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clang-p2996/mlir/test/lib/Interfaces/TilingInterface/TestTilingInterfaceTransformOps.cpp
Yun-Fly 9bc3102bea [mlir][scf] Extend consumer fusion to multiple tilable users (#111955) 
Before, consumer fusion expects single usage(or others are terminator
op). This patch supports multiple tilable consumers fusion. 
E.g.
```
%0 = scf.for {
  ...
  %p = tiledProducer
  ...
}
%1 = tilableConsumer1 ins(%0 : ...)
%2 = tilableConsumer2 ins(%0 : ...)
```
===>
```
%0:3 = scf.for {
  ...
  %p = tiledProducer
  %1 = tiledConsumer1 ins(%p : ...)
  %2 = tiledConsumer2 ins(%p : ...)
  ...
}
```
The key process is ensuring that the first user of loop 
should not dominate any define of consumer operand(s).
2024-11-06 10:03:23 +08:00

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//===- TestTilingInterfaceTransformOps.cpp - Test `TilingInterface` ------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines transform dialect operations used for testing
// TilingInterface
//
//===----------------------------------------------------------------------===//
#include "mlir/Dialect/Affine/IR/AffineOps.h"
#include "mlir/Dialect/Index/IR/IndexDialect.h"
#include "mlir/Dialect/SCF/Transforms/TileUsingInterface.h"
#include "mlir/Dialect/Transform/IR/TransformAttrs.h"
#include "mlir/Dialect/Transform/IR/TransformDialect.h"
#include "mlir/Dialect/Transform/Interfaces/TransformInterfaces.h"
#include "mlir/Dialect/Utils/StaticValueUtils.h"
#include "mlir/IR/Dominance.h"
#include "mlir/IR/OpImplementation.h"
#include "mlir/Interfaces/TilingInterface.h"
#define GET_OP_CLASSES
#include "TestTilingInterfaceTransformOps.h.inc"
using namespace mlir;
using namespace mlir::transform;
//===----------------------------------------------------------------------===//
// TestFuseAndYieldOp
//===----------------------------------------------------------------------===//
static llvm::SmallDenseSet<Operation *> collectTiledAndFusedOps(Operation *op) {
SmallVector<Operation *> worklist;
llvm::SmallDenseSet<Operation *> producers;
worklist.push_back(op);
producers.insert(op);
while (!worklist.empty()) {
Operation *current = worklist.pop_back_val();
for (OpOperand &operand : current->getOpOperands()) {
Operation *producer = operand.get().getDefiningOp();
if (!producer || !isa<TilingInterface>(producer) ||
producers.contains(producer))
continue;
worklist.push_back(producer);
producers.insert(producer);
}
}
return producers;
}
/// Apply a tile and fuse transformation to all payload ops and store both the
/// tiled operation as well as the created tile loops.
template <typename Range>
static LogicalResult
applyTileAndFuseToAll(RewriterBase &rewriter, Operation *transformOp,
Range &&payloadOps, unsigned numLoops,
ArrayRef<OpFoldResult> tileSizes,
ArrayRef<int64_t> interchange, bool useForall,
TransformResults &transformResults) {
SmallVector<Operation *> tiledOps;
SmallVector<SmallVector<Operation *>> loopOps(numLoops);
for (Operation *target : payloadOps) {
auto tilingInterfaceOp = dyn_cast<TilingInterface>(target);
if (!tilingInterfaceOp)
return transformOp->emitError("only TilingInterface ops are supported");
DominanceInfo dominanceInfo(tilingInterfaceOp);
llvm::SmallDenseSet<Operation *> tiledAndFusedOps =
collectTiledAndFusedOps(tilingInterfaceOp);
llvm::DenseSet<Operation *> yieldReplacementsFor;
for (auto op : tiledAndFusedOps) {
if (llvm::any_of(op->getUsers(), [&](Operation *user) {
return dominanceInfo.properlyDominates(tilingInterfaceOp, user);
})) {
yieldReplacementsFor.insert(op);
}
}
scf::SCFTilingOptions tilingOptions;
tilingOptions.setTileSizes(tileSizes).setInterchange(interchange);
if (useForall) {
tilingOptions.setLoopType(scf::SCFTilingOptions::LoopType::ForallOp);
}
scf::SCFTileAndFuseOptions tileAndFuseOptions;
tileAndFuseOptions.setTilingOptions(tilingOptions);
scf::SCFTileAndFuseOptions::ControlFnTy controlFn =
[&](tensor::ExtractSliceOp candidateSliceOp, OpResult originalProducer,
bool isDestinationOperand)
-> std::optional<scf::SCFTileAndFuseOptions::ControlFnResult> {
Operation *owner = originalProducer.getOwner();
bool yieldProducerReplacement = yieldReplacementsFor.contains(owner);
return scf::SCFTileAndFuseOptions::ControlFnResult{
yieldProducerReplacement};
};
tileAndFuseOptions.setFusionControlFn(controlFn);
rewriter.setInsertionPoint(target);
FailureOr<scf::SCFTileAndFuseResult> tiledResults =
scf::tileConsumerAndFuseProducersUsingSCF(rewriter, tilingInterfaceOp,
tileAndFuseOptions);
if (failed(tiledResults))
return failure();
// Perform the replacement of tiled and fused values.
