doxygen/Dialect_2Shape_2IR_2Shape_8cpp_source.html

 //===- Shape.cpp - MLIR Shape Operations ----------------------------------===//

 //

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

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

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

 //

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


 #include <utility>


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


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

 #include "mlir/Dialect/Bufferization/IR/BufferizableOpInterface.h"

 #include "mlir/Dialect/CommonFolders.h"

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

 #include "mlir/Dialect/Traits.h"

 #include "mlir/Dialect/UB/IR/UBOps.h"

 #include "mlir/IR/Builders.h"

 #include "mlir/IR/BuiltinTypes.h"

 #include "mlir/IR/DialectImplementation.h"

 #include "mlir/IR/Matchers.h"

 #include "mlir/IR/PatternMatch.h"

 #include "mlir/IR/TypeUtilities.h"

 #include "mlir/Interfaces/FunctionImplementation.h"

 #include "mlir/Transforms/InliningUtils.h"

 #include "llvm/ADT/SetOperations.h"

 #include "llvm/ADT/SmallString.h"

 #include "llvm/ADT/TypeSwitch.h"

 #include "llvm/Support/raw_ostream.h"


 using namespace mlir;

 using namespace mlir::shape;


 #include "mlir/Dialect/Shape/IR/ShapeOpsDialect.cpp.inc"


 namespace {

 #include "ShapeCanonicalization.inc"

 } // namespace


 RankedTensorType shape::getExtentTensorType(MLIRContext *ctx, int64_t rank) {

   return RankedTensorType::get({rank}, IndexType::get(ctx));

 }


 bool shape::isExtentTensorType(Type type) {

   auto ranked = llvm::dyn_cast<RankedTensorType>(type);

   return ranked && ranked.getRank() == 1 && ranked.getElementType().isIndex();

 }


 LogicalResult shape::getShapeVec(Value input,

                                  SmallVectorImpl<int64_t> &shapeValues) {

   if (auto inputOp = input.getDefiningOp<ShapeOfOp>()) {

     auto type = llvm::cast<ShapedType>(inputOp.getArg().getType());

     if (!type.hasRank())

       return failure();

     llvm::append_range(shapeValues, type.getShape());

     return success();

   }

   DenseIntElementsAttr attr;

   if (matchPattern(input, m_Constant(&attr))) {

     llvm::append_range(shapeValues, attr.getValues<int64_t>());

     return success();

   }

   return failure();

 }


 static bool isErrorPropagationPossible(TypeRange operandTypes) {

   return llvm::any_of(operandTypes,

                       llvm::IsaPred<SizeType, ShapeType, ValueShapeType>);

 }


 static LogicalResult verifySizeOrIndexOp(Operation *op) {

   assert(op != nullptr && op->getNumResults() == 1);

   Type resultTy = op->getResultTypes().front();

   if (isErrorPropagationPossible(op->getOperandTypes())) {

     if (!llvm::isa<SizeType>(resultTy))

       return op->emitOpError()

              << "if at least one of the operands can hold error values then "

                 "the result must be of type `size` to propagate them";

   }

   return success();

 }


 static LogicalResult verifyShapeOrExtentTensorOp(Operation *op) {

   assert(op != nullptr && op->getNumResults() == 1);

   Type resultTy = op->getResultTypes().front();

   if (isErrorPropagationPossible(op->getOperandTypes())) {

     if (!llvm::isa<ShapeType>(resultTy))

       return op->emitOpError()

              << "if at least one of the operands can hold error values then "

                 "the result must be of type `shape` to propagate them";

   }

   return success();

 }


 template <typename... Ty>

 static bool eachHasOnlyOneOfTypes(TypeRange typeRange) {

   return typeRange.size() == 1 && llvm::isa<Ty...>(typeRange.front());

 }


 template <typename... Ty, typename... ranges>

 static bool eachHasOnlyOneOfTypes(TypeRange l, ranges... rs) {

   return eachHasOnlyOneOfTypes<Ty...>(l) && eachHasOnlyOneOfTypes<Ty...>(rs...);

 }


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

 // InlinerInterface

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


 namespace {

 /// This class defines the interface for inlining shape dialect ops.

 struct ShapeInlinerInterface : public DialectInlinerInterface {

   using DialectInlinerInterface::DialectInlinerInterface;


   // Returns true if the given region 'src' can be inlined into the region

   // 'dest' that is attached to an operation registered to the current dialect.

   bool isLegalToInline(Region *dest, Region *src, bool wouldBeCloned,

                        IRMapping &) const final {

     return true;

   }


   // Returns true if the given operation 'op', that is registered to this

   // dialect, can be inlined into the region 'dest' that is attached to an

   // operation registered to the current dialect.

   bool isLegalToInline(Operation *op, Region *dest, bool wouldBeCloned,

                        IRMapping &) const final {

     return true;

   }

 };

 } // namespace


 void ShapeDialect::initialize() {

   addOperations<

 #define GET_OP_LIST

 #include "mlir/Dialect/Shape/IR/ShapeOps.cpp.inc"

       >();

   addTypes<

 #define GET_TYPEDEF_LIST

 #include "mlir/Dialect/Shape/IR/ShapeOpsTypes.cpp.inc"

       >();

   addInterfaces<ShapeInlinerInterface>();

   // Allow unknown operations during prototyping and testing. As the dialect is

   // still evolving it makes it simple to start with an unregistered ops and

   // try different variants before actually defining the op.

   allowUnknownOperations();

   declarePromisedInterfaces<bufferization::BufferizableOpInterface, AssumingOp,

                             AssumingYieldOp>();

 }


 Operation *ShapeDialect::materializeConstant(OpBuilder &builder,

                                              Attribute value, Type type,

                                              Location loc) {

   if (auto poison = dyn_cast<ub::PoisonAttr>(value))

     return builder.create<ub::PoisonOp>(loc, type, poison);


   if (llvm::isa<ShapeType>(type) || isExtentTensorType(type))

     return builder.create<ConstShapeOp>(

         loc, type, llvm::cast<DenseIntElementsAttr>(value));

   if (llvm::isa<SizeType>(type))

     return builder.create<ConstSizeOp>(loc, type,

                                        llvm::cast<IntegerAttr>(value));

   if (llvm::isa<WitnessType>(type))

     return builder.create<ConstWitnessOp>(loc, type,

                                           llvm::cast<BoolAttr>(value));


   return arith::ConstantOp::materialize(builder, value, type, loc);

 }


 LogicalResult ShapeDialect::verifyOperationAttribute(Operation *op,

                                                      NamedAttribute attribute) {

   // Verify shape.lib attribute.

   if (attribute.getName() == "shape.lib") {

     if (!op->hasTrait<OpTrait::SymbolTable>())

       return op->emitError(

           "shape.lib attribute may only be on op implementing SymbolTable");


     if (auto symbolRef = llvm::dyn_cast<SymbolRefAttr>(attribute.getValue())) {

       auto *symbol = SymbolTable::lookupSymbolIn(op, symbolRef);

       if (!symbol)

         return op->emitError("shape function library ")

                << symbolRef << " not found";

       return isa<shape::FunctionLibraryOp>(symbol)

                  ? success()

                  : op->emitError()

                        << symbolRef << " required to be shape function library";

     }


     if (auto arr = llvm::dyn_cast<ArrayAttr>(attribute.getValue())) {

       // Verify all entries are function libraries and mappings in libraries

       // refer to unique ops.

       DenseSet<StringAttr> key;

       for (auto it : arr) {

         if (!llvm::isa<SymbolRefAttr>(it))

           return op->emitError(

               "only SymbolRefAttr allowed in shape.lib attribute array");


         auto shapeFnLib = dyn_cast<shape::FunctionLibraryOp>(

             SymbolTable::lookupSymbolIn(op, llvm::cast<SymbolRefAttr>(it)));

         if (!shapeFnLib)

           return op->emitError()

                  << it << " does not refer to FunctionLibraryOp";

         for (auto mapping : shapeFnLib.getMapping()) {

           if (!key.insert(mapping.getName()).second) {

             return op->emitError("only one op to shape mapping allowed, found "

                                  "multiple for `")

                    << mapping.getName() << "`";

           }

         }

       }

       return success();

     }


     return op->emitError("only SymbolRefAttr or array of SymbolRefAttrs "

                          "allowed as shape.lib attribute");

   }

   return success();

 }


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

 // AnyOp

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


 // TODO: Canonicalization should be implemented for shapes that can be

 // determined through mixtures of the known dimensions of the inputs.

 OpFoldResult AnyOp::fold(FoldAdaptor adaptor) {

   // Only the last operand is checked because AnyOp is commutative.

   if (adaptor.getInputs().back())

     return adaptor.getInputs().back();


   return nullptr;

 }


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

 // AssumingOp

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


 ParseResult AssumingOp::parse(OpAsmParser &parser, OperationState &result) {

   result.regions.reserve(1);

   Region *doRegion = result.addRegion();


   auto &builder = parser.getBuilder();

   OpAsmParser::UnresolvedOperand cond;

   if (parser.parseOperand(cond) ||

       parser.resolveOperand(cond, builder.getType<WitnessType>(),

                             result.operands))

     return failure();


   // Parse optional results type list.

   if (parser.parseOptionalArrowTypeList(result.types))

     return failure();


   // Parse the region and add a terminator if elided.

   if (parser.parseRegion(*doRegion, /*arguments=*/{}, /*argTypes=*/{}))

     return failure();

   AssumingOp::ensureTerminator(*doRegion, parser.getBuilder(), result.location);


   // Parse the optional attribute list.

   if (parser.parseOptionalAttrDict(result.attributes))

     return failure();

   return success();

 }


 void AssumingOp::print(OpAsmPrinter &p) {

   bool yieldsResults = !getResults().empty();


   p << " " << getWitness();

   if (yieldsResults)

     p << " -> (" << getResultTypes() << ")";

   p << ' ';

   p.printRegion(getDoRegion(),

                 /*printEntryBlockArgs=*/false,

                 /*printBlockTerminators=*/yieldsResults);

   p.printOptionalAttrDict((*this)->getAttrs());

 }


 namespace {

 // Removes AssumingOp with a passing witness and inlines the region.

 struct AssumingWithTrue : public OpRewritePattern<AssumingOp> {

   using OpRewritePattern<AssumingOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(AssumingOp op,

                                 PatternRewriter &rewriter) const override {

     auto witness = op.getWitness().getDefiningOp<ConstWitnessOp>();

     if (!witness || !witness.getPassingAttr())

       return failure();


     AssumingOp::inlineRegionIntoParent(op, rewriter);

     return success();

   }

 };


 struct AssumingOpRemoveUnusedResults : public OpRewritePattern<AssumingOp> {

   using OpRewritePattern<AssumingOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(AssumingOp op,

                                 PatternRewriter &rewriter) const override {

     Block *body = op.getBody();

     auto yieldOp = llvm::cast<AssumingYieldOp>(body->getTerminator());


     // Find used values.

     SmallVector<Value, 4> newYieldOperands;

     for (auto [opResult, yieldOperand] :

          llvm::zip(op.getResults(), yieldOp.getOperands())) {

       if (!opResult.getUses().empty()) {

         newYieldOperands.push_back(yieldOperand);

       }

     }


     // Rewrite only if redundant results exist.

     if (newYieldOperands.size() == yieldOp->getNumOperands())

       return failure();


     // Replace yield op in the old assuming op's body and move the entire region

     // to the new assuming op.

     rewriter.setInsertionPointToEnd(body);

     auto newYieldOp =

         rewriter.replaceOpWithNewOp<AssumingYieldOp>(yieldOp, newYieldOperands);

     rewriter.setInsertionPoint(op);

     auto newOp = rewriter.create<AssumingOp>(

         op.getLoc(), newYieldOp->getOperandTypes(), op.getWitness());

     newOp.getDoRegion().takeBody(op.getDoRegion());


     // Use the new results to replace the previously used ones.

