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llvm-project/mlir/lib/Dialect/SparseTensor/Transforms/SparsificationAndBufferizationPass.cpp
Michele Scuttari 61d5fdf50c
[MLIR] Add bufferization state class to OneShotBufferization pass (#141019) 
Follow-up on #138143, which was reverted due to a missing update a method signature (more specifically, the bufferization interface for `tensor::ConcatOp`) that was not catched before merging. The old PR description is reported in the next lines.

This PR is a follow-up on https://github.com/llvm/llvm-project/pull/138125, and adds a bufferization state class providing information about the IR. The information currently consists of a cached list of symbol tables, which aims to solve the quadratic scaling of the bufferization task with respect to the number of symbols. The PR breaks API compatibility: the bufferize method of the BufferizableOpInterface has been enriched with a reference to a BufferizationState object.

The bufferization state must be kept in a valid state by the interface implementations. For example, if an operation with the Symbol trait is inserted or replaced, its parent SymbolTable must be updated accordingly (see, for example, the bufferization of arith::ConstantOp, where the symbol table of the module gets the new global symbol inserted). Similarly, the invalidation of a symbol table must be performed if an operation with the SymbolTable trait is removed (this can be performed using the invalidateSymbolTable method, introduced in https://github.com/llvm/llvm-project/pull/138014).
2025-05-23 09:21:35 +02:00

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//===- SparsificationAndBufferizationPass.cpp - Tensor to Memref Lowering -===//
//
// 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 "mlir/Dialect/SparseTensor/Transforms/Passes.h"
#include "mlir/Dialect/Affine/IR/AffineOps.h"
#include "mlir/Dialect/Bufferization/IR/BufferizableOpInterface.h"
#include "mlir/Dialect/Bufferization/IR/Bufferization.h"
#include "mlir/Dialect/Bufferization/Transforms/Bufferize.h"
#include "mlir/Dialect/Bufferization/Transforms/OneShotAnalysis.h"
#include "mlir/Dialect/Bufferization/Transforms/OneShotModuleBufferize.h"
#include "mlir/Dialect/Bufferization/Transforms/Passes.h"
#include "mlir/Dialect/Bufferization/Transforms/Transforms.h"
#include "mlir/Dialect/Func/IR/FuncOps.h"
#include "mlir/Dialect/GPU/IR/GPUDialect.h"
#include "mlir/Dialect/LLVMIR/LLVMDialect.h"
#include "mlir/Dialect/Linalg/IR/Linalg.h"
#include "mlir/Dialect/MemRef/IR/MemRef.h"
#include "mlir/Dialect/SCF/IR/SCF.h"
#include "mlir/Dialect/SparseTensor/IR/SparseTensor.h"
#include "mlir/Dialect/SparseTensor/Transforms/Passes.h"
#include "mlir/Dialect/Vector/IR/VectorOps.h"
#include "mlir/Pass/PassManager.h"
#include "mlir/Transforms/Passes.h"
using namespace mlir;
namespace mlir {
#define GEN_PASS_DEF_SPARSIFICATIONANDBUFFERIZATION
#include "mlir/Dialect/SparseTensor/Transforms/Passes.h.inc"
namespace sparse_tensor {
/// Return `true` if one of the given types is a sparse tensor type.
static bool containsSparseTensor(TypeRange types) {
for (Type t : types)
if (isa<TensorType>(t) && getSparseTensorEncoding(t))
return true;
return false;
}
/// A pass that lowers tensor ops to memref ops, regardless of whether they are
/// dense or sparse.
///
/// One-Shot Analysis is used to detect RaW conflicts and to insert buffer
/// copies of the tensor level (`insertTensorCopies`). Afterwards, the lowering
/// of tensor ops to memref ops follows a different code path depending on
/// whether the op is sparse or dense:
///
/// * Sparse tensor ops are lowered through Sparsification and follow-up pass
/// that lowers sparse_tensor dialect ops.
/// * Dense tensor ops are lowered through BufferizableOpInterface
/// implementations.
class SparsificationAndBufferizationPass
: public impl::SparsificationAndBufferizationBase<
SparsificationAndBufferizationPass> {
public:
// Private pass options only.
