Legalize MinimumBroadcastShapes op.

Use it in TransformUnrankedHloPass, which allows to reduce the maximum
rank for rank specialized broadcast from 6 to 5.

PiperOrigin-RevId: 360415743
This commit is contained in:
Adrian Kuegel 2021-03-02 06:37:48 -08:00 committed by TensorFlow MLIR Team
parent 329b1fd071
commit 0683db3b24
3 changed files with 102 additions and 77 deletions

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@ -51,6 +51,7 @@ struct ChloLegalizeToHloPass
conversionTarget.addLegalDialect< conversionTarget.addLegalDialect<
MhloDialect, mlir::StandardOpsDialect, mlir::tensor::TensorDialect, MhloDialect, mlir::StandardOpsDialect, mlir::tensor::TensorDialect,
mlir::shape::ShapeDialect, mlir::scf::SCFDialect>(); mlir::shape::ShapeDialect, mlir::scf::SCFDialect>();
conversionTarget.addLegalOp<chlo::MinimumBroadcastShapesOp>();
if (broadcast_only_) { if (broadcast_only_) {
chlo::PopulateChloBroadcastingPatterns(&getContext(), chlo::PopulateChloBroadcastingPatterns(&getContext(),

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@ -223,9 +223,8 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
} }
static Value createBroadcastToKnownRank(OpBuilder &builder, ChloOpTy op, static Value createBroadcastToKnownRank(OpBuilder &builder, ChloOpTy op,
Value value, int targeted_rank) { Value shape, int targeted_rank) {
auto loc = op.getLoc(); auto loc = op.getLoc();
Value shape = builder.create<shape::ShapeOfOp>(loc, value);
SmallVector<int64_t, 6> ranked_shape(targeted_rank, 1); SmallVector<int64_t, 6> ranked_shape(targeted_rank, 1);
auto unknown_rank_extent_tensor_type = RankedTensorType::get( auto unknown_rank_extent_tensor_type = RankedTensorType::get(
{RankedTensorType::kDynamicSize}, builder.getIndexType()); {RankedTensorType::kDynamicSize}, builder.getIndexType());
@ -246,6 +245,7 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
static void createRankSpecializedBroadcastAndOp(OpBuilder &if_builder, static void createRankSpecializedBroadcastAndOp(OpBuilder &if_builder,
ChloOpTy op, ChloOpTy op,
ValueRange operands, ValueRange operands,
ValueRange operand_shapes,
int targeted_rank) { int targeted_rank) {
auto loc = op.getLoc(); auto loc = op.getLoc();
SmallVector<Value, 2> reshaped_operands; SmallVector<Value, 2> reshaped_operands;
@ -253,10 +253,12 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
auto dynamic_dimensions = llvm::SmallVector<int64_t, 6>( auto dynamic_dimensions = llvm::SmallVector<int64_t, 6>(
targeted_rank, RankedTensorType::kDynamicSize); targeted_rank, RankedTensorType::kDynamicSize);
for (Value operand : operands) { for (auto it : llvm::zip(operands, operand_shapes)) {
Value operand, shape;
std::tie(operand, shape) = it;
// Handle shape broadcasting and inference. // Handle shape broadcasting and inference.
Value extended_operand_casted = Value extended_operand_casted =
createBroadcastToKnownRank(if_builder, op, operand, targeted_rank); createBroadcastToKnownRank(if_builder, op, shape, targeted_rank);
// 1. Reshape operands to the given rank (with the same number of // 1. Reshape operands to the given rank (with the same number of
// elements) // elements)
@ -290,13 +292,37 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
ValueRange operands) { ValueRange operands) {
auto loc = op.getLoc(); auto loc = op.getLoc();
// Find the larger rank of the operands. // Get the minimum broadcast shapes of the operands.
SmallVector<Value> shapes;
shapes.reserve(operands.size());
auto extent_tensor_type = RankedTensorType::get({ShapedType::kDynamicSize}, auto extent_tensor_type = RankedTensorType::get({ShapedType::kDynamicSize},
rewriter.getIndexType()); rewriter.getIndexType());
Value greater_rank;
for (Value operand : operands) { for (Value operand : operands) {
Value shape = Value shape =
rewriter.create<shape::ShapeOfOp>(loc, extent_tensor_type, operand); rewriter.create<shape::ShapeOfOp>(loc, extent_tensor_type, operand);
shapes.push_back(shape);
}
auto broadcast_shape = rewriter.create<shape::BroadcastOp>(
loc, extent_tensor_type, shapes, nullptr);
SmallVector<Type> result_types(shapes.size(), extent_tensor_type);
auto reduced_shapes =
rewriter
.create<chlo::MinimumBroadcastShapesOp>(loc, result_types, shapes)
.results();
SmallVector<Value> reshaped_operands;
reshaped_operands.reserve(operands.size());
for (auto it : llvm::zip(operands, reduced_shapes)) {
Value operand;
Value reduced_shape;
std::tie(operand, reduced_shape) = it;
auto reshaped_operand = rewriter.create<mhlo::DynamicReshapeOp>(
loc, operand.getType(), operand, reduced_shape);
reshaped_operands.push_back(reshaped_operand);
}
// Find the largest rank of the operands.