     SmallVector<Value, 4> replacementValues;

     auto src = newOp.getResults().begin();

     for (auto it : op.getResults()) {

       if (it.getUses().empty())

         replacementValues.push_back(nullptr);

       else

         replacementValues.push_back(*src++);

     }

     rewriter.replaceOp(op, replacementValues);

     return success();

   }

 };

 } // namespace


 void AssumingOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                              MLIRContext *context) {

   patterns.add<AssumingOpRemoveUnusedResults, AssumingWithTrue>(context);

 }


 // See RegionBranchOpInterface in Interfaces/ControlFlowInterfaces.td

 void AssumingOp::getSuccessorRegions(

     RegionBranchPoint point, SmallVectorImpl<RegionSuccessor> &regions) {

   // AssumingOp has unconditional control flow into the region and back to the

   // parent, so return the correct RegionSuccessor purely based on the index

   // being None or 0.

   if (!point.isParent()) {

     regions.push_back(RegionSuccessor(getResults()));

     return;

   }


   regions.push_back(RegionSuccessor(&getDoRegion()));

 }


 void AssumingOp::inlineRegionIntoParent(AssumingOp &op,

                                         PatternRewriter &rewriter) {

   auto *blockBeforeAssuming = rewriter.getInsertionBlock();

   auto *assumingBlock = op.getBody();

   auto initPosition = rewriter.getInsertionPoint();

   auto *blockAfterAssuming =

       rewriter.splitBlock(blockBeforeAssuming, initPosition);


   // Remove the AssumingOp and AssumingYieldOp.

   auto &yieldOp = assumingBlock->back();

   rewriter.inlineRegionBefore(op.getDoRegion(), blockAfterAssuming);

   rewriter.replaceOp(op, yieldOp.getOperands());

   rewriter.eraseOp(&yieldOp);


   // Merge blocks together as there was no branching behavior from the

   // AssumingOp.

   rewriter.mergeBlocks(assumingBlock, blockBeforeAssuming);

   rewriter.mergeBlocks(blockAfterAssuming, blockBeforeAssuming);

 }


 void AssumingOp::build(

     OpBuilder &builder, OperationState &result, Value witness,

     function_ref<SmallVector<Value, 2>(OpBuilder &, Location)> bodyBuilder) {

   OpBuilder::InsertionGuard g(builder);


   result.addOperands(witness);

   Region *bodyRegion = result.addRegion();

   builder.createBlock(bodyRegion);


   // Build body.

   SmallVector<Value, 2> yieldValues = bodyBuilder(builder, result.location);

   builder.create<AssumingYieldOp>(result.location, yieldValues);


   SmallVector<Type, 2> assumingTypes;

   for (Value v : yieldValues)

     assumingTypes.push_back(v.getType());

   result.addTypes(assumingTypes);

 }


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

 // AddOp

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


 LogicalResult mlir::shape::AddOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     AddOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<SizeType>(adaptor.getLhs().getType()) ||

       llvm::isa<SizeType>(adaptor.getRhs().getType()))

     inferredReturnTypes.assign({SizeType::get(context)});

   else

     inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::AddOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 OpFoldResult mlir::shape::AddOp::fold(FoldAdaptor adaptor) {

   // add(x, 0) -> x

   if (matchPattern(getRhs(), m_Zero()))

     return getLhs();


   return constFoldBinaryOp<IntegerAttr>(

       adaptor.getOperands(),

       [](APInt a, const APInt &b) { return std::move(a) + b; });

 }


 LogicalResult shape::AddOp::verify() { return verifySizeOrIndexOp(*this); }


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

 // AssumingAllOp

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


 namespace {


 // Merge multiple `shape.assuming_all` operations together.

 //

 //   %0 = shape.assuming_all %w0, %w1

 //   %1 = shape.assuming_all %w2, %0

 //

 // to:

 //

 //   %0 = shape.assuming_all %w0, %w2, %w2

 struct MergeAssumingAllOps : public OpRewritePattern<AssumingAllOp> {

   using OpRewritePattern<AssumingAllOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(AssumingAllOp op,

                                 PatternRewriter &rewriter) const override {

     SmallVector<Value> operands;


     for (Value operand : op.getInputs()) {

       if (auto assumeAll = operand.getDefiningOp<AssumingAllOp>())

         operands.append(assumeAll.operand_begin(), assumeAll->operand_end());

       else

         operands.push_back(operand);

     }


     // We didn't find any other `assuming_all` ops to merge with.

     if (operands.size() == op.getNumOperands())

       return failure();


     // Replace with a new `assuming_all` operation with merged constraints.

     rewriter.replaceOpWithNewOp<AssumingAllOp>(op, operands);

     return success();

   }

 };


 // Eliminate `cstr_broadcastable` operands from `assuming_all` operation that

 // are subsumed by others.

 //

 //   %0 = shape.cstr_broadcastable %shape0, %shape1

 //   %1 = shape.cstr_broadcastable %shape0, %shape1, %shape2

 //

 //   %2 = shape.cstr_broadcastable %shape3, %shape4

 //   %3 = shape.cstr_broadcastable %shape3, %shape4, %shape5

 //

 //   %4 = shape.assuming_all %0, %1, %2, %3

 //

 // to:

 //

 //   %0 = shape.cstr_broadcastable %shape0, %shape1, %shape2

 //   %1 = shape.cstr_broadcastable %shape3, %shape4, %shape5

 //   %2 = shape.assuming_all %0, %1

 //

 // In this example if shapes [0, 1, 2] are broadcastable, then it means that

 // shapes [0, 1] are broadcastable too, and can be removed from the list of

 // constraints. If shapes [0, 1, 2] are not broadcastable, then it doesn't

 // matter if shapes [0, 1] are broadcastable (same for shapes [3, 4, 5]).

 struct AssumingAllOfCstrBroadcastable : public OpRewritePattern<AssumingAllOp> {

   using OpRewritePattern<AssumingAllOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(AssumingAllOp op,

                                 PatternRewriter &rewriter) const override {

     // Collect all `CstrBroadcastableOp` operands first.

     SetVector<CstrBroadcastableOp> operands;

     for (Value operand : op.getInputs()) {

       // TODO: Apply this optimization if some of the witnesses are not

       // produced by the `cstr_broadcastable`.

       auto broadcastable = operand.getDefiningOp<CstrBroadcastableOp>();

       if (!broadcastable)

         return failure();


       operands.insert(broadcastable);

     }


     // Skip trivial `assuming_all` operations.

     if (operands.size() <= 1)

       return failure();


     // Collect shapes checked by `cstr_broadcastable` operands.

     SmallVector<std::pair<CstrBroadcastableOp, DenseSet<Value>>> shapes;

     for (auto cstr : operands) {

       DenseSet<Value> shapesSet(cstr->operand_begin(), cstr->operand_end());

       shapes.emplace_back(cstr, std::move(shapesSet));

     }


     // Sort by the number of shape operands (larger to smaller).

     llvm::sort(shapes, [](auto a, auto b) {

       return a.first.getNumOperands() > b.first.getNumOperands();

     });


     // We start from the `cst_broadcastable` operations with largest number of

     // shape operands, and remove redundant `cst_broadcastable` operations. We

     // do this until we find a set of `cst_broadcastable` operations with

     // non-overlapping constraints.

     SmallVector<CstrBroadcastableOp> markedForErase;


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

       auto isSubset = [&](auto pair) {

         return llvm::set_is_subset(pair.second, shapes[i].second);

       };


       // Keep redundant `cstr_broadcastable` operations to be erased.

       auto *it = std::remove_if(shapes.begin() + i + 1, shapes.end(), isSubset);

       for (auto *it0 = it; it0 < shapes.end(); ++it0)

         markedForErase.push_back(it0->first);

       shapes.erase(it, shapes.end());

     }


     // We didn't find any operands that could be removed.

     if (markedForErase.empty())

       return failure();


     // Collect non-overlapping `cst_broadcastable` constraints.

     SmallVector<Value> uniqueConstraints;

     for (auto &shape : shapes)

       uniqueConstraints.push_back(shape.first.getResult());


     // Replace with a new `assuming_all` operation ...

     rewriter.replaceOpWithNewOp<AssumingAllOp>(op, uniqueConstraints);


     // ... and maybe erase `cstr_broadcastable` ops without uses.

     for (auto &op : markedForErase)

       if (op->use_empty())

         rewriter.eraseOp(op);


     return success();

   }

 };


 struct AssumingAllToCstrEqCanonicalization

     : public OpRewritePattern<AssumingAllOp> {

   using OpRewritePattern<AssumingAllOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(AssumingAllOp op,

                                 PatternRewriter &rewriter) const override {

     SmallVector<Value, 8> shapes;

     for (Value w : op.getInputs()) {

       auto cstrEqOp = w.getDefiningOp<CstrEqOp>();

       if (!cstrEqOp)

         return failure();

       bool disjointShapes = llvm::none_of(cstrEqOp.getShapes(), [&](Value s) {

         return llvm::is_contained(shapes, s);

       });

       if (!shapes.empty() && !cstrEqOp.getShapes().empty() && disjointShapes)

         return failure();

       shapes.append(cstrEqOp.getShapes().begin(), cstrEqOp.getShapes().end());

     }

     rewriter.replaceOpWithNewOp<CstrEqOp>(op, shapes);

     return success();

   }

 };


 template <typename OpTy>

 struct RemoveDuplicateOperandsPattern : public OpRewritePattern<OpTy> {

   using OpRewritePattern<OpTy>::OpRewritePattern;


   LogicalResult matchAndRewrite(OpTy op,

                                 PatternRewriter &rewriter) const override {

     // Find unique operands.

     SetVector<Value> unique(op.operand_begin(), op.operand_end());


     // Reduce op to equivalent with unique operands.

     if (unique.size() < op.getNumOperands()) {

       rewriter.replaceOpWithNewOp<OpTy>(op, op->getResultTypes(),

                                         unique.takeVector(), op->getAttrs());

       return success();

     }


     return failure();

   }

 };

 } // namespace


 void AssumingAllOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                 MLIRContext *context) {

   patterns

       .add<MergeAssumingAllOps, AssumingAllOneOp,

            AssumingAllOfCstrBroadcastable, AssumingAllToCstrEqCanonicalization,

            RemoveDuplicateOperandsPattern<AssumingAllOp>>(context);

 }


 OpFoldResult AssumingAllOp::fold(FoldAdaptor adaptor) {

   // Iterate in reverse to first handle all constant operands. They are

   // guaranteed to be the tail of the inputs because this is commutative.

   for (int idx = adaptor.getInputs().size() - 1; idx >= 0; idx--) {

     Attribute a = adaptor.getInputs()[idx];

     // Cannot fold if any inputs are not constant;

     if (!a)

       return nullptr;


     // We do not need to keep statically known values after handling them in

     // this method.

     getOperation()->eraseOperand(idx);


     // Always false if any input is statically known false

     if (!llvm::cast<BoolAttr>(a).getValue())

       return a;

   }

   // If this is reached, all inputs were statically known passing.

   return BoolAttr::get(getContext(), true);

 }


 LogicalResult AssumingAllOp::verify() {

   // Ensure that AssumingAllOp contains at least one operand

   if (getNumOperands() == 0)

     return emitOpError("no operands specified");


   return success();

 }


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

 // BroadcastOp

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


 OpFoldResult BroadcastOp::fold(FoldAdaptor adaptor) {

   if (getShapes().size() == 1) {

     // Otherwise, we need a cast which would be a canonicalization, not folding.

     if (getShapes().front().getType() != getType())

       return nullptr;

     return getShapes().front();

   }


   // TODO: Support folding with more than 2 input shapes

   if (getShapes().size() > 2)

     return nullptr;


   if (!adaptor.getShapes()[0] || !adaptor.getShapes()[1])

     return nullptr;

   auto lhsShape = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getShapes()[0])

           .getValues<int64_t>());

   auto rhsShape = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getShapes()[1])

           .getValues<int64_t>());

   SmallVector<int64_t, 6> resultShape;


   // If the shapes are not compatible, we can't fold it.