SparsificationAndBufferizationPass(
const bufferization::OneShotBufferizationOptions &bufferizationOptions,
const SparsificationOptions &sparsificationOptions,
bool createSparseDeallocs, bool enableRuntimeLibrary,
bool enableBufferInitialization)
: bufferizationOptions(bufferizationOptions),
sparsificationOptions(sparsificationOptions),
createSparseDeallocs(createSparseDeallocs),
enableRuntimeLibrary(enableRuntimeLibrary),
enableBufferInitialization(enableBufferInitialization) {}
// Private pass options and visible pass options.
SparsificationAndBufferizationPass(
const bufferization::OneShotBufferizationOptions &bufferizationOptions,
const SparsificationOptions &sparsificationOptions,
bool createSparseDeallocs, bool enableRuntimeLibrary,
bool enableBufferInitialization, unsigned vl, bool vla, bool index32,
bool gpu, SparseEmitStrategy emitStrategy,
SparseParallelizationStrategy parallelizationStrategy)
: bufferizationOptions(bufferizationOptions),
sparsificationOptions(sparsificationOptions),
createSparseDeallocs(createSparseDeallocs),
enableRuntimeLibrary(enableRuntimeLibrary),
enableBufferInitialization(enableBufferInitialization) {
// Set the visible pass options explicitly.
vectorLength = vl;
enableVLAVectorization = vla;
enableSIMDIndex32 = index32;
enableGPULibgen = gpu;
sparseEmitStrategy = emitStrategy;
parallelization = parallelizationStrategy;
}
/// Bufferize all dense ops. This assumes that no further analysis is needed
/// and that all required buffer copies were already inserted by
/// `insertTensorCopies` in the form of `bufferization.alloc_tensor` ops.
LogicalResult runDenseBufferization() {
bufferization::OneShotBufferizationOptions updatedOptions =
bufferizationOptions;
// Skip all sparse ops.
updatedOptions.opFilter.denyOperation([&](Operation *op) {
if (containsSparseTensor(TypeRange(op->getResults())) ||
containsSparseTensor(TypeRange(op->getOperands())))
return true;
if (auto funcOp = dyn_cast<func::FuncOp>(op)) {
FunctionType funcType = funcOp.getFunctionType();
if (containsSparseTensor(funcType.getInputs()) ||
containsSparseTensor(funcType.getResults()))
return true;
}
return false;
});
bufferization::BufferizationState bufferizationState;
if (failed(bufferization::bufferizeModuleOp(cast<ModuleOp>(getOperation()),
updatedOptions,
bufferizationState)))
return failure();
bufferization::removeBufferizationAttributesInModule(getOperation());
return success();
}
void runOnOperation() override {
// Overrides the default emit strategy using user-provided value.
this->sparsificationOptions.sparseEmitStrategy = sparseEmitStrategy;
// Overrides the default parallelization strategy using user-provided value.
this->sparsificationOptions.parallelizationStrategy = parallelization;
// Run enabling transformations.
{
OpPassManager pm("builtin.module");
pm.addPass(createPreSparsificationRewritePass());
pm.addNestedPass<func::FuncOp>(
bufferization::createEmptyTensorToAllocTensorPass());
if (failed(runPipeline(pm, getOperation())))
return signalPassFailure();
}
// Insert tensor copies. This step runs One-Shot Analysis (which analyzes
// SSA use-def chains of tensor IR) and decides where buffer copies are
// needed and where buffers can be written to in-place. These decisions are
// materialized in the IR in the form of `bufferization.alloc_tensor` ops.
//
// Note: All following steps in this pass must be careful not to modify the
// structure of the IR (i.e., tensor use-def chains), as that could
// invalidate the results of the analysis. From now on, only small and
// localized rewrites are allowed, such as replacing a tensor op with its
// memref equivalent.
if (failed(bufferization::insertTensorCopies(getOperation(),
bufferizationOptions)))
return signalPassFailure();
// Option `testAnalysisOnly` is a debug/testing flag. If set, the results of
// OneShotAnalysis are added to the IR via attributes. In that case, do not
// continue with the remaining pipeline.
if (bufferizationOptions.testAnalysisOnly)
return;
// Bufferize all sparse ops. No further analysis is needed. All required
// buffer copies were already inserted by `insertTensorCopies` in the form
// of `bufferization.alloc_tensor` ops.
