mlir/lib/Rewrite/PatternApplicator.cpp - llvm-project - Git at Google

 //===- PatternApplicator.cpp - Pattern Application Engine -------*- C++ -*-===//
 //
 // 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 implements an applicator that applies pattern rewrites based upon a
 // user defined cost model.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Rewrite/PatternApplicator.h"
 #include "ByteCode.h"
 #include "llvm/Support/Debug.h"

 #define DEBUG_TYPE "pattern-application"

 using namespace mlir;
 using namespace mlir::detail;

 PatternApplicator::PatternApplicator(
     const FrozenRewritePatternSet &frozenPatternList)
     : frozenPatternList(frozenPatternList) {
   if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
     mutableByteCodeState = std::make_unique<PDLByteCodeMutableState>();
     bytecode->initializeMutableState(*mutableByteCodeState);
   }
 }
 PatternApplicator::~PatternApplicator() {}

 #ifndef NDEBUG
 /// Log a message for a pattern that is impossible to match.
 static void logImpossibleToMatch(const Pattern &pattern) {
     llvm::dbgs() << "Ignoring pattern '" << pattern.getRootKind()
                  << "' because it is impossible to match or cannot lead "
                     "to legal IR (by cost model)\n";
 }

 /// Log IR after pattern application.
 static Operation *getDumpRootOp(Operation *op) {
   return op->getParentWithTrait<mlir::OpTrait::IsIsolatedFromAbove>();
 }
 static void logSucessfulPatternApplication(Operation *op) {
   llvm::dbgs() << "// *** IR Dump After Pattern Application ***\n";
   op->dump();
   llvm::dbgs() << "\n\n";
 }
 #endif

 void PatternApplicator::applyCostModel(CostModel model) {
   // Apply the cost model to the bytecode patterns first, and then the native
   // patterns.
   if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
     for (auto it : llvm::enumerate(bytecode->getPatterns()))
       mutableByteCodeState->updatePatternBenefit(it.index(), model(it.value()));
   }

   // Copy over the patterns so that we can sort by benefit based on the cost
   // model. Patterns that are already impossible to match are ignored.
   patterns.clear();
   for (const auto &it : frozenPatternList.getOpSpecificNativePatterns()) {
     for (const RewritePattern *pattern : it.second) {
       if (pattern->getBenefit().isImpossibleToMatch())
         LLVM_DEBUG(logImpossibleToMatch(*pattern));
       else
         patterns[it.first].push_back(pattern);
     }
   }
   anyOpPatterns.clear();
   for (const RewritePattern &pattern :
        frozenPatternList.getMatchAnyOpNativePatterns()) {
     if (pattern.getBenefit().isImpossibleToMatch())
       LLVM_DEBUG(logImpossibleToMatch(pattern));
     else
       anyOpPatterns.push_back(&pattern);
   }

   // Sort the patterns using the provided cost model.
   llvm::SmallDenseMap<const Pattern *, PatternBenefit> benefits;
   auto cmp = [&benefits](const Pattern *lhs, const Pattern *rhs) {
     return benefits[lhs] > benefits[rhs];
   };
   auto processPatternList = [&](SmallVectorImpl<const 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()) {
         LLVM_DEBUG(logImpossibleToMatch(*list.front()));
         list.clear();
       }
       return;
     }

     // Collect the dynamic benefits for the current pattern list.
     benefits.clear();
     for (const Pattern *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()) {
       LLVM_DEBUG(logImpossibleToMatch(*list.back()));
       list.pop_back();
     }
   };
   for (auto &it : patterns)
     processPatternList(it.second);
   processPatternList(anyOpPatterns);
 }

 void PatternApplicator::walkAllPatterns(
     function_ref<void(const Pattern &)> walk) {
   for (const auto &it : frozenPatternList.getOpSpecificNativePatterns())
     for (const auto &pattern : it.second)
       walk(*pattern);
   for (const Pattern &it : frozenPatternList.getMatchAnyOpNativePatterns())
     walk(it);
   if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
     for (const Pattern &it : bytecode->getPatterns())
       walk(it);
   }
 }

