mlir/lib/IR/PatternMatch.cpp - llvm-project - Git at Google

 //===- 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"
 #include "mlir/IR/Operation.h"
 #include "mlir/IR/Value.h"

 using namespace mlir;

 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 implementation
 //===----------------------------------------------------------------------===//

 Pattern::Pattern(StringRef rootName, PatternBenefit benefit,
                  MLIRContext *context)
     : rootKind(OperationName(rootName, context)), benefit(benefit) {}
 Pattern::Pattern(PatternBenefit benefit, MatchAnyOpTypeTag)
     : benefit(benefit) {}

 // Out-of-line vtable anchor.
 void Pattern::anchor() {}

 //===----------------------------------------------------------------------===//
 // RewritePattern and PatternRewriter implementation
 //===----------------------------------------------------------------------===//

 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!");
 }

 RewritePattern::RewritePattern(StringRef rootName,
                                ArrayRef<StringRef> 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);
                  });
 }
 RewritePattern::RewritePattern(ArrayRef<StringRef> 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);
                  });
 }

 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();
 }

 /// 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 &region, Region &parent,
                                          Region::iterator before) {
   parent.getBlocks().splice(before, region.getBlocks());
 }
 void PatternRewriter::inlineRegionBefore(Region &region, 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 &region, Region &parent,
                                         Region::iterator before,
                                         BlockAndValueMapping &mapping) {
   region.cloneInto(&parent, before, mapping);
 }
 void PatternRewriter::cloneRegionBefore(Region &region, Region &parent,
                                         Region::iterator before) {
   BlockAndValueMapping mapping;
   cloneRegionBefore(region, parent, before, mapping);
 }
 void PatternRewriter::cloneRegionBefore(Region &region, Block *before) {
   cloneRegionBefore(region, *before->getParent(), before->getIterator());
 }

 //===----------------------------------------------------------------------===//
 // PatternMatcher implementation
 //===----------------------------------------------------------------------===//

 void PatternApplicator::applyCostModel(CostModel model) {
   // Separate patterns by root kind to simplify lookup later on.
   patterns.clear();
   anyOpPatterns.clear();
   for (const auto &pat : owningPatternList) {
     // If the pattern is always impossible to match, just ignore it.
     if (pat->getBenefit().isImpossibleToMatch())
       continue;
     if (Optional<OperationName> opName = pat->getRootKind())
       patterns[*opName].push_back(pat.get());
     else
       anyOpPatterns.push_back(pat.get());
   }

   // Sort the patterns using the provided cost model.
   llvm::SmallDenseMap<RewritePattern *, PatternBenefit> benefits;
   auto cmp = [&benefits](RewritePattern *lhs, RewritePattern *rhs) {
     return benefits[lhs] > benefits[rhs];
   };
   auto processPatternList = [&](SmallVectorImpl<RewritePattern *> &list) {
     // Special case for one pattern in the list, which is the most common case.
     if (list.size() == 1) {
       if (model(*list.front()).isImpossibleToMatch())
         list.clear();
       return;
     }

     // Collect the dynamic benefits for the current pattern list.
     benefits.clear();
     for (RewritePattern *pat : list)
       benefits.try_emplace(pat, model(*pat));

     // Sort patterns with highest benefit first, and remove those that are
     // impossible to match.
     std::stable_sort(list.begin(), list.end(), cmp);
     while (!list.empty() && benefits[list.back()].isImpossibleToMatch())
       list.pop_back();
   };
   for (auto &it : patterns)
     processPatternList(it.second);
   processPatternList(anyOpPatterns);
 }

 void PatternApplicator::walkAllPatterns(
     function_ref<void(const RewritePattern &)> walk) {
   for (auto &it : owningPatternList)
     walk(*it);
 }

 LogicalResult PatternApplicator::matchAndRewrite(
     Operation *op, PatternRewriter &rewriter,
     function_ref<bool(const RewritePattern &)> canApply,
     function_ref<void(const RewritePattern &)> onFailure,
     function_ref<LogicalResult(const RewritePattern &)> onSuccess) {
   // Check to see if there are patterns matching this specific operation type.
   MutableArrayRef<RewritePattern *> opPatterns;
   auto patternIt = patterns.find(op->getName());
   if (patternIt != patterns.end())
     opPatterns = patternIt->second;