   // TODO: Fold to an "error".

   if (!OpTrait::util::getBroadcastedShape(lhsShape, rhsShape, resultShape))

     return nullptr;


   Builder builder(getContext());

   return builder.getIndexTensorAttr(resultShape);

 }


 LogicalResult BroadcastOp::verify() {

   return verifyShapeOrExtentTensorOp(*this);

 }


 namespace {

 template <typename OpTy>

 struct RemoveEmptyShapeOperandsPattern : public OpRewritePattern<OpTy> {

   using OpRewritePattern<OpTy>::OpRewritePattern;


   LogicalResult matchAndRewrite(OpTy op,

                                 PatternRewriter &rewriter) const override {

     auto isPotentiallyNonEmptyShape = [](Value shape) {

       if (auto extentTensorTy =

               llvm::dyn_cast<RankedTensorType>(shape.getType())) {

         if (extentTensorTy.getDimSize(0) == 0)

           return false;

       }

       if (auto constShape = shape.getDefiningOp<ConstShapeOp>()) {

         if (constShape.getShape().empty())

           return false;

       }

       return true;

     };

     auto newOperands = llvm::to_vector<8>(

         llvm::make_filter_range(op->getOperands(), isPotentiallyNonEmptyShape));


     // Reduce op to equivalent without empty shape operands.

     if (newOperands.size() < op.getNumOperands()) {

       rewriter.replaceOpWithNewOp<OpTy>(op, op->getResultTypes(), newOperands,

                                         op->getAttrs());

       return success();

     }


     return failure();

   }

 };


 struct BroadcastForwardSingleOperandPattern

     : public OpRewritePattern<BroadcastOp> {

   using OpRewritePattern<BroadcastOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(BroadcastOp op,

                                 PatternRewriter &rewriter) const override {

     if (op.getNumOperands() != 1)

       return failure();

     Value replacement = op.getShapes().front();


     // Insert cast if needed.

     if (replacement.getType() != op.getType()) {

       auto loc = op.getLoc();

       if (llvm::isa<ShapeType>(op.getType())) {

         replacement = rewriter.create<FromExtentTensorOp>(loc, replacement);

       } else {

         assert(!llvm::isa<ShapeType>(op.getType()) &&

                !llvm::isa<ShapeType>(replacement.getType()) &&

                "expect extent tensor cast");

         replacement =

             rewriter.create<tensor::CastOp>(loc, op.getType(), replacement);

       }

     }


     rewriter.replaceOp(op, replacement);

     return success();

   }

 };


 struct BroadcastFoldConstantOperandsPattern

     : public OpRewritePattern<BroadcastOp> {

   using OpRewritePattern<BroadcastOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(BroadcastOp op,

                                 PatternRewriter &rewriter) const override {

     SmallVector<int64_t, 8> foldedConstantShape;

     SmallVector<Value, 8> newShapeOperands;

     for (Value shape : op.getShapes()) {

       if (auto constShape = shape.getDefiningOp<ConstShapeOp>()) {

         SmallVector<int64_t, 8> newFoldedConstantShape;

         if (OpTrait::util::getBroadcastedShape(

                 foldedConstantShape,

                 llvm::to_vector<8>(constShape.getShape().getValues<int64_t>()),

                 newFoldedConstantShape)) {

           foldedConstantShape = newFoldedConstantShape;

           continue;

         }

       }

       newShapeOperands.push_back(shape);

     }


     // Need at least two constant operands to fold anything.

     if (op.getNumOperands() - newShapeOperands.size() < 2)

       return failure();


     auto foldedConstantOperandsTy = RankedTensorType::get(

         {static_cast<int64_t>(foldedConstantShape.size())},

         rewriter.getIndexType());

     newShapeOperands.push_back(rewriter.create<ConstShapeOp>(

         op.getLoc(), foldedConstantOperandsTy,

         rewriter.getIndexTensorAttr(foldedConstantShape)));

     rewriter.replaceOpWithNewOp<BroadcastOp>(op, op.getType(),

                                              newShapeOperands);

     return success();

   }

 };


 template <typename OpTy>

 struct CanonicalizeCastExtentTensorOperandsPattern

     : public OpRewritePattern<OpTy> {

   using OpRewritePattern<OpTy>::OpRewritePattern;


   LogicalResult matchAndRewrite(OpTy op,

                                 PatternRewriter &rewriter) const override {

     // Canonicalize operands.

     bool anyChange = false;

     auto canonicalizeOperand = [&](Value operand) -> Value {

       if (auto castOp = operand.getDefiningOp<tensor::CastOp>()) {

         // Only eliminate the cast if it holds no shape information.

         bool isInformationLoosingCast =

             llvm::cast<RankedTensorType>(castOp.getType()).isDynamicDim(0);

         if (isInformationLoosingCast) {

           anyChange = true;

           return castOp.getSource();

         }

       }

       return operand;

     };

     auto newOperands = llvm::to_vector<8>(

         llvm::map_range(op.getOperands(), canonicalizeOperand));


     // Rewrite op if any change required.

     if (!anyChange)

       return failure();

     rewriter.replaceOpWithNewOp<OpTy>(op, op->getResultTypes(), newOperands);

     return success();

   }

 };


 struct BroadcastConcretizeResultTypePattern

     : public OpRewritePattern<BroadcastOp> {

   using OpRewritePattern<BroadcastOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(BroadcastOp op,

                                 PatternRewriter &rewriter) const override {

     // Only concretize dynamic extent tensor result types.

     auto resultTy = llvm::dyn_cast<RankedTensorType>(op.getType());

     if (!resultTy || !resultTy.isDynamicDim(0))

       return failure();


     // Infer resulting shape rank if possible.

     int64_t maxRank = 0;

     for (Value shape : op.getShapes()) {

       if (auto extentTensorTy =

               llvm::dyn_cast<RankedTensorType>(shape.getType())) {

         // Cannot infer resulting shape rank if any operand is dynamically

         // ranked.

         if (extentTensorTy.isDynamicDim(0))

           return failure();

         maxRank = std::max(maxRank, extentTensorTy.getDimSize(0));

       }

     }


     auto newOp = rewriter.create<BroadcastOp>(

         op.getLoc(), getExtentTensorType(getContext(), maxRank),

         op.getShapes());

     rewriter.replaceOpWithNewOp<tensor::CastOp>(op, op.getType(), newOp);

     return success();

   }

 };

 } // namespace


 void BroadcastOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                               MLIRContext *context) {

   patterns.add<BroadcastConcretizeResultTypePattern,

                BroadcastFoldConstantOperandsPattern,

                BroadcastForwardSingleOperandPattern,

                CanonicalizeCastExtentTensorOperandsPattern<BroadcastOp>,

                RemoveDuplicateOperandsPattern<BroadcastOp>,

                RemoveEmptyShapeOperandsPattern<BroadcastOp>>(context);

 }


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

 // ConcatOp

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


 OpFoldResult ConcatOp::fold(FoldAdaptor adaptor) {

   if (!adaptor.getLhs() || !adaptor.getRhs())

     return nullptr;

   auto lhsShape = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getLhs()).getValues<int64_t>());

   auto rhsShape = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getRhs()).getValues<int64_t>());

   SmallVector<int64_t, 6> resultShape;

   resultShape.append(lhsShape.begin(), lhsShape.end());

   resultShape.append(rhsShape.begin(), rhsShape.end());

   Builder builder(getContext());

   return builder.getIndexTensorAttr(resultShape);

 }


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

 // ConstShapeOp

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


 void ConstShapeOp::print(OpAsmPrinter &p) {

   p << " ";

   p.printOptionalAttrDict((*this)->getAttrs(), /*elidedAttrs=*/{"shape"});

   p << "[";

   interleaveComma(getShape().getValues<int64_t>(), p);

   p << "] : ";

   p.printType(getType());

 }


 ParseResult ConstShapeOp::parse(OpAsmParser &parser, OperationState &result) {

   if (parser.parseOptionalAttrDict(result.attributes))

     return failure();

   // We piggy-back on ArrayAttr parsing, though we don't internally store the

   // shape as an ArrayAttr.

   // TODO: Implement custom parser and maybe make syntax a bit more concise.

   Attribute extentsRaw;

   NamedAttrList dummy;

   if (parser.parseAttribute(extentsRaw, "dummy", dummy))

     return failure();

   auto extentsArray = llvm::dyn_cast<ArrayAttr>(extentsRaw);

   if (!extentsArray)

     return failure();

   SmallVector<int64_t, 6> ints;

   for (Attribute extent : extentsArray) {

     IntegerAttr attr = llvm::dyn_cast<IntegerAttr>(extent);

     if (!attr)

       return failure();

     ints.push_back(attr.getInt());

   }

   Builder &builder = parser.getBuilder();

   result.addAttribute("shape", builder.getIndexTensorAttr(ints));

   Type resultTy;

   if (parser.parseColonType(resultTy))

     return failure();

   result.types.push_back(resultTy);

   return success();

 }


 OpFoldResult ConstShapeOp::fold(FoldAdaptor) { return getShapeAttr(); }


 void ConstShapeOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                MLIRContext *context) {

   patterns.add<TensorCastConstShape>(context);

 }


 LogicalResult mlir::shape::ConstShapeOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     ConstShapeOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   Builder b(context);

   const Properties prop = adaptor.getProperties();

   inferredReturnTypes.assign({RankedTensorType::get(

       {static_cast<int64_t>(prop.shape.size())}, b.getIndexType())});

   return success();

 }


 bool mlir::shape::ConstShapeOp::isCompatibleReturnTypes(TypeRange l,

                                                         TypeRange r) {

   if (l.size() != 1 || r.size() != 1)

     return false;


   Type lhs = l.front();

   Type rhs = r.front();


   if (llvm::isa<ShapeType>(lhs) || llvm::isa<ShapeType>(rhs))

     // Shape type is compatible with all other valid return types.

     return true;

   return lhs == rhs;

 }


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

 // CstrBroadcastableOp

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


 void CstrBroadcastableOp::getCanonicalizationPatterns(

     RewritePatternSet &patterns, MLIRContext *context) {

   // Canonicalization patterns have overlap with the considerations during

   // folding in case additional shape information is inferred at some point that

   // does not result in folding.