SmallVector<Operation *> opsToReplace{target};
llvm::append_range(opsToReplace, tiledResults->fusedProducers);
for (Operation *toReplace : opsToReplace) {
for (OpResult res : toReplace->getResults())
if (auto replacement = tiledResults->replacements.lookup(res)) {
Operation *replacementOp = replacement.getDefiningOp();
rewriter.replaceUsesWithIf(res, replacement, [&](OpOperand &use) {
Operation *user = use.getOwner();
return dominanceInfo.properlyDominates(replacementOp, user) &&
user->getParentOp() == replacementOp->getParentOp();
});
}
if (toReplace->use_empty()) {
rewriter.eraseOp(toReplace);
}
}
// Report back the relevant handles to the transform op.
tiledOps.push_back(tiledResults->tiledAndFusedOps.front());
assert(tiledResults->loops.size() == numLoops &&
"Mismatched number of loops, tile and fuse transform should have "
"failed");
for (unsigned int i = 0; i < numLoops; ++i)
loopOps[i].push_back(tiledResults->loops[i]);
}
transformResults.set(transformOp->getOpResult(0), tiledOps);
for (unsigned int i = 0; i < numLoops; ++i)
transformResults.set(transformOp->getOpResult(i + 1), loopOps[i]);
return success();
}
DiagnosedSilenceableFailure
transform::TestFuseAndYieldOp::apply(TransformRewriter &rewriter,
TransformResults &transformResults,
TransformState &state) {
SmallVector<int64_t> tileSizes =
extractFromIntegerArrayAttr<int64_t>(getTileSizes());
SmallVector<int64_t> tileInterchange =
extractFromIntegerArrayAttr<int64_t>(getTileInterchange());
SmallVector<OpFoldResult> tileSizesOfr =
getAsIndexOpFoldResult(rewriter.getContext(), tileSizes);
LogicalResult result = applyTileAndFuseToAll(
rewriter, getOperation(), state.getPayloadOps(getTarget()),
tileSizes.size() - llvm::count(tileSizes, 0), tileSizesOfr,
tileInterchange, getUseForall(), transformResults);
return failed(result) ? DiagnosedSilenceableFailure::definiteFailure()
: DiagnosedSilenceableFailure::success();
}
//===----------------------------------------------------------------------===//
// TestFuseConsumerOp
//===----------------------------------------------------------------------===//
/// Apply fusing of consumer transformation to all payload ops and store both
/// the original consumer operation as well as the fused consumer operation.
template <typename Range>
static LogicalResult
applyFuseConsumer(RewriterBase &rewriter, Operation *transformOp,
Range &&payloadOps, uint32_t numConsumerToFuse,
TransformResults &transformResults) {
SmallVector<Operation *> originalConsumerOps;
SmallVector<Operation *> fusedConsumerOps;
for (Operation *target : payloadOps) {
rewriter.setInsertionPoint(target);
while (numConsumerToFuse--) {
FailureOr<scf::SCFFuseConsumerOfSliceResult> fuseConsumerResults =
scf::tileAndFuseConsumerOfSlice(rewriter, target);
if (failed(fuseConsumerResults))
return failure();
// Report back the relevant handles to the transform op.
