//===- BufferizableOpInterface.cpp - Bufferizable Ops ---=----------------===// // // 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/Bufferization/IR/BufferizableOpInterface.h" #include "mlir/Dialect/Bufferization/IR/Bufferization.h" #include "mlir/Dialect/Func/IR/FuncOps.h" #include "mlir/Dialect/MemRef/IR/MemRef.h" #include "mlir/Dialect/Tensor/IR/Tensor.h" #include "mlir/IR/AsmState.h" #include "mlir/IR/BlockAndValueMapping.h" #include "mlir/IR/BuiltinOps.h" #include "mlir/IR/Operation.h" #include "mlir/IR/TypeUtilities.h" #include "mlir/IR/Value.h" #include "llvm/Support/Debug.h" //===----------------------------------------------------------------------===// // BufferizableOpInterface //===----------------------------------------------------------------------===// namespace mlir { namespace bufferization { #include "mlir/Dialect/Bufferization/IR/BufferizableOpInterface.cpp.inc" } // namespace bufferization } // namespace mlir #define DEBUG_TYPE "bufferizable-op-interface" #define DBGS() (llvm::dbgs() << '[' << DEBUG_TYPE << "] ") #define LDBG(X) LLVM_DEBUG(DBGS() << (X)) using namespace mlir; using namespace bufferization; /// Attribute name used to mark region arguments that can be bufferized /// in-place during linalg comprehensive bufferization. constexpr const ::llvm::StringLiteral bufferization::BufferizableOpInterface::kInplaceableAttrName; /// Create an AllocTensorOp for the given shaped value. If `copy` is set, the /// shaped value is copied. Otherwise, a tensor with undefined contents is /// allocated. Value bufferization::allocateTensorForShapedValue(OpBuilder &b, Location loc, Value shapedValue, bool escape, bool copy) { Value tensor; if (shapedValue.getType().isa()) { tensor = shapedValue; } else if (shapedValue.getType().isa()) { tensor = b.create(loc, shapedValue); } else { llvm_unreachable("expected RankedTensorType or MemRefType"); } RankedTensorType tensorType = tensor.getType().cast(); SmallVector dynamicSizes; if (!copy) { // Compute the dynamic part of the shape. // First try to query the shape via ReifyRankedShapedTypeOpInterface. bool reifiedShapes = false; if (shapedValue.getType().isa() && shapedValue.isa()) { if (auto rankedOp = dyn_cast_or_null( shapedValue.getDefiningOp())) { ReifiedRankedShapedTypeDims resultDims; if (succeeded(rankedOp.reifyResultShapes(b, resultDims))) { reifiedShapes = true; auto &shape = resultDims[shapedValue.cast().getResultNumber()]; for (const auto &dim : enumerate(tensorType.getShape())) if (ShapedType::isDynamic(dim.value())) dynamicSizes.push_back(shape[dim.index()]); } } } // If the shape could not be reified, create DimOps. if (!reifiedShapes) populateDynamicDimSizes(b, loc, tensor, dynamicSizes); } return b.create(loc, tensorType, dynamicSizes, copy ? tensor : Value(), escape); } LogicalResult BufferizableOpInterface::resolveTensorOpOperandConflicts( RewriterBase &rewriter, const AnalysisState &state) { OpBuilder::InsertionGuard g(rewriter); Operation *op = getOperation(); SmallVector outOfPlaceOpOperands; DenseSet copiedOpOperands; DenseSet escapingOpOperandCopies; SmallVector outOfPlaceOpResults; DenseSet copiedOpResults; DenseSet escapingOpResultCopies; // Find all out-of-place OpOperands. for (OpOperand &opOperand : op->getOpOperands()) { Type operandType = opOperand.get().getType(); if (!operandType.isa()) continue; if (state.isInPlace(opOperand)) continue; if (operandType.isa()) return op->emitError("copies of unranked tensors are not supported"); SmallVector aliasingOpResults = state.getAliasingOpResult(opOperand); // Is the result yielded from a block? Or are deallocations turned off // entirely? In either case, mark the allocation as "escaping", so that it // will not be deallocated. bool escape = !state.getOptions().createDeallocs || llvm::any_of(aliasingOpResults, [&](Value v) { return state.isTensorYielded(v); }); if (aliasingOpResults.size() == 1 && !state.bufferizesToMemoryWrite(opOperand) && state.getAliasingOpOperand(aliasingOpResults.front()).size() == 1) { // The op itself does not write but may create exactly one alias. Instead // of copying the OpOperand, copy the OpResult. The OpResult can sometimes // be smaller than the OpOperand (e.g., in the case of an extract_slice, // where the result is usually a smaller part of the source). outOfPlaceOpResults.push_back(aliasingOpResults.front()); if (!state.canOmitTensorCopy(opOperand)) copiedOpResults.insert(aliasingOpResults.front()); if (escape) escapingOpResultCopies.insert(aliasingOpResults.front()); } else { // In all other cases, make a copy of the OpOperand. outOfPlaceOpOperands.push_back(&opOperand); if (!state.canOmitTensorCopy(opOperand)) copiedOpOperands.insert(&opOperand); if (escape) escapingOpOperandCopies.insert(&opOperand); } } // Insert copies of OpOperands. rewriter.setInsertionPoint(op); for (OpOperand *opOperand : outOfPlaceOpOperands) { Value copy = allocateTensorForShapedValue( rewriter, op->getLoc(), opOperand->get(), escapingOpOperandCopies.contains(opOperand), copiedOpOperands.contains(opOperand)); rewriter.updateRootInPlace(op, [&]() { opOperand->set(copy); }); } // Insert copies of OpResults. rewriter.setInsertionPointAfter(op); for (OpResult opResult : outOfPlaceOpResults) { Value copy = allocateTensorForShapedValue(rewriter, op->getLoc(), opResult, escapingOpResultCopies.contains(opResult), copiedOpResults.count(opResult)); SmallVector uses = llvm::to_vector(llvm::map_range( opResult.getUses(), [](OpOperand &use) { return &use; })); for (OpOperand *use : uses) { // Do not update the alloc_tensor op that we just created. if (use->getOwner() != copy.getDefiningOp()) rewriter.updateRootInPlace(use->getOwner(), [&]() { use->set(copy); }); } } return success(); } //===----------------------------------------------------------------------===// // OpFilter //===----------------------------------------------------------------------===// bool OpFilter::isOpAllowed(Operation *op) const { // All other ops: Allow/disallow according to filter. bool isAllowed = !hasAllowRule(); for (const Entry &entry : entries) { bool filterResult = entry.fn(op); switch (entry.type) { case Entry::ALLOW: isAllowed |= filterResult; break; case Entry::DENY: if (filterResult) // DENY filter matches. This op is no allowed. (Even if other ALLOW // filters may match.) return false; }; } return isAllowed; } //===----------------------------------------------------------------------===// // BufferizationOptions //===----------------------------------------------------------------------===// // Default constructor for BufferizationOptions. BufferizationOptions::BufferizationOptions() = default; bool BufferizationOptions::isOpAllowed(Operation *op) const { // Special case: If function boundary bufferization is deactivated, do not // allow ops that belong to the `func` dialect. bool isFuncBoundaryOp = isa_and_nonnull(op->getDialect()); if (!bufferizeFunctionBoundaries && isFuncBoundaryOp) return false; return opFilter.isOpAllowed(op); } BufferizableOpInterface BufferizationOptions::dynCastBufferizableOp(Operation *op) const { auto bufferizableOp = dyn_cast(op); if (!bufferizableOp) return nullptr; if (!isOpAllowed(op)) return nullptr; return bufferizableOp; } BufferizableOpInterface BufferizationOptions::dynCastBufferizableOp(Value value) const { if (auto bufferizableOp = value.getDefiningOp()) if (isOpAllowed(bufferizableOp.getOperation())) return bufferizableOp; return nullptr; } void BufferizationOptions::addDialectStateInitializer( StringRef name, const DialectStateInitFn &fn) { stateInitializers.push_back( [=](AnalysisState &state) { state.insertDialectState(name, fn()); }); } //===----------------------------------------------------------------------===// // Helper functions for BufferizableOpInterface //===----------------------------------------------------------------------===// static void setInsertionPointAfter(OpBuilder &b, Value value) { if (auto bbArg = value.dyn_cast()) { b.setInsertionPointToStart(bbArg.getOwner()); } else { b.setInsertionPointAfter(value.getDefiningOp()); } } /// Determine which OpOperand* will alias with `result` if the op is bufferized /// in place. Return an empty vector if the op is not bufferizable. SmallVector AnalysisState::getAliasingOpOperand(OpResult result) const { if (Operation *op = result.getDefiningOp()) if (auto bufferizableOp = getOptions().dynCastBufferizableOp(op)) return bufferizableOp.getAliasingOpOperand(result, *this); return {}; } /// Determine which OpResult will alias with `opOperand` if the op is bufferized /// in place. Return an empty vector if the op is not bufferizable. SmallVector AnalysisState::getAliasingOpResult(OpOperand &opOperand) const { if (auto bufferizableOp = getOptions().dynCastBufferizableOp(opOperand.getOwner())) return bufferizableOp.getAliasingOpResult(opOperand, *this); return {}; } /// Return true if `opOperand` bufferizes to a memory read. Return `true` if the /// op is not bufferizable. bool AnalysisState::bufferizesToMemoryRead(OpOperand &opOperand) const { if (auto bufferizableOp = getOptions().dynCastBufferizableOp(opOperand.getOwner())) return bufferizableOp.bufferizesToMemoryRead(opOperand, *this); // Unknown op that returns a tensor. The inplace analysis does not support it. // Conservatively return true. return true; } /// Return true if `opOperand` bufferizes to a memory write. Return /// `true` if the op is not bufferizable. bool AnalysisState::bufferizesToMemoryWrite(OpOperand &opOperand) const { if (auto bufferizableOp = getOptions().dynCastBufferizableOp(opOperand.getOwner())) return bufferizableOp.bufferizesToMemoryWrite(opOperand, *this); // Unknown op that returns a tensor. The inplace analysis does not support it. // Conservatively return true. return true; } /// Return true if `opOperand` does neither read nor write but bufferizes to an /// alias. Return false if the op is not bufferizable. bool AnalysisState::bufferizesToAliasOnly(OpOperand &opOperand) const { if (auto bufferizableOp = getOptions().dynCastBufferizableOp(opOperand.getOwner())) return bufferizableOp.bufferizesToAliasOnly(opOperand, *this); // Unknown op that returns a tensor. The inplace analysis does not support it. // Conservatively return false. return false; } /// Return true if the given value is read by an op that bufferizes to a memory /// read. Also takes into account ops that create an alias but do not read by /// themselves (e.g., ExtractSliceOp). bool AnalysisState::isValueRead(Value value) const { assert(value.getType().isa() && "expected TensorType"); SmallVector workingSet; for (OpOperand &use : value.getUses()) workingSet.push_back(&use); while (!workingSet.empty()) { OpOperand *uMaybeReading = workingSet.pop_back_val(); // Skip over all ops that neither read nor write (but create an alias). if (bufferizesToAliasOnly(*uMaybeReading)) for (OpResult opResult : getAliasingOpResult(*uMaybeReading)) for (OpOperand &use : opResult.getUses()) workingSet.push_back(&use); if (bufferizesToMemoryRead(*uMaybeReading)) return true; } return false; } // Starting from `value`, follow the use-def chain in reverse, always selecting // the aliasing OpOperands. Find and return Values for which `condition` // evaluates to true. OpOperands of such matching Values are not traversed any // further. llvm::SetVector AnalysisState::findValueInReverseUseDefChain( Value value, llvm::function_ref condition) const { llvm::SetVector result, workingSet; workingSet.insert(value); while (!workingSet.empty()) { Value value = workingSet.pop_back_val(); if (condition(value) || value.isa()) { result.insert(value); continue; } OpResult opResult = value.cast(); SmallVector opOperands = getAliasingOpOperand(opResult); if (opOperands.empty() || !options.isOpAllowed(value.getDefiningOp())) { result.insert(value); continue; } for (OpOperand *o : opOperands) workingSet.insert(o->get()); } return result; } // Find the Values of the last preceding write of a given Value. llvm::SetVector AnalysisState::findLastPrecedingWrite(Value value) const { return findValueInReverseUseDefChain(value, [&](Value value) { Operation *op = value.getDefiningOp(); if (!op) return true; auto bufferizableOp = options.dynCastBufferizableOp(op); if (!bufferizableOp) return true; return bufferizableOp.isMemoryWrite(value.cast(), *this); }); } AnalysisState::AnalysisState(const BufferizationOptions &options) : options(options) { for (const BufferizationOptions::AnalysisStateInitFn &fn : options.stateInitializers) fn(*this); } bool AnalysisState::canOmitTensorCopy(OpOperand &opOperand) const { // Do not copy if the tensor has undefined contents. if (hasUndefinedContents(&opOperand)) return true; // Do not copy if the buffer of the tensor is entirely overwritten (with // values that do not depend on the old tensor). if (bufferizesToMemoryWrite(opOperand) && !bufferizesToMemoryRead(opOperand)) return true; // Do not copy if the tensor is never read. SmallVector aliasingOpResults = getAliasingOpResult(opOperand); if (!bufferizesToMemoryRead(opOperand) && llvm::none_of(aliasingOpResults, [&](OpResult opResult) { return isValueRead(opResult); })) return true; // Default: Cannot omit the copy. return false; } bool AnalysisState::isInPlace(OpOperand &opOperand) const { // ToMemrefOps are always in-place. if (isa(opOperand.getOwner())) return