 LogicalResult PatternApplicator::matchAndRewrite(
     Operation *op, PatternRewriter &rewriter,
     function_ref<bool(const Pattern &)> canApply,
     function_ref<void(const Pattern &)> onFailure,
     function_ref<LogicalResult(const Pattern &)> onSuccess) {
   // Before checking native patterns, first match against the bytecode. This
   // won't automatically perform any rewrites so there is no need to worry about
   // conflicts.
   SmallVector<PDLByteCode::MatchResult, 4> pdlMatches;
   const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode();
   if (bytecode)
     bytecode->match(op, rewriter, pdlMatches, *mutableByteCodeState);

   // Check to see if there are patterns matching this specific operation type.
   MutableArrayRef<const 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.
   unsigned opIt = 0, opE = opPatterns.size();
   unsigned anyIt = 0, anyE = anyOpPatterns.size();
   unsigned pdlIt = 0, pdlE = pdlMatches.size();
   LogicalResult result = failure();
   do {
     // Find the next pattern with the highest benefit.
     const Pattern *bestPattern = nullptr;
     unsigned *bestPatternIt = &opIt;
     const PDLByteCode::MatchResult *pdlMatch = nullptr;

     /// Operation specific patterns.
     if (opIt < opE)
       bestPattern = opPatterns[opIt];
     /// Operation agnostic patterns.
     if (anyIt < anyE &&
         (!bestPattern ||
          bestPattern->getBenefit() < anyOpPatterns[anyIt]->getBenefit())) {
       bestPatternIt = &anyIt;
       bestPattern = anyOpPatterns[anyIt];
     }
     /// PDL patterns.
     if (pdlIt < pdlE && (!bestPattern || bestPattern->getBenefit() <
                                              pdlMatches[pdlIt].benefit)) {
       bestPatternIt = &pdlIt;
       pdlMatch = &pdlMatches[pdlIt];
       bestPattern = pdlMatch->pattern;
     }
     if (!bestPattern)
       break;

     // Update the pattern iterator on failure so that this pattern isn't
     // attempted again.
     ++(*bestPatternIt);

     // Check that the pattern can be applied.
     if (canApply && !canApply(*bestPattern))
       continue;

     // Try to match and rewrite this pattern. The patterns are sorted by
     // benefit, so if we match we can immediately rewrite. For PDL patterns, the
     // match has already been performed, we just need to rewrite.
     rewriter.setInsertionPoint(op);
 #ifndef NDEBUG
     // Operation `op` may be invalidated after applying the rewrite pattern.
     Operation *dumpRootOp = getDumpRootOp(op);
 #endif
     if (pdlMatch) {
       bytecode->rewrite(rewriter, *pdlMatch, *mutableByteCodeState);
       result = success(!onSuccess || succeeded(onSuccess(*bestPattern)));
     } else {
       const auto *pattern = static_cast<const RewritePattern *>(bestPattern);

       LLVM_DEBUG(llvm::dbgs()
                  << "Trying to match \"" << pattern->getDebugName() << "\"\n");
       result = pattern->matchAndRewrite(op, rewriter);
       LLVM_DEBUG(llvm::dbgs() << "\"" << pattern->getDebugName() << "\" result "
                               << succeeded(result) << "\n");

       if (succeeded(result) && onSuccess && failed(onSuccess(*pattern)))
         result = failure();
     }
     if (succeeded(result)) {
       LLVM_DEBUG(logSucessfulPatternApplication(dumpRootOp));
       break;
     }