   patterns.add<CanonicalizeCastExtentTensorOperandsPattern<CstrBroadcastableOp>,

                CstrBroadcastableEqOps,

                RemoveDuplicateOperandsPattern<CstrBroadcastableOp>,

                RemoveEmptyShapeOperandsPattern<CstrBroadcastableOp>>(context);

 }


 // Return true if there is exactly one attribute not representing a scalar

 // broadcast.

 static bool hasAtMostSingleNonScalar(ArrayRef<Attribute> attributes) {

   bool nonScalarSeen = false;

   for (Attribute a : attributes) {

     if (!a || llvm::cast<DenseIntElementsAttr>(a).getNumElements() != 0) {

       if (nonScalarSeen)

         return false;

       nonScalarSeen = true;

     }

   }

   return true;

 }


 OpFoldResult CstrBroadcastableOp::fold(FoldAdaptor adaptor) {

   // No broadcasting is needed if all operands but one are scalar.

   if (hasAtMostSingleNonScalar(adaptor.getShapes()))

     return BoolAttr::get(getContext(), true);


   if ([&] {

         SmallVector<SmallVector<int64_t, 6>, 6> extents;

         for (const auto &operand : adaptor.getShapes()) {

           if (!operand)

             return false;

           extents.push_back(llvm::to_vector<6>(

               llvm::cast<DenseIntElementsAttr>(operand).getValues<int64_t>()));

         }

         return OpTrait::util::staticallyKnownBroadcastable(extents);

       }())

     return BoolAttr::get(getContext(), true);


   // Lastly, see if folding can be completed based on what constraints are known

   // on the input shapes.

   if ([&] {

         SmallVector<SmallVector<int64_t, 6>, 6> extents;

         for (auto shapeValue : getShapes()) {

           extents.emplace_back();

           if (failed(getShapeVec(shapeValue, extents.back())))

             return false;

         }

         return OpTrait::util::staticallyKnownBroadcastable(extents);

       }())

     return BoolAttr::get(getContext(), true);


   // Because a failing witness result here represents an eventual assertion

   // failure, we do not replace it with a constant witness.

   return nullptr;

 }


 LogicalResult CstrBroadcastableOp::verify() {

   // Ensure that CstrBroadcastableOp contains at least two operands

   if (getNumOperands() < 2)

     return emitOpError("required at least 2 input shapes");

   return success();

 }


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

 // CstrEqOp

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


 void CstrEqOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                            MLIRContext *context) {

   // If inputs are equal, return passing witness

   patterns.add<CstrEqEqOps>(context);

 }


 OpFoldResult CstrEqOp::fold(FoldAdaptor adaptor) {

   if (llvm::all_of(adaptor.getShapes(), [&](Attribute a) {

         return a && a == adaptor.getShapes().front();

       }))

     return BoolAttr::get(getContext(), true);


   // Because a failing witness result here represents an eventual assertion

   // failure, we do not try to replace it with a constant witness. Similarly, we

   // cannot if there are any non-const inputs.

   return nullptr;

 }


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

 // ConstSizeOp

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


 void ConstSizeOp::build(OpBuilder &builder, OperationState &result,

                         int64_t value) {

   build(builder, result, builder.getIndexAttr(value));

 }


 OpFoldResult ConstSizeOp::fold(FoldAdaptor) { return getValueAttr(); }


 void ConstSizeOp::getAsmResultNames(

     llvm::function_ref<void(Value, StringRef)> setNameFn) {

   SmallString<4> buffer;

   llvm::raw_svector_ostream os(buffer);

   os << "c" << getValue();

   setNameFn(getResult(), os.str());

 }


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

 // ConstWitnessOp

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


 OpFoldResult ConstWitnessOp::fold(FoldAdaptor) { return getPassingAttr(); }


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

 // CstrRequireOp

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


 OpFoldResult CstrRequireOp::fold(FoldAdaptor adaptor) {

   return adaptor.getPred();

 }


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

 // DimOp

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


 std::optional<int64_t> DimOp::getConstantIndex() {

   if (auto constSizeOp = getIndex().getDefiningOp<ConstSizeOp>())

     return constSizeOp.getValue().getLimitedValue();

   if (auto constantOp = getIndex().getDefiningOp<arith::ConstantOp>())

     return llvm::cast<IntegerAttr>(constantOp.getValue()).getInt();

   return std::nullopt;

 }


 OpFoldResult DimOp::fold(FoldAdaptor adaptor) {

   Type valType = getValue().getType();

   auto valShapedType = llvm::dyn_cast<ShapedType>(valType);

   if (!valShapedType || !valShapedType.hasRank())

     return nullptr;

   std::optional<int64_t> index = getConstantIndex();

   if (!index.has_value())

     return nullptr;

   if (index.value() < 0 || index.value() >= valShapedType.getRank())

     return nullptr;

   auto extent = valShapedType.getDimSize(*index);

   if (ShapedType::isDynamic(extent))

     return nullptr;

   return IntegerAttr::get(IndexType::get(getContext()), extent);

 }


 LogicalResult mlir::shape::DimOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     DimOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   inferredReturnTypes.assign({adaptor.getIndex().getType()});

   return success();

 }


 bool mlir::shape::DimOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


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

 // DivOp

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


 OpFoldResult DivOp::fold(FoldAdaptor adaptor) {

   auto lhs = llvm::dyn_cast_if_present<IntegerAttr>(adaptor.getLhs());

   if (!lhs)

     return nullptr;

   auto rhs = llvm::dyn_cast_if_present<IntegerAttr>(adaptor.getRhs());

   if (!rhs)

     return nullptr;


   // Division in APInt does not follow floor(lhs, rhs) when the result is

   // negative. Rather, APInt rounds toward zero.

   APInt quotient, remainder;

   APInt::sdivrem(lhs.getValue(), rhs.getValue(), quotient, remainder);

   if (quotient.isNegative() && !remainder.isZero()) {

     quotient -= 1;

   }


   Type indexTy = IndexType::get(getContext());

   return IntegerAttr::get(indexTy, quotient);

 }


 LogicalResult mlir::shape::DivOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     DivOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<SizeType>(adaptor.getLhs().getType()) ||

       llvm::isa<SizeType>(adaptor.getRhs().getType()))

     inferredReturnTypes.assign({SizeType::get(context)});

   else

     inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::DivOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 LogicalResult DivOp::verify() { return verifySizeOrIndexOp(*this); }


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

 // ShapeEqOp

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


 OpFoldResult ShapeEqOp::fold(FoldAdaptor adaptor) {

   bool allSame = true;

   if (!adaptor.getShapes().empty() && !adaptor.getShapes().front())

     return {};

   for (Attribute operand : adaptor.getShapes().drop_front()) {

     if (!operand)

       return {};

     allSame = allSame && operand == adaptor.getShapes().front();

   }

   return BoolAttr::get(getContext(), allSame);

 }


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

 // IndexToSizeOp

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


 OpFoldResult IndexToSizeOp::fold(FoldAdaptor adaptor) {

   // Constant values of both types, `shape.size` and `index`, are represented as

   // `IntegerAttr`s which makes constant folding simple.

   if (Attribute arg = adaptor.getArg())

     return arg;

   return {};

 }


 void IndexToSizeOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                 MLIRContext *context) {

   patterns.add<SizeToIndexToSizeCanonicalization>(context);

 }


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

 // FromExtentsOp

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


 OpFoldResult FromExtentsOp::fold(FoldAdaptor adaptor) {

   if (llvm::any_of(adaptor.getExtents(), [](Attribute a) { return !a; }))

     return nullptr;

   SmallVector<int64_t, 6> extents;

   for (auto attr : adaptor.getExtents())

     extents.push_back(llvm::cast<IntegerAttr>(attr).getInt());

   Builder builder(getContext());

   return builder.getIndexTensorAttr(extents);

 }


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

 // FunctionLibraryOp

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


 void FunctionLibraryOp::build(OpBuilder &builder, OperationState &result,

                               StringRef name) {

   result.attributes.push_back(builder.getNamedAttr(

       ::mlir::SymbolTable::getSymbolAttrName(), builder.getStringAttr(name)));

 }


 FuncOp FunctionLibraryOp::getShapeFunction(Operation *op) {

   auto attr = llvm::dyn_cast_or_null<FlatSymbolRefAttr>(

       getMapping().get(op->getName().getIdentifier()));

   if (!attr)

     return nullptr;

   return lookupSymbol<FuncOp>(attr);

 }


 ParseResult FunctionLibraryOp::parse(OpAsmParser &parser,

                                      OperationState &result) {

   // Parse the op name.

   StringAttr nameAttr;

   if (parser.parseSymbolName(nameAttr, ::mlir::SymbolTable::getSymbolAttrName(),

                              result.attributes))

     return failure();


   if (parser.parseOptionalAttrDictWithKeyword(result.attributes))

     return failure();


   auto *bodyRegion = result.addRegion();

   if (parser.parseRegion(*bodyRegion))

     return failure();


   if (parser.parseKeyword("mapping"))

     return failure();


   DictionaryAttr mappingAttr;

   if (parser.parseAttribute(mappingAttr,

                             parser.getBuilder().getType<NoneType>(), "mapping",

                             result.attributes))

     return failure();

   return success();

 }


 void FunctionLibraryOp::print(OpAsmPrinter &p) {

   p << ' ';

   p.printSymbolName(getName());

   p.printOptionalAttrDictWithKeyword(

       (*this)->getAttrs(), {mlir::SymbolTable::getSymbolAttrName(), "mapping"});

   p << ' ';

   p.printRegion(getRegion(), /*printEntryBlockArgs=*/false,

                 /*printBlockTerminators=*/false);

   p << " mapping ";

   p.printAttributeWithoutType(getMappingAttr());

 }


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

 // FuncOp

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


 FuncOp FuncOp::create(Location location, StringRef name, FunctionType type,

                       ArrayRef<NamedAttribute> attrs) {

   OpBuilder builder(location->getContext());

   OperationState state(location, getOperationName());

   FuncOp::build(builder, state, name, type, attrs);

   return cast<FuncOp>(Operation::create(state));

 }

 FuncOp FuncOp::create(Location location, StringRef name, FunctionType type,

                       Operation::dialect_attr_range attrs) {

   SmallVector<NamedAttribute, 8> attrRef(attrs);

   return create(location, name, type, llvm::ArrayRef(attrRef));

 }

 FuncOp FuncOp::create(Location location, StringRef name, FunctionType type,

                       ArrayRef<NamedAttribute> attrs,

                       ArrayRef<DictionaryAttr> argAttrs) {

   FuncOp func = create(location, name, type, attrs);

   func.setAllArgAttrs(argAttrs);

   return func;

 }


 void FuncOp::build(OpBuilder &builder, OperationState &state, StringRef name,

                    FunctionType type, ArrayRef<NamedAttribute> attrs,

                    ArrayRef<DictionaryAttr> argAttrs) {

   state.addAttribute(FuncOp::getSymNameAttrName(state.name),

                      builder.getStringAttr(name));

   state.addAttribute(FuncOp::getFunctionTypeAttrName(state.name),

                      TypeAttr::get(type));

   state.attributes.append(attrs.begin(), attrs.end());

   state.addRegion();


   if (argAttrs.empty())

     return;

   assert(type.getNumInputs() == argAttrs.size());

   function_interface_impl::addArgAndResultAttrs(

       builder, state, argAttrs, /*resultAttrs=*/std::nullopt,

       getArgAttrsAttrName(state.name), getResAttrsAttrName(state.name));

