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

 //===- BufferOptimizations.cpp - pre-pass optimizations for bufferization -===//
 //
 // 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 logic for three optimization passes. The first two
 // passes try to move alloc nodes out of blocks to reduce the number of
 // allocations and copies during buffer deallocation. The third pass tries to
 // convert heap-based allocations to stack-based allocations, if possible.

 #include "PassDetail.h"
 #include "mlir/Dialect/MemRef/IR/MemRef.h"
 #include "mlir/IR/Operation.h"
 #include "mlir/Interfaces/LoopLikeInterface.h"
 #include "mlir/Pass/Pass.h"
 #include "mlir/Transforms/BufferUtils.h"
 #include "mlir/Transforms/Passes.h"

 using namespace mlir;

 /// Returns true if the given operation implements a known high-level region-
 /// based control-flow interface.
 static bool isKnownControlFlowInterface(Operation *op) {
   return isa<LoopLikeOpInterface, RegionBranchOpInterface>(op);
 }

 /// Check if the size of the allocation is less than the given size. The
 /// transformation is only applied to small buffers since large buffers could
 /// exceed the stack space.
 static bool defaultIsSmallAlloc(Value alloc, unsigned maximumSizeInBytes,
                                 unsigned bitwidthOfIndexType,
                                 unsigned maxRankOfAllocatedMemRef) {
   auto type = alloc.getType().dyn_cast<ShapedType>();
   if (!type || !alloc.getDefiningOp<memref::AllocOp>())
     return false;
   if (!type.hasStaticShape()) {
     // Check if the dynamic shape dimension of the alloc is produced by RankOp.
     // If this is the case, it is likely to be small. Furthermore, the dimension
     // is limited to the maximum rank of the allocated memref to avoid large
     // values by multiplying several small values.
     if (type.getRank() <= maxRankOfAllocatedMemRef) {
       return llvm::all_of(
           alloc.getDefiningOp()->getOperands(),
           [&](Value operand) { return operand.getDefiningOp<RankOp>(); });
     }
     return false;
   }
   // For index types, use the provided size, as the type does not know.
   unsigned int bitwidth = type.getElementType().isIndex()
                               ? bitwidthOfIndexType
                               : type.getElementTypeBitWidth();
   return type.getNumElements() * bitwidth <= maximumSizeInBytes * 8;
 }

 /// Checks whether the given aliases leave the allocation scope.
 static bool
 leavesAllocationScope(Region *parentRegion,
                       const BufferViewFlowAnalysis::ValueSetT &aliases) {
   for (Value alias : aliases) {
     for (auto *use : alias.getUsers()) {
       // If there is at least one alias that leaves the parent region, we know
       // that this alias escapes the whole region and hence the associated
       // allocation leaves allocation scope.
       if (isRegionReturnLike(use) && use->getParentRegion() == parentRegion)
         return true;
     }
   }
   return false;
 }

 /// Checks, if an automated allocation scope for a given alloc value exists.
 static bool hasAllocationScope(Value alloc,
                                const BufferViewFlowAnalysis &aliasAnalysis) {
   Region *region = alloc.getParentRegion();
   do {
     if (Operation *parentOp = region->getParentOp()) {
       // Check if the operation is an automatic allocation scope and whether an
       // alias leaves the scope. This means, an allocation yields out of
       // this scope and can not be transformed in a stack-based allocation.
       if (parentOp->hasTrait<OpTrait::AutomaticAllocationScope>() &&
           !leavesAllocationScope(region, aliasAnalysis.resolve(alloc)))
         return true;
       // Check if the operation is a known control flow interface and break the
       // loop to avoid transformation in loops. Furthermore skip transformation
       // if the operation does not implement a RegionBeanchOpInterface.
       if (BufferPlacementTransformationBase::isLoop(parentOp) ||
           !isKnownControlFlowInterface(parentOp))
         break;
     }
   } while ((region = region->getParentRegion()));
   return false;
 }

 namespace {

 //===----------------------------------------------------------------------===//
 // BufferAllocationHoisting
 //===----------------------------------------------------------------------===//

 /// A base implementation compatible with the `BufferAllocationHoisting` class.
 struct BufferAllocationHoistingStateBase {
   /// A pointer to the current dominance info.
   DominanceInfo *dominators;

   /// The current allocation value.
   Value allocValue;

   /// The current placement block (if any).
   Block *placementBlock;

