[Mlir-commits] [mlir] [mlir][scf] Extend fuse producer to multi-level candidates case (PR #97803)
llvmlistbot at llvm.org
llvmlistbot at llvm.org
Fri Jul 5 02:27:13 PDT 2024
https://github.com/Yun-Fly created https://github.com/llvm/llvm-project/pull/97803
Although producer can be already fused within nest loop structure at present, it didn't work for multi-level candidates `extractSliceOp` case, E.g.
```
func.func @gemm_fill_fusion(%arg0: tensor<256x512xf32>, %arg1: tensor<512x256xf32>, %arg2: tensor<256x256xf32>) -> tensor<256x256xf32> {
%c0 = arith.constant 0 : index
%c64 = arith.constant 64 : index
%c128 = arith.constant 128 : index
%cst = arith.constant 0.000000e+00 : f32
%dest0 = tensor.empty() : tensor<256x256xf32>
%dest1 = linalg.fill ins(%cst : f32) outs(%dest0 : tensor<256x256xf32>) -> tensor<256x256xf32>
%1 = scf.forall (%arg3, %arg4) in (2, 2) shared_outs(%arg5 = %dest1) -> tensor<256x256xf32> {
%iv0 = affine.apply #map(%arg3)
%iv1 = affine.apply #map(%arg4)
%extracted_slice_1 = tensor.extract_slice %arg5[%iv0, %iv1] [128, 128] [1, 1] : tensor<256x256xf32> to tensor<128x128xf32>
%extracted_slice_2 = tensor.extract_slice %arg0[%iv0, 0] [128, 512] [1, 1] : tensor<256x512xf32> to tensor<128x512xf32>
%extracted_slice_3 = tensor.extract_slice %arg1[0, %iv1] [512, 128] [1, 1] : tensor<512x256xf32> to tensor<512x128xf32>
%2 = scf.for %arg6 = %c0 to %c128 step %c64 iter_args(%arg7 = %extracted_slice_1) -> (tensor<128x128xf32>) {
%3 = scf.for %arg8 = %c0 to %c128 step %c64 iter_args(%arg9 = %arg7) -> (tensor<128x128xf32>) {
%extracted_slice_4 = tensor.extract_slice %arg9[%arg6, %arg8] [64, 64] [1, 1] : tensor<128x128xf32> to tensor<64x64xf32>
%extracted_slice_5 = tensor.extract_slice %extracted_slice_2[%arg6, 0] [64, 512] [1, 1] : tensor<128x512xf32> to tensor<64x512xf32>
%extracted_slice_6 = tensor.extract_slice %extracted_slice_3[0, %arg8] [512, 64] [1, 1] : tensor<512x128xf32> to tensor<512x64xf32>
%4 = linalg.matmul ins(%extracted_slice_5, %extracted_slice_6 : tensor<64x512xf32>, tensor<512x64xf32>) outs(%extracted_slice_4 : tensor<64x64xf32>) -> tensor<64x64xf32>
%insert_slice = tensor.insert_slice %4 into %arg9[%arg6, %arg8] [64, 64] [1, 1] : tensor<64x64xf32> into tensor<128x128xf32>
scf.yield %insert_slice : tensor<128x128xf32>
}
scf.yield %3 : tensor<128x128xf32>
}
scf.forall.in_parallel {
tensor.parallel_insert_slice %2 into %arg5[%iv0, %iv1] [128, 128] [1, 1] : tensor<128x128xf32> into tensor<256x256xf32>
}
}
return %1 : tensor<256x256xf32>
}
```
If we want to fuse producer `fill` into `%extracted_slice_4`, current status in master will be broken at `getUntiledProducerFromSliceSource` due to upper candidate slice `%extracted_slice_1` . This PR extends fusing producer to multi-level `extractSliceOp` cases.
This patch uses multiple application of existing tiling interface as same as another counterpart [PR](https://github.com/llvm/llvm-project/pull/94190).