 }


 ParseResult FuncOp::parse(OpAsmParser &parser, OperationState &result) {

   auto buildFuncType =

       [](Builder &builder, ArrayRef<Type> argTypes, ArrayRef<Type> results,

          function_interface_impl::VariadicFlag,

          std::string &) { return builder.getFunctionType(argTypes, results); };


   return function_interface_impl::parseFunctionOp(

       parser, result, /*allowVariadic=*/false,

       getFunctionTypeAttrName(result.name), buildFuncType,

       getArgAttrsAttrName(result.name), getResAttrsAttrName(result.name));

 }


 void FuncOp::print(OpAsmPrinter &p) {

   function_interface_impl::printFunctionOp(

       p, *this, /*isVariadic=*/false, getFunctionTypeAttrName(),

       getArgAttrsAttrName(), getResAttrsAttrName());

 }


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

 // GetExtentOp

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


 std::optional<int64_t> GetExtentOp::getConstantDim() {

   if (auto constSizeOp = getDim().getDefiningOp<ConstSizeOp>())

     return constSizeOp.getValue().getLimitedValue();

   if (auto constantOp = getDim().getDefiningOp<arith::ConstantOp>())

     return llvm::cast<IntegerAttr>(constantOp.getValue()).getInt();

   return std::nullopt;

 }


 OpFoldResult GetExtentOp::fold(FoldAdaptor adaptor) {

   auto elements = llvm::dyn_cast_if_present<DenseIntElementsAttr>(adaptor.getShape());

   if (!elements)

     return nullptr;

   std::optional<int64_t> dim = getConstantDim();

   if (!dim.has_value())

     return nullptr;

   if (dim.value() >= elements.getNumElements())

     return nullptr;

   return elements.getValues<Attribute>()[(uint64_t)dim.value()];

 }


 void GetExtentOp::build(OpBuilder &builder, OperationState &result, Value shape,

                         int64_t dim) {

   auto loc = result.location;

   auto dimAttr = builder.getIndexAttr(dim);

   if (llvm::isa<ShapeType>(shape.getType())) {

     Value dim = builder.create<ConstSizeOp>(loc, dimAttr);

     build(builder, result, builder.getType<SizeType>(), shape, dim);

   } else {

     Value dim =

         builder.create<arith::ConstantOp>(loc, builder.getIndexType(), dimAttr);

     build(builder, result, builder.getIndexType(), shape, dim);

   }

 }


 LogicalResult mlir::shape::GetExtentOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     GetExtentOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::GetExtentOp::isCompatibleReturnTypes(TypeRange l,

                                                        TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 LogicalResult GetExtentOp::verify() { return verifySizeOrIndexOp(*this); }


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

 // IsBroadcastableOp

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


 void IsBroadcastableOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                     MLIRContext *context) {

   patterns.add<RemoveDuplicateOperandsPattern<IsBroadcastableOp>>(context);

 }


 OpFoldResult IsBroadcastableOp::fold(FoldAdaptor adaptor) {

   // Can always broadcast fewer than two shapes.

   if (adaptor.getShapes().size() < 2) {

     return BoolAttr::get(getContext(), true);

   }


   return nullptr;

 }


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

 // MeetOp

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


 LogicalResult mlir::shape::MeetOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     MeetOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (adaptor.getOperands().empty())

     return failure();


   auto isShapeType = [](Type arg) {

     if (llvm::isa<ShapeType>(arg))

       return true;

     return isExtentTensorType(arg);

   };


   ValueRange::type_range types = adaptor.getOperands().getTypes();

   Type acc = types.front();

   for (auto t : drop_begin(types)) {

     Type l = acc, r = t;

     if (!llvm::isa<ShapeType, SizeType>(l))

       std::swap(l, r);


     // Handle sizes, propagate error type if present.

     if (llvm::isa<SizeType>(l)) {

       if (llvm::isa<SizeType, IndexType>(r))

         acc = l;

       else

         return emitOptionalError(location, "requires all sizes or shapes");

     } else if (llvm::isa<IndexType>(l)) {

       if (llvm::isa<IndexType>(r))

         acc = r;

       else

         return emitOptionalError(location, "requires all sizes or shapes");

     } else if (llvm::isa<ShapeType>(l)) {

       // Handle shapes, propagate error type if present.

       if (isShapeType(r))

         acc = l;

       else

         return emitOptionalError(location, "requires all sizes or shapes");

     } else if (isExtentTensorType(l)) {

       auto rank1 = llvm::cast<RankedTensorType>(l).getShape()[0];

       auto rank2 = llvm::cast<RankedTensorType>(r).getShape()[0];

       if (ShapedType::isDynamic(rank1))

         acc = l;

       else if (ShapedType::isDynamic(rank2))

         acc = r;

       else if (rank1 != rank2)

         return emitOptionalError(location, "unequal shape cardinality");

       else

         acc = l;

     }

   }

   inferredReturnTypes.assign({acc});

   return success();

 }


 bool mlir::shape::MeetOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   if (l.size() != 1 || r.size() != 1)

     return false;

   if (l == r)

     return true;


   Type lhs = l.front();

   Type rhs = r.front();


   if (!llvm::isa<ShapeType, SizeType>(lhs))

     std::swap(lhs, rhs);


   if (llvm::isa<SizeType>(lhs))

     return llvm::isa<SizeType, IndexType>(rhs);

   if (llvm::isa<ShapeType>(lhs))

     return llvm::isa<ShapeType, TensorType>(rhs);


   if (succeeded(verifyCompatibleShapes({lhs, rhs})))

     return true;

   return false;

 }


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

 // RankOp

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


 OpFoldResult shape::RankOp::fold(FoldAdaptor adaptor) {

   auto shape = llvm::dyn_cast_if_present<DenseIntElementsAttr>(adaptor.getShape());

   if (!shape)

     return {};

   int64_t rank = shape.getNumElements();

   Builder builder(getContext());

   return builder.getIndexAttr(rank);

 }


 /// Evaluate the `rank` operation for shapes of ranked tensors at compile time.

 /// Constant folding fails in cases where only the rank is constant, not the

 /// shape itself.

 /// This canonicalization matches `shape.rank(shape.shape_of(%ranked_tensor))`.

 ///

 /// Example:

 ///

 /// %shape = shape.shape_of %ranked_tensor : tensor<1x2x?xf32>

 /// %rank = shape.rank %shape

 ///

 /// becomes

 ///

 /// %rank = shape.const_size 3


 namespace {

 struct RankShapeOfCanonicalizationPattern

     : public OpRewritePattern<shape::RankOp> {

   using OpRewritePattern<shape::RankOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(shape::RankOp op,

                                 PatternRewriter &rewriter) const override {

     auto shapeOfOp = op.getShape().getDefiningOp<ShapeOfOp>();

     if (!shapeOfOp)

       return failure();

     auto rankedTensorType =

         llvm::dyn_cast<RankedTensorType>(shapeOfOp.getArg().getType());

     if (!rankedTensorType)

       return failure();

     int64_t rank = rankedTensorType.getRank();

     if (llvm::isa<IndexType>(op.getType())) {

       rewriter.replaceOpWithNewOp<arith::ConstantIndexOp>(op.getOperation(),

                                                           rank);

     } else if (llvm::isa<shape::SizeType>(op.getType())) {

       rewriter.replaceOpWithNewOp<shape::ConstSizeOp>(op.getOperation(), rank);

     } else {

       return failure();

     }

     return success();

   }

 };

 } // namespace


 void shape::RankOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                 MLIRContext *context) {

   patterns.add<RankShapeOfCanonicalizationPattern>(context);

 }


 LogicalResult mlir::shape::RankOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     RankOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<ShapeType>(adaptor.getShape().getType()))

     inferredReturnTypes.assign({SizeType::get(context)});

   else

     inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::RankOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 LogicalResult shape::RankOp::verify() { return verifySizeOrIndexOp(*this); }


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

 // NumElementsOp

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


 OpFoldResult NumElementsOp::fold(FoldAdaptor adaptor) {


   // Fold only when argument constant.

   Attribute shape = adaptor.getShape();

   if (!shape)

     return {};


   APInt product(64, 1);

   for (auto value : llvm::cast<DenseIntElementsAttr>(shape))

     product *= value;

   Builder builder(getContext());

   return builder.getIndexAttr(product.getLimitedValue());

 }


 LogicalResult mlir::shape::NumElementsOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     NumElementsOp::Adaptor adaptor,

     SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<ShapeType>(adaptor.getShape().getType()))

     inferredReturnTypes.assign({SizeType::get(context)});

   else

     inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::NumElementsOp::isCompatibleReturnTypes(TypeRange l,

                                                          TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 LogicalResult shape::NumElementsOp::verify() {

   return verifySizeOrIndexOp(*this);

 }


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

 // MaxOp

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


 OpFoldResult MaxOp::fold(FoldAdaptor adaptor) {

   // If operands are equal, just propagate one.

   if (getLhs() == getRhs())

     return getLhs();

   return nullptr;

 }


 LogicalResult mlir::shape::MaxOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     MaxOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (adaptor.getLhs().getType() == adaptor.getRhs().getType())

     inferredReturnTypes.assign({adaptor.getLhs().getType()});

   else

     inferredReturnTypes.assign({SizeType::get(context)});

   return success();

 }


 bool mlir::shape::MaxOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   if (l.size() != 1 || r.size() != 1)

     return false;

   if (llvm::isa<ShapeType>(l.front()) && llvm::isa<ShapeType>(r.front()))

     return true;

   if (llvm::isa<SizeType>(l.front()) && llvm::isa<SizeType>(r.front()))

     return true;

   return false;

 }


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

 // MinOp

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


 OpFoldResult MinOp::fold(FoldAdaptor adaptor) {

   // If operands are equal, just propagate one.

   if (getLhs() == getRhs())

     return getLhs();

   return nullptr;

 }


 LogicalResult mlir::shape::MinOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     MinOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (adaptor.getLhs().getType() == adaptor.getRhs().getType())

     inferredReturnTypes.assign({adaptor.getLhs().getType()});

   else

     inferredReturnTypes.assign({SizeType::get(context)});

   return success();

 }


 bool mlir::shape::MinOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   if (l.size() != 1 || r.size() != 1)

     return false;

   if (llvm::isa<ShapeType>(l.front()) && llvm::isa<ShapeType>(r.front()))

     return true;

   if (llvm::isa<SizeType>(l.front()) && llvm::isa<SizeType>(r.front()))

     return true;

   return false;

 }


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

 // MulOp

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


 OpFoldResult MulOp::fold(FoldAdaptor adaptor) {

   auto lhs = llvm::dyn_cast_if_present<IntegerAttr>(adaptor.getLhs());

   if (!lhs)

     return nullptr;

   auto rhs = llvm::dyn_cast_if_present<IntegerAttr>(adaptor.getRhs());

   if (!rhs)

     return nullptr;

   APInt folded = lhs.getValue() * rhs.getValue();

   Type indexTy = IndexType::get(getContext());

   return IntegerAttr::get(indexTy, folded);

 }


 LogicalResult mlir::shape::MulOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     MulOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<SizeType>(adaptor.getLhs().getType()) ||

       llvm::isa<SizeType>(adaptor.getRhs().getType()))

     inferredReturnTypes.assign({SizeType::get(context)});

   else

     inferredReturnTypes.assign({IndexType::get(context)});

   return success();

 }


 bool mlir::shape::MulOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   // SizeType is compatible with IndexType.

