Summary: Generalize broadcastable trait to variadic operands. Update the documentation that still talked about element type as part of broadcastable trait (that bug was already fixed). Also rename Broadcastable to ResultBroadcastableShape to be more explicit that the trait affects the result shape (it is possible for op to allow broadcastable operands but not have result shape that is broadcast compatible with operands). Doing some intermediate work to have getBroadcastedType take an optional elementType as input and use that if specified, instead of the common element type of type1 and type2 in this function. Differential Revision: https://reviews.llvm.org/D72559
219 lines
8.2 KiB
C++
219 lines
8.2 KiB
C++
//===- Traits.cpp - Common op traits shared by dialects -------------------===//
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//
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// Part of the MLIR Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "mlir/Dialect/Traits.h"
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#include "mlir/IR/StandardTypes.h"
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#include "mlir/IR/TypeUtilities.h"
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#include "llvm/Support/FormatVariadic.h"
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using namespace mlir;
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bool OpTrait::util::getBroadcastedShape(ArrayRef<int64_t> shape1,
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ArrayRef<int64_t> shape2,
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SmallVectorImpl<int64_t> &resultShape) {
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// To compute the result broadcasted shape, we compare operand shapes
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// element-wise: starting with the trailing dimensions, and working the
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// way backward. Two dimensions are compatible when
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// 1. they are equal, or
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// 2. one of them is 1
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// The result shape has the maximum among the two inputs at every
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// dimension index.
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resultShape.clear();
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if (shape1.size() > shape2.size()) {
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std::copy(shape1.begin(), shape1.end(), std::back_inserter(resultShape));
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} else {
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std::copy(shape2.begin(), shape2.end(), std::back_inserter(resultShape));
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}
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auto i1 = shape1.rbegin(), e1 = shape1.rend();
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auto i2 = shape2.rbegin(), e2 = shape2.rend();
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auto iR = resultShape.rbegin();
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// Check each dimension is consistent.
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for (; i1 != e1 && i2 != e2; ++i1, ++i2, ++iR) {
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if (*i1 == -1 || *i2 == -1) {
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// One or both dimensions is unknown. Follow TensorFlow behavior:
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// - If either dimension is greater than 1, we assume that the program is
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// correct, and the other dimension will be broadcast to match it.
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// - If either dimension is 1, the other dimension is the output.
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if (*i1 > 1) {
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*iR = *i1;
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} else if (*i2 > 1) {
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*iR = *i2;
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} else if (*i1 == 1) {
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*iR = *i2;
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} else if (*i2 == 1) {
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*iR = *i1;
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} else {
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*iR = -1;
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}
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} else {
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if (*i1 == *i2 || *i2 == 1) {
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*iR = *i1;
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} else if (*i1 == 1) {
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*iR = *i2;
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} else {
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// This dimension of the two operand types is incompatible.
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resultShape.clear();
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return false;
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}
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}
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}
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return true;
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}
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/// Returns the shape of the given type. Scalars will be considered as having a
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/// shape with zero dimensions.
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static ArrayRef<int64_t> getShape(Type type) {
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if (auto sType = type.dyn_cast<ShapedType>())
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return sType.getShape();
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return {};
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}
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/// Returns the result broadcast composition type from the two given types by
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/// following NumPy broadcast semantics. Returned type may have dynamic shape if
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/// either of the input types has dynamic shape. Returns null type if the two
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/// given types are not broadcast-compatible.
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///
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/// elementType, if specified, will be used as the element type of the
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/// broadcasted result type. Otherwise it is required that the element type of
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/// type1 and type2 is the same and this element type will be used as the
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/// resultant element type.
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Type OpTrait::util::getBroadcastedType(Type type1, Type type2,
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Type elementType) {
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// If the elementType is not specified, then the use the common element type
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// of the inputs or fail if there is no common element type.
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if (!elementType) {
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elementType = getElementTypeOrSelf(type1);
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if (elementType != getElementTypeOrSelf(type2))
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return {};
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}
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// If one of the types is unranked tensor, then the other type shouldn't be
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// vector and the result should have unranked tensor type.
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if (type1.isa<UnrankedTensorType>() || type2.isa<UnrankedTensorType>()) {
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if (type1.isa<VectorType>() || type2.isa<VectorType>())
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return {};
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return UnrankedTensorType::get(elementType);
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}
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// Returns the type kind if the given type is a vector or ranked tensor type.
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// Returns llvm::None otherwise.