>From a4c2778feb7ae4ce0b0d5c4969f786a3b61bb925 Mon Sep 17 00:00:00 2001
From: "Song, Yunfei" <yunfei.song at intel.com>
Date: Fri, 5 Jul 2024 02:12:59 -0700
Subject: [PATCH] extend fuse producer to multi-level extractSliceOp
---
.../SCF/Transforms/TileUsingInterface.h | 8 ++
.../SCF/Transforms/TileUsingInterface.cpp | 111 +++++++++++++++++-
.../tile-and-fuse-producer.mlir | 86 ++++++++++++++
.../TestTilingInterfaceTransformOps.cpp | 50 ++++++++
.../TestTilingInterfaceTransformOps.td | 19 +++
5 files changed, 273 insertions(+), 1 deletion(-)
create mode 100644 mlir/test/Interfaces/TilingInterface/tile-and-fuse-producer.mlir
diff --git a/mlir/include/mlir/Dialect/SCF/Transforms/TileUsingInterface.h b/mlir/include/mlir/Dialect/SCF/Transforms/TileUsingInterface.h
index d68ca11207376..36888c3d6d607 100644
--- a/mlir/include/mlir/Dialect/SCF/Transforms/TileUsingInterface.h
+++ b/mlir/include/mlir/Dialect/SCF/Transforms/TileUsingInterface.h
@@ -136,11 +136,19 @@ struct SCFFuseProducerOfSliceResult {
Value tiledAndFusedProducer; // Tile and fused producer value.
SmallVector<Operation *> tiledOps;
};
+std::optional<SCFFuseProducerOfSliceResult>
+tileAndFuseProducerOfSliceImpl(RewriterBase &rewriter,
+ tensor::ExtractSliceOp candidateSliceOp,
+ MutableArrayRef<LoopLikeOpInterface> loops);
+
std::optional<SCFFuseProducerOfSliceResult>
tileAndFuseProducerOfSlice(RewriterBase &rewriter,
tensor::ExtractSliceOp candidateSliceOp,
MutableArrayRef<LoopLikeOpInterface> loops);
+std::optional<SCFFuseProducerOfSliceResult>
+tileAndFuseProducerOfSlice(RewriterBase &rewriter, Operation *candidateSliceOp);
+
/// Reconstruct the fused producer from within the tiled-and-fused code. Based
/// on the slice of the producer computed in place it is possible that within
/// the loop nest same slice of the producer is computed multiple times. It is
diff --git a/mlir/lib/Dialect/SCF/Transforms/TileUsingInterface.cpp b/mlir/lib/Dialect/SCF/Transforms/TileUsingInterface.cpp
index a1392813d6de3..d6baa69618dae 100644
--- a/mlir/lib/Dialect/SCF/Transforms/TileUsingInterface.cpp
+++ b/mlir/lib/Dialect/SCF/Transforms/TileUsingInterface.cpp
@@ -835,7 +835,7 @@ getUntiledProducerFromSliceSource(OpOperand *source,
/// Implementation of fusing producer of a single slice by computing the
/// slice of the producer in-place.
std::optional<scf::SCFFuseProducerOfSliceResult>
-mlir::scf::tileAndFuseProducerOfSlice(
+mlir::scf::tileAndFuseProducerOfSliceImpl(
RewriterBase &rewriter, tensor::ExtractSliceOp candidateSliceOp,
MutableArrayRef<LoopLikeOpInterface> loops) {
// 1. Get the producer of the source (potentially walking through
@@ -949,6 +949,115 @@ mlir::scf::tileAndFuseProducerOfSlice(
tileAndFuseResult->tiledOps};
}
+/// Get the Root source of target ExtractSliceOp
+/// %0 =
+/// %1 = scf.for(%arg1 = %0)
+/// %2 = extract %arg1
+/// %3 = scf.for(%arg2 = %2)
+/// %4 = extract %args2
+/// ...
