mlir/lib/Reducer/ReductionTreePass.cpp - llvm-project - Git at Google

 //===- ReductionTreePass.cpp - ReductionTreePass Implementation -----------===//
 //
 // 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 defines the Reduction Tree Pass class. It provides a framework for
 // the implementation of different reduction passes in the MLIR Reduce tool. It
 // allows for custom specification of the variant generation behavior. It
 // implements methods that define the different possible traversals of the
 // reduction tree.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/IR/DialectInterface.h"
 #include "mlir/IR/OpDefinition.h"
 #include "mlir/Reducer/PassDetail.h"
 #include "mlir/Reducer/Passes.h"
 #include "mlir/Reducer/ReductionNode.h"
 #include "mlir/Reducer/ReductionPatternInterface.h"
 #include "mlir/Reducer/Tester.h"
 #include "mlir/Rewrite/FrozenRewritePatternSet.h"
 #include "mlir/Transforms/GreedyPatternRewriteDriver.h"

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/Support/Allocator.h"
 #include "llvm/Support/ManagedStatic.h"

 using namespace mlir;

 /// We implicitly number each operation in the region and if an operation's
 /// number falls into rangeToKeep, we need to keep it and apply the given
 /// rewrite patterns on it.
 static void applyPatterns(Region &region,
                           const FrozenRewritePatternSet &patterns,
                           ArrayRef<ReductionNode::Range> rangeToKeep,
                           bool eraseOpNotInRange) {
   std::vector<Operation *> opsNotInRange;
   std::vector<Operation *> opsInRange;
   size_t keepIndex = 0;
   for (auto op : enumerate(region.getOps())) {
     int index = op.index();
     if (keepIndex < rangeToKeep.size() &&
         index == rangeToKeep[keepIndex].second)
       ++keepIndex;
     if (keepIndex == rangeToKeep.size() || index < rangeToKeep[keepIndex].first)
       opsNotInRange.push_back(&op.value());
     else
       opsInRange.push_back(&op.value());
   }

   // `applyOpPatternsAndFold` may erase the ops so we can't do the pattern
   // matching in above iteration. Besides, erase op not-in-range may end up in
   // invalid module, so `applyOpPatternsAndFold` should come before that
   // transform.
   for (Operation *op : opsInRange)
     // `applyOpPatternsAndFold` returns whether the op is convered. Omit it
     // because we don't have expectation this reduction will be success or not.
     (void)applyOpPatternsAndFold(op, patterns);

   if (eraseOpNotInRange)
     for (Operation *op : opsNotInRange) {
       op->dropAllUses();
       op->erase();
     }
 }

 /// We will apply the reducer patterns to the operations in the ranges specified
 /// by ReductionNode. Note that we are not able to remove an operation without
 /// replacing it with another valid operation. However, The validity of module
 /// reduction is based on the Tester provided by the user and that means certain
 /// invalid module is still interested by the use. Thus we provide an
 /// alternative way to remove operations, which is using `eraseOpNotInRange` to
 /// erase the operations not in the range specified by ReductionNode.
 template <typename IteratorType>
 static LogicalResult findOptimal(ModuleOp module, Region &region,
                                  const FrozenRewritePatternSet &patterns,
                                  const Tester &test, bool eraseOpNotInRange) {
   std::pair<Tester::Interestingness, size_t> initStatus =
       test.isInteresting(module);
   // While exploring the reduction tree, we always branch from an interesting
   // node. Thus the root node must be interesting.
   if (initStatus.first != Tester::Interestingness::True)
     return module.emitWarning() << "uninterested module will not be reduced";

   llvm::SpecificBumpPtrAllocator<ReductionNode> allocator;

   std::vector<ReductionNode::Range> ranges{
       {0, std::distance(region.op_begin(), region.op_end())}};

   ReductionNode *root = allocator.Allocate();
   new (root) ReductionNode(nullptr, std::move(ranges), allocator);
   // Duplicate the module for root node and locate the region in the copy.
   if (failed(root->initialize(module, region)))
     llvm_unreachable("unexpected initialization failure");
   root->update(initStatus);

   ReductionNode *smallestNode = root;
   IteratorType iter(root);

   while (iter != IteratorType::end()) {
     ReductionNode &currentNode = *iter;
     Region &curRegion = currentNode.getRegion();

     applyPatterns(curRegion, patterns, currentNode.getRanges(),
                   eraseOpNotInRange);
     currentNode.update(test.isInteresting(currentNode.getModule()));

     if (currentNode.isInteresting() == Tester::Interestingness::True &&
         currentNode.getSize() < smallestNode->getSize())
       smallestNode = &currentNode;