Value greater_rank;
for (Value shape : reduced_shapes) {
Value rank = Value rank =
rewriter.create<shape::RankOp>(loc, rewriter.getIndexType(), shape); rewriter.create<shape::RankOp>(loc, rewriter.getIndexType(), shape);
if (!greater_rank) { if (!greater_rank) {
@ -314,17 +340,19 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
scf::IfOp if_op = createIfOpForRankSpecializedBroadcastAndOp( scf::IfOp if_op = createIfOpForRankSpecializedBroadcastAndOp(
rewriter, op, greater_rank, 1); rewriter, op, greater_rank, 1);
OpBuilder if_builder = if_op.getThenBodyBuilder(rewriter.getListener()); OpBuilder if_builder = if_op.getThenBodyBuilder(rewriter.getListener());
createRankSpecializedBroadcastAndOp(if_builder, op, operands, 1); createRankSpecializedBroadcastAndOp(if_builder, op, reshaped_operands,
reduced_shapes, 1);
// Put each subsequent rank specialization inside the else statement of the // Put each subsequent rank specialization inside the else statement of the
// previous one. // previous one.
OpBuilder else_builder = if_op.getElseBodyBuilder(rewriter.getListener()); OpBuilder else_builder = if_op.getElseBodyBuilder(rewriter.getListener());
constexpr int kMaxRankSpecialization = 6; constexpr int kMaxRankSpecialization = 5;
for (int i = 2; i < kMaxRankSpecialization; i++) { for (int i = 2; i < kMaxRankSpecialization; i++) {
auto inner_if = createIfOpForRankSpecializedBroadcastAndOp( auto inner_if = createIfOpForRankSpecializedBroadcastAndOp(
else_builder, op, greater_rank, i); else_builder, op, greater_rank, i);
if_builder = inner_if.getThenBodyBuilder(rewriter.getListener()); if_builder = inner_if.getThenBodyBuilder(rewriter.getListener());
createRankSpecializedBroadcastAndOp(if_builder, op, operands, i); createRankSpecializedBroadcastAndOp(if_builder, op, reshaped_operands,
reduced_shapes, i);
else_builder.create<scf::YieldOp>(loc, inner_if.getResult(0)); else_builder.create<scf::YieldOp>(loc, inner_if.getResult(0));
else_builder = inner_if.getElseBodyBuilder(rewriter.getListener()); else_builder = inner_if.getElseBodyBuilder(rewriter.getListener());
} }
@ -336,12 +364,15 @@ struct ConvertUnrankedDynamicBroadcastOpHelper {
kMaxRankSpecialization), kMaxRankSpecialization),
"Input for dynamic binary op lowering was of a rank greater than " + "Input for dynamic binary op lowering was of a rank greater than " +
std::to_string(kMaxRankSpecialization)); std::to_string(kMaxRankSpecialization));
// Add the rank 6 specialization to the innermost else block. // Add the rank 5 specialization to the innermost else block.
createRankSpecializedBroadcastAndOp(else_builder, op, operands, createRankSpecializedBroadcastAndOp(else_builder, op, reshaped_operands,
kMaxRankSpecialization); reduced_shapes, kMaxRankSpecialization);
// Return the result of the outermost if statement. // Return the reshaped result of the outermost if statement.
return if_op.getResult(0); auto result = if_op.getResult(0);
auto reshaped_result = rewriter.create<mhlo::DynamicReshapeOp>(
loc, result.getType(), result, broadcast_shape);
return reshaped_result;
} }
}; };
@ -497,16 +528,17 @@ struct ConvertUnrankedDynamicBroadcastSelectOp
struct TransformUnrankedHloPass struct TransformUnrankedHloPass
: public PassWrapper<TransformUnrankedHloPass, FunctionPass> { : public PassWrapper<TransformUnrankedHloPass, FunctionPass> {
void getDependentDialects(DialectRegistry &registry) const override { void getDependentDialects(DialectRegistry &registry) const override {
registry.insert<shape::ShapeDialect, mhlo::MhloDialect>(); registry.insert<chlo::HloClientDialect, mhlo::MhloDialect,
shape::ShapeDialect>();
} }
void runOnFunction() override { void runOnFunction() override {
// Setup conversion target. // Setup conversion target.