+/// @param targetSliceOp: %4 = extract %args2
+/// @param extractSliceOpChain: chain of all related extract sliceOp
+/// @return Value of Root Source : %0
+static FailureOr<Value> getRootSourceOfExtractSliceOp(
+ Operation *targetSliceOp,
+ SmallVectorImpl<tensor::ExtractSliceOp> &extractSliceOpChain,
+ int curDepth = 0, int maxDepth = 5) {
+ assert(isa<tensor::ExtractSliceOp>(targetSliceOp));
+ // control recursive time in avoid of stack overflow
+ if (curDepth > maxDepth)
+ return failure();
+
+ auto extractOp = cast<tensor::ExtractSliceOp>(targetSliceOp);
+ extractSliceOpChain.push_back(extractOp);
+ Value rootSource = extractOp.getSourceMutable().get();
+
+ while (true) {
+ if (auto iterArg = dyn_cast<BlockArgument>(rootSource)) {
+ if (auto outerLoop = dyn_cast<LoopLikeOpInterface>(
+ iterArg.getOwner()->getParentOp())) {
+ rootSource = outerLoop.getTiedLoopInit(iterArg)->get();
+ continue;
+ }
+ return failure();
+ } else if (auto sliceOp =
+ rootSource.getDefiningOp<tensor::ExtractSliceOp>()) {
+ // walk up loop to find larger candidate extractSliceOp
+ return getRootSourceOfExtractSliceOp(sliceOp, extractSliceOpChain,
+ curDepth + 1);
+ }
+ break;
+ }
+ return rootSource;
+}
+
+/// Return outer loops of given ForOp(included) until the predict function
+/// succeed(excluded), sorted from outer to inner.
+static SmallVector<LoopLikeOpInterface>
+getOuterLoopsUntil(LoopLikeOpInterface loop,
+ std::function<LogicalResult(LoopLikeOpInterface)> pred) {
+ SmallVector<LoopLikeOpInterface> outerLoops = {loop};
+ auto forOp = loop->getParentOfType<LoopLikeOpInterface>();
+ while (forOp) {
+ if (succeeded(pred(forOp)))
+ break;
+ outerLoops.push_back(forOp);
+ forOp = forOp->getParentOfType<LoopLikeOpInterface>();
+ }
+ return {outerLoops.rbegin(), outerLoops.rend()};
+}
+
+/// Enhanced version of `tileAndFuseProducerOfSliceImpl`, which can deal with
+/// multi-level `extractSliceOp`. E.g.
+///
+/// %0 = untiled_producer
+/// %1 = scf.for(%arg1 = %0)
+/// %2 = extract %arg1
+/// %3 = scf.for(%arg2 = %2)
+/// %4 = extract %args2
+/// %5 = tiled_consumer ins(%4)
+std::optional<scf::SCFFuseProducerOfSliceResult>
+mlir::scf::tileAndFuseProducerOfSlice(RewriterBase &rewriter,
+ Operation *candidateSliceOp) {
+ SmallVector<tensor::ExtractSliceOp> sliceOpChain;
+ if (failed(getRootSourceOfExtractSliceOp(candidateSliceOp, sliceOpChain))) {
+ return std::nullopt;
+ }
+
+ std::optional<scf::SCFFuseProducerOfSliceResult> fuseProducerResult;
+ // reverse from outer to inner
+ std::reverse(sliceOpChain.begin(), sliceOpChain.end());
+ // multiple application of `tileAndFuseProducerOfSliceImpl`
+ for (auto &&[index, sliceOp] : llvm::enumerate(sliceOpChain)) {
+ Operation *upperSliceOp = index ? sliceOpChain[index - 1] : nullptr;
+ auto untilUpperSliceFound =
+ [&upperSliceOp](LoopLikeOpInterface loop) -> LogicalResult {
+ if (upperSliceOp) {
+ Block &body = loop->getRegion(0).front();
+ if (upperSliceOp->getBlock() == &body)
+ return success();
+ }
+ return failure();
+ };
+ SmallVector<LoopLikeOpInterface> outerLoops = getOuterLoopsUntil(
+ sliceOp->getParentOfType<LoopLikeOpInterface>(), untilUpperSliceFound);
+ fuseProducerResult =
+ tileAndFuseProducerOfSliceImpl(rewriter, sliceOp, outerLoops);
+ if (!fuseProducerResult) {
+ return std::nullopt;
+ }
+ }
+ return fuseProducerResult;
+}
+
+/// To be compatible with previous behavior
+std::optional<scf::SCFFuseProducerOfSliceResult>
+mlir::scf::tileAndFuseProducerOfSlice(
+ RewriterBase &rewriter, tensor::ExtractSliceOp candidateSliceOp,
+ MutableArrayRef<LoopLikeOpInterface> loops) {
+ return tileAndFuseProducerOfSliceImpl(rewriter, candidateSliceOp, loops);
+}
+
/// Reconstruct the fused producer from within the tiled-and-fused code.