     ++iter;
   }

   // At here, we have found an optimal path to reduce the given region. Retrieve
   // the path and apply the reducer to it.
   SmallVector<ReductionNode *> trace;
   ReductionNode *curNode = smallestNode;
   trace.push_back(curNode);
   while (curNode != root) {
     curNode = curNode->getParent();
     trace.push_back(curNode);
   }

   // Reduce the region through the optimal path.
   while (!trace.empty()) {
     ReductionNode *top = trace.pop_back_val();
     applyPatterns(region, patterns, top->getStartRanges(), eraseOpNotInRange);
   }

   if (test.isInteresting(module).first != Tester::Interestingness::True)
     llvm::report_fatal_error("Reduced module is not interesting");
   if (test.isInteresting(module).second != smallestNode->getSize())
     llvm::report_fatal_error(
         "Reduced module doesn't have consistent size with smallestNode");
   return success();
 }

 template <typename IteratorType>
 static LogicalResult findOptimal(ModuleOp module, Region &region,
                                  const FrozenRewritePatternSet &patterns,
                                  const Tester &test) {
   // We separate the reduction process into 2 steps, the first one is to erase
   // redundant operations and the second one is to apply the reducer patterns.

   // In the first phase, we don't apply any patterns so that we only select the
   // range of operations to keep to the module stay interesting.
   if (failed(findOptimal<IteratorType>(module, region, /*patterns=*/{}, test,
                                        /*eraseOpNotInRange=*/true)))
     return failure();
   // In the second phase, we suppose that no operation is redundant, so we try
   // to rewrite the operation into simpler form.
   return findOptimal<IteratorType>(module, region, patterns, test,
                                    /*eraseOpNotInRange=*/false);
 }

 namespace {

 //===----------------------------------------------------------------------===//
 // Reduction Pattern Interface Collection
 //===----------------------------------------------------------------------===//

 class ReductionPatternInterfaceCollection
     : public DialectInterfaceCollection<DialectReductionPatternInterface> {
 public:
   using Base::Base;

   // Collect the reduce patterns defined by each dialect.
   void populateReductionPatterns(RewritePatternSet &pattern) const {
     for (const DialectReductionPatternInterface &interface : *this)
       interface.populateReductionPatterns(pattern);
   }
 };

 //===----------------------------------------------------------------------===//
 // ReductionTreePass
 //===----------------------------------------------------------------------===//

 /// This class defines the Reduction Tree Pass. It provides a framework to
 /// to implement a reduction pass using a tree structure to keep track of the
 /// generated reduced variants.
 class ReductionTreePass : public ReductionTreeBase<ReductionTreePass> {
 public:
   ReductionTreePass() = default;
   ReductionTreePass(const ReductionTreePass &pass) = default;

   LogicalResult initialize(MLIRContext *context) override;

   /// Runs the pass instance in the pass pipeline.
   void runOnOperation() override;

 private:
   LogicalResult reduceOp(ModuleOp module, Region &region);

   FrozenRewritePatternSet reducerPatterns;
 };

 } // end anonymous namespace

 LogicalResult ReductionTreePass::initialize(MLIRContext *context) {
   RewritePatternSet patterns(context);
   ReductionPatternInterfaceCollection reducePatternCollection(context);
   reducePatternCollection.populateReductionPatterns(patterns);
   reducerPatterns = std::move(patterns);
   return success();
 }

 void ReductionTreePass::runOnOperation() {
   Operation *topOperation = getOperation();
   while (topOperation->getParentOp() != nullptr)
     topOperation = topOperation->getParentOp();
   ModuleOp module = cast<ModuleOp>(topOperation);

   SmallVector<Operation *, 8> workList;
   workList.push_back(getOperation());

   do {
     Operation *op = workList.pop_back_val();

     for (Region &region : op->getRegions())
       if (!region.empty())
         if (failed(reduceOp(module, region)))
           return signalPassFailure();

     for (Region &region : op->getRegions())
       for (Operation &op : region.getOps())
         if (op.getNumRegions() != 0)
           workList.push_back(&op);
   } while (!workList.empty());
 }