MLIRContext &ctx = getContext(); MLIRContext &ctx = getContext();
ConversionTarget target(ctx); ConversionTarget target(ctx);
target.addLegalDialect<mhlo::MhloDialect, StandardOpsDialect, target.addLegalDialect<chlo::HloClientDialect, mhlo::MhloDialect,
shape::ShapeDialect, scf::SCFDialect, StandardOpsDialect, shape::ShapeDialect,
tensor::TensorDialect>(); scf::SCFDialect, tensor::TensorDialect>();
target.addLegalOp<FuncOp>(); target.addLegalOp<FuncOp>();
#define ADD_LEGAL_MHLO(op) AddLegalOpOnRankedTensor<mhlo::op>(&target) #define ADD_LEGAL_MHLO(op) AddLegalOpOnRankedTensor<mhlo::op>(&target)
#define ADD_LEGAL_CHLO(op) AddLegalOpOnRankedTensor<chlo::op>(&target) #define ADD_LEGAL_CHLO(op) AddLegalOpOnRankedTensor<chlo::op>(&target)

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@ -199,20 +199,24 @@ func @addUnrankedUnranked(
// CHECK-NEXT: %[[RESHAPED_SAME_RESULT:.*]] = "mhlo.dynamic_reshape"(%[[FLATTENED_RESULT]], %[[ANY_SHAPE]]) : (tensor<?xf32>, tensor<?xindex>) -> tensor<*xf32> // CHECK-NEXT: %[[RESHAPED_SAME_RESULT:.*]] = "mhlo.dynamic_reshape"(%[[FLATTENED_RESULT]], %[[ANY_SHAPE]]) : (tensor<?xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESHAPED_SAME_RESULT]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESHAPED_SAME_RESULT]] : tensor<*xf32>
// CHECK-NEXT: } else { // CHECK-NEXT: } else {
// CHECK-NEXT: %[[LHS_RANK:.*]] = shape.rank %[[LHS_SHAPE]] : tensor<?xindex> -> index // CHECK-NEXT: %[[RESULT_SHAPE:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[RHS_SHAPE]] : tensor<?xindex>, tensor<?xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[RHS_RANK:.*]] = shape.rank %[[RHS_SHAPE]] : tensor<?xindex> -> index // CHECK-NEXT: %[[MINIMUM_SHAPES:.*]]:2 = chlo.minimum_broadcast_shapes %[[LHS_SHAPE]], %[[RHS_SHAPE]] : tensor<?xindex>, tensor<?xindex> -> tensor<?xindex>, tensor<?xindex>
// CHECK-NEXT: %[[MINIMUM_RESHAPED_LHS:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[MINIMUM_SHAPES]]#0) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: %[[MINIMUM_RESHAPED_RHS:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[MINIMUM_SHAPES]]#1) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: %[[LHS_RANK:.*]] = shape.rank %[[MINIMUM_SHAPES]]#0 : tensor<?xindex> -> index
// CHECK-NEXT: %[[RHS_RANK:.*]] = shape.rank %[[MINIMUM_SHAPES]]#1 : tensor<?xindex> -> index
// CHECK-NEXT: %[[LHS_RANK_GREATER:.*]] = cmpi sgt, %[[LHS_RANK]], %[[RHS_RANK]] : index // CHECK-NEXT: %[[LHS_RANK_GREATER:.*]] = cmpi sgt, %[[LHS_RANK]], %[[RHS_RANK]] : index
// CHECK-NEXT: %[[GREATEST_RANK:.*]] = select %[[LHS_RANK_GREATER]], %[[LHS_RANK]], %[[RHS_RANK]] : index // CHECK-NEXT: %[[GREATEST_RANK:.*]] = select %[[LHS_RANK_GREATER]], %[[LHS_RANK]], %[[RHS_RANK]] : index
// Handle rank 1 specialization // Handle rank 1 specialization
// CHECK-NEXT: %[[GREATEST_RANK_IS_1:.*]] = cmpi eq, %[[GREATEST_RANK]], %[[C1]] : index // CHECK-NEXT: %[[GREATEST_RANK_IS_1:.*]] = cmpi eq, %[[GREATEST_RANK]], %[[C1]] : index
// CHECK-NEXT: %[[RESULT_RANK_1:.*]] = scf.if %[[GREATEST_RANK_IS_1]] -> (tensor<*xf32>) { // CHECK-NEXT: %[[RESULT_RANK_SPECIALIZATION:.*]] = scf.if %[[GREATEST_RANK_IS_1]] -> (tensor<*xf32>) {
// CHECK-NEXT: %[[CONST_SHAPE_1:.*]] = shape.const_shape [1] // CHECK-NEXT: %[[CONST_SHAPE_1:.*]] = shape.const_shape [1]
// CHECK-NEXT: %[[BROADCASTED_LHS_1:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_LHS_1:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS_1:.*]] = tensor.cast %[[BROADCASTED_LHS_1]] : tensor<?xindex> to tensor<1xindex> // CHECK-NEXT: %[[CASTED_LHS_1:.*]] = tensor.cast %[[BROADCASTED_LHS_1]] : tensor<?xindex> to tensor<1xindex>
// CHECK-NEXT: %[[RESHAPED_LHS_1:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_1]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32> // CHECK-NEXT: %[[RESHAPED_LHS_1:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS_1]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS_1:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_RHS_1:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS_1:.*]] = tensor.cast %[[BROADCASTED_RHS_1]] : tensor<?xindex> to tensor<1xindex> // CHECK-NEXT: %[[CASTED_RHS_1:.*]] = tensor.cast %[[BROADCASTED_RHS_1]] : tensor<?xindex> to tensor<1xindex>