   /// Initializes the state base.
   BufferAllocationHoistingStateBase(DominanceInfo *dominators, Value allocValue,
                                     Block *placementBlock)
       : dominators(dominators), allocValue(allocValue),
         placementBlock(placementBlock) {}
 };

 /// Implements the actual hoisting logic for allocation nodes.
 template <typename StateT>
 class BufferAllocationHoisting : public BufferPlacementTransformationBase {
 public:
   BufferAllocationHoisting(Operation *op)
       : BufferPlacementTransformationBase(op), dominators(op),
         postDominators(op), scopeOp(op) {}

   /// Moves allocations upwards.
   void hoist() {
     SmallVector<Value> allocsAndAllocas;
     for (BufferPlacementAllocs::AllocEntry &entry : allocs)
       allocsAndAllocas.push_back(std::get<0>(entry));
     scopeOp->walk(
         [&](memref::AllocaOp op) { allocsAndAllocas.push_back(op.memref()); });

     for (auto allocValue : allocsAndAllocas) {
       if (!StateT::shouldHoistOpType(allocValue.getDefiningOp()))
         continue;
       Operation *definingOp = allocValue.getDefiningOp();
       assert(definingOp && "No defining op");
       auto operands = definingOp->getOperands();
       auto resultAliases = aliases.resolve(allocValue);
       // Determine the common dominator block of all aliases.
       Block *dominatorBlock =
           findCommonDominator(allocValue, resultAliases, dominators);
       // Init the initial hoisting state.
       StateT state(&dominators, allocValue, allocValue.getParentBlock());
       // Check for additional allocation dependencies to compute an upper bound
       // for hoisting.
       Block *dependencyBlock = nullptr;
       // If this node has dependencies, check all dependent nodes. This ensures
       // that all dependency values have been computed before allocating the
       // buffer.
       for (Value depValue : operands) {
         Block *depBlock = depValue.getParentBlock();
         if (!dependencyBlock || dominators.dominates(dependencyBlock, depBlock))
           dependencyBlock = depBlock;
       }

       // Find the actual placement block and determine the start operation using
       // an upper placement-block boundary. The idea is that placement block
       // cannot be moved any further upwards than the given upper bound.
       Block *placementBlock = findPlacementBlock(
           state, state.computeUpperBound(dominatorBlock, dependencyBlock));
       Operation *startOperation = BufferPlacementAllocs::getStartOperation(
           allocValue, placementBlock, liveness);

       // Move the alloc in front of the start operation.
       Operation *allocOperation = allocValue.getDefiningOp();
       allocOperation->moveBefore(startOperation);
     }
   }

 private:
   /// Finds a valid placement block by walking upwards in the CFG until we
   /// either cannot continue our walk due to constraints (given by the StateT
   /// implementation) or we have reached the upper-most dominator block.
   Block *findPlacementBlock(StateT &state, Block *upperBound) {
     Block *currentBlock = state.placementBlock;
     // Walk from the innermost regions/loops to the outermost regions/loops and
     // find an appropriate placement block that satisfies the constraint of the
     // current StateT implementation. Walk until we reach the upperBound block
     // (if any).

     // If we are not able to find a valid parent operation or an associated
     // parent block, break the walk loop.
     Operation *parentOp;
     Block *parentBlock;
     while ((parentOp = currentBlock->getParentOp()) &&
            (parentBlock = parentOp->getBlock()) &&
            (!upperBound ||
             dominators.properlyDominates(upperBound, currentBlock))) {
       // Try to find an immediate dominator and check whether the parent block
       // is above the immediate dominator (if any).
       DominanceInfoNode *idom = nullptr;

       // DominanceInfo doesn't support getNode queries for single-block regions.
       if (!currentBlock->isEntryBlock())
         idom = dominators.getNode(currentBlock)->getIDom();

       if (idom && dominators.properlyDominates(parentBlock, idom->getBlock())) {
         // If the current immediate dominator is below the placement block, move
         // to the immediate dominator block.
         currentBlock = idom->getBlock();
         state.recordMoveToDominator(currentBlock);
       } else {
         // We have to move to our parent block since an immediate dominator does
         // either not exist or is above our parent block. If we cannot move to
         // our parent operation due to constraints given by the StateT
         // implementation, break the walk loop. Furthermore, we should not move
         // allocations out of unknown region-based control-flow operations.
         if (!isKnownControlFlowInterface(parentOp) ||
             !state.isLegalPlacement(parentOp))
           break;
         // Move to our parent block by notifying the current StateT
         // implementation.
         currentBlock = parentBlock;
         state.recordMoveToParent(currentBlock);
       }
     }
     // Return the finally determined placement block.
     return state.placementBlock;
   }