 LogicalResult ReductionTreePass::reduceOp(ModuleOp module, Region &region) {
   Tester test(testerName, testerArgs);
   switch (traversalModeId) {
   case TraversalMode::SinglePath:
     return findOptimal<ReductionNode::iterator<TraversalMode::SinglePath>>(
         module, region, reducerPatterns, test);
   default:
     return module.emitError() << "unsupported traversal mode detected";
   }
 }

 std::unique_ptr<Pass> mlir::createReductionTreePass() {
   return std::make_unique<ReductionTreePass>();
 }
	//===- ReductionTreePass.cpp - ReductionTreePass Implementation -----------===//
	//
	// 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 defines the Reduction Tree Pass class. It provides a framework for
	// the implementation of different reduction passes in the MLIR Reduce tool. It
	// allows for custom specification of the variant generation behavior. It
	// implements methods that define the different possible traversals of the
	// reduction tree.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/IR/DialectInterface.h"
	#include "mlir/IR/OpDefinition.h"
	#include "mlir/Reducer/PassDetail.h"
	#include "mlir/Reducer/Passes.h"
	#include "mlir/Reducer/ReductionNode.h"
	#include "mlir/Reducer/ReductionPatternInterface.h"
	#include "mlir/Reducer/Tester.h"
	#include "mlir/Rewrite/FrozenRewritePatternSet.h"
	#include "mlir/Transforms/GreedyPatternRewriteDriver.h"

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/Support/Allocator.h"
	#include "llvm/Support/ManagedStatic.h"

	using namespace mlir;

	/// We implicitly number each operation in the region and if an operation's
	/// number falls into rangeToKeep, we need to keep it and apply the given
	/// rewrite patterns on it.
	static void applyPatterns(Region &region,
	const FrozenRewritePatternSet &patterns,
	ArrayRef<ReductionNode::Range> rangeToKeep,
	bool eraseOpNotInRange) {
	std::vector<Operation *> opsNotInRange;
	std::vector<Operation *> opsInRange;
	size_t keepIndex = 0;
	for (auto op : enumerate(region.getOps())) {
	int index = op.index();
	if (keepIndex < rangeToKeep.size() &&
	index == rangeToKeep[keepIndex].second)
	++keepIndex;
	if (keepIndex == rangeToKeep.size() \|\| index < rangeToKeep[keepIndex].first)
	opsNotInRange.push_back(&op.value());
	else
	opsInRange.push_back(&op.value());
	}

	// `applyOpPatternsAndFold` may erase the ops so we can't do the pattern
	// matching in above iteration. Besides, erase op not-in-range may end up in
	// invalid module, so `applyOpPatternsAndFold` should come before that
	// transform.
	for (Operation *op : opsInRange)
	// `applyOpPatternsAndFold` returns whether the op is convered. Omit it
	// because we don't have expectation this reduction will be success or not.
	(void)applyOpPatternsAndFold(op, patterns);

	if (eraseOpNotInRange)
	for (Operation *op : opsNotInRange) {
	op->dropAllUses();
	op->erase();
	}
	}

	/// We will apply the reducer patterns to the operations in the ranges specified
	/// by ReductionNode. Note that we are not able to remove an operation without
	/// replacing it with another valid operation. However, The validity of module
	/// reduction is based on the Tester provided by the user and that means certain
	/// invalid module is still interested by the use. Thus we provide an
	/// alternative way to remove operations, which is using `eraseOpNotInRange` to
	/// erase the operations not in the range specified by ReductionNode.
	template <typename IteratorType>
	static LogicalResult findOptimal(ModuleOp module, Region &region,
	const FrozenRewritePatternSet &patterns,
	const Tester &test, bool eraseOpNotInRange) {
	std::pair<Tester::Interestingness, size_t> initStatus =
	test.isInteresting(module);
	// While exploring the reduction tree, we always branch from an interesting
	// node. Thus the root node must be interesting.
	if (initStatus.first != Tester::Interestingness::True)
	return module.emitWarning() << "uninterested module will not be reduced";

	llvm::SpecificBumpPtrAllocator<ReductionNode> allocator;

	std::vector<ReductionNode::Range> ranges{
	{0, std::distance(region.op_begin(), region.op_end())}};

	ReductionNode *root = allocator.Allocate();
	new (root) ReductionNode(nullptr, std::move(ranges), allocator);
	// Duplicate the module for root node and locate the region in the copy.
	if (failed(root->initialize(module, region)))
	llvm_unreachable("unexpected initialization failure");
	root->update(initStatus);

	ReductionNode *smallestNode = root;
	IteratorType iter(root);

	while (iter != IteratorType::end()) {
	ReductionNode &currentNode = *iter;
	Region &curRegion = currentNode.getRegion();

	applyPatterns(curRegion, patterns, currentNode.getRanges(),
	eraseOpNotInRange);
	currentNode.update(test.isInteresting(currentNode.getModule()));

	if (currentNode.isInteresting() == Tester::Interestingness::True &&
	currentNode.getSize() < smallestNode->getSize())
	smallestNode = &currentNode;