// CHECK-NEXT: %[[RESHAPED_RHS_1:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_1]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32> // CHECK-NEXT: %[[RESHAPED_RHS_1:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS_1]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32>
// CHECK-NEXT: %[[RESULT_RANK_1:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_1]], %[[RESHAPED_RHS_1]] : (tensor<?xf32>, tensor<?xf32>) -> tensor<?xf32> // CHECK-NEXT: %[[RESULT_RANK_1:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_1]], %[[RESHAPED_RHS_1]] : (tensor<?xf32>, tensor<?xf32>) -> tensor<?xf32>
// CHECK-NEXT: %[[RESULT_1:.*]] = tensor.cast %[[RESULT_RANK_1]] : tensor<?xf32> to tensor<*xf32> // CHECK-NEXT: %[[RESULT_1:.*]] = tensor.cast %[[RESULT_RANK_1]] : tensor<?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_1]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_1]] : tensor<*xf32>
@ -222,12 +226,12 @@ func @addUnrankedUnranked(
// Handle rank 2 specialization // Handle rank 2 specialization
// CHECK-NEXT: %[[VAL_26:.*]] = scf.if %[[GREATEST_RANK_IS_2]] -> (tensor<*xf32>) { // CHECK-NEXT: %[[VAL_26:.*]] = scf.if %[[GREATEST_RANK_IS_2]] -> (tensor<*xf32>) {
// CHECK-NEXT: %[[CONST_SHAPE_2:.*]] = shape.const_shape [1, 1] // CHECK-NEXT: %[[CONST_SHAPE_2:.*]] = shape.const_shape [1, 1]
// CHECK-NEXT: %[[BROADCASTED_LHS_2:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_2]] : tensor<?xindex>, tensor<2xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_LHS_2:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_2]] : tensor<?xindex>, tensor<2xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS_2:.*]] = tensor.cast %[[BROADCASTED_LHS_2]] : tensor<?xindex> to tensor<2xindex> // CHECK-NEXT: %[[CASTED_LHS_2:.*]] = tensor.cast %[[BROADCASTED_LHS_2]] : tensor<?xindex> to tensor<2xindex>
// CHECK-NEXT: %[[RESHAPED_LHS_2:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_2]]) : (tensor<*xf32>, tensor<2xindex>) -> tensor<?x?xf32> // CHECK-NEXT: %[[RESHAPED_LHS_2:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS_2]]) : (tensor<*xf32>, tensor<2xindex>) -> tensor<?x?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS_2:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_2]] : tensor<?xindex>, tensor<2xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_RHS_2:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_2]] : tensor<?xindex>, tensor<2xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS_2:.*]] = tensor.cast %[[BROADCASTED_RHS_2]] : tensor<?xindex> to tensor<2xindex> // CHECK-NEXT: %[[CASTED_RHS_2:.*]] = tensor.cast %[[BROADCASTED_RHS_2]] : tensor<?xindex> to tensor<2xindex>
// CHECK-NEXT: %[[RESHAPED_RHS_2:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_2]]) : (tensor<*xf32>, tensor<2xindex>) -> tensor<?x?xf32> // CHECK-NEXT: %[[RESHAPED_RHS_2:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS_2]]) : (tensor<*xf32>, tensor<2xindex>) -> tensor<?x?xf32>
// CHECK-NEXT: %[[RESULT_RANK_2:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_2]], %[[RESHAPED_RHS_2]] : (tensor<?x?xf32>, tensor<?x?xf32>) -> tensor<?x?xf32> // CHECK-NEXT: %[[RESULT_RANK_2:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_2]], %[[RESHAPED_RHS_2]] : (tensor<?x?xf32>, tensor<?x?xf32>) -> tensor<?x?xf32>
// CHECK-NEXT: %[[RESULT_2:.*]] = tensor.cast %[[RESULT_RANK_2]] : tensor<?x?xf32> to tensor<*xf32> // CHECK-NEXT: %[[RESULT_2:.*]] = tensor.cast %[[RESULT_RANK_2]] : tensor<?x?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_2]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_2]] : tensor<*xf32>
@ -237,12 +241,12 @@ func @addUnrankedUnranked(
// Handle rank 3 specialization // Handle rank 3 specialization
// CHECK-NEXT: %[[VAL_34:.*]] = scf.if %[[GREATEST_RANK_IS_3]] -> (tensor<*xf32>) { // CHECK-NEXT: %[[VAL_34:.*]] = scf.if %[[GREATEST_RANK_IS_3]] -> (tensor<*xf32>) {
// CHECK-NEXT: %[[CONST_SHAPE_3:.*]] = shape.const_shape [1, 1, 1] // CHECK-NEXT: %[[CONST_SHAPE_3:.*]] = shape.const_shape [1, 1, 1]
// CHECK-NEXT: %[[BROADCASTED_LHS_3:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_3]] : tensor<?xindex>, tensor<3xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_LHS_3:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_3]] : tensor<?xindex>, tensor<3xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS_3:.*]] = tensor.cast %[[BROADCASTED_LHS_3]] : tensor<?xindex> to tensor<3xindex> // CHECK-NEXT: %[[CASTED_LHS_3:.*]] = tensor.cast %[[BROADCASTED_LHS_3]] : tensor<?xindex> to tensor<3xindex>