     // Perform any necessary cleanups.
     if (onFailure)
       onFailure(*bestPattern);
   } while (true);

   if (mutableByteCodeState)
     mutableByteCodeState->cleanupAfterMatchAndRewrite();
   return result;
 }
	//===- PatternApplicator.cpp - Pattern Application Engine -------- C++ --===//
	//
	// 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 implements an applicator that applies pattern rewrites based upon a
	// user defined cost model.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Rewrite/PatternApplicator.h"
	#include "ByteCode.h"
	#include "llvm/Support/Debug.h"

	#define DEBUG_TYPE "pattern-application"

	using namespace mlir;
	using namespace mlir::detail;

	PatternApplicator::PatternApplicator(
	const FrozenRewritePatternSet &frozenPatternList)
	: frozenPatternList(frozenPatternList) {
	if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
	mutableByteCodeState = std::make_unique<PDLByteCodeMutableState>();
	bytecode->initializeMutableState(*mutableByteCodeState);
	}
	}
	PatternApplicator::~PatternApplicator() {}

	#ifndef NDEBUG
	/// Log a message for a pattern that is impossible to match.
	static void logImpossibleToMatch(const Pattern &pattern) {
	llvm::dbgs() << "Ignoring pattern '" << pattern.getRootKind()
	<< "' because it is impossible to match or cannot lead "
	"to legal IR (by cost model)\n";
	}

	/// Log IR after pattern application.
	static Operation getDumpRootOp(Operation op) {
	return op->getParentWithTrait<mlir::OpTrait::IsIsolatedFromAbove>();
	}
	static void logSucessfulPatternApplication(Operation *op) {
	llvm::dbgs() << "// * IR Dump After Pattern Application *\n";
	op->dump();
	llvm::dbgs() << "\n\n";
	}
	#endif

	void PatternApplicator::applyCostModel(CostModel model) {
	// Apply the cost model to the bytecode patterns first, and then the native
	// patterns.
	if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
	for (auto it : llvm::enumerate(bytecode->getPatterns()))
	mutableByteCodeState->updatePatternBenefit(it.index(), model(it.value()));
	}

	// Copy over the patterns so that we can sort by benefit based on the cost
	// model. Patterns that are already impossible to match are ignored.
	patterns.clear();
	for (const auto &it : frozenPatternList.getOpSpecificNativePatterns()) {
	for (const RewritePattern *pattern : it.second) {
	if (pattern->getBenefit().isImpossibleToMatch())
	LLVM_DEBUG(logImpossibleToMatch(*pattern));
	else
	patterns[it.first].push_back(pattern);
	}
	}
	anyOpPatterns.clear();
	for (const RewritePattern &pattern :
	frozenPatternList.getMatchAnyOpNativePatterns()) {
	if (pattern.getBenefit().isImpossibleToMatch())
	LLVM_DEBUG(logImpossibleToMatch(pattern));
	else
	anyOpPatterns.push_back(&pattern);
	}

	// Sort the patterns using the provided cost model.
	llvm::SmallDenseMap<const Pattern *, PatternBenefit> benefits;
	auto cmp = [&benefits](const Pattern lhs, const Pattern rhs) {
	return benefits[lhs] > benefits[rhs];
	};
	auto processPatternList = [&](SmallVectorImpl<const 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()) {
	LLVM_DEBUG(logImpossibleToMatch(*list.front()));
	list.clear();
	}
	return;
	}

	// Collect the dynamic benefits for the current pattern list.
	benefits.clear();
	for (const Pattern *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()) {
	LLVM_DEBUG(logImpossibleToMatch(*list.back()));
	list.pop_back();
	}
	};
	for (auto &it : patterns)
	processPatternList(it.second);
	processPatternList(anyOpPatterns);
	}

	void PatternApplicator::walkAllPatterns(
	function_ref<void(const Pattern &)> walk) {
	for (const auto &it : frozenPatternList.getOpSpecificNativePatterns())
	for (const auto &pattern : it.second)
	walk(*pattern);
	for (const Pattern &it : frozenPatternList.getMatchAnyOpNativePatterns())
	walk(it);
	if (const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode()) {
	for (const Pattern &it : bytecode->getPatterns())
	walk(it);
	}
	}