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auto getCompositeTypeKind = [](Type type) -> Optional<StandardTypes::Kind> {
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if (type.isa<VectorType>() || type.isa<RankedTensorType>())
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return static_cast<StandardTypes::Kind>(type.getKind());
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return llvm::None;
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};
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// Make sure the composite type, if has, is consistent.
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auto compositeKind1 = getCompositeTypeKind(type1);
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auto compositeKind2 = getCompositeTypeKind(type2);
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Optional<StandardTypes::Kind> resultCompositeKind;
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if (compositeKind1 && compositeKind2) {
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// Disallow mixing vector and tensor.
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if (compositeKind1 != compositeKind2)
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return {};
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resultCompositeKind = compositeKind1;
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} else if (compositeKind1) {
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resultCompositeKind = compositeKind1;
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} else if (compositeKind2) {
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resultCompositeKind = compositeKind2;
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}
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// Get the shape of each type.
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SmallVector<int64_t, 4> resultShape;
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if (!getBroadcastedShape(getShape(type1), getShape(type2), resultShape))
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return {};
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// Compose the final broadcasted type
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if (resultCompositeKind == StandardTypes::Vector)
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return VectorType::get(resultShape, elementType);
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if (resultCompositeKind == StandardTypes::RankedTensor)
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return RankedTensorType::get(resultShape, elementType);
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return elementType;
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}
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/// Returns a tuple corresponding to whether range has tensor or vector type.
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template <typename iterator_range>
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static std::tuple<bool, bool> hasTensorOrVectorType(iterator_range types) {
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return std::make_tuple(
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llvm::any_of(types, [](Type t) { return t.isa<TensorType>(); }),
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llvm::any_of(types, [](Type t) { return t.isa<VectorType>(); }));
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}
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static bool areCompatibleShapes(ArrayRef<int64_t> shape1,
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ArrayRef<int64_t> shape2) {
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auto isCompatible = [](int64_t dim1, int64_t dim2) {
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return dim1 == dim2 || dim1 == -1 || dim2 == -1;
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};
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if (shape1.size() != shape2.size())
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return false;
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for (auto p : llvm::zip(shape1, shape2))
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if (!isCompatible(std::get<0>(p), std::get<1>(p)))
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return false;
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return true;
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}
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static std::string getShapeString(ArrayRef<int64_t> shape) {
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// TODO: should replace with printing shape more uniformly across here and
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// when in type.
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return formatv("'{0:$[x]}'", llvm::make_range(shape.begin(), shape.end()));
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}
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LogicalResult OpTrait::impl::verifyCompatibleOperandBroadcast(Operation *op) {
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// Ensure broadcasting only tensor or only vector types.
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auto operandsHasTensorVectorType =
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hasTensorOrVectorType(op->getOperandTypes());
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auto resultsHasTensorVectorType = hasTensorOrVectorType(op->getResultTypes());
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if ((std::get<0>(operandsHasTensorVectorType) ||
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std::get<0>(resultsHasTensorVectorType)) &&
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(std::get<1>(operandsHasTensorVectorType) ||
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std::get<1>(resultsHasTensorVectorType)))
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return op->emitError("cannot broadcast vector with tensor");
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auto rankedOperands = make_filter_range(
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op->getOperandTypes(), [](Type t) { return t.isa<RankedTensorType>(); });
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// If all operands are unranked, then all result shapes are possible.
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if (rankedOperands.empty())
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return success();
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// Compute broadcasted shape of operands (which requires that operands are
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// broadcast compatible). The results need to be broadcast compatible with
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// this result shape.
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SmallVector<int64_t, 4> resultShape;
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(void)util::getBroadcastedShape(getShape(*rankedOperands.begin()), {},
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resultShape);
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for (auto other : make_early_inc_range(rankedOperands)) {
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SmallVector<int64_t, 4> temp = resultShape;
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if (!util::getBroadcastedShape(temp, getShape(other), resultShape))
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return op->emitOpError("operands don't have broadcast-compatible shapes");
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}
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auto rankedResults = make_filter_range(
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op->getResultTypes(), [](Type t) { return t.isa<RankedTensorType>(); });
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// If all of the results are unranked then no further verfication.
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if (rankedResults.empty())
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return success();
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for (auto type : rankedResults) {
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ArrayRef<int64_t> actualSuffix =
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getShape(type).take_back(resultShape.size());
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if (!areCompatibleShapes(actualSuffix, resultShape))
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return op->emitOpError()
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<< "result type " << getShapeString(getShape(type))
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<< " not broadcast compatible with broadcasted operands's shapes "
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<< getShapeString(resultShape);
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}
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return success();
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}
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