// CHECK-NEXT: %[[RESHAPED_LHS_3:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_3]]) : (tensor<*xf32>, tensor<3xindex>) -> tensor<?x?x?xf32> // CHECK-NEXT: %[[RESHAPED_LHS_3:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS_3]]) : (tensor<*xf32>, tensor<3xindex>) -> tensor<?x?x?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS_3:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_3]] : tensor<?xindex>, tensor<3xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_RHS_3:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_3]] : tensor<?xindex>, tensor<3xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS_3:.*]] = tensor.cast %[[BROADCASTED_RHS_3]] : tensor<?xindex> to tensor<3xindex> // CHECK-NEXT: %[[CASTED_RHS_3:.*]] = tensor.cast %[[BROADCASTED_RHS_3]] : tensor<?xindex> to tensor<3xindex>
// CHECK-NEXT: %[[RESHAPED_RHS_3:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_3]]) : (tensor<*xf32>, tensor<3xindex>) -> tensor<?x?x?xf32> // CHECK-NEXT: %[[RESHAPED_RHS_3:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS_3]]) : (tensor<*xf32>, tensor<3xindex>) -> tensor<?x?x?xf32>
// CHECK-NEXT: %[[RESULT_RANK_3:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_3]], %[[RESHAPED_RHS_3]] : (tensor<?x?x?xf32>, tensor<?x?x?xf32>) -> tensor<?x?x?xf32> // CHECK-NEXT: %[[RESULT_RANK_3:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_3]], %[[RESHAPED_RHS_3]] : (tensor<?x?x?xf32>, tensor<?x?x?xf32>) -> tensor<?x?x?xf32>
// CHECK-NEXT: %[[RESULT_3:.*]] = tensor.cast %[[RESULT_RANK_3]] : tensor<?x?x?xf32> to tensor<*xf32> // CHECK-NEXT: %[[RESULT_3:.*]] = tensor.cast %[[RESULT_RANK_3]] : tensor<?x?x?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_3]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_3]] : tensor<*xf32>
@ -252,47 +256,30 @@ func @addUnrankedUnranked(
// Handle rank 4 specialization // Handle rank 4 specialization
// CHECK-NEXT: %[[VAL_42:.*]] = scf.if %[[GREATEST_RANK_IS_4]] -> (tensor<*xf32>) { // CHECK-NEXT: %[[VAL_42:.*]] = scf.if %[[GREATEST_RANK_IS_4]] -> (tensor<*xf32>) {
// CHECK-NEXT: %[[CONST_SHAPE_4:.*]] = shape.const_shape [1, 1, 1, 1] // CHECK-NEXT: %[[CONST_SHAPE_4:.*]] = shape.const_shape [1, 1, 1, 1]
// CHECK-NEXT: %[[BROADCASTED_LHS_4:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_4]] : tensor<?xindex>, tensor<4xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_LHS_4:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_4]] : tensor<?xindex>, tensor<4xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS_4:.*]] = tensor.cast %[[BROADCASTED_LHS_4]] : tensor<?xindex> to tensor<4xindex> // CHECK-NEXT: %[[CASTED_LHS_4:.*]] = tensor.cast %[[BROADCASTED_LHS_4]] : tensor<?xindex> to tensor<4xindex>
// CHECK-NEXT: %[[RESHAPED_LHS_4:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_4]]) : (tensor<*xf32>, tensor<4xindex>) -> tensor<?x?x?x?xf32> // CHECK-NEXT: %[[RESHAPED_LHS_4:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS_4]]) : (tensor<*xf32>, tensor<4xindex>) -> tensor<?x?x?x?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS_4:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_4]] : tensor<?xindex>, tensor<4xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_RHS_4:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_4]] : tensor<?xindex>, tensor<4xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS_4:.*]] = tensor.cast %[[BROADCASTED_RHS_4]] : tensor<?xindex> to tensor<4xindex> // CHECK-NEXT: %[[CASTED_RHS_4:.*]] = tensor.cast %[[BROADCASTED_RHS_4]] : tensor<?xindex> to tensor<4xindex>
// CHECK-NEXT: %[[RESHAPED_RHS_4:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_4]]) : (tensor<*xf32>, tensor<4xindex>) -> tensor<?x?x?x?xf32> // CHECK-NEXT: %[[RESHAPED_RHS_4:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS_4]]) : (tensor<*xf32>, tensor<4xindex>) -> tensor<?x?x?x?xf32>
// CHECK-NEXT: %[[RESULT_RANK_4:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_4]], %[[RESHAPED_RHS_4]] : (tensor<?x?x?x?xf32>, tensor<?x?x?x?xf32>) -> tensor<?x?x?x?xf32> // CHECK-NEXT: %[[RESULT_RANK_4:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_4]], %[[RESHAPED_RHS_4]] : (tensor<?x?x?x?xf32>, tensor<?x?x?x?xf32>) -> tensor<?x?x?x?xf32>