   // Process the patterns for that match the specific operation type, and any
   // operation type in an interleaved fashion.
   // FIXME: It'd be nice to just write an llvm::make_merge_range utility
   // and pass in a comparison function. That would make this code trivial.
   auto opIt = opPatterns.begin(), opE = opPatterns.end();
   auto anyIt = anyOpPatterns.begin(), anyE = anyOpPatterns.end();
   while (opIt != opE && anyIt != anyE) {
     // Try to match the pattern providing the most benefit.
     RewritePattern *pattern;
     if ((*opIt)->getBenefit() >= (*anyIt)->getBenefit())
       pattern = *(opIt++);
     else
       pattern = *(anyIt++);

     // Otherwise, try to match the generic pattern.
     if (succeeded(matchAndRewrite(op, *pattern, rewriter, canApply, onFailure,
                                   onSuccess)))
       return success();
   }
   // If we break from the loop, then only one of the ranges can still have
   // elements. Loop over both without checking given that we don't need to
   // interleave anymore.
   for (RewritePattern *pattern : llvm::concat<RewritePattern *>(
            llvm::make_range(opIt, opE), llvm::make_range(anyIt, anyE))) {
     if (succeeded(matchAndRewrite(op, *pattern, rewriter, canApply, onFailure,
                                   onSuccess)))
       return success();
   }
   return failure();
 }

 LogicalResult PatternApplicator::matchAndRewrite(
     Operation *op, const RewritePattern &pattern, PatternRewriter &rewriter,
     function_ref<bool(const RewritePattern &)> canApply,
     function_ref<void(const RewritePattern &)> onFailure,
     function_ref<LogicalResult(const RewritePattern &)> onSuccess) {
   // Check that the pattern can be applied.
   if (canApply && !canApply(pattern))
     return failure();

   // Try to match and rewrite this pattern. The patterns are sorted by
   // benefit, so if we match we can immediately rewrite.
   rewriter.setInsertionPoint(op);
   if (succeeded(pattern.matchAndRewrite(op, rewriter)))
     return success(!onSuccess || succeeded(onSuccess(pattern)));

   if (onFailure)
     onFailure(pattern);
   return failure();
 }
	//===- 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"
	#include "mlir/IR/Operation.h"
	#include "mlir/IR/Value.h"

	using namespace mlir;

	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 implementation
	//===----------------------------------------------------------------------===//

	Pattern::Pattern(StringRef rootName, PatternBenefit benefit,
	MLIRContext *context)
	: rootKind(OperationName(rootName, context)), benefit(benefit) {}
	Pattern::Pattern(PatternBenefit benefit, MatchAnyOpTypeTag)
	: benefit(benefit) {}

	// Out-of-line vtable anchor.
	void Pattern::anchor() {}

	//===----------------------------------------------------------------------===//
	// RewritePattern and PatternRewriter implementation
	//===----------------------------------------------------------------------===//

	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!");
	}

	RewritePattern::RewritePattern(StringRef rootName,
	ArrayRef<StringRef> 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);
	});
	}
	RewritePattern::RewritePattern(ArrayRef<StringRef> 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);
	});
	}

	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();
	}

	/// 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 &region, Region &parent,
	Region::iterator before) {
	parent.getBlocks().splice(before, region.getBlocks());
	}
	void PatternRewriter::inlineRegionBefore(Region &region, 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 &region, Region &parent,
	Region::iterator before,
	BlockAndValueMapping &mapping) {
	region.cloneInto(&parent, before, mapping);
	}
	void PatternRewriter::cloneRegionBefore(Region &region, Region &parent,
	Region::iterator before) {
	BlockAndValueMapping mapping;
	cloneRegionBefore(region, parent, before, mapping);
	}
	void PatternRewriter::cloneRegionBefore(Region &region, Block *before) {
	cloneRegionBefore(region, *before->getParent(), before->getIterator());
	}

	//===----------------------------------------------------------------------===//
	// PatternMatcher implementation
	//===----------------------------------------------------------------------===//

	void PatternApplicator::applyCostModel(CostModel model) {
	// Separate patterns by root kind to simplify lookup later on.
	patterns.clear();
	anyOpPatterns.clear();
	for (const auto &pat : owningPatternList) {
	// If the pattern is always impossible to match, just ignore it.
	if (pat->getBenefit().isImpossibleToMatch())
	continue;
	if (Optional<OperationName> opName = pat->getRootKind())
	patterns[*opName].push_back(pat.get());
	else
	anyOpPatterns.push_back(pat.get());
	}