   /// The dominator info to find the appropriate start operation to move the
   /// allocs.
   DominanceInfo dominators;

   /// The post dominator info to move the dependent allocs in the right
   /// position.
   PostDominanceInfo postDominators;

   /// The map storing the final placement blocks of a given alloc value.
   llvm::DenseMap<Value, Block *> placementBlocks;

   /// The operation that this transformation is working on. It is used to also
   /// gather allocas.
   Operation *scopeOp;
 };

 /// A state implementation compatible with the `BufferAllocationHoisting` class
 /// that hoists allocations into dominator blocks while keeping them inside of
 /// loops.
 struct BufferAllocationHoistingState : BufferAllocationHoistingStateBase {
   using BufferAllocationHoistingStateBase::BufferAllocationHoistingStateBase;

   /// Computes the upper bound for the placement block search.
   Block *computeUpperBound(Block *dominatorBlock, Block *dependencyBlock) {
     // If we do not have a dependency block, the upper bound is given by the
     // dominator block.
     if (!dependencyBlock)
       return dominatorBlock;

     // Find the "lower" block of the dominator and the dependency block to
     // ensure that we do not move allocations above this block.
     return dominators->properlyDominates(dominatorBlock, dependencyBlock)
                ? dependencyBlock
                : dominatorBlock;
   }

   /// Returns true if the given operation does not represent a loop.
   bool isLegalPlacement(Operation *op) {
     return !BufferPlacementTransformationBase::isLoop(op);
   }

   /// Returns true if the given operation should be considered for hoisting.
   static bool shouldHoistOpType(Operation *op) {
     return llvm::isa<memref::AllocOp>(op);
   }

   /// Sets the current placement block to the given block.
   void recordMoveToDominator(Block *block) { placementBlock = block; }

   /// Sets the current placement block to the given block.
   void recordMoveToParent(Block *block) { recordMoveToDominator(block); }
 };

 /// A state implementation compatible with the `BufferAllocationHoisting` class
 /// that hoists allocations out of loops.
 struct BufferAllocationLoopHoistingState : BufferAllocationHoistingStateBase {
   using BufferAllocationHoistingStateBase::BufferAllocationHoistingStateBase;

   /// Remembers the dominator block of all aliases.
   Block *aliasDominatorBlock;

   /// Computes the upper bound for the placement block search.
   Block *computeUpperBound(Block *dominatorBlock, Block *dependencyBlock) {
     aliasDominatorBlock = dominatorBlock;
     // If there is a dependency block, we have to use this block as an upper
     // bound to satisfy all allocation value dependencies.
     return dependencyBlock ? dependencyBlock : nullptr;
   }

   /// Returns true if the given operation represents a loop and one of the
   /// aliases caused the `aliasDominatorBlock` to be "above" the block of the
   /// given loop operation. If this is the case, it indicates that the
   /// allocation is passed via a back edge.
   bool isLegalPlacement(Operation *op) {
     return BufferPlacementTransformationBase::isLoop(op) &&
            !dominators->dominates(aliasDominatorBlock, op->getBlock());
   }

   /// Returns true if the given operation should be considered for hoisting.
   static bool shouldHoistOpType(Operation *op) {
     return llvm::isa<memref::AllocOp, memref::AllocaOp>(op);
   }

   /// Does not change the internal placement block, as we want to move
   /// operations out of loops only.
   void recordMoveToDominator(Block *block) {}

   /// Sets the current placement block to the given block.
   void recordMoveToParent(Block *block) { placementBlock = block; }
 };

 //===----------------------------------------------------------------------===//
 // BufferPlacementPromotion
 //===----------------------------------------------------------------------===//

 /// Promotes heap-based allocations to stack-based allocations (if possible).
 class BufferPlacementPromotion : BufferPlacementTransformationBase {
 public:
   BufferPlacementPromotion(Operation *op)
       : BufferPlacementTransformationBase(op) {}

