mlir/lib/Transforms/Utils/FoldUtils.cpp - llvm-project - Git at Google

 //===- FoldUtils.cpp ---- Fold Utilities ----------------------------------===//
 //
 // 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 various operation fold utilities. These utilities are
 // intended to be used by passes to unify and simply their logic.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Transforms/FoldUtils.h"

 #include "mlir/IR/Builders.h"
 #include "mlir/IR/Matchers.h"
 #include "mlir/IR/Operation.h"

 using namespace mlir;

 /// Given an operation, find the parent region that folded constants should be
 /// inserted into.
 static Region *
 getInsertionRegion(DialectInterfaceCollection<DialectFoldInterface> &interfaces,
                    Block *insertionBlock) {
   while (Region *region = insertionBlock->getParent()) {
     // Insert in this region for any of the following scenarios:
     //  * The parent is unregistered, or is known to be isolated from above.
     //  * The parent is a top-level operation.
     auto *parentOp = region->getParentOp();
     if (parentOp->mightHaveTrait<OpTrait::IsIsolatedFromAbove>() ||
         !parentOp->getBlock())
       return region;

     // Otherwise, check if this region is a desired insertion region.
     auto *interface = interfaces.getInterfaceFor(parentOp);
     if (LLVM_UNLIKELY(interface && interface->shouldMaterializeInto(region)))
       return region;

     // Traverse up the parent looking for an insertion region.
     insertionBlock = parentOp->getBlock();
   }
   llvm_unreachable("expected valid insertion region");
 }

 /// A utility function used to materialize a constant for a given attribute and
 /// type. On success, a valid constant value is returned. Otherwise, null is
 /// returned
 static Operation *materializeConstant(Dialect *dialect, OpBuilder &builder,
                                       Attribute value, Type type,
                                       Location loc) {
   auto insertPt = builder.getInsertionPoint();
   (void)insertPt;

   // Ask the dialect to materialize a constant operation for this value.
   if (auto *constOp = dialect->materializeConstant(builder, value, type, loc)) {
     assert(insertPt == builder.getInsertionPoint());
     assert(matchPattern(constOp, m_Constant()));
     return constOp;
   }

   return nullptr;
 }

 //===----------------------------------------------------------------------===//
 // OperationFolder
 //===----------------------------------------------------------------------===//

 LogicalResult OperationFolder::tryToFold(
     Operation *op, function_ref<void(Operation *)> processGeneratedConstants,
     function_ref<void(Operation *)> preReplaceAction, bool *inPlaceUpdate) {
   if (inPlaceUpdate)
     *inPlaceUpdate = false;

   // If this is a unique'd constant, return failure as we know that it has
   // already been folded.
   if (referencedDialects.count(op))
     return failure();

   // Try to fold the operation.
   SmallVector<Value, 8> results;
   OpBuilder builder(op);
   if (failed(tryToFold(builder, op, results, processGeneratedConstants)))
     return failure();

   // Check to see if the operation was just updated in place.
   if (results.empty()) {
     if (inPlaceUpdate)
       *inPlaceUpdate = true;
     return success();
   }

   // Constant folding succeeded. We will start replacing this op's uses and
   // erase this op. Invoke the callback provided by the caller to perform any
   // pre-replacement action.
   if (preReplaceAction)
     preReplaceAction(op);

   // Replace all of the result values and erase the operation.
   for (unsigned i = 0, e = results.size(); i != e; ++i)
     op->getResult(i).replaceAllUsesWith(results[i]);
   op->erase();
   return success();
 }

 /// Notifies that the given constant `op` should be remove from this
 /// OperationFolder's internal bookkeeping.
 void OperationFolder::notifyRemoval(Operation *op) {
   // Check to see if this operation is uniqued within the folder.
   auto it = referencedDialects.find(op);
   if (it == referencedDialects.end())
     return;

   // Get the constant value for this operation, this is the value that was used
   // to unique the operation internally.
   Attribute constValue;
   matchPattern(op, m_Constant(&constValue));
   assert(constValue);

   // Get the constant map that this operation was uniqued in.
   auto &uniquedConstants =
       foldScopes[getInsertionRegion(interfaces, op->getBlock())];