originalConsumerOps.push_back(
fuseConsumerResults->origConsumerOperand->getOwner());
fusedConsumerOps.push_back(
fuseConsumerResults->tiledAndFusedConsumerOperand->getOwner());
}
}
transformResults.set(transformOp->getOpResult(0), originalConsumerOps);
transformResults.set(transformOp->getOpResult(1), fusedConsumerOps);
return success();
}
DiagnosedSilenceableFailure
transform::TestFuseConsumerOp::apply(TransformRewriter &rewriter,
TransformResults &transformResults,
TransformState &state) {
LogicalResult result = applyFuseConsumer(
rewriter, getOperation(), state.getPayloadOps(getTarget()),
getNumConsumerToFuse(), transformResults);
return failed(result) ? DiagnosedSilenceableFailure::definiteFailure()
: DiagnosedSilenceableFailure::success();
}
void transform::TestFuseConsumerOp::getEffects(
SmallVectorImpl<MemoryEffects::EffectInstance> &effects) {
consumesHandle(getTargetMutable(), effects);
producesHandle(getOperation()->getOpResults(), effects);
modifiesPayload(effects);
}
//===----------------------------------------------------------------------===//
// TestTileUsingForallOp
//===----------------------------------------------------------------------===//
/// Apply a tiling transformation to all payload ops and store both the
/// tiled operation as well as the created tile loops.
template <typename Range>
static LogicalResult
applyTileToAll(RewriterBase &rewriter, Operation *transformOp,
Range &&payloadOps, ArrayRef<OpFoldResult> tileSizes,
ArrayRef<int64_t> interchange, std::optional<ArrayAttr> mapping,
TransformResults &transformResults) {
SmallVector<Operation *> tiledOps;
SmallVector<Operation *> loopOps;
for (Operation *target : payloadOps) {
auto tilingInterfaceOp = dyn_cast<TilingInterface>(target);
if (!tilingInterfaceOp)
return transformOp->emitError("only TilingInterface ops are supported");
scf::SCFTilingOptions tilingOptions;
tilingOptions.setTileSizes(tileSizes).setInterchange(interchange);
if (mapping) {
tilingOptions.setMapping(mapping.value().getValue());
}
tilingOptions.setLoopType(scf::SCFTilingOptions::LoopType::ForallOp);
rewriter.setInsertionPoint(target);
FailureOr<scf::SCFTilingResult> tiledResults =
scf::tileUsingSCF(rewriter, tilingInterfaceOp, tilingOptions);
if (failed(tiledResults))
return failure();
// Perform the replacement of tiled and fused values.
rewriter.replaceOp(tilingInterfaceOp, tiledResults->replacements);
// Report back the relevant handles to the transform op.
tiledOps.push_back(tiledResults->tiledOps.front());
for (Operation *loop : tiledResults->loops)
loopOps.push_back(loop);
}
transformResults.set(transformOp->getOpResult(0), tiledOps);
for (auto [index, loop] : llvm::enumerate(loopOps))
transformResults.set(transformOp->getOpResult(index + 1), {loop});
return success();
}
DiagnosedSilenceableFailure
transform::TestTileUsingForallOp::apply(TransformRewriter &rewriter,
TransformResults &transformResults,
TransformState &state) {
SmallVector<int64_t> tileSizes =
extractFromIntegerArrayAttr<int64_t>(getTileSizes());
SmallVector<int64_t> interchange =
extractFromIntegerArrayAttr<int64_t>(getInterchange());
SmallVector<OpFoldResult> tileSizesOfr =
getAsIndexOpFoldResult(rewriter.getContext(), tileSizes);
LogicalResult result =
applyTileToAll(rewriter, getOperation(), state.getPayloadOps(getTarget()),
tileSizesOfr, interchange, getMapping(), transformResults);
return failed(result) ? DiagnosedSilenceableFailure::definiteFailure()
: DiagnosedSilenceableFailure::success();
}
void transform::TestTileUsingForallOp::getEffects(
SmallVectorImpl<MemoryEffects::EffectInstance> &effects) {
consumesHandle(getTargetMutable(), effects);
producesHandle(getOperation()->getOpResults(), effects);
modifiesPayload(effects);
}
//===----------------------------------------------------------------------===//
// TestFuseUsingForallOp
//===----------------------------------------------------------------------===//
/// Apply a tiling transformation to all payload ops and store both the
/// tiled operation as well as the created tile loops.
template <typename Range>
static LogicalResult applyTilingToAll(
RewriterBase &rewriter, Operation *transformOp, Range &&payloadOps,
unsigned numLoops, TransformResults &transformResults,
function_ref<FailureOr<scf::SCFTileAndFuseResult>(TilingInterface)>
applyFn) {
SmallVector<Operation *> tiledLinalgOps;
SmallVector<SmallVector<Operation *>> loopOps(1);
for (Operation *target : payloadOps) {
auto tilingInterfaceOp = dyn_cast<TilingInterface>(target);
if (!tilingInterfaceOp)
return transformOp->emitError("only TilingInterface ops are supported");
rewriter.setInsertionPoint(target);
FailureOr<scf::SCFTileAndFuseResult> tiledResults =
applyFn(tilingInterfaceOp);
if (failed(tiledResults))
return failure();
// Perform the replacement of tiled and fused values.