true; // In the absence of analysis information, OpOperands that bufferize to a // memory write are out-of-place, i.e., an alloc and copy is inserted. return !bufferizesToMemoryWrite(opOperand); } bool AnalysisState::areEquivalentBufferizedValues(Value v1, Value v2) const { // In the absence of analysis information, we do not know if the values are // equivalent. The conservative answer is "false". return false; } bool AnalysisState::areAliasingBufferizedValues(Value v1, Value v2) const { // In the absence of analysis information, we do not know if the values may be // aliasing. The conservative answer is "true". return true; } bool AnalysisState::hasUndefinedContents(OpOperand *opOperand) const { // In the absence of analysis information, the conservative answer is "false". return false; } bool AnalysisState::isTensorYielded(Value tensor) const { // In the absence of analysis information, the conservative answer is "true". if (!tensor.getDefiningOp()) return true; // For AllocTensorOp results, we can do better: They do not alias with any // preceding value, so we can follow SSA use-def chains and do a simple // analysis. SmallVector worklist; for (OpOperand &use : tensor.getUses()) worklist.push_back(&use); while (!worklist.empty()) { OpOperand *operand = worklist.pop_back_val(); Operation *op = operand->getOwner(); // If the op is not bufferizable, we can safely assume that the value is not // yielded. (When bufferizing that op, it must handle such cases.) if (!options.dynCastBufferizableOp(op)) continue; // We cannot analyze through ToMemrefOps, so we have to conservatively // assume that the value is yielded. if (isa(op)) return true; // Check if the op is returning/yielding. if (isRegionReturnLike(op)) return true; // Add all aliasing OpResults to the worklist. // Note: In the absence of detailed analysis information (e.g., there may be // no function call analysis information), this `getAliasingOpResult` is // conservative and may report additional OpResults as potentially aliasing. for (OpResult opResult : getAliasingOpResult(*operand)) for (OpOperand &use : opResult.getUses()) worklist.push_back(&use); } // No ReturnLike op found: The value is not yielded. return false; } // bufferization.to_memref is not allowed to change the rank. static void ensureToMemrefOpIsValid(Value tensor, Type memrefType) { #ifndef NDEBUG auto rankedTensorType = tensor.getType().dyn_cast(); assert((!rankedTensorType || memrefType.cast().getRank() == rankedTensorType.getRank()) && "to_memref would be invalid: mismatching ranks"); #endif } Value bufferization::getBuffer(RewriterBase &rewriter, Value value, const BufferizationOptions &options) { auto tensorType = value.getType().dyn_cast(); assert(tensorType && "unexpected non-tensor type"); // Replace "%t = to_tensor %m" with %m. if (auto toTensorOp = value.getDefiningOp()) return toTensorOp.memref(); // Insert to_memref op. OpBuilder::InsertionGuard g(rewriter); setInsertionPointAfter(rewriter, value); Type memrefType = getMemRefType(tensorType, options); ensureToMemrefOpIsValid(value, memrefType); return rewriter.create(value.getLoc(), memrefType, value); } /// Return the buffer type for a given Value (tensor) after bufferization. BaseMemRefType bufferization::getBufferType(Value value, const BufferizationOptions &options) { auto tensorType = value.getType().dyn_cast(); assert(tensorType && "unexpected non-tensor type"); if (auto toTensorOp = value.getDefiningOp()) return toTensorOp.memref().getType().cast(); return getMemRefType(tensorType, options); } void bufferization::replaceOpWithBufferizedValues(RewriterBase &rewriter, Operation *op, ValueRange values) { assert(values.size() == op->getNumResults() && "expected one value per OpResult"); OpBuilder::InsertionGuard g(rewriter); // Replace all OpResults with the given values. SmallVector replacements; for (OpResult opResult : op->getOpResults()) { Value replacement = values[opResult.getResultNumber()]; if (opResult.getType().isa()) { // The OpResult is a tensor. Such values are replaced with memrefs during // bufferization. assert((replacement.getType().isa() || replacement.getType().isa()) && "tensor op result should be replaced with a memref value"); // The existing uses of the OpResult still expect a tensor. Insert a // ToTensorOp. Throughout bufferization, this ToTensorOp will gradually // loose all of its users and eventually DCE away. rewriter.setInsertionPointAfter(op); replacement = rewriter.create( replacement.getLoc(), replacement); } replacements.push_back(replacement); } rewriter.replaceOp(op, replacements); } //===----------------------------------------------------------------------===// // Bufferization-specific scoped alloc/dealloc insertion support. //===----------------------------------------------------------------------===// /// Create a memref allocation with the given type and dynamic extents. FailureOr BufferizationOptions::createAlloc(OpBuilder &b, Location loc, MemRefType type, ValueRange dynShape) const { if (allocationFn) return (*allocationFn)(b, loc, type, dynShape, bufferAlignment); // Default bufferallocation via AllocOp. if (bufferAlignment != 0) return b .create(loc, type, dynShape, b.getI64IntegerAttr(bufferAlignment)) .getResult(); return b.create(loc, type, dynShape).getResult(); } /// Creates a memref deallocation. The given memref buffer must have been /// allocated using `createAlloc`. LogicalResult BufferizationOptions::createDealloc(OpBuilder &b, Location loc, Value allocatedBuffer) const { if (deallocationFn) return (*deallocationFn)(b, loc, allocatedBuffer); // Default buffer deallocation via DeallocOp. b.create(loc, allocatedBuffer); return success(); } /// Create a memory copy between two memref buffers. LogicalResult BufferizationOptions::createMemCpy(OpBuilder &b, Location loc, Value from, Value to) const { if (memCpyFn) return (*memCpyFn)(b, loc, from, to); b.create(loc, from, to); return success(); } //===----------------------------------------------------------------------===// // Bufferization-specific BlockAndValueMapping support with debugging. //===----------------------------------------------------------------------===// bool bufferization::isFunctionArgument(Value value) { auto bbArg = value.dyn_cast(); if (!bbArg) return false; return isa(bbArg.getOwner()->getParentOp()); } BaseMemRefType bufferization::getMemRefType(TensorType tensorType, const BufferizationOptions &options, MemRefLayoutAttrInterface layout, Attribute memorySpace) { // Case 1: Unranked memref type. if (auto unrankedTensorType = tensorType.dyn_cast()) { assert(!layout && "UnrankedTensorType cannot have a layout map"); return UnrankedMemRefType::get(unrankedTensorType.getElementType(), memorySpace); } // Case 2: Ranked memref type with specified layout. auto rankedTensorType = tensorType.cast(); if (layout) { return MemRefType::get(rankedTensorType.getShape(), rankedTensorType.getElementType(), layout, memorySpace); } // Case 3: Configured with "fully dynamic layout maps". if (options.unknownTypeConversion == BufferizationOptions::LayoutMapOption::FullyDynamicLayoutMap) return getMemRefTypeWithFullyDynamicLayout(tensorType, memorySpace); // Case 4: Configured with "static identity layout maps". if (options.unknownTypeConversion == BufferizationOptions::LayoutMapOption::IdentityLayoutMap) return getMemRefTypeWithStaticIdentityLayout(tensorType, memorySpace); llvm_unreachable("InferLayoutMap is an invalid option"); } BaseMemRefType bufferization::getMemRefTypeWithFullyDynamicLayout(TensorType tensorType, Attribute memorySpace) { // Case 1: Unranked memref type. if (auto unrankedTensorType = tensorType.dyn_cast()) { return UnrankedMemRefType::get(unrankedTensorType.getElementType(), memorySpace); } // Case 2: Ranked memref type. auto rankedTensorType = tensorType.cast(); int64_t dynamicOffset = ShapedType::kDynamicStrideOrOffset; SmallVector dynamicStrides(rankedTensorType.getRank(), ShapedType::kDynamicStrideOrOffset); AffineMap stridedLayout = makeStridedLinearLayoutMap( dynamicStrides, dynamicOffset, rankedTensorType.getContext()); return MemRefType::get(rankedTensorType.getShape(), rankedTensorType.getElementType(), stridedLayout, memorySpace); } /// Return a MemRef type with a static identity layout (i.e., no layout map). If /// the given tensor type is unranked, return an unranked MemRef type. BaseMemRefType bufferization::getMemRefTypeWithStaticIdentityLayout(TensorType tensorType, Attribute memorySpace) { // Case 1: Unranked memref type. if (auto unrankedTensorType = tensorType.dyn_cast()) { return UnrankedMemRefType::get(unrankedTensorType.getElementType(), memorySpace); } // Case 2: Ranked memref type. auto rankedTensorType = tensorType.cast(); MemRefLayoutAttrInterface layout = {}; return MemRefType::get(rankedTensorType.getShape(), rankedTensorType.getElementType(), layout, memorySpace); }