   // Erase all of the references to this operation.
   auto type = op->getResult(0).getType();
   for (auto *dialect : it->second)
     uniquedConstants.erase(std::make_tuple(dialect, constValue, type));
   referencedDialects.erase(it);
 }

 /// Clear out any constants cached inside of the folder.
 void OperationFolder::clear() {
   foldScopes.clear();
   referencedDialects.clear();
 }

 /// Get or create a constant using the given builder. On success this returns
 /// the constant operation, nullptr otherwise.
 Value OperationFolder::getOrCreateConstant(OpBuilder &builder, Dialect *dialect,
                                            Attribute value, Type type,
                                            Location loc) {
   OpBuilder::InsertionGuard foldGuard(builder);

   // Use the builder insertion block to find an insertion point for the
   // constant.
   auto *insertRegion =
       getInsertionRegion(interfaces, builder.getInsertionBlock());
   auto &entry = insertRegion->front();
   builder.setInsertionPoint(&entry, entry.begin());

   // Get the constant map for the insertion region of this operation.
   auto &uniquedConstants = foldScopes[insertRegion];
   Operation *constOp = tryGetOrCreateConstant(uniquedConstants, dialect,
                                               builder, value, type, loc);
   return constOp ? constOp->getResult(0) : Value();
 }

 /// Tries to perform folding on the given `op`. If successful, populates
 /// `results` with the results of the folding.
 LogicalResult OperationFolder::tryToFold(
     OpBuilder &builder, Operation *op, SmallVectorImpl<Value> &results,
     function_ref<void(Operation *)> processGeneratedConstants) {
   SmallVector<Attribute, 8> operandConstants;
   SmallVector<OpFoldResult, 8> foldResults;

   // If this is a commutative operation, move constants to be trailing operands.
   if (op->getNumOperands() >= 2 && op->hasTrait<OpTrait::IsCommutative>()) {
     std::stable_partition(
         op->getOpOperands().begin(), op->getOpOperands().end(),
         [&](OpOperand &O) { return !matchPattern(O.get(), m_Constant()); });
   }

   // Check to see if any operands to the operation is constant and whether
   // the operation knows how to constant fold itself.
   operandConstants.assign(op->getNumOperands(), Attribute());
   for (unsigned i = 0, e = op->getNumOperands(); i != e; ++i)
     matchPattern(op->getOperand(i), m_Constant(&operandConstants[i]));

   // Attempt to constant fold the operation.
   if (failed(op->fold(operandConstants, foldResults)))
     return failure();

   // Check to see if the operation was just updated in place.
   if (foldResults.empty())
     return success();
   assert(foldResults.size() == op->getNumResults());

   // Create a builder to insert new operations into the entry block of the
   // insertion region.
   auto *insertRegion =
       getInsertionRegion(interfaces, builder.getInsertionBlock());
   auto &entry = insertRegion->front();
   OpBuilder::InsertionGuard foldGuard(builder);
   builder.setInsertionPoint(&entry, entry.begin());

   // Get the constant map for the insertion region of this operation.
   auto &uniquedConstants = foldScopes[insertRegion];

   // Create the result constants and replace the results.
   auto *dialect = op->getDialect();
   for (unsigned i = 0, e = op->getNumResults(); i != e; ++i) {
     assert(!foldResults[i].isNull() && "expected valid OpFoldResult");

     // Check if the result was an SSA value.
     if (auto repl = foldResults[i].dyn_cast<Value>()) {
       if (repl.getType() != op->getResult(i).getType())
         return failure();
       results.emplace_back(repl);
       continue;
     }

     // Check to see if there is a canonicalized version of this constant.
     auto res = op->getResult(i);
     Attribute attrRepl = foldResults[i].get<Attribute>();
     if (auto *constOp =
             tryGetOrCreateConstant(uniquedConstants, dialect, builder, attrRepl,
                                    res.getType(), op->getLoc())) {
       // Ensure that this constant dominates the operation we are replacing it
       // with. This may not automatically happen if the operation being folded
       // was inserted before the constant within the insertion block.
       Block *opBlock = op->getBlock();
       if (opBlock == constOp->getBlock() && &opBlock->front() != constOp)
         constOp->moveBefore(&opBlock->front());

       results.push_back(constOp->getResult(0));
       continue;
     }
     // If materialization fails, cleanup any operations generated for the
     // previous results and return failure.
     for (Operation &op : llvm::make_early_inc_range(
              llvm::make_range(entry.begin(), builder.getInsertionPoint()))) {
       notifyRemoval(&op);
       op.erase();
     }
     return failure();
   }