   /// Promote buffers to stack-based allocations.
   void promote(function_ref<bool(Value)> isSmallAlloc) {
     for (BufferPlacementAllocs::AllocEntry &entry : allocs) {
       Value alloc = std::get<0>(entry);
       Operation *dealloc = std::get<1>(entry);
       // Checking several requirements to transform an AllocOp into an AllocaOp.
       // The transformation is done if the allocation is limited to a given
       // size. Furthermore, a deallocation must not be defined for this
       // allocation entry and a parent allocation scope must exist.
       if (!isSmallAlloc(alloc) || dealloc ||
           !hasAllocationScope(alloc, aliases))
         continue;

       Operation *startOperation = BufferPlacementAllocs::getStartOperation(
           alloc, alloc.getParentBlock(), liveness);
       // Build a new alloca that is associated with its parent
       // `AutomaticAllocationScope` determined during the initialization phase.
       OpBuilder builder(startOperation);
       Operation *allocOp = alloc.getDefiningOp();
       Operation *alloca = builder.create<memref::AllocaOp>(
           alloc.getLoc(), alloc.getType().cast<MemRefType>(),
           allocOp->getOperands());

       // Replace the original alloc by a newly created alloca.
       allocOp->replaceAllUsesWith(alloca);
       allocOp->erase();
     }
   }
 };

 //===----------------------------------------------------------------------===//
 // BufferOptimizationPasses
 //===----------------------------------------------------------------------===//

 /// The buffer hoisting pass that hoists allocation nodes into dominating
 /// blocks.
 struct BufferHoistingPass : BufferHoistingBase<BufferHoistingPass> {

   void runOnFunction() override {
     // Hoist all allocations into dominator blocks.
     BufferAllocationHoisting<BufferAllocationHoistingState> optimizer(
         getFunction());
     optimizer.hoist();
   }
 };

 /// The buffer loop hoisting pass that hoists allocation nodes out of loops.
 struct BufferLoopHoistingPass : BufferLoopHoistingBase<BufferLoopHoistingPass> {

   void runOnFunction() override {
     // Hoist all allocations out of loops.
     BufferAllocationHoisting<BufferAllocationLoopHoistingState> optimizer(
         getFunction());
     optimizer.hoist();
   }
 };

 /// The promote buffer to stack pass that tries to convert alloc nodes into
 /// alloca nodes.
 class PromoteBuffersToStackPass
     : public PromoteBuffersToStackBase<PromoteBuffersToStackPass> {
 public:
   PromoteBuffersToStackPass(unsigned maxAllocSizeInBytes,
                             unsigned bitwidthOfIndexType,
                             unsigned maxRankOfAllocatedMemRef) {
     this->maxAllocSizeInBytes = maxAllocSizeInBytes;
     this->bitwidthOfIndexType = bitwidthOfIndexType;
     this->maxRankOfAllocatedMemRef = maxRankOfAllocatedMemRef;
   }

   explicit PromoteBuffersToStackPass(std::function<bool(Value)> isSmallAlloc)
       : isSmallAlloc(std::move(isSmallAlloc)) {}

   LogicalResult initialize(MLIRContext *context) override {
     if (isSmallAlloc == nullptr) {
       isSmallAlloc = [=](Value alloc) {
         return defaultIsSmallAlloc(alloc, maxAllocSizeInBytes,
                                    bitwidthOfIndexType,
                                    maxRankOfAllocatedMemRef);
       };
     }
     return success();
   }

   void runOnFunction() override {
     // Move all allocation nodes and convert candidates into allocas.
     BufferPlacementPromotion optimizer(getFunction());
     optimizer.promote(isSmallAlloc);
   }

 private:
   std::function<bool(Value)> isSmallAlloc;
 };

 } // end anonymous namespace

 std::unique_ptr<Pass> mlir::createBufferHoistingPass() {
   return std::make_unique<BufferHoistingPass>();
 }

 std::unique_ptr<Pass> mlir::createBufferLoopHoistingPass() {
   return std::make_unique<BufferLoopHoistingPass>();
 }

 std::unique_ptr<Pass>
 mlir::createPromoteBuffersToStackPass(unsigned maxAllocSizeInBytes,
                                       unsigned bitwidthOfIndexType,
                                       unsigned maxRankOfAllocatedMemRef) {
   return std::make_unique<PromoteBuffersToStackPass>(
       maxAllocSizeInBytes, bitwidthOfIndexType, maxRankOfAllocatedMemRef);
 }

 std::unique_ptr<Pass>
 mlir::createPromoteBuffersToStackPass(std::function<bool(Value)> isSmallAlloc) {
   return std::make_unique<PromoteBuffersToStackPass>(std::move(isSmallAlloc));
 }
	//===- BufferOptimizations.cpp - pre-pass optimizations for bufferization -===//
	//
	// 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 logic for three optimization passes. The first two
	// passes try to move alloc nodes out of blocks to reduce the number of
	// allocations and copies during buffer deallocation. The third pass tries to
	// convert heap-based allocations to stack-based allocations, if possible.