LogicalResult mlir::scf::yieldReplacementForFusedProducer(
RewriterBase &rewriter, tensor::ExtractSliceOp sliceOp,
diff --git a/mlir/test/Interfaces/TilingInterface/tile-and-fuse-producer.mlir b/mlir/test/Interfaces/TilingInterface/tile-and-fuse-producer.mlir
new file mode 100644
index 0000000000000..ef1c6952a55e1
--- /dev/null
+++ b/mlir/test/Interfaces/TilingInterface/tile-and-fuse-producer.mlir
@@ -0,0 +1,86 @@
+// RUN: mlir-opt --transform-interpreter --cse --split-input-file %s | FileCheck %s
+
+#map = affine_map<(d0) -> (d0 * 128)>
+module {
+ func.func @gemm_fill_fusion_multi_level_extract_slice(%arg0: tensor<256x512xf32>, %arg1: tensor<512x256xf32>, %arg2: tensor<256x256xf32>) -> tensor<256x256xf32> {
+ %c0 = arith.constant 0 : index
+ %c64 = arith.constant 64 : index
+ %c128 = arith.constant 128 : index
+ %cst = arith.constant 0.000000e+00 : f32
+ %dest0 = tensor.empty() : tensor<256x256xf32>
+ %dest1 = linalg.fill ins(%cst : f32) outs(%dest0 : tensor<256x256xf32>) -> tensor<256x256xf32>
+ %1 = scf.forall (%arg3, %arg4) in (2, 2) shared_outs(%arg5 = %dest1) -> tensor<256x256xf32> {
+ %iv0 = affine.apply #map(%arg3)
+ %iv1 = affine.apply #map(%arg4)
+ %extracted_slice_1 = tensor.extract_slice %arg5[%iv0, %iv1] [128, 128] [1, 1] : tensor<256x256xf32> to tensor<128x128xf32>
+ %extracted_slice_2 = tensor.extract_slice %arg0[%iv0, 0] [128, 512] [1, 1] : tensor<256x512xf32> to tensor<128x512xf32>
+ %extracted_slice_3 = tensor.extract_slice %arg1[0, %iv1] [512, 128] [1, 1] : tensor<512x256xf32> to tensor<512x128xf32>
+ %2 = scf.for %arg6 = %c0 to %c128 step %c64 iter_args(%arg7 = %extracted_slice_1) -> (tensor<128x128xf32>) {
+ %3 = scf.for %arg8 = %c0 to %c128 step %c64 iter_args(%arg9 = %arg7) -> (tensor<128x128xf32>) {
+ %extracted_slice_4 = tensor.extract_slice %arg9[%arg6, %arg8] [64, 64] [1, 1] : tensor<128x128xf32> to tensor<64x64xf32>
+ %extracted_slice_5 = tensor.extract_slice %extracted_slice_2[%arg6, 0] [64, 512] [1, 1] : tensor<128x512xf32> to tensor<64x512xf32>
+ %extracted_slice_6 = tensor.extract_slice %extracted_slice_3[0, %arg8] [512, 64] [1, 1] : tensor<512x128xf32> to tensor<512x64xf32>
+ %4 = linalg.matmul ins(%extracted_slice_5, %extracted_slice_6 : tensor<64x512xf32>, tensor<512x64xf32>) outs(%extracted_slice_4 : tensor<64x64xf32>) -> tensor<64x64xf32>
+ %insert_slice = tensor.insert_slice %4 into %arg9[%arg6, %arg8] [64, 64] [1, 1] : tensor<64x64xf32> into tensor<128x128xf32>
+ scf.yield %insert_slice : tensor<128x128xf32>
+ }
+ scf.yield %3 : tensor<128x128xf32>
+ }
+ scf.forall.in_parallel {
+ tensor.parallel_insert_slice %2 into %arg5[%iv0, %iv1] [128, 128] [1, 1] : tensor<128x128xf32> into tensor<256x256xf32>
+ }
+ }
+ return %1 : tensor<256x256xf32>
+ }
+}
+
+module attributes {transform.with_named_sequence} {
+ transform.named_sequence @__transform_main(%arg1 : !transform.any_op {transform.readonly}) {
+ %matmul = transform.structured.match ops{["linalg.matmul"]} in %arg1
+ : (!transform.any_op) -> !transform.any_op
+ %yield = transform.get_producer_of_operand %matmul[2]
+ : (!transform.any_op) -> !transform.any_op
+ %a, %b = transform.test.fuse_producer %yield