   return eachHasOnlyOneOfTypes<SizeType, IndexType>(l, r);

 }


 LogicalResult shape::MulOp::verify() { return verifySizeOrIndexOp(*this); }


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

 // ShapeOfOp

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


 namespace {

 /// Replace shape_of(x) where x has a constant shape with a const_shape op.

 struct ShapeOfOpToConstShapeOp : public OpRewritePattern<shape::ShapeOfOp> {

   using OpRewritePattern<shape::ShapeOfOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(shape::ShapeOfOp op,

                                 PatternRewriter &rewriter) const override {

     auto type = llvm::dyn_cast<ShapedType>(op.getArg().getType());

     if (!type || !type.hasStaticShape())

       return failure();

     Location loc = op.getLoc();

     Value constShape =

         rewriter

             .create<ConstShapeOp>(loc,

                                   rewriter.getIndexTensorAttr(type.getShape()))

             .getResult();

     if (constShape.getType() != op.getResult().getType())

       constShape = rewriter.create<tensor::CastOp>(

           loc, op.getResult().getType(), constShape);

     rewriter.replaceOp(op, constShape);

     return success();

   }

 };


 // Canonicalize

 //

 // %0 = tensor.reshape %input(%shape) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>

 // %1 = shape.shape_of %0 : tensor<*xf32> -> tensor<?xindex>

 //

 // to

 //

 // %0 = tensor.reshape %input(%shape) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>

 // %1 = %shape

 //

 struct ShapeOfFromReshape : public OpRewritePattern<shape::ShapeOfOp> {

   using OpRewritePattern<shape::ShapeOfOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(shape::ShapeOfOp op,

                                 PatternRewriter &rewriter) const override {

     auto tensorReshapeOp = op.getArg().getDefiningOp<tensor::ReshapeOp>();

     if (!tensorReshapeOp)

       return rewriter.notifyMatchFailure(op, "producer is not tensor.reshape");

     if (!isa<TensorType>(op.getType()))

       return rewriter.notifyMatchFailure(op, "result is not a tensor");


     // Operand 'shape' of 'tensor.reshape' may now be used as the result of

     // 'shape.shape_of'. While its type is guaranteed to be compatible in well-

     // formed IR, it may not be identical (dynamically vs statically shaped),

     // in which case it needs to be cast first.

     Value shape = tensorReshapeOp.getShape();

     if (op.getType() != shape.getType())

       shape = rewriter.create<tensor::CastOp>(op.getLoc(), op.getType(), shape);


     rewriter.replaceOp(op, shape);

     return success();

   }

 };


 // Canonicalize

 // ```

 // %0 = shape.shape_of %arg : tensor<?x?x?xf32> -> tensor<3xindex>

 // %1 = tensor.cast %0 : tensor<3xindex> to tensor<?xindex>

 // ```

 // to

 // ```

 // %1 = shape.shape_of %arg : tensor<?x?x?xf32> -> tensor<?xindex>

 // ```

 struct ShapeOfCastExtentTensor : public OpRewritePattern<tensor::CastOp> {

   using OpRewritePattern<tensor::CastOp>::OpRewritePattern;


   LogicalResult matchAndRewrite(tensor::CastOp op,

                                 PatternRewriter &rewriter) const override {

     auto ty = llvm::dyn_cast<RankedTensorType>(op.getType());

     if (!ty || ty.getRank() != 1)

       return failure();


     auto shapeOfOp = op.getSource().getDefiningOp<ShapeOfOp>();

     if (!shapeOfOp)

       return failure();


     // Argument type must be ranked and must not conflict.

     auto argTy = llvm::dyn_cast<RankedTensorType>(shapeOfOp.getArg().getType());

     if (!argTy || (!ty.isDynamicDim(0) && ty.getDimSize(0) != argTy.getRank()))

       return failure();


     rewriter.replaceOpWithNewOp<ShapeOfOp>(op, ty, shapeOfOp.getArg());

     return success();

   }

 };

 } // namespace


 void ShapeOfOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                             MLIRContext *context) {

   patterns.add<ShapeOfCastExtentTensor, ShapeOfFromReshape,

                ExtractFromShapeOfExtentTensor, ShapeOfOpToConstShapeOp>(

       context);

 }


 LogicalResult mlir::shape::ShapeOfOp::inferReturnTypes(

     MLIRContext *context, std::optional<Location> location,

     ShapeOfOp::Adaptor adaptor, SmallVectorImpl<Type> &inferredReturnTypes) {

   if (llvm::isa<ValueShapeType>(adaptor.getArg().getType()))

     inferredReturnTypes.assign({ShapeType::get(context)});

   else {

     auto shapedTy = llvm::cast<ShapedType>(adaptor.getArg().getType());

     int64_t rank =

         shapedTy.hasRank() ? shapedTy.getRank() : ShapedType::kDynamic;

     Type indexTy = IndexType::get(context);

     Type extentTensorTy = RankedTensorType::get({rank}, indexTy);

     inferredReturnTypes.assign({extentTensorTy});

   }

   return success();

 }


 bool mlir::shape::ShapeOfOp::isCompatibleReturnTypes(TypeRange l, TypeRange r) {

   if (l.size() != 1 || r.size() != 1)

     return false;

   if (l == r)

     return true;


   Type lhs = l.front();

   Type rhs = r.front();


   if (!llvm::isa<ShapeType, ShapedType>(lhs) ||

       !llvm::isa<ShapeType, ShapedType>(rhs))

     return false;


   if (llvm::isa<ShapeType>(lhs) || llvm::isa<ShapeType>(rhs))

     // Shape type is compatible with all other valid return types.

     return true;


   if (succeeded(verifyCompatibleShapes({lhs, rhs})))

     return true;

   return false;

 }


 LogicalResult shape::ShapeOfOp::verify() {

   return verifyShapeOrExtentTensorOp(*this);

 }


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

 // SizeToIndexOp

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


 OpFoldResult SizeToIndexOp::fold(FoldAdaptor adaptor) {

   // Constant values of both types, `shape.size` and `index`, are represented as

   // `IntegerAttr`s which makes constant folding simple.

   if (Attribute arg = adaptor.getArg())

     return arg;

   return OpFoldResult();

 }


 void SizeToIndexOp::getCanonicalizationPatterns(RewritePatternSet &patterns,

                                                 MLIRContext *context) {

   patterns.add<IndexToSizeToIndexCanonicalization>(context);

 }


 bool SizeToIndexOp::areCastCompatible(TypeRange inputs, TypeRange outputs) {

   if (inputs.size() != 1 || outputs.size() != 1)

     return false;

   return llvm::isa<IndexType, SizeType>(inputs[0]) &&

          llvm::isa<IndexType>(outputs[0]);

 }


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

 // YieldOp

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


 LogicalResult shape::YieldOp::verify() {

   auto *parentOp = (*this)->getParentOp();

   auto results = parentOp->getResults();

   auto operands = getOperands();


   if (parentOp->getNumResults() != getNumOperands())

     return emitOpError() << "number of operands does not match number of "

                             "results of its parent";

   for (auto e : llvm::zip(results, operands))

     if (std::get<0>(e).getType() != std::get<1>(e).getType())

       return emitOpError() << "types mismatch between yield op and its parent";


   return success();

 }


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

 // SplitAtOp

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


 LogicalResult SplitAtOp::fold(FoldAdaptor adaptor,

                               SmallVectorImpl<OpFoldResult> &results) {

   if (!adaptor.getOperand() || !adaptor.getIndex())

     return failure();

   auto shapeVec = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getOperand()).getValues<int64_t>());

   auto shape = llvm::ArrayRef(shapeVec);

   auto splitPoint = llvm::cast<IntegerAttr>(adaptor.getIndex()).getInt();

   // Verify that the split point is in the correct range.

   // TODO: Constant fold to an "error".

   int64_t rank = shape.size();

   if (-rank > splitPoint || splitPoint > rank)

     return failure();

   if (splitPoint < 0)

     splitPoint += shape.size();

   Builder builder(adaptor.getOperand().getContext());

   results.push_back(builder.getIndexTensorAttr(shape.take_front(splitPoint)));

   results.push_back(builder.getIndexTensorAttr(shape.drop_front(splitPoint)));

   return success();

 }


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

 // ToExtentTensorOp

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


 OpFoldResult ToExtentTensorOp::fold(FoldAdaptor adaptor) {

   if (!adaptor.getInput())

     return OpFoldResult();

   Builder builder(getContext());

   auto shape = llvm::to_vector<6>(

       llvm::cast<DenseIntElementsAttr>(adaptor.getInput()).getValues<int64_t>());

   auto type = RankedTensorType::get({static_cast<int64_t>(shape.size())},

                                     builder.getIndexType());

   return DenseIntElementsAttr::get(type, shape);

 }


 bool ToExtentTensorOp::areCastCompatible(TypeRange inputs, TypeRange outputs) {

   if (inputs.size() != 1 || outputs.size() != 1)

     return false;

   if (auto inputTensor = llvm::dyn_cast<RankedTensorType>(inputs[0])) {

     if (!llvm::isa<IndexType>(inputTensor.getElementType()) ||

         inputTensor.getRank() != 1)

       return false;

   } else if (!llvm::isa<ShapeType>(inputs[0])) {

     return false;

   }


   TensorType outputTensor = llvm::dyn_cast<TensorType>(outputs[0]);

   return outputTensor && llvm::isa<IndexType>(outputTensor.getElementType());

 }


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

 // ReduceOp

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


 void ReduceOp::build(OpBuilder &builder, OperationState &result, Value shape,

                      ValueRange initVals) {

   OpBuilder::InsertionGuard g(builder);

   result.addOperands(shape);

   result.addOperands(initVals);


   Region *bodyRegion = result.addRegion();

   Block *bodyBlock = builder.createBlock(

       bodyRegion, /*insertPt=*/{}, builder.getIndexType(), result.location);


   Type elementType;

   if (auto tensorType = llvm::dyn_cast<TensorType>(shape.getType()))

     elementType = tensorType.getElementType();

   else

     elementType = SizeType::get(builder.getContext());

   bodyBlock->addArgument(elementType, shape.getLoc());


   for (Value initVal : initVals) {

     bodyBlock->addArgument(initVal.getType(), initVal.getLoc());

     result.addTypes(initVal.getType());

   }

 }


 LogicalResult ReduceOp::verify() {

   // Verify block arg types.

   Block &block = getRegion().front();


   // The block takes index, extent, and aggregated values as arguments.

   auto blockArgsCount = getInitVals().size() + 2;

   if (block.getNumArguments() != blockArgsCount)

     return emitOpError() << "ReduceOp body is expected to have "

                          << blockArgsCount << " arguments";


   // The first block argument is the index and must always be of type `index`.

   if (!llvm::isa<IndexType>(block.getArgument(0).getType()))

     return emitOpError(

         "argument 0 of ReduceOp body is expected to be of IndexType");


   // The second block argument is the extent and must be of type `size` or

   // `index`, depending on whether the reduce operation is applied to a shape or

   // to an extent tensor.