SmallVector<Operation *> opsToReplace{target};
llvm::append_range(opsToReplace, tiledResults->fusedProducers);
for (Operation *toReplace : opsToReplace) {
for (OpResult res : toReplace->getResults())
if (auto replacement = tiledResults->replacements.lookup(res))
rewriter.replaceAllUsesWith(res, replacement);
if (toReplace->use_empty())
rewriter.eraseOp(toReplace);
}
// Report back the relevant handles to the transform op.
tiledLinalgOps.push_back(tiledResults->tiledAndFusedOps.front());
assert(tiledResults->loops.size() == 1 &&
cast<scf::ForallOp>(tiledResults->loops[0]).getRank() == numLoops &&
"Mismatched number of loops, tile and fuse transform should have "
"failed");
loopOps[0] = {tiledResults->loops[0]};
}
transformResults.set(transformOp->getOpResult(0), tiledLinalgOps);
if (!loopOps.empty())
transformResults.set(transformOp->getOpResult(1), loopOps[0]);
return success();
}
DiagnosedSilenceableFailure
transform::TestFuseUsingForallOp::apply(TransformRewriter &rewriter,
TransformResults &transformResults,
TransformState &state) {
SmallVector<int64_t> tileSizes =
extractFromIntegerArrayAttr<int64_t>(getTileSizes());
SmallVector<int64_t> tileInterchange =
extractFromIntegerArrayAttr<int64_t>(getInterchange());
scf::SCFTilingOptions tilingOptions;
tilingOptions.interchangeVector = tileInterchange;
SmallVector<OpFoldResult> tileSizesOfr =
getAsIndexOpFoldResult(rewriter.getContext(), tileSizes);
tilingOptions = tilingOptions.setTileSizes(tileSizesOfr);
tilingOptions.setLoopType(scf::SCFTilingOptions::LoopType::ForallOp);
scf::SCFTileAndFuseOptions tileAndFuseOptions;
tileAndFuseOptions.tilingOptions = tilingOptions;
LogicalResult result = applyTilingToAll(
rewriter, getOperation(), state.getPayloadOps(getRootOp()),
tileSizes.size() - llvm::count(tileSizes, 0), transformResults,
[&](TilingInterface tilingInterfaceOp)
-> FailureOr<scf::SCFTileAndFuseResult> {
return tileConsumerAndFuseProducersUsingSCF(rewriter, tilingInterfaceOp,
tileAndFuseOptions);
});
return failed(result) ? DiagnosedSilenceableFailure::definiteFailure()
: DiagnosedSilenceableFailure::success();
}
void transform::TestFuseUsingForallOp::getEffects(
SmallVectorImpl<MemoryEffects::EffectInstance> &effects) {
consumesHandle(getRootOpMutable(), effects);
producesHandle(getOperation()->getOpResults(), effects);
modifiesPayload(effects);
}
#define GET_OP_CLASSES
#include "TestTilingInterfaceTransformOps.cpp.inc"
namespace {
class TestTilingInterfaceDialectExtension
: public transform::TransformDialectExtension<
TestTilingInterfaceDialectExtension> {
public:
MLIR_DEFINE_EXPLICIT_INTERNAL_INLINE_TYPE_ID(
TestTilingInterfaceDialectExtension)
using Base::Base;
void init() {
declareDependentDialect<affine::AffineDialect>();
declareDependentDialect<index::IndexDialect>();
declareDependentDialect<scf::SCFDialect>();
declareDependentDialect<tensor::TensorDialect>();
registerTransformOps<
#define GET_OP_LIST
#include "TestTilingInterfaceTransformOps.cpp.inc"
>();
}
};
} // namespace
namespace test {
void registerTestTilingInterfaceTransformDialectExtension(
DialectRegistry &registry) {
registry.addExtensions<TestTilingInterfaceDialectExtension>();
}
} // namespace test
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