	++iter;
	}

	// At here, we have found an optimal path to reduce the given region. Retrieve
	// the path and apply the reducer to it.
	SmallVector<ReductionNode *> trace;
	ReductionNode *curNode = smallestNode;
	trace.push_back(curNode);
	while (curNode != root) {
	curNode = curNode->getParent();
	trace.push_back(curNode);
	}

	// Reduce the region through the optimal path.
	while (!trace.empty()) {
	ReductionNode *top = trace.pop_back_val();
	applyPatterns(region, patterns, top->getStartRanges(), eraseOpNotInRange);
	}

	if (test.isInteresting(module).first != Tester::Interestingness::True)
	llvm::report_fatal_error("Reduced module is not interesting");
	if (test.isInteresting(module).second != smallestNode->getSize())
	llvm::report_fatal_error(
	"Reduced module doesn't have consistent size with smallestNode");
	return success();
	}

	template <typename IteratorType>
	static LogicalResult findOptimal(ModuleOp module, Region &region,
	const FrozenRewritePatternSet &patterns,
	const Tester &test) {
	// We separate the reduction process into 2 steps, the first one is to erase
	// redundant operations and the second one is to apply the reducer patterns.

	// In the first phase, we don't apply any patterns so that we only select the
	// range of operations to keep to the module stay interesting.
	if (failed(findOptimal<IteratorType>(module, region, /patterns=/{}, test,
	/eraseOpNotInRange=/true)))
	return failure();
	// In the second phase, we suppose that no operation is redundant, so we try
	// to rewrite the operation into simpler form.
	return findOptimal<IteratorType>(module, region, patterns, test,
	/eraseOpNotInRange=/false);
	}

	namespace {

	//===----------------------------------------------------------------------===//
	// Reduction Pattern Interface Collection
	//===----------------------------------------------------------------------===//

	class ReductionPatternInterfaceCollection
	: public DialectInterfaceCollection<DialectReductionPatternInterface> {
	public:
	using Base::Base;

	// Collect the reduce patterns defined by each dialect.
	void populateReductionPatterns(RewritePatternSet &pattern) const {
	for (const DialectReductionPatternInterface &interface : *this)
	interface.populateReductionPatterns(pattern);
	}
	};

	//===----------------------------------------------------------------------===//
	// ReductionTreePass
	//===----------------------------------------------------------------------===//

	/// This class defines the Reduction Tree Pass. It provides a framework to
	/// to implement a reduction pass using a tree structure to keep track of the
	/// generated reduced variants.
	class ReductionTreePass : public ReductionTreeBase<ReductionTreePass> {
	public:
	ReductionTreePass() = default;
	ReductionTreePass(const ReductionTreePass &pass) = default;

	LogicalResult initialize(MLIRContext *context) override;

	/// Runs the pass instance in the pass pipeline.
	void runOnOperation() override;

	private:
	LogicalResult reduceOp(ModuleOp module, Region &region);

	FrozenRewritePatternSet reducerPatterns;
	};

	} // end anonymous namespace

	LogicalResult ReductionTreePass::initialize(MLIRContext *context) {
	RewritePatternSet patterns(context);
	ReductionPatternInterfaceCollection reducePatternCollection(context);
	reducePatternCollection.populateReductionPatterns(patterns);
	reducerPatterns = std::move(patterns);
	return success();
	}

	void ReductionTreePass::runOnOperation() {
	Operation *topOperation = getOperation();
	while (topOperation->getParentOp() != nullptr)
	topOperation = topOperation->getParentOp();
	ModuleOp module = cast<ModuleOp>(topOperation);

	SmallVector<Operation *, 8> workList;
	workList.push_back(getOperation());

	do {
	Operation *op = workList.pop_back_val();

	for (Region &region : op->getRegions())
	if (!region.empty())
	if (failed(reduceOp(module, region)))
	return signalPassFailure();

	for (Region &region : op->getRegions())
	for (Operation &op : region.getOps())
	if (op.getNumRegions() != 0)
	workList.push_back(&op);
	} while (!workList.empty());
	}

	LogicalResult ReductionTreePass::reduceOp(ModuleOp module, Region &region) {
	Tester test(testerName, testerArgs);
	switch (traversalModeId) {
	case TraversalMode::SinglePath:
	return findOptimal<ReductionNode::iterator<TraversalMode::SinglePath>>(
	module, region, reducerPatterns, test);
	default:
	return module.emitError() << "unsupported traversal mode detected";
	}
	}

	std::unique_ptr<Pass> mlir::createReductionTreePass() {
	return std::make_unique<ReductionTreePass>();
	}