//===- PatternMatch.cpp - Base classes for pattern match ------------------===// // // 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/IR/PatternMatch.h" #include "mlir/IR/BlockAndValueMapping.h" using namespace mlir; //===----------------------------------------------------------------------===// // PatternBenefit //===----------------------------------------------------------------------===// PatternBenefit::PatternBenefit(unsigned benefit) : representation(benefit) { assert(representation == benefit && benefit != ImpossibleToMatchSentinel && "This pattern match benefit is too large to represent"); } unsigned short PatternBenefit::getBenefit() const { assert(!isImpossibleToMatch() && "Pattern doesn't match"); return representation; } //===----------------------------------------------------------------------===// // Pattern //===----------------------------------------------------------------------===// Pattern::Pattern(StringRef rootName, PatternBenefit benefit, MLIRContext *context) : rootKind(OperationName(rootName, context)), benefit(benefit) {} Pattern::Pattern(PatternBenefit benefit, MatchAnyOpTypeTag tag) : benefit(benefit) {} Pattern::Pattern(StringRef rootName, ArrayRef generatedNames, PatternBenefit benefit, MLIRContext *context) : Pattern(rootName, benefit, context) { generatedOps.reserve(generatedNames.size()); std::transform(generatedNames.begin(), generatedNames.end(), std::back_inserter(generatedOps), [context](StringRef name) { return OperationName(name, context); }); } Pattern::Pattern(ArrayRef generatedNames, PatternBenefit benefit, MLIRContext *context, MatchAnyOpTypeTag tag) : Pattern(benefit, tag) { generatedOps.reserve(generatedNames.size()); std::transform(generatedNames.begin(), generatedNames.end(), std::back_inserter(generatedOps), [context](StringRef name) { return OperationName(name, context); }); } //===----------------------------------------------------------------------===// // RewritePattern //===----------------------------------------------------------------------===// void RewritePattern::rewrite(Operation *op, PatternRewriter &rewriter) const { llvm_unreachable("need to implement either matchAndRewrite or one of the " "rewrite functions!"); } LogicalResult RewritePattern::match(Operation *op) const { llvm_unreachable("need to implement either match or matchAndRewrite!"); } /// Out-of-line vtable anchor. void RewritePattern::anchor() {} //===----------------------------------------------------------------------===// // PDLValue //===----------------------------------------------------------------------===// void PDLValue::print(raw_ostream &os) { if (!impl) { os << ""; return; } if (Value val = impl.dyn_cast()) { os << val; return; } AttrOpTypeImplT aotImpl = impl.get(); if (Attribute attr = aotImpl.dyn_cast()) os << attr; else if (Operation *op = aotImpl.dyn_cast()) os << *op; else os << aotImpl.get(); } //===----------------------------------------------------------------------===// // PDLPatternModule //===----------------------------------------------------------------------===// void PDLPatternModule::mergeIn(PDLPatternModule &&other) { // Ignore the other module if it has no patterns. if (!other.pdlModule) return; // Steal the other state if we have no patterns. if (!pdlModule) { constraintFunctions = std::move(other.constraintFunctions); createFunctions = std::move(other.createFunctions); rewriteFunctions = std::move(other.rewriteFunctions); pdlModule = std::move(other.pdlModule); return; } // Steal the functions of the other module. for (auto &it : constraintFunctions) registerConstraintFunction(it.first(), std::move(it.second)); for (auto &it : createFunctions) registerCreateFunction(it.first(), std::move(it.second)); for (auto &it : rewriteFunctions) registerRewriteFunction(it.first(), std::move(it.second)); // Merge the pattern operations from the other module into this one. Block *block = pdlModule->getBody(); block->getTerminator()->erase(); block->getOperations().splice(block->end(), other.pdlModule->getBody()->getOperations()); } //===----------------------------------------------------------------------===// // Function Registry void PDLPatternModule::registerConstraintFunction( StringRef name, PDLConstraintFunction constraintFn) { auto it = constraintFunctions.try_emplace(name, std::move(constraintFn)); (void)it; assert(it.second && "constraint with the given name has already been registered"); } void PDLPatternModule::registerCreateFunction(StringRef name, PDLCreateFunction createFn) { auto it = createFunctions.try_emplace(name, std::move(createFn)); (void)it; assert(it.second && "native create function with the given name has " "already been registered"); } void PDLPatternModule::registerRewriteFunction(StringRef name, PDLRewriteFunction rewriteFn) { auto it = rewriteFunctions.try_emplace(name, std::move(rewriteFn)); (void)it; assert(it.second && "native rewrite function with the given name has " "already been registered"); } //===----------------------------------------------------------------------===// // PatternRewriter //===----------------------------------------------------------------------===// PatternRewriter::~PatternRewriter() { // Out of line to provide a vtable anchor for the class. } /// This method performs the final replacement for a pattern, where the /// results of the operation are updated to use the specified list of SSA /// values. void PatternRewriter::replaceOp(Operation *op, ValueRange newValues) { // Notify the rewriter subclass that we're about to replace this root. notifyRootReplaced(op); assert(op->getNumResults() == newValues.size() && "incorrect # of replacement values"); op->replaceAllUsesWith(newValues); notifyOperationRemoved(op); op->erase(); } /// This method erases an operation that is known to have no uses. The uses of /// the given operation *must* be known to be dead. void PatternRewriter::eraseOp(Operation *op) { assert(op->use_empty() && "expected 'op' to have no uses"); notifyOperationRemoved(op); op->erase(); } void PatternRewriter::eraseBlock(Block *block) { for (auto &op : llvm::make_early_inc_range(llvm::reverse(*block))) { assert(op.use_empty() && "expected 'op' to have no uses"); eraseOp(&op); } block->erase(); } /// Merge the operations of block 'source' into the end of block 'dest'. /// 'source's predecessors must be empty or only contain 'dest`. /// 'argValues' is used to replace the block arguments of 'source' after /// merging. void PatternRewriter::mergeBlocks(Block *source, Block *dest, ValueRange argValues) { assert(llvm::all_of(source->getPredecessors(), [dest](Block *succ) { return succ == dest; }) && "expected 'source' to have no predecessors or only 'dest'"); assert(argValues.size() == source->getNumArguments() && "incorrect # of argument replacement values"); // Replace all of the successor arguments with the provided values. for (auto it : llvm::zip(source->getArguments(), argValues)) std::get<0>(it).replaceAllUsesWith(std::get<1>(it)); // Splice the operations of the 'source' block into the 'dest' block and erase // it. dest->getOperations().splice(dest->end(), source->getOperations()); source->dropAllUses(); source->erase(); } // Merge the operations of block 'source' before the operation 'op'. Source // block should not have existing predecessors or successors. void PatternRewriter::mergeBlockBefore(Block *source, Operation *op, ValueRange argValues) { assert(source->hasNoPredecessors() && "expected 'source' to have no predecessors"); assert(source->hasNoSuccessors() && "expected 'source' to have no successors"); // Split the block containing 'op' into two, one containing all operations // before 'op' (prologue) and another (epilogue) containing 'op' and all // operations after it. Block *prologue = op->getBlock(); Block *epilogue = splitBlock(prologue, op->getIterator()); // Merge the source block at the end of the prologue. mergeBlocks(source, prologue, argValues); // Merge the epilogue at the end the prologue. mergeBlocks(epilogue, prologue); } /// Split the operations starting at "before" (inclusive) out of the given /// block into a new block, and return it. Block *PatternRewriter::splitBlock(Block *block, Block::iterator before) { return block->splitBlock(before); } /// 'op' and 'newOp' are known to have the same number of results, replace the /// uses of op with uses of newOp void PatternRewriter::replaceOpWithResultsOfAnotherOp(Operation *op, Operation *newOp) { assert(op->getNumResults() == newOp->getNumResults() && "replacement op doesn't match results of original op"); if (op->getNumResults() == 1) return replaceOp(op, newOp->getResult(0)); return replaceOp(op, newOp->getResults()); } /// Move the blocks that belong to "region" before the given position in /// another region. The two regions must be different. The caller is in /// charge to update create the operation transferring the control flow to the /// region and pass it the correct block arguments. void PatternRewriter::inlineRegionBefore(Region ®ion, Region &parent, Region::iterator before) { parent.getBlocks().splice(before, region.getBlocks()); } void PatternRewriter::inlineRegionBefore(Region ®ion, Block *before) { inlineRegionBefore(region, *before->getParent(), before->getIterator()); } /// Clone the blocks that belong to "region" before the given position in /// another region "parent". The two regions must be different. The caller is /// responsible for creating or updating the operation transferring flow of /// control to the region and passing it the correct block arguments. void PatternRewriter::cloneRegionBefore(Region ®ion, Region &parent, Region::iterator before, BlockAndValueMapping &mapping) { region.cloneInto(&parent, before, mapping); } void PatternRewriter::cloneRegionBefore(Region ®ion, Region &parent, Region::iterator before) { BlockAndValueMapping mapping; cloneRegionBefore(region, parent, before, mapping); } void PatternRewriter::cloneRegionBefore(Region ®ion, Block *before) { cloneRegionBefore(region, *before->getParent(), before->getIterator()); }