// CHECK-NEXT: %[[RESULT_4:.*]] = tensor.cast %[[RESULT_RANK_4]] : tensor<?x?x?x?xf32> to tensor<*xf32> // CHECK-NEXT: %[[RESULT_4:.*]] = tensor.cast %[[RESULT_RANK_4]] : tensor<?x?x?x?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_4]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_4]] : tensor<*xf32>
// CHECK-NEXT: } else { // CHECK-NEXT: } else {
// CHECK-NEXT: %[[C5:.*]] = constant 5 : index // CHECK-NEXT: %[[C5:.*]] = constant 5 : index
// CHECK-NEXT: %[[GREATEST_RANK_IS_5:.*]] = cmpi eq, %[[GREATEST_RANK]], %[[C5]] : index // CHECK-NEXT: %[[GREATEST_RANK_IS_5:.*]] = cmpi eq, %[[GREATEST_RANK]], %[[C5]] : index
// CHECK-NEXT: assert %[[GREATEST_RANK_IS_5]]
// Handle rank 5 specialization // Handle rank 5 specialization
// CHECK-NEXT: %[[VAL_50:.*]] = scf.if %[[GREATEST_RANK_IS_5]] -> (tensor<*xf32>) { // CHECK-NEXT: %[[CONST_SHAPE_5:.*]] = shape.const_shape [1, 1, 1, 1, 1]
// CHECK-NEXT: %[[CONST_SHAPE_5:.*]] = shape.const_shape [1, 1, 1, 1, 1] // CHECK-NEXT: %[[BROADCASTED_LHS_5:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_5]] : tensor<?xindex>, tensor<5xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[BROADCASTED_LHS_5:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_5]] : tensor<?xindex>, tensor<5xindex> -> tensor<?xindex> // CHECK-NEXT: %[[CASTED_LHS_5:.*]] = tensor.cast %[[BROADCASTED_LHS_5]] : tensor<?xindex> to tensor<5xindex>
// CHECK-NEXT: %[[CASTED_LHS_5:.*]] = tensor.cast %[[BROADCASTED_LHS_5]] : tensor<?xindex> to tensor<5xindex> // CHECK-NEXT: %[[RESHAPED_LHS_5:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS_5]]) : (tensor<*xf32>, tensor<5xindex>) -> tensor<?x?x?x?x?xf32>
// CHECK-NEXT: %[[RESHAPED_LHS_5:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_5]]) : (tensor<*xf32>, tensor<5xindex>) -> tensor<?x?x?x?x?xf32> // CHECK-NEXT: %[[BROADCASTED_RHS_5:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_5]] : tensor<?xindex>, tensor<5xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[BROADCASTED_RHS_5:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_5]] : tensor<?xindex>, tensor<5xindex> -> tensor<?xindex> // CHECK-NEXT: %[[CASTED_RHS_5:.*]] = tensor.cast %[[BROADCASTED_RHS_5]] : tensor<?xindex> to tensor<5xindex>
// CHECK-NEXT: %[[CASTED_RHS_5:.*]] = tensor.cast %[[BROADCASTED_RHS_5]] : tensor<?xindex> to tensor<5xindex> // CHECK-NEXT: %[[RESHAPED_RHS_5:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS_5]]) : (tensor<*xf32>, tensor<5xindex>) -> tensor<?x?x?x?x?xf32>
// CHECK-NEXT: %[[RESHAPED_RHS_5:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_5]]) : (tensor<*xf32>, tensor<5xindex>) -> tensor<?x?x?x?x?xf32> // CHECK-NEXT: %[[RESULT_RANK_5:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_5]], %[[RESHAPED_RHS_5]] : (tensor<?x?x?x?x?xf32>, tensor<?x?x?x?x?xf32>) -> tensor<?x?x?x?x?xf32>
// CHECK-NEXT: %[[RESULT_RANK_5:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_5]], %[[RESHAPED_RHS_5]] : (tensor<?x?x?x?x?xf32>, tensor<?x?x?x?x?xf32>) -> tensor<?x?x?x?x?xf32> // CHECK-NEXT: %[[RESULT_5:.*]] = tensor.cast %[[RESULT_RANK_5]] : tensor<?x?x?x?x?xf32> to tensor<*xf32>
// CHECK-NEXT: %[[RESULT_5:.*]] = tensor.cast %[[RESULT_RANK_5]] : tensor<?x?x?x?x?xf32> to tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_5]] : tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_5]] : tensor<*xf32>
// CHECK-NEXT: } else {
// CHECK-NEXT: %[[C6:.*]] = constant 6 : index
// CHECK-NEXT: %[[GREATEST_RANK_IS_6:.*]] = cmpi eq, %[[GREATEST_RANK]], %[[C6]] : index
// CHECK-NEXT: assert %[[GREATEST_RANK_IS_6]]
// Handle rank 6 specialization
// CHECK-NEXT: %[[CONST_SHAPE_6:.*]] = shape.const_shape [1, 1, 1, 1, 1, 1]
// CHECK-NEXT: %[[BROADCASTED_LHS_6:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_6]] : tensor<?xindex>, tensor<6xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS_6:.*]] = tensor.cast %[[BROADCASTED_LHS_6]] : tensor<?xindex> to tensor<6xindex>
// CHECK-NEXT: %[[RESHAPED_LHS_6:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS_6]]) : (tensor<*xf32>, tensor<6xindex>) -> tensor<?x?x?x?x?x?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS_6:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_6]] : tensor<?xindex>, tensor<6xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS_6:.*]] = tensor.cast %[[BROADCASTED_RHS_6]] : tensor<?xindex> to tensor<6xindex>
// CHECK-NEXT: %[[RESHAPED_RHS_6:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS_6]]) : (tensor<*xf32>, tensor<6xindex>) -> tensor<?x?x?x?x?x?xf32>