	LogicalResult PatternApplicator::matchAndRewrite(
	Operation *op, PatternRewriter &rewriter,
	function_ref<bool(const Pattern &)> canApply,
	function_ref<void(const Pattern &)> onFailure,
	function_ref<LogicalResult(const Pattern &)> onSuccess) {
	// Before checking native patterns, first match against the bytecode. This
	// won't automatically perform any rewrites so there is no need to worry about
	// conflicts.
	SmallVector<PDLByteCode::MatchResult, 4> pdlMatches;
	const PDLByteCode *bytecode = frozenPatternList.getPDLByteCode();
	if (bytecode)
	bytecode->match(op, rewriter, pdlMatches, *mutableByteCodeState);

	// Check to see if there are patterns matching this specific operation type.
	MutableArrayRef<const 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.
	unsigned opIt = 0, opE = opPatterns.size();
	unsigned anyIt = 0, anyE = anyOpPatterns.size();
	unsigned pdlIt = 0, pdlE = pdlMatches.size();
	LogicalResult result = failure();
	do {
	// Find the next pattern with the highest benefit.
	const Pattern *bestPattern = nullptr;
	unsigned *bestPatternIt = &opIt;
	const PDLByteCode::MatchResult *pdlMatch = nullptr;

	/// Operation specific patterns.
	if (opIt < opE)
	bestPattern = opPatterns[opIt];
	/// Operation agnostic patterns.
	if (anyIt < anyE &&
	(!bestPattern \|\|
	bestPattern->getBenefit() < anyOpPatterns[anyIt]->getBenefit())) {
	bestPatternIt = &anyIt;
	bestPattern = anyOpPatterns[anyIt];
	}
	/// PDL patterns.
	if (pdlIt < pdlE && (!bestPattern \|\| bestPattern->getBenefit() <
	pdlMatches[pdlIt].benefit)) {
	bestPatternIt = &pdlIt;
	pdlMatch = &pdlMatches[pdlIt];
	bestPattern = pdlMatch->pattern;
	}
	if (!bestPattern)
	break;

	// Update the pattern iterator on failure so that this pattern isn't
	// attempted again.
	++(*bestPatternIt);

	// Check that the pattern can be applied.
	if (canApply && !canApply(*bestPattern))
	continue;

	// Try to match and rewrite this pattern. The patterns are sorted by
	// benefit, so if we match we can immediately rewrite. For PDL patterns, the
	// match has already been performed, we just need to rewrite.
	rewriter.setInsertionPoint(op);
	#ifndef NDEBUG
	// Operation `op` may be invalidated after applying the rewrite pattern.
	Operation *dumpRootOp = getDumpRootOp(op);
	#endif
	if (pdlMatch) {
	bytecode->rewrite(rewriter, pdlMatch, mutableByteCodeState);
	result = success(!onSuccess \|\| succeeded(onSuccess(*bestPattern)));
	} else {
	const auto pattern = static_cast<const RewritePattern >(bestPattern);

	LLVM_DEBUG(llvm::dbgs()
	<< "Trying to match \"" << pattern->getDebugName() << "\"\n");
	result = pattern->matchAndRewrite(op, rewriter);
	LLVM_DEBUG(llvm::dbgs() << "\"" << pattern->getDebugName() << "\" result "
	<< succeeded(result) << "\n");

	if (succeeded(result) && onSuccess && failed(onSuccess(*pattern)))
	result = failure();
	}
	if (succeeded(result)) {
	LLVM_DEBUG(logSucessfulPatternApplication(dumpRootOp));
	break;
	}

	// Perform any necessary cleanups.
	if (onFailure)
	onFailure(*bestPattern);
	} while (true);

	if (mutableByteCodeState)
	mutableByteCodeState->cleanupAfterMatchAndRewrite();
	return result;
	}