   Type extentTy = block.getArgument(1).getType();

   if (llvm::isa<ShapeType>(getShape().getType())) {

     if (!llvm::isa<SizeType>(extentTy))

       return emitOpError("argument 1 of ReduceOp body is expected to be of "

                          "SizeType if the ReduceOp operates on a ShapeType");

   } else {

     if (!llvm::isa<IndexType>(extentTy))

       return emitOpError(

           "argument 1 of ReduceOp body is expected to be of IndexType if the "

           "ReduceOp operates on an extent tensor");

   }


   for (const auto &type : llvm::enumerate(getInitVals()))

     if (block.getArgument(type.index() + 2).getType() != type.value().getType())

       return emitOpError() << "type mismatch between argument "

                            << type.index() + 2

                            << " of ReduceOp body and initial value "

                            << type.index();

   return success();

 }


 ParseResult ReduceOp::parse(OpAsmParser &parser, OperationState &result) {

   // Parse operands.

   SmallVector<OpAsmParser::UnresolvedOperand, 3> operands;

   Type shapeOrExtentTensorType;

   if (parser.parseOperandList(operands, /*requiredOperandCount=*/-1,

                               OpAsmParser::Delimiter::Paren) ||

       parser.parseColonType(shapeOrExtentTensorType) ||

       parser.parseOptionalArrowTypeList(result.types))

     return failure();


   // Resolve operands.

   auto initVals = llvm::ArrayRef(operands).drop_front();

   if (parser.resolveOperand(operands.front(), shapeOrExtentTensorType,

                             result.operands) ||

       parser.resolveOperands(initVals, result.types, parser.getNameLoc(),

                              result.operands))

     return failure();


   // Parse the body.

   Region *body = result.addRegion();

   if (parser.parseRegion(*body, /*args=*/{}, /*argTypes=*/{}))

     return failure();


   // Parse attributes.

   if (parser.parseOptionalAttrDict(result.attributes))

     return failure();


   return success();

 }


 void ReduceOp::print(OpAsmPrinter &p) {

   p << '(' << getShape() << ", " << getInitVals()

     << ") : " << getShape().getType();

   p.printOptionalArrowTypeList(getResultTypes());

   p << ' ';

   p.printRegion(getRegion());

   p.printOptionalAttrDict((*this)->getAttrs());

 }


 #define GET_OP_CLASSES

 #include "mlir/Dialect/Shape/IR/ShapeOps.cpp.inc"


 #define GET_TYPEDEF_CLASSES

 #include "mlir/Dialect/Shape/IR/ShapeOpsTypes.cpp.inc"

BufferizableOpInterface.h

Builders.h

CommonFolders.h

DialectImplementation.h

isErrorPropagationPossible
static bool isErrorPropagationPossible(TypeRange operandTypes)
Definition: Shape.cpp:67

hasAtMostSingleNonScalar
static bool hasAtMostSingleNonScalar(ArrayRef< Attribute > attributes)
Definition: Shape.cpp:962

verifyShapeOrExtentTensorOp
static LogicalResult verifyShapeOrExtentTensorOp(Operation *op)
Definition: Shape.cpp:84

eachHasOnlyOneOfTypes
static bool eachHasOnlyOneOfTypes(TypeRange typeRange)
Definition: Shape.cpp:97

verifySizeOrIndexOp
static LogicalResult verifySizeOrIndexOp(Operation *op)
Definition: Shape.cpp:72

materializeConstant
static Operation * materializeConstant(Dialect *dialect, OpBuilder &builder, Attribute value, Type type, Location loc)
A utility function used to materialize a constant for a given attribute and type.
Definition: FoldUtils.cpp:50

FunctionImplementation.h

product
static int64_t product(ArrayRef< int64_t > vals)
Definition: GPUHeuristics.cpp:116

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

isLegalToInline
static bool isLegalToInline(InlinerInterface &interface, Region *src, Region *insertRegion, bool shouldCloneInlinedRegion, IRMapping &valueMapping)
Utility to check that all of the operations within 'src' can be inlined.
Definition: InliningUtils.cpp:146

InliningUtils.h

getNumElements
static int64_t getNumElements(Type t)
Compute the total number of elements in the given type, also taking into account nested types.
Definition: LLVMDialect.cpp:2848

Matchers.h

PatternMatch.h

max
static Value max(ImplicitLocOpBuilder &builder, Value value, Value bound)
Definition: PolynomialApproximation.cpp:209

print
static void print(spirv::VerCapExtAttr triple, DialectAsmPrinter &printer)
Definition: SPIRVAttributes.cpp:623

getShape
static ArrayRef< int64_t > getShape(Type type)
Returns the shape of the given type.
Definition: Traits.cpp:118

Traits.h

TypeUtilities.h

UBOps.h

llvm::ArrayRef
Definition: LLVM.h:48

llvm::DenseSet
Definition: LLVM.h:59

llvm::SetVector
Definition: LLVM.h:66

llvm::SmallString
Definition: LLVM.h:41

llvm::SmallVectorImpl
Definition: LLVM.h:74

llvm::SmallVector
Definition: LLVM.h:72

llvm::function_ref
Definition: LLVM.h:90

llvm::iterator_range
Definition: LLVM.h:92

mlir::AsmParser::parseSymbolName
ParseResult parseSymbolName(StringAttr &result)
Parse an -identifier and store it (without the '@' symbol) in a string attribute.
Definition: OpImplementation.h:1153

mlir::AsmParser::Delimiter::Paren
@ Paren
Parens surrounding zero or more operands.

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

mlir::AsmParser::parseOptionalAttrDict
virtual ParseResult parseOptionalAttrDict(NamedAttrList &result)=0
Parse a named dictionary into 'result' if it is present.

mlir::AsmParser::parseOptionalAttrDictWithKeyword
virtual ParseResult parseOptionalAttrDictWithKeyword(NamedAttrList &result)=0
Parse a named dictionary into 'result' if the attributes keyword is present.

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

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

mlir::AsmParser::parseOptionalArrowTypeList
virtual ParseResult parseOptionalArrowTypeList(SmallVectorImpl< Type > &result)=0
Parse an optional arrow followed by a type list.

mlir::AsmParser::parseKeyword
ParseResult parseKeyword(StringRef keyword)
Parse a given keyword.
Definition: OpImplementation.h:889

mlir::AsmParser::parseAttribute
virtual ParseResult parseAttribute(Attribute &result, Type type={})=0
Parse an arbitrary attribute of a given type and return it in result.

mlir::AsmPrinter::printAttributeWithoutType
virtual void printAttributeWithoutType(Attribute attr)
Print the given attribute without its type.
Definition: AsmPrinter.cpp:2835

mlir::AsmPrinter::printType
virtual void printType(Type type)
Definition: AsmPrinter.cpp:2815

mlir::AsmPrinter::printSymbolName
virtual void printSymbolName(StringRef symbolRef)
Print the given string as a symbol reference, i.e.
Definition: AsmPrinter.cpp:2853

mlir::AsmPrinter::printOptionalArrowTypeList
void printOptionalArrowTypeList(TypeRange &&types)
Print an optional arrow followed by a type list.
Definition: OpImplementation.h:210

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

mlir::Attribute::getContext
MLIRContext * getContext() const
Return the context this attribute belongs to.
Definition: Attributes.cpp:37

mlir::Block
Block represents an ordered list of Operations.
Definition: Block.h:33

mlir::Block::getArgument
BlockArgument getArgument(unsigned i)
Definition: Block.h:129

mlir::Block::getNumArguments
unsigned getNumArguments()
Definition: Block.h:128

mlir::Block::back
Operation & back()
Definition: Block.h:152

mlir::Block::getTerminator
Operation * getTerminator()
Get the terminator operation of this block.
Definition: Block.cpp:246

mlir::Block::addArgument
BlockArgument addArgument(Type type, Location loc)
Add one value to the argument list.
Definition: Block.cpp:155

mlir::Block::front
Operation & front()
Definition: Block.h:153

mlir::BoolAttr::get
static BoolAttr get(MLIRContext *context, bool value)
Definition: MLIRContext.cpp:1176

mlir::Builder
This class is a general helper class for creating context-global objects like types,...
Definition: Builders.h:50

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

mlir::Builder::getFunctionType
FunctionType getFunctionType(TypeRange inputs, TypeRange results)
Definition: Builders.cpp:120

mlir::Builder::getType
Ty getType(Args &&...args)
Get or construct an instance of the type Ty with provided arguments.
Definition: Builders.h:99

mlir::Builder::getStringAttr
StringAttr getStringAttr(const Twine &bytes)
Definition: Builders.cpp:302

mlir::Builder::getIndexTensorAttr
DenseIntElementsAttr getIndexTensorAttr(ArrayRef< int64_t > values)
Definition: Builders.cpp:233

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

mlir::Builder::getIndexType
IndexType getIndexType()
Definition: Builders.cpp:95

mlir::Builder::getNamedAttr
NamedAttribute getNamedAttr(StringRef name, Attribute val)
Definition: Builders.cpp:134

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::DialectInlinerInterface
This is the interface that must be implemented by the dialects of operations to be inlined.
Definition: InliningUtils.h:44

mlir::DialectInlinerInterface::DialectInlinerInterface
DialectInlinerInterface(Dialect *dialect)
Definition: InliningUtils.h:46

mlir::IRMapping
This is a utility class for mapping one set of IR entities to another.
Definition: IRMapping.h:26

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::NamedAttrList
NamedAttrList is array of NamedAttributes that tracks whether it is sorted and does some basic work t...
Definition: OperationSupport.h:801

mlir::NamedAttrList::push_back
void push_back(NamedAttribute newAttribute)
Add an attribute with the specified name.
Definition: OperationSupport.cpp:76

mlir::NamedAttribute
NamedAttribute represents a combination of a name and an Attribute value.
Definition: Attributes.h:207

mlir::NamedAttribute::getName
StringAttr getName() const
Return the name of the attribute.
Definition: Attributes.cpp:49

mlir::NamedAttribute::getValue
Attribute getValue() const
Return the value of the attribute.
Definition: Attributes.h:221

mlir::OpAsmParser
The OpAsmParser has methods for interacting with the asm parser: parsing things from it,...
Definition: OpImplementation.h:1462

mlir::OpAsmParser::parseRegion
virtual ParseResult parseRegion(Region &region, ArrayRef< Argument > arguments={}, bool enableNameShadowing=false)=0
Parses a region.

mlir::OpAsmParser::resolveOperand
virtual ParseResult resolveOperand(const UnresolvedOperand &operand, Type type, SmallVectorImpl< Value > &result)=0
Resolve an operand to an SSA value, emitting an error on failure.

mlir::OpAsmParser::resolveOperands
ParseResult resolveOperands(Operands &&operands, Type type, SmallVectorImpl< Value > &result)
Resolve a list of operands to SSA values, emitting an error on failure, or appending the results to t...
Definition: OpImplementation.h:1582

mlir::OpAsmParser::parseOperand
virtual ParseResult parseOperand(UnresolvedOperand &result, bool allowResultNumber=true)=0
Parse a single SSA value operand name along with a result number if allowResultNumber is true.

mlir::OpAsmParser::parseOperandList
virtual ParseResult parseOperandList(SmallVectorImpl< UnresolvedOperand > &result, Delimiter delimiter=Delimiter::None, bool allowResultNumber=true, int requiredOperandCount=-1)=0
Parse zero or more SSA comma-separated operand references with a specified surrounding delimiter,...

mlir::OpAsmPrinter
This is a pure-virtual base class that exposes the asmprinter hooks necessary to implement a custom p...
Definition: OpImplementation.h:412

mlir::OpAsmPrinter::printOptionalAttrDictWithKeyword
virtual void printOptionalAttrDictWithKeyword(ArrayRef< NamedAttribute > attrs, ArrayRef< StringRef > elidedAttrs={})=0
If the specified operation has attributes, print out an attribute dictionary prefixed with 'attribute...