// CHECK-NEXT: %[[RESULT_RANK_6:.*]] = chlo.broadcast_add %[[RESHAPED_LHS_6]], %[[RESHAPED_RHS_6]] : (tensor<?x?x?x?x?x?xf32>, tensor<?x?x?x?x?x?xf32>) -> tensor<?x?x?x?x?x?xf32>
// CHECK-NEXT: %[[RESULT_6:.*]] = tensor.cast %[[RESULT_RANK_6]] : tensor<?x?x?x?x?x?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_6]] : tensor<*xf32>
// CHECK-NEXT: }
// CHECK-NEXT: scf.yield %[[VAL_65:.*]] : tensor<*xf32>
// CHECK-NEXT: } // CHECK-NEXT: }
// CHECK-NEXT: scf.yield %[[VAL_66:.*]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[VAL_66:.*]] : tensor<*xf32>
// CHECK-NEXT: } // CHECK-NEXT: }
@ -300,7 +287,8 @@ func @addUnrankedUnranked(
// CHECK-NEXT: } // CHECK-NEXT: }
// CHECK-NEXT: scf.yield %[[VAL_68:.*]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[VAL_68:.*]] : tensor<*xf32>
// CHECK-NEXT: } // CHECK-NEXT: }
// CHECK-NEXT: scf.yield %[[VAL_69:.*]] : tensor<*xf32> // CHECK-NEXT: %[[RESHAPED_RESULT:.*]] = "mhlo.dynamic_reshape"(%[[RESULT_RANK_SPECIALIZATION]], %[[RESULT_SHAPE]]) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESHAPED_RESULT]] : tensor<*xf32>
// CHECK-NEXT: } // CHECK-NEXT: }
// CHECK-NEXT: scf.yield %[[VAL_70:.*]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[VAL_70:.*]] : tensor<*xf32>
// CHECK-NEXT: } // CHECK-NEXT: }
@ -325,13 +313,18 @@ func @selectUnrankedUnrankedUnranked(
// CHECK-SAME: %[[LHS:.*]]: tensor<*xf32>, // CHECK-SAME: %[[LHS:.*]]: tensor<*xf32>,
// CHECK-SAME: %[[RHS:.*]]: tensor<*xf32>) -> tensor<*xf32> { // CHECK-SAME: %[[RHS:.*]]: tensor<*xf32>) -> tensor<*xf32> {
// CHECK-NEXT: %[[PRED_SHAPE:.*]] = shape.shape_of %[[PRED]] : tensor<*xi1> -> tensor<?xindex> // CHECK-NEXT: %[[PRED_SHAPE:.*]] = shape.shape_of %[[PRED]] : tensor<*xi1> -> tensor<?xindex>
// CHECK-NEXT: %[[PRED_RANK:.*]] = shape.rank %[[PRED_SHAPE]] : tensor<?xindex> -> index
// CHECK-NEXT: %[[LHS_SHAPE:.*]] = shape.shape_of %[[LHS]] : tensor<*xf32> -> tensor<?xindex> // CHECK-NEXT: %[[LHS_SHAPE:.*]] = shape.shape_of %[[LHS]] : tensor<*xf32> -> tensor<?xindex>
// CHECK-NEXT: %[[LHS_RANK:.*]] = shape.rank %[[LHS_SHAPE]] : tensor<?xindex> -> index // CHECK-NEXT: %[[RHS_SHAPE:.*]] = shape.shape_of %[[RHS]] : tensor<*xf32> -> tensor<?xindex>
// CHECK-NEXT: %[[RESULT_SHAPE:.*]] = shape.broadcast %[[PRED_SHAPE]], %[[LHS_SHAPE]], %[[RHS_SHAPE]] : tensor<?xindex>, tensor<?xindex>, tensor<?xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[MINIMUM_SHAPES:.*]]:3 = chlo.minimum_broadcast_shapes %[[PRED_SHAPE]], %[[LHS_SHAPE]], %[[RHS_SHAPE]] : tensor<?xindex>, tensor<?xindex>, tensor<?xindex> -> tensor<?xindex>, tensor<?xindex>, tensor<?xindex>
// CHECK-NEXT: %[[MINIMUM_RESHAPED_PRED:.*]] = "mhlo.dynamic_reshape"(%[[PRED]], %[[MINIMUM_SHAPES]]#0) : (tensor<*xi1>, tensor<?xindex>) -> tensor<*xi1>
// CHECK-NEXT: %[[MINIMUM_RESHAPED_LHS:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[MINIMUM_SHAPES]]#1) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: %[[MINIMUM_RESHAPED_RHS:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[MINIMUM_SHAPES]]#2) : (tensor<*xf32>, tensor<?xindex>) -> tensor<*xf32>
// CHECK-NEXT: %[[PRED_RANK:.*]] = shape.rank %[[MINIMUM_SHAPES]]#0 : tensor<?xindex> -> index
// CHECK-NEXT: %[[LHS_RANK:.*]] = shape.rank %[[MINIMUM_SHAPES]]#1 : tensor<?xindex> -> index
// CHECK-NEXT: %[[GREATER_RANK_CMP:.*]] = cmpi sgt, %[[PRED_RANK]], %[[LHS_RANK]] : index // CHECK-NEXT: %[[GREATER_RANK_CMP:.*]] = cmpi sgt, %[[PRED_RANK]], %[[LHS_RANK]] : index
// CHECK-NEXT: %[[GREATER_RANK:.*]] = select %[[GREATER_RANK_CMP]], %[[PRED_RANK]], %[[LHS_RANK]] : index // CHECK-NEXT: %[[GREATER_RANK:.*]] = select %[[GREATER_RANK_CMP]], %[[PRED_RANK]], %[[LHS_RANK]] : index
// CHECK-NEXT: %[[RHS_SHAPE:.*]] = shape.shape_of %[[RHS]] : tensor<*xf32> -> tensor<?xindex> // CHECK-NEXT: %[[RHS_RANK:.*]] = shape.rank %[[MINIMUM_SHAPES]]#2 : tensor<?xindex> -> index
// CHECK-NEXT: %[[RHS_RANK:.*]] = shape.rank %[[RHS_SHAPE]] : tensor<?xindex> -> index
// CHECK-NEXT: %[[GREATEST_RANK_CMP:.*]] = cmpi sgt, %[[GREATER_RANK]], %[[RHS_RANK]] : index // CHECK-NEXT: %[[GREATEST_RANK_CMP:.*]] = cmpi sgt, %[[GREATER_RANK]], %[[RHS_RANK]] : index
// CHECK-NEXT: %[[GREATEST_RANK:.*]] = select %[[GREATEST_RANK_CMP]], %[[GREATER_RANK]], %[[RHS_RANK]] : index // CHECK-NEXT: %[[GREATEST_RANK:.*]] = select %[[GREATEST_RANK_CMP]], %[[GREATER_RANK]], %[[RHS_RANK]] : index
// CHECK-NEXT: %c1 = constant 1 : index // CHECK-NEXT: %c1 = constant 1 : index
