector &unusedDims)
Drop the dims that are listed in unusedDims.
Definition: AffineMap.cpp:717

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::getUnusedDimsBitVector
llvm::SmallBitVector getUnusedDimsBitVector(ArrayRef< AffineMap > maps)
Definition: AffineMap.cpp:928

mlir::m_Constant
detail::constant_op_matcher m_Constant()
Matches a constant foldable operation.
Definition: Matchers.h:369

mlir::OpInterfaceRewritePattern
OpInterfaceRewritePattern is a wrapper around RewritePattern that allows for matching and rewriting a...
Definition: PatternMatch.h:373

mlir::OpRewritePattern
OpRewritePattern is a wrapper around RewritePattern that allows for matching and rewriting against an...
Definition: PatternMatch.h:358

mlir::OpRewritePattern::OpRewritePattern
OpRewritePattern(MLIRContext *context, PatternBenefit benefit=1, ArrayRef< StringRef > generatedNames={})
Patterns must specify the root operation name they match against, and can also specify the benefit of...
Definition: PatternMatch.h:362