	#include "PassDetail.h"
	#include "mlir/Dialect/MemRef/IR/MemRef.h"
	#include "mlir/IR/Operation.h"
	#include "mlir/Interfaces/LoopLikeInterface.h"
	#include "mlir/Pass/Pass.h"
	#include "mlir/Transforms/BufferUtils.h"
	#include "mlir/Transforms/Passes.h"

	using namespace mlir;

	/// Returns true if the given operation implements a known high-level region-
	/// based control-flow interface.
	static bool isKnownControlFlowInterface(Operation *op) {
	return isa<LoopLikeOpInterface, RegionBranchOpInterface>(op);
	}

	/// Check if the size of the allocation is less than the given size. The
	/// transformation is only applied to small buffers since large buffers could
	/// exceed the stack space.
	static bool defaultIsSmallAlloc(Value alloc, unsigned maximumSizeInBytes,
	unsigned bitwidthOfIndexType,
	unsigned maxRankOfAllocatedMemRef) {
	auto type = alloc.getType().dyn_cast<ShapedType>();
	if (!type \|\| !alloc.getDefiningOp<memref::AllocOp>())
	return false;
	if (!type.hasStaticShape()) {
	// Check if the dynamic shape dimension of the alloc is produced by RankOp.
	// If this is the case, it is likely to be small. Furthermore, the dimension
	// is limited to the maximum rank of the allocated memref to avoid large
	// values by multiplying several small values.
	if (type.getRank() <= maxRankOfAllocatedMemRef) {
	return llvm::all_of(
	alloc.getDefiningOp()->getOperands(),
	[&](Value operand) { return operand.getDefiningOp<RankOp>(); });
	}
	return false;
	}
	// For index types, use the provided size, as the type does not know.
	unsigned int bitwidth = type.getElementType().isIndex()
	? bitwidthOfIndexType
	: type.getElementTypeBitWidth();
	return type.getNumElements() * bitwidth <= maximumSizeInBytes * 8;
	}

	/// Checks whether the given aliases leave the allocation scope.
	static bool
	leavesAllocationScope(Region *parentRegion,
	const BufferViewFlowAnalysis::ValueSetT &aliases) {
	for (Value alias : aliases) {
	for (auto *use : alias.getUsers()) {
	// If there is at least one alias that leaves the parent region, we know
	// that this alias escapes the whole region and hence the associated
	// allocation leaves allocation scope.
	if (isRegionReturnLike(use) && use->getParentRegion() == parentRegion)
	return true;
	}
	}
	return false;
	}

	/// Checks, if an automated allocation scope for a given alloc value exists.
	static bool hasAllocationScope(Value alloc,
	const BufferViewFlowAnalysis &aliasAnalysis) {
	Region *region = alloc.getParentRegion();
	do {
	if (Operation *parentOp = region->getParentOp()) {
	// Check if the operation is an automatic allocation scope and whether an
	// alias leaves the scope. This means, an allocation yields out of
	// this scope and can not be transformed in a stack-based allocation.
	if (parentOp->hasTrait<OpTrait::AutomaticAllocationScope>() &&
	!leavesAllocationScope(region, aliasAnalysis.resolve(alloc)))
	return true;
	// Check if the operation is a known control flow interface and break the
	// loop to avoid transformation in loops. Furthermore skip transformation
	// if the operation does not implement a RegionBeanchOpInterface.
	if (BufferPlacementTransformationBase::isLoop(parentOp) \|\|
	!isKnownControlFlowInterface(parentOp))
	break;
	}
	} while ((region = region->getParentRegion()));
	return false;
	}

	namespace {

	//===----------------------------------------------------------------------===//
	// BufferAllocationHoisting
	//===----------------------------------------------------------------------===//

	/// A base implementation compatible with the `BufferAllocationHoisting` class.
	struct BufferAllocationHoistingStateBase {
	/// A pointer to the current dominance info.
	DominanceInfo *dominators;

	/// The current allocation value.
	Value allocValue;

	/// The current placement block (if any).
	Block *placementBlock;