   // Process any newly generated operations.
   if (processGeneratedConstants) {
     for (auto i = entry.begin(), e = builder.getInsertionPoint(); i != e; ++i)
       processGeneratedConstants(&*i);
   }

   return success();
 }

 /// Try to get or create a new constant entry. On success this returns the
 /// constant operation value, nullptr otherwise.
 Operation *OperationFolder::tryGetOrCreateConstant(
     ConstantMap &uniquedConstants, Dialect *dialect, OpBuilder &builder,
     Attribute value, Type type, Location loc) {
   // Check if an existing mapping already exists.
   auto constKey = std::make_tuple(dialect, value, type);
   Operation *&constOp = uniquedConstants[constKey];
   if (constOp)
     return constOp;

   // If one doesn't exist, try to materialize one.
   if (!(constOp = materializeConstant(dialect, builder, value, type, loc)))
     return nullptr;

   // Check to see if the generated constant is in the expected dialect.
   auto *newDialect = constOp->getDialect();
   if (newDialect == dialect) {
     referencedDialects[constOp].push_back(dialect);
     return constOp;
   }

   // If it isn't, then we also need to make sure that the mapping for the new
   // dialect is valid.
   auto newKey = std::make_tuple(newDialect, value, type);

   // If an existing operation in the new dialect already exists, delete the
   // materialized operation in favor of the existing one.
   if (auto *existingOp = uniquedConstants.lookup(newKey)) {
     constOp->erase();
     referencedDialects[existingOp].push_back(dialect);
     return constOp = existingOp;
   }

   // Otherwise, update the new dialect to the materialized operation.
   referencedDialects[constOp].assign({dialect, newDialect});
   auto newIt = uniquedConstants.insert({newKey, constOp});
   return newIt.first->second;
 }
	//===- FoldUtils.cpp ---- Fold Utilities ----------------------------------===//
	//
	// 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 various operation fold utilities. These utilities are
	// intended to be used by passes to unify and simply their logic.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Transforms/FoldUtils.h"

	#include "mlir/IR/Builders.h"
	#include "mlir/IR/Matchers.h"
	#include "mlir/IR/Operation.h"

	using namespace mlir;

	/// Given an operation, find the parent region that folded constants should be
	/// inserted into.
	static Region *
	getInsertionRegion(DialectInterfaceCollection<DialectFoldInterface> &interfaces,
	Block *insertionBlock) {
	while (Region *region = insertionBlock->getParent()) {
	// Insert in this region for any of the following scenarios:
	// * The parent is unregistered, or is known to be isolated from above.
	// * The parent is a top-level operation.
	auto *parentOp = region->getParentOp();
	if (parentOp->mightHaveTrait<OpTrait::IsIsolatedFromAbove>() \|\|
	!parentOp->getBlock())
	return region;

	// Otherwise, check if this region is a desired insertion region.
	auto *interface = interfaces.getInterfaceFor(parentOp);
	if (LLVM_UNLIKELY(interface && interface->shouldMaterializeInto(region)))
	return region;

	// Traverse up the parent looking for an insertion region.
	insertionBlock = parentOp->getBlock();
	}
	llvm_unreachable("expected valid insertion region");
	}

	/// A utility function used to materialize a constant for a given attribute and
	/// type. On success, a valid constant value is returned. Otherwise, null is
	/// returned
	static Operation materializeConstant(Dialect dialect, OpBuilder &builder,
	Attribute value, Type type,
	Location loc) {
	auto insertPt = builder.getInsertionPoint();
	(void)insertPt;

	// Ask the dialect to materialize a constant operation for this value.
	if (auto *constOp = dialect->materializeConstant(builder, value, type, loc)) {
	assert(insertPt == builder.getInsertionPoint());
	assert(matchPattern(constOp, m_Constant()));
	return constOp;
	}

	return nullptr;
	}

	//===----------------------------------------------------------------------===//
	// OperationFolder
	//===----------------------------------------------------------------------===//