+ : (!transform.any_op) -> (!transform.any_op, !transform.any_op)
+ transform.yield
+ }
+}
+
+// CHECK: #[[MAP0:.*]] = affine_map<(d0) -> (d0 * 128)>
+// CHECK: func.func @gemm_fill_fusion_multi_level_extract_slice(
+// CHECK-SAME: %[[ARG0:[a-zA-Z0-9]+]]: tensor<256x512xf32>
+// CHECK-SAME: %[[ARG1:[a-zA-Z0-9]+]]: tensor<512x256xf32>
+// CHECK-SAME: %[[ARG2:[a-zA-Z0-9]+]]: tensor<256x256xf32>
+// CHECK: %[[C0:.*]] = arith.constant 0 : index
+// CHECK: %[[dest0:.*]] = tensor.empty() : tensor<256x256xf32>
+// CHECK: %[[FORALL_RESULT:.*]] = scf.forall (%[[IV1:.*]], %[[IV2:.*]]) in (2, 2)
+// CHECK-SAME: shared_outs(%[[INIT_ARG0:.*]] = %[[dest0]])
+// CHECK-SAME: {
+// CHECK: %[[AFFINE_IV1:.*]] = affine.apply #[[MAP0]](%[[IV1]])
+// CHECK: %[[AFFINE_IV2:.*]] = affine.apply #[[MAP0]](%[[IV2]])
+// CHECK: %[[FILL_OUT_SLICE0:.*]] = tensor.extract_slice %[[INIT_ARG0]][%[[AFFINE_IV1]], %[[AFFINE_IV2]]] [128, 128] [1, 1]
+// CHECK: %[[INPUT_SLICE0:.*]] = tensor.extract_slice %[[ARG0]][%[[AFFINE_IV1]], 0] [128, 512] [1, 1]
+// CHECK: %[[WEIGHT_SLICE0:.*]] = tensor.extract_slice %[[ARG1]][0, %[[AFFINE_IV2]]] [512, 128] [1, 1]
+// CHECK: %[[LOOP_RESULT1:.*]] = scf.for %[[IV3:.*]] = %[[C0]]
+// CHECK-SAME: iter_args(%[[INIT_ARG1:.*]] = %[[FILL_OUT_SLICE0]])
+// CHECK-SAME: {
+// CHECK: %[[LOOP_RESULT2:.*]] = scf.for %[[IV4:.*]] = %[[C0]]
+// CHECK-SAME: iter_args(%[[INIT_ARG2:.*]] = %[[INIT_ARG1]])
+// CHECK-SAME: {
+// CHECK: %[[FILL_OUT_SLICE1:.*]] = tensor.extract_slice %[[INIT_ARG2]][%[[IV3]], %[[IV4]]] [64, 64] [1, 1]
+// CHECK: %[[TILED_FILL_OUT:.*]] = linalg.fill
+// CHECK-SAME: outs(%[[FILL_OUT_SLICE1]] :
+// CHECK: %[[INPUT_SLICE1:.*]] = tensor.extract_slice %[[INPUT_SLICE0]][%[[IV3]], 0] [64, 512] [1, 1]
+// CHECK: %[[WEIGHT_SLICE1:.*]] = tensor.extract_slice %[[WEIGHT_SLICE0]][0, %[[IV4]]] [512, 64] [1, 1]
+// CHECK: %[[TILED_MAT_OUT:.*]] = linalg.matmul
+// CHECK-SAME: outs(%[[TILED_FILL_OUT]] :
+// CHECK: %[[INSERT_MAT:.*]] = tensor.insert_slice %[[TILED_MAT_OUT]] into %[[INIT_ARG2]][%[[IV3]], %[[IV4]]] [64, 64] [1, 1]
+// CHECK: scf.yield %[[INSERT_MAT]] :
+// CHECK: }
+// CHECK: scf.yield %[[LOOP_RESULT2]] :
+// CHECK: }
+// CHECK: scf.forall.in_parallel {
+// CHECK: tensor.parallel_insert_slice %[[LOOP_RESULT1]] into %[[INIT_ARG0]][%[[AFFINE_IV1]], %[[AFFINE_IV2]]] [128, 128] [1, 1]
+// CHECK: }
+// CHECK: }
+// CHECK: return %[[FORALL_RESULT]] :
\ No newline at end of file
diff --git a/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.cpp b/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.cpp
index 8f206d9077272..8d3d5b23a53e9 100644
--- a/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.cpp
+++ b/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.cpp
@@ -160,6 +160,56 @@ transform::TestFuseAndYieldOp::apply(TransformRewriter &rewriter,
: DiagnosedSilenceableFailure::success();
}
+//===----------------------------------------------------------------------===//
+// TestFuseProducerOp
+//===----------------------------------------------------------------------===//
+
+/// Apply fusing of producer transformation to all payload ops and store both
+/// the original producer operation as well as the fused producer operation.