{
OpPassManager pm("builtin.module");
if (enableGPULibgen)
pm.addPass(createSparseGPUCodegenPass(0, enableRuntimeLibrary));
pm.addPass(createSparseReinterpretMapPass(ReinterpretMapScope::kAll));
pm.addPass(createSparsificationPass(sparsificationOptions));
if (sparsificationOptions.sparseEmitStrategy ==
SparseEmitStrategy::kSparseIterator) {
pm.addNestedPass<func::FuncOp>(createSparseSpaceCollapsePass());
pm.addNestedPass<func::FuncOp>(createLowerSparseIterationToSCFPass());
}
pm.addNestedPass<func::FuncOp>(createStageSparseOperationsPass());
pm.addPass(createLowerSparseOpsToForeachPass(enableRuntimeLibrary,
/*enableConvert=*/true));
pm.addPass(
createSparseReinterpretMapPass(ReinterpretMapScope::kExceptGeneric));
pm.addNestedPass<func::FuncOp>(createLowerForeachToSCFPass());
pm.addPass(mlir::createLoopInvariantCodeMotionPass());
if (vectorLength > 0) {
pm.addPass(createSparseVectorizationPass(
vectorLength, enableVLAVectorization, enableSIMDIndex32));
}
if (enableRuntimeLibrary) {
pm.addPass(createSparseTensorConversionPass());
} else {
pm.addPass(createSparseTensorCodegenPass(createSparseDeallocs,
enableBufferInitialization));
pm.addPass(createSparseBufferRewritePass(enableBufferInitialization));
}
if (failed(runPipeline(pm, getOperation())))
return signalPassFailure();
}
// Bufferize all dense ops.
if (failed(runDenseBufferization()))
signalPassFailure();
}
private:
bufferization::OneShotBufferizationOptions bufferizationOptions;
SparsificationOptions sparsificationOptions;
bool createSparseDeallocs;
bool enableRuntimeLibrary;
bool enableBufferInitialization;
};
} // namespace sparse_tensor
} // namespace mlir
mlir::bufferization::OneShotBufferizationOptions
mlir::getBufferizationOptionsForSparsification(bool analysisOnly) {
using namespace mlir::bufferization;
OneShotBufferizationOptions options;
options.bufferizeFunctionBoundaries = true;
options.setFunctionBoundaryTypeConversion(LayoutMapOption::IdentityLayoutMap);
options.unknownTypeConverterFn = [](Value value, Attribute memorySpace,
const BufferizationOptions &options) {
return getMemRefTypeWithStaticIdentityLayout(
cast<TensorType>(value.getType()), memorySpace);
};
if (analysisOnly) {
options.testAnalysisOnly = true;
options.printConflicts = true;
}
// Since this mini-pipeline may be used in alternative pipelines (viz.
// different from the default "sparsifier" pipeline) where unknown ops
// are handled by alternative bufferization methods that are downstream
// of this mini-pipeline, we allow unknown ops by default (failure to
// bufferize is eventually apparent by failing to convert to LLVM IR).
options.allowUnknownOps = true;
return options;
}
std::unique_ptr<mlir::Pass> mlir::createSparsificationAndBufferizationPass() {
SparsificationOptions sparseOptions;
return std::make_unique<
mlir::sparse_tensor::SparsificationAndBufferizationPass>(
getBufferizationOptionsForSparsification(/*analysisOnly=*/false),
sparseOptions,
/*createSparseDeallocs=*/false,
/*enableRuntimeLibrary=*/false,
/*enableBufferInitialization=*/false);
}
std::unique_ptr<mlir::Pass> mlir::createSparsificationAndBufferizationPass(
const bufferization::OneShotBufferizationOptions &bufferizationOptions,
const SparsificationOptions &sparsificationOptions,
bool createSparseDeallocs, bool enableRuntimeLibrary,
bool enableBufferInitialization, unsigned vectorLength,
bool enableVLAVectorization, bool enableSIMDIndex32, bool enableGPULibgen,
SparseEmitStrategy emitStrategy,
SparseParallelizationStrategy parallelizationStrategy) {
return std::make_unique<
mlir::sparse_tensor::SparsificationAndBufferizationPass>(
bufferizationOptions, sparsificationOptions, createSparseDeallocs,
enableRuntimeLibrary, enableBufferInitialization, vectorLength,
enableVLAVectorization, enableSIMDIndex32, enableGPULibgen, emitStrategy,
parallelizationStrategy);
}
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