	LogicalResult OperationFolder::tryToFold(
	Operation op, function_ref<void(Operation )> processGeneratedConstants,
	function_ref<void(Operation )> preReplaceAction, bool inPlaceUpdate) {
	if (inPlaceUpdate)
	*inPlaceUpdate = false;

	// If this is a unique'd constant, return failure as we know that it has
	// already been folded.
	if (referencedDialects.count(op))
	return failure();

	// Try to fold the operation.
	SmallVector<Value, 8> results;
	OpBuilder builder(op);
	if (failed(tryToFold(builder, op, results, processGeneratedConstants)))
	return failure();

	// Check to see if the operation was just updated in place.
	if (results.empty()) {
	if (inPlaceUpdate)
	*inPlaceUpdate = true;
	return success();
	}

	// Constant folding succeeded. We will start replacing this op's uses and
	// erase this op. Invoke the callback provided by the caller to perform any
	// pre-replacement action.
	if (preReplaceAction)
	preReplaceAction(op);

	// Replace all of the result values and erase the operation.
	for (unsigned i = 0, e = results.size(); i != e; ++i)
	op->getResult(i).replaceAllUsesWith(results[i]);
	op->erase();
	return success();
	}

	/// Notifies that the given constant `op` should be remove from this
	/// OperationFolder's internal bookkeeping.
	void OperationFolder::notifyRemoval(Operation *op) {
	// Check to see if this operation is uniqued within the folder.
	auto it = referencedDialects.find(op);
	if (it == referencedDialects.end())
	return;

	// Get the constant value for this operation, this is the value that was used
	// to unique the operation internally.
	Attribute constValue;
	matchPattern(op, m_Constant(&constValue));
	assert(constValue);

	// Get the constant map that this operation was uniqued in.
	auto &uniquedConstants =
	foldScopes[getInsertionRegion(interfaces, op->getBlock())];

	// Erase all of the references to this operation.
	auto type = op->getResult(0).getType();
	for (auto *dialect : it->second)
	uniquedConstants.erase(std::make_tuple(dialect, constValue, type));
	referencedDialects.erase(it);
	}

	/// Clear out any constants cached inside of the folder.
	void OperationFolder::clear() {
	foldScopes.clear();
	referencedDialects.clear();
	}

	/// Get or create a constant using the given builder. On success this returns
	/// the constant operation, nullptr otherwise.
	Value OperationFolder::getOrCreateConstant(OpBuilder &builder, Dialect *dialect,
	Attribute value, Type type,
	Location loc) {
	OpBuilder::InsertionGuard foldGuard(builder);

	// Use the builder insertion block to find an insertion point for the
	// constant.
	auto *insertRegion =
	getInsertionRegion(interfaces, builder.getInsertionBlock());
	auto &entry = insertRegion->front();
	builder.setInsertionPoint(&entry, entry.begin());

	// Get the constant map for the insertion region of this operation.
	auto &uniquedConstants = foldScopes[insertRegion];
	Operation *constOp = tryGetOrCreateConstant(uniquedConstants, dialect,
	builder, value, type, loc);
	return constOp ? constOp->getResult(0) : Value();
	}

	/// Tries to perform folding on the given `op`. If successful, populates
	/// `results` with the results of the folding.
	LogicalResult OperationFolder::tryToFold(
	OpBuilder &builder, Operation *op, SmallVectorImpl<Value> &results,
	function_ref<void(Operation *)> processGeneratedConstants) {
	SmallVector<Attribute, 8> operandConstants;
	SmallVector<OpFoldResult, 8> foldResults;

	// If this is a commutative operation, move constants to be trailing operands.
	if (op->getNumOperands() >= 2 && op->hasTrait<OpTrait::IsCommutative>()) {
	std::stable_partition(
	op->getOpOperands().begin(), op->getOpOperands().end(),
	[&](OpOperand &O) { return !matchPattern(O.get(), m_Constant()); });
	}