+template <typename Range>
+static LogicalResult
+applyFuseProducer(RewriterBase &rewriter, Operation *transformOp,
+ Range &&payloadOps, TransformResults &transformResults) {
+ SmallVector<Operation *> originalProducerOps;
+ SmallVector<Operation *> fusedProducerOps;
+
+ for (Operation *target : payloadOps) {
+ rewriter.setInsertionPoint(target);
+
+ std::optional<scf::SCFFuseProducerOfSliceResult> fuseProducerResults =
+ scf::tileAndFuseProducerOfSlice(rewriter, target);
+
+ if (!fuseProducerResults)
+ return failure();
+
+ // Report back the relevant handles to the transform op.
+ originalProducerOps.push_back(fuseProducerResults->origProducer.getOwner());
+ fusedProducerOps.push_back(fuseProducerResults->tiledOps[0]);
+ }
+
+ transformResults.set(transformOp->getOpResult(0), originalProducerOps);
+ transformResults.set(transformOp->getOpResult(1), fusedProducerOps);
+ return success();
+}
+
+DiagnosedSilenceableFailure
+transform::TestFuseProducerOp::apply(TransformRewriter &rewriter,
+ TransformResults &transformResults,
+ TransformState &state) {
+ LogicalResult result =
+ applyFuseProducer(rewriter, getOperation(),
+ state.getPayloadOps(getTarget()), transformResults);
+ return failed(result) ? DiagnosedSilenceableFailure::definiteFailure()
+ : DiagnosedSilenceableFailure::success();
+}
+
+void transform::TestFuseProducerOp::getEffects(
+ SmallVectorImpl<MemoryEffects::EffectInstance> &effects) {
+ consumesHandle(getTargetMutable(), effects);
+ producesHandle(getOperation()->getOpResults(), effects);
+ modifiesPayload(effects);
+}
+
//===----------------------------------------------------------------------===//
// TestFuseConsumerOp
//===----------------------------------------------------------------------===//
diff --git a/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.td b/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.td
index d55d746bd6aa9..6e73478c35c4a 100644
--- a/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.td
+++ b/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.td
@@ -49,6 +49,25 @@ def TestFuseAndYieldOp : Op<Transform_Dialect, "test.fuse_and_yield",
}];
}
+def TestFuseProducerOp : Op<Transform_Dialect, "test.fuse_producer",
+ [DeclareOpInterfaceMethods<TransformOpInterface>,
+ DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
+ ReportTrackingListenerFailuresOpTrait]> {
+ let description = [{
+ Fuses the producer of the operation pointed to by the target handle
+ using the options provided as attributes.
+ }];
+
+ let arguments =
+ (ins TransformHandleTypeInterface:$target);
+ let results = (outs TransformHandleTypeInterface:$producer,
+ TransformHandleTypeInterface:$fused_producer);
+
+ let assemblyFormat = [{
+ $target attr-dict `:` functional-type(operands, results)
+ }];
+}
+
def TestFuseConsumerOp : Op<Transform_Dialect, "test.fuse_consumer",
[DeclareOpInterfaceMethods<TransformOpInterface>,
DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
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