mlir::OpAsmPrinter::printOptionalAttrDict
virtual void printOptionalAttrDict(ArrayRef< NamedAttribute > attrs, ArrayRef< StringRef > elidedAttrs={})=0
If the specified operation has attributes, print out an attribute dictionary with their values.

mlir::OpAsmPrinter::printRegion
virtual void printRegion(Region &blocks, bool printEntryBlockArgs=true, bool printBlockTerminators=true, bool printEmptyBlock=false)=0
Prints a region.

mlir::OpBuilder::InsertionGuard
RAII guard to reset the insertion point of the builder when destroyed.
Definition: Builders.h:356

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

mlir::OpBuilder::getInsertionPoint
Block::iterator getInsertionPoint() const
Returns the current insertion point of the builder.
Definition: Builders.h:453

mlir::OpBuilder::setInsertionPoint
void setInsertionPoint(Block *block, Block::iterator insertPoint)
Set the insertion point to the specified location.
Definition: Builders.h:406

mlir::OpBuilder::setInsertionPointToEnd
void setInsertionPointToEnd(Block *block)
Sets the insertion point to the end of the specified block.
Definition: Builders.h:444

mlir::OpBuilder::createBlock
Block * createBlock(Region *parent, Region::iterator insertPt={}, TypeRange argTypes=std::nullopt, ArrayRef< Location > locs=std::nullopt)
Add new block with 'argTypes' arguments and set the insertion point to the end of it.
Definition: Builders.cpp:470

mlir::OpBuilder::create
Operation * create(const OperationState &state)
Creates an operation given the fields represented as an OperationState.
Definition: Builders.cpp:497

mlir::OpBuilder::getInsertionBlock
Block * getInsertionBlock() const
Return the block the current insertion point belongs to.
Definition: Builders.h:450

mlir::OpFoldResult
This class represents a single result from folding an operation.
Definition: OpDefinition.h:268

mlir::OpTrait::SymbolTable
A trait used to provide symbol table functionalities to a region operation.
Definition: SymbolTable.h:435

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::hasTrait
bool hasTrait()
Returns true if the operation was registered with a particular trait, e.g.
Definition: Operation.h:745

mlir::Operation::create
static Operation * create(Location location, OperationName name, TypeRange resultTypes, ValueRange operands, NamedAttrList &&attributes, OpaqueProperties properties, BlockRange successors, unsigned numRegions)
Create a new Operation with the specific fields.
Definition: Operation.cpp:67

mlir::Operation::emitError
InFlightDiagnostic emitError(const Twine &message={})
Emit an error about fatal conditions with this operation, reporting up to any diagnostic handlers tha...
Definition: Operation.cpp:268

mlir::Operation::getName
OperationName getName()
The name of an operation is the key identifier for it.
Definition: Operation.h:119

mlir::Operation::getOperandTypes
operand_type_range getOperandTypes()
Definition: Operation.h:392

mlir::Operation::getResultTypes
result_type_range getResultTypes()
Definition: Operation.h:423

mlir::Operation::emitOpError
InFlightDiagnostic emitOpError(const Twine &message={})
Emit an error with the op name prefixed, like "'dim' op " which is convenient for verifiers.
Definition: Operation.cpp:671

mlir::Operation::getNumResults
unsigned getNumResults()
Return the number of results held by this operation.
Definition: Operation.h:399

mlir::PatternRewriter
A special type of RewriterBase that coordinates the application of a rewrite pattern on the current I...
Definition: PatternMatch.h:791

mlir::RegionBranchPoint
This class represents a point being branched from in the methods of the RegionBranchOpInterface.
Definition: ControlFlowInterfaces.h:198

mlir::RegionBranchPoint::isParent
bool isParent() const
Returns true if branching from the parent op.
Definition: ControlFlowInterfaces.h:231

mlir::RegionSuccessor
This class represents a successor of a region.
Definition: ControlFlowInterfaces.h:165

mlir::Region
This class contains a list of basic blocks and a link to the parent operation it is attached to.
Definition: Region.h:26

mlir::RewritePatternSet
Definition: PatternMatch.h:814

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:853

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:724

mlir::RewriterBase::splitBlock
Block * splitBlock(Block *block, Block::iterator before)
Split the operations starting at "before" (inclusive) out of the given block into a new block,...
Definition: PatternMatch.cpp:346

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::mergeBlocks
void mergeBlocks(Block *source, Block *dest, ValueRange argValues=std::nullopt)
Inline the operations of block 'source' into the end of block 'dest'.
Definition: PatternMatch.cpp:339

mlir::RewriterBase::eraseOp
virtual void eraseOp(Operation *op)
This method erases an operation that is known to have no uses.
Definition: PatternMatch.cpp:161

mlir::RewriterBase::inlineRegionBefore
void inlineRegionBefore(Region &region, Region &parent, Region::iterator before)
Move the blocks that belong to "region" before the given position in another region "parent".
Definition: PatternMatch.cpp:372

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:542

mlir::SymbolTable::getSymbolAttrName
static StringRef getSymbolAttrName()
Return the name of the attribute used for symbol names.
Definition: SymbolTable.h:76

mlir::SymbolTable::lookupSymbolIn
static Operation * lookupSymbolIn(Operation *op, StringAttr symbol)
Returns the operation registered with the given symbol name with the regions of 'symbolTableOp'.
Definition: SymbolTable.cpp:385

mlir::TensorType
Tensor types represent multi-dimensional arrays, and have two variants: RankedTensorType and Unranked...
Definition: BuiltinTypes.h:102

mlir::TensorType::getElementType
Type getElementType() const
Returns the element type of this tensor type.
Definition: BuiltinTypes.cpp:277

mlir::TypeRange
This class provides an abstraction over the various different ranges of value types.
Definition: TypeRange.h:36

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

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

mlir::ValueRange::type_range
ValueTypeRange< ValueRange > type_range
Definition: ValueRange.h:410

mlir::ValueTypeRange::front
Type front()
Return first type in the range.
Definition: TypeRange.h:148

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

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

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

mlir::function_interface_impl::VariadicFlag
A named class for passing around the variadic flag.
Definition: FunctionImplementation.h:26

Arith.h

Shape.h

Tensor.h

BuiltinTypes.h

mlir::OpTrait::util::staticallyKnownBroadcastable
bool staticallyKnownBroadcastable(ArrayRef< SmallVector< int64_t, 6 >> shapes)
Returns true if a broadcast between n shapes is guaranteed to be successful and not result in an erro...
Definition: Traits.cpp:25

mlir::OpTrait::util::getBroadcastedShape
bool getBroadcastedShape(ArrayRef< int64_t > shape1, ArrayRef< int64_t > shape2, SmallVectorImpl< int64_t > &resultShape)
Returns true and sets resultShape to the broadcasted shape from the two given shapes if they are broa...
Definition: Traits.cpp:60

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

mlir::function_interface_impl::addArgAndResultAttrs
void addArgAndResultAttrs(Builder &builder, OperationState &result, ArrayRef< DictionaryAttr > argAttrs, ArrayRef< DictionaryAttr > resultAttrs, StringAttr argAttrsName, StringAttr resAttrsName)
Adds argument and result attributes, provided as argAttrs and resultAttrs arguments,...
Definition: FunctionImplementation.cpp:128

mlir::function_interface_impl::printFunctionOp
void printFunctionOp(OpAsmPrinter &p, FunctionOpInterface op, bool isVariadic, StringRef typeAttrName, StringAttr argAttrsName, StringAttr resAttrsName)
Printer implementation for function-like operations.
Definition: FunctionImplementation.cpp:315

mlir::function_interface_impl::parseFunctionOp
ParseResult parseFunctionOp(OpAsmParser &parser, OperationState &result, bool allowVariadic, StringAttr typeAttrName, FuncTypeBuilder funcTypeBuilder, StringAttr argAttrsName, StringAttr resAttrsName)
Parser implementation for function-like operations.
Definition: FunctionImplementation.cpp:164

mlir::presburger::detail::getIndex
DynamicAPInt getIndex(const ConeV &cone)
Get the index of a cone, i.e., the volume of the parallelepiped spanned by its generators,...
Definition: Barvinok.cpp:63

mlir::query::parse
QueryRef parse(llvm::StringRef line, const QuerySession &qs)
Definition: Query.cpp:20

mlir::shape
Definition: ShapeMappingAnalysis.h:20

mlir::shape::isExtentTensorType
bool isExtentTensorType(Type)
Definition: Shape.cpp:45

mlir::shape::getShapeVec
LogicalResult getShapeVec(Value input, SmallVectorImpl< int64_t > &shapeValues)
Definition: Shape.cpp:50

mlir::shape::getExtentTensorType
RankedTensorType getExtentTensorType(MLIRContext *ctx, int64_t rank=ShapedType::kDynamic)
Alias type for extent tensors.
Definition: Shape.cpp:41

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::verifyCompatibleShapes
LogicalResult verifyCompatibleShapes(TypeRange types1, TypeRange types2)
Returns success if the given two arrays have the same number of elements and each pair wise entries h...
Definition: TypeUtilities.cpp:95

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

mlir::emitOptionalError
LogicalResult emitOptionalError(std::optional< Location > loc, Args &&...args)
Overloads of the above emission functions that take an optionally null location.
Definition: Diagnostics.h:497

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

mlir::m_Zero
detail::constant_int_predicate_matcher m_Zero()
Matches a constant scalar / vector splat / tensor splat integer zero.
Definition: Matchers.h:437

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::m_Constant
detail::constant_op_matcher m_Constant()
Matches a constant foldable operation.
Definition: Matchers.h:369

mlir::verify
LogicalResult verify(Operation *op, bool verifyRecursively=true)
Perform (potentially expensive) checks of invariants, used to detect compiler bugs,...
Definition: Verifier.cpp:426

mlir::OpAsmParser::UnresolvedOperand
This is the representation of an operand reference.
Definition: OpImplementation.h:1513

mlir::OpRewritePattern
OpRewritePattern is a wrapper around RewritePattern that allows for matching and rewriting against an...
Definition: PatternMatch.h:358

mlir::OperationState
This represents an operation in an abstracted form, suitable for use with the builder APIs.
Definition: OperationSupport.h:950

mlir::OperationState::operands
SmallVector< Value, 4 > operands
Definition: OperationSupport.h:953

mlir::OperationState::name
OperationName name
Definition: OperationSupport.h:952

mlir::OperationState::addOperands
void addOperands(ValueRange newOperands)
Definition: OperationSupport.cpp:212

mlir::OperationState::addAttribute
void addAttribute(StringRef name, Attribute attr)
Add an attribute with the specified name.
Definition: OperationSupport.h:1035

mlir::OperationState::addTypes
void addTypes(ArrayRef< Type > newTypes)
Definition: OperationSupport.h:1025

mlir::OperationState::regions
SmallVector< std::unique_ptr< Region >, 1 > regions
Regions that the op will hold.
Definition: OperationSupport.h:960

mlir::OperationState::attributes
NamedAttrList attributes
Definition: OperationSupport.h:956

mlir::OperationState::types
SmallVector< Type, 4 > types
Types of the results of this operation.
Definition: OperationSupport.h:955

mlir::OperationState::location
Location location
Definition: OperationSupport.h:951

mlir::OperationState::addRegion
Region * addRegion()
Create a region that should be attached to the operation.
Definition: OperationSupport.cpp:220