	// Sort the patterns using the provided cost model.
	llvm::SmallDenseMap<RewritePattern *, PatternBenefit> benefits;
	auto cmp = [&benefits](RewritePattern lhs, RewritePattern rhs) {
	return benefits[lhs] > benefits[rhs];
	};
	auto processPatternList = [&](SmallVectorImpl<RewritePattern *> &list) {
	// Special case for one pattern in the list, which is the most common case.
	if (list.size() == 1) {
	if (model(*list.front()).isImpossibleToMatch())
	list.clear();
	return;
	}

	// Collect the dynamic benefits for the current pattern list.
	benefits.clear();
	for (RewritePattern *pat : list)
	benefits.try_emplace(pat, model(*pat));

	// Sort patterns with highest benefit first, and remove those that are
	// impossible to match.
	std::stable_sort(list.begin(), list.end(), cmp);
	while (!list.empty() && benefits[list.back()].isImpossibleToMatch())
	list.pop_back();
	};
	for (auto &it : patterns)
	processPatternList(it.second);
	processPatternList(anyOpPatterns);
	}

	void PatternApplicator::walkAllPatterns(
	function_ref<void(const RewritePattern &)> walk) {
	for (auto &it : owningPatternList)
	walk(*it);
	}

	LogicalResult PatternApplicator::matchAndRewrite(
	Operation *op, PatternRewriter &rewriter,
	function_ref<bool(const RewritePattern &)> canApply,
	function_ref<void(const RewritePattern &)> onFailure,
	function_ref<LogicalResult(const RewritePattern &)> onSuccess) {
	// Check to see if there are patterns matching this specific operation type.
	MutableArrayRef<RewritePattern *> opPatterns;
	auto patternIt = patterns.find(op->getName());
	if (patternIt != patterns.end())
	opPatterns = patternIt->second;

	// Process the patterns for that match the specific operation type, and any
	// operation type in an interleaved fashion.
	// FIXME: It'd be nice to just write an llvm::make_merge_range utility
	// and pass in a comparison function. That would make this code trivial.
	auto opIt = opPatterns.begin(), opE = opPatterns.end();
	auto anyIt = anyOpPatterns.begin(), anyE = anyOpPatterns.end();
	while (opIt != opE && anyIt != anyE) {
	// Try to match the pattern providing the most benefit.
	RewritePattern *pattern;
	if ((opIt)->getBenefit() >= (anyIt)->getBenefit())
	pattern = *(opIt++);
	else
	pattern = *(anyIt++);

	// Otherwise, try to match the generic pattern.
	if (succeeded(matchAndRewrite(op, *pattern, rewriter, canApply, onFailure,
	onSuccess)))
	return success();
	}
	// If we break from the loop, then only one of the ranges can still have
	// elements. Loop over both without checking given that we don't need to
	// interleave anymore.
	for (RewritePattern pattern : llvm::concat<RewritePattern >(
	llvm::make_range(opIt, opE), llvm::make_range(anyIt, anyE))) {
	if (succeeded(matchAndRewrite(op, *pattern, rewriter, canApply, onFailure,
	onSuccess)))
	return success();
	}
	return failure();
	}

	LogicalResult PatternApplicator::matchAndRewrite(
	Operation *op, const RewritePattern &pattern, PatternRewriter &rewriter,
	function_ref<bool(const RewritePattern &)> canApply,
	function_ref<void(const RewritePattern &)> onFailure,
	function_ref<LogicalResult(const RewritePattern &)> onSuccess) {
	// Check that the pattern can be applied.
	if (canApply && !canApply(pattern))
	return failure();

	// Try to match and rewrite this pattern. The patterns are sorted by
	// benefit, so if we match we can immediately rewrite.
	rewriter.setInsertionPoint(op);
	if (succeeded(pattern.matchAndRewrite(op, rewriter)))
	return success(!onSuccess \|\| succeeded(onSuccess(pattern)));

	if (onFailure)
	onFailure(pattern);
	return failure();
	}