	// Check to see if any operands to the operation is constant and whether
	// the operation knows how to constant fold itself.
	operandConstants.assign(op->getNumOperands(), Attribute());
	for (unsigned i = 0, e = op->getNumOperands(); i != e; ++i)
	matchPattern(op->getOperand(i), m_Constant(&operandConstants[i]));

	// Attempt to constant fold the operation.
	if (failed(op->fold(operandConstants, foldResults)))
	return failure();

	// Check to see if the operation was just updated in place.
	if (foldResults.empty())
	return success();
	assert(foldResults.size() == op->getNumResults());

	// Create a builder to insert new operations into the entry block of the
	// insertion region.
	auto *insertRegion =
	getInsertionRegion(interfaces, builder.getInsertionBlock());
	auto &entry = insertRegion->front();
	OpBuilder::InsertionGuard foldGuard(builder);
	builder.setInsertionPoint(&entry, entry.begin());

	// Get the constant map for the insertion region of this operation.
	auto &uniquedConstants = foldScopes[insertRegion];

	// Create the result constants and replace the results.
	auto *dialect = op->getDialect();
	for (unsigned i = 0, e = op->getNumResults(); i != e; ++i) {
	assert(!foldResults[i].isNull() && "expected valid OpFoldResult");

	// Check if the result was an SSA value.
	if (auto repl = foldResults[i].dyn_cast<Value>()) {
	if (repl.getType() != op->getResult(i).getType())
	return failure();
	results.emplace_back(repl);
	continue;
	}

	// Check to see if there is a canonicalized version of this constant.
	auto res = op->getResult(i);
	Attribute attrRepl = foldResults[i].get<Attribute>();
	if (auto *constOp =
	tryGetOrCreateConstant(uniquedConstants, dialect, builder, attrRepl,
	res.getType(), op->getLoc())) {
	// Ensure that this constant dominates the operation we are replacing it
	// with. This may not automatically happen if the operation being folded
	// was inserted before the constant within the insertion block.
	Block *opBlock = op->getBlock();
	if (opBlock == constOp->getBlock() && &opBlock->front() != constOp)
	constOp->moveBefore(&opBlock->front());

	results.push_back(constOp->getResult(0));
	continue;
	}
	// If materialization fails, cleanup any operations generated for the
	// previous results and return failure.
	for (Operation &op : llvm::make_early_inc_range(
	llvm::make_range(entry.begin(), builder.getInsertionPoint()))) {
	notifyRemoval(&op);
	op.erase();
	}
	return failure();
	}

	// Process any newly generated operations.
	if (processGeneratedConstants) {
	for (auto i = entry.begin(), e = builder.getInsertionPoint(); i != e; ++i)
	processGeneratedConstants(&*i);
	}

	return success();
	}

	/// Try to get or create a new constant entry. On success this returns the
	/// constant operation value, nullptr otherwise.
	Operation *OperationFolder::tryGetOrCreateConstant(
	ConstantMap &uniquedConstants, Dialect *dialect, OpBuilder &builder,
	Attribute value, Type type, Location loc) {
	// Check if an existing mapping already exists.
	auto constKey = std::make_tuple(dialect, value, type);
	Operation *&constOp = uniquedConstants[constKey];
	if (constOp)
	return constOp;

	// If one doesn't exist, try to materialize one.
	if (!(constOp = materializeConstant(dialect, builder, value, type, loc)))
	return nullptr;

	// Check to see if the generated constant is in the expected dialect.
	auto *newDialect = constOp->getDialect();
	if (newDialect == dialect) {
	referencedDialects[constOp].push_back(dialect);
	return constOp;
	}

	// If it isn't, then we also need to make sure that the mapping for the new
	// dialect is valid.
	auto newKey = std::make_tuple(newDialect, value, type);

	// If an existing operation in the new dialect already exists, delete the
	// materialized operation in favor of the existing one.
	if (auto *existingOp = uniquedConstants.lookup(newKey)) {
	constOp->erase();
	referencedDialects[existingOp].push_back(dialect);
	return constOp = existingOp;
	}

	// Otherwise, update the new dialect to the materialized operation.
	referencedDialects[constOp].assign({dialect, newDialect});
	auto newIt = uniquedConstants.insert({newKey, constOp});
	return newIt.first->second;
	}