@ -339,15 +332,15 @@ func @selectUnrankedUnrankedUnranked(
// Handle rank 1 specialization // Handle rank 1 specialization
// CHECK-NEXT: scf.if %[[GREATEST_RANK_IS_1]] -> (tensor<*xf32>) { // CHECK-NEXT: scf.if %[[GREATEST_RANK_IS_1]] -> (tensor<*xf32>) {
// CHECK-NEXT: %[[CONST_SHAPE_1:.*]] = shape.const_shape [1] : tensor<1xindex> // CHECK-NEXT: %[[CONST_SHAPE_1:.*]] = shape.const_shape [1] : tensor<1xindex>
// CHECK-NEXT: %[[BROADCASTED_PRED:.*]] = shape.broadcast %[[PRED_SHAPE]], %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_PRED:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#0, %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_PRED:.*]] = tensor.cast %[[BROADCASTED_PRED]] : tensor<?xindex> to tensor<1xindex> // CHECK-NEXT: %[[CASTED_PRED:.*]] = tensor.cast %[[BROADCASTED_PRED]] : tensor<?xindex> to tensor<1xindex>
// CHECK-NEXT: %[[RESHAPED_PRED:.*]] = "mhlo.dynamic_reshape"(%[[PRED]], %[[CASTED_PRED]]) : (tensor<*xi1>, tensor<1xindex>) -> tensor<?xi1> // CHECK-NEXT: %[[RESHAPED_PRED:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_PRED]], %[[CASTED_PRED]]) : (tensor<*xi1>, tensor<1xindex>) -> tensor<?xi1>
// CHECK-NEXT: %[[BROADCASTED_LHS:.*]] = shape.broadcast %[[LHS_SHAPE]], %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_LHS:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#1, %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_LHS:.*]] = tensor.cast %[[BROADCASTED_LHS]] : tensor<?xindex> to tensor<1xindex> // CHECK-NEXT: %[[CASTED_LHS:.*]] = tensor.cast %[[BROADCASTED_LHS]] : tensor<?xindex> to tensor<1xindex>
// CHECK-NEXT: %[[RESHAPED_LHS:.*]] = "mhlo.dynamic_reshape"(%[[LHS]], %[[CASTED_LHS]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32> // CHECK-NEXT: %[[RESHAPED_LHS:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_LHS]], %[[CASTED_LHS]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32>
// CHECK-NEXT: %[[BROADCASTED_RHS:.*]] = shape.broadcast %[[RHS_SHAPE]], %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex> // CHECK-NEXT: %[[BROADCASTED_RHS:.*]] = shape.broadcast %[[MINIMUM_SHAPES]]#2, %[[CONST_SHAPE_1]] : tensor<?xindex>, tensor<1xindex> -> tensor<?xindex>
// CHECK-NEXT: %[[CASTED_RHS:.*]] = tensor.cast %[[BROADCASTED_RHS]] : tensor<?xindex> to tensor<1xindex> // CHECK-NEXT: %[[CASTED_RHS:.*]] = tensor.cast %[[BROADCASTED_RHS]] : tensor<?xindex> to tensor<1xindex>
// CHECK-NEXT: %[[RESHAPED_RHS:.*]] = "mhlo.dynamic_reshape"(%[[RHS]], %[[CASTED_RHS]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32> // CHECK-NEXT: %[[RESHAPED_RHS:.*]] = "mhlo.dynamic_reshape"(%[[MINIMUM_RESHAPED_RHS]], %[[CASTED_RHS]]) : (tensor<*xf32>, tensor<1xindex>) -> tensor<?xf32>
// CHECK-NEXT: %[[RESULT_RANK_1:.*]] = chlo.broadcast_select %[[RESHAPED_PRED]], %[[RESHAPED_LHS]], %[[RESHAPED_RHS]] : (tensor<?xi1>, tensor<?xf32>, tensor<?xf32>) -> tensor<?xf32> // CHECK-NEXT: %[[RESULT_RANK_1:.*]] = chlo.broadcast_select %[[RESHAPED_PRED]], %[[RESHAPED_LHS]], %[[RESHAPED_RHS]] : (tensor<?xi1>, tensor<?xf32>, tensor<?xf32>) -> tensor<?xf32>
// CHECK-NEXT: %[[RESULT_1:.*]] = tensor.cast %[[RESULT_RANK_1:.*]] : tensor<?xf32> to tensor<*xf32> // CHECK-NEXT: %[[RESULT_1:.*]] = tensor.cast %[[RESULT_RANK_1:.*]] : tensor<?xf32> to tensor<*xf32>
// CHECK-NEXT: scf.yield %[[RESULT_1]] : tensor<*xf32> // CHECK-NEXT: scf.yield %[[RESULT_1]] : tensor<*xf32>
@ -357,4 +350,3 @@ func @selectUnrankedUnrankedUnranked(
// CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?xi1>, tensor<?x?x?xf32>, tensor<?x?x?xf32>) -> tensor<?x?x?xf32> // CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?xi1>, tensor<?x?x?xf32>, tensor<?x?x?xf32>) -> tensor<?x?x?xf32>
// CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?x?xi1>, tensor<?x?x?x?xf32>, tensor<?x?x?x?xf32>) -> tensor<?x?x?x?xf32> // CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?x?xi1>, tensor<?x?x?x?xf32>, tensor<?x?x?x?xf32>) -> tensor<?x?x?x?xf32>
// CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?x?x?xi1>, tensor<?x?x?x?x?xf32>, tensor<?x?x?x?x?xf32>) -> tensor<?x?x?x?x?xf32> // CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?x?x?xi1>, tensor<?x?x?x?x?xf32>, tensor<?x?x?x?x?xf32>) -> tensor<?x?x?x?x?xf32>
// CHECK: chlo.broadcast_select {{.*}} : (tensor<?x?x?x?x?x?xi1>, tensor<?x?x?x?x?x?xf32>, tensor<?x?x?x?x?x?xf32>) -> tensor<?x?x?x?x?x?xf32>