	/// Initializes the state base.
	BufferAllocationHoistingStateBase(DominanceInfo *dominators, Value allocValue,
	Block *placementBlock)
	: dominators(dominators), allocValue(allocValue),
	placementBlock(placementBlock) {}
	};

	/// Implements the actual hoisting logic for allocation nodes.
	template <typename StateT>
	class BufferAllocationHoisting : public BufferPlacementTransformationBase {
	public:
	BufferAllocationHoisting(Operation *op)
	: BufferPlacementTransformationBase(op), dominators(op),
	postDominators(op), scopeOp(op) {}

	/// Moves allocations upwards.
	void hoist() {
	SmallVector<Value> allocsAndAllocas;
	for (BufferPlacementAllocs::AllocEntry &entry : allocs)
	allocsAndAllocas.push_back(std::get<0>(entry));
	scopeOp->walk(
	[&](memref::AllocaOp op) { allocsAndAllocas.push_back(op.memref()); });

	for (auto allocValue : allocsAndAllocas) {
	if (!StateT::shouldHoistOpType(allocValue.getDefiningOp()))
	continue;
	Operation *definingOp = allocValue.getDefiningOp();
	assert(definingOp && "No defining op");
	auto operands = definingOp->getOperands();
	auto resultAliases = aliases.resolve(allocValue);
	// Determine the common dominator block of all aliases.
	Block *dominatorBlock =
	findCommonDominator(allocValue, resultAliases, dominators);
	// Init the initial hoisting state.
	StateT state(&dominators, allocValue, allocValue.getParentBlock());
	// Check for additional allocation dependencies to compute an upper bound
	// for hoisting.
	Block *dependencyBlock = nullptr;
	// If this node has dependencies, check all dependent nodes. This ensures
	// that all dependency values have been computed before allocating the
	// buffer.
	for (Value depValue : operands) {
	Block *depBlock = depValue.getParentBlock();
	if (!dependencyBlock \|\| dominators.dominates(dependencyBlock, depBlock))
	dependencyBlock = depBlock;
	}

	// Find the actual placement block and determine the start operation using
	// an upper placement-block boundary. The idea is that placement block
	// cannot be moved any further upwards than the given upper bound.
	Block *placementBlock = findPlacementBlock(
	state, state.computeUpperBound(dominatorBlock, dependencyBlock));
	Operation *startOperation = BufferPlacementAllocs::getStartOperation(
	allocValue, placementBlock, liveness);

	// Move the alloc in front of the start operation.
	Operation *allocOperation = allocValue.getDefiningOp();
	allocOperation->moveBefore(startOperation);
	}
	}

	private:
	/// Finds a valid placement block by walking upwards in the CFG until we
	/// either cannot continue our walk due to constraints (given by the StateT
	/// implementation) or we have reached the upper-most dominator block.
	Block findPlacementBlock(StateT &state, Block upperBound) {
	Block *currentBlock = state.placementBlock;
	// Walk from the innermost regions/loops to the outermost regions/loops and
	// find an appropriate placement block that satisfies the constraint of the
	// current StateT implementation. Walk until we reach the upperBound block
	// (if any).

	// If we are not able to find a valid parent operation or an associated
	// parent block, break the walk loop.
	Operation *parentOp;
	Block *parentBlock;
	while ((parentOp = currentBlock->getParentOp()) &&
	(parentBlock = parentOp->getBlock()) &&
	(!upperBound \|\|
	dominators.properlyDominates(upperBound, currentBlock))) {
	// Try to find an immediate dominator and check whether the parent block
	// is above the immediate dominator (if any).
	DominanceInfoNode *idom = nullptr;

	// DominanceInfo doesn't support getNode queries for single-block regions.
	if (!currentBlock->isEntryBlock())
	idom = dominators.getNode(currentBlock)->getIDom();

	if (idom && dominators.properlyDominates(parentBlock, idom->getBlock())) {
	// If the current immediate dominator is below the placement block, move
	// to the immediate dominator block.
	currentBlock = idom->getBlock();
	state.recordMoveToDominator(currentBlock);
	} else {
	// We have to move to our parent block since an immediate dominator does
	// either not exist or is above our parent block. If we cannot move to
	// our parent operation due to constraints given by the StateT
	// implementation, break the walk loop. Furthermore, we should not move
	// allocations out of unknown region-based control-flow operations.
	if (!isKnownControlFlowInterface(parentOp) \|\|
	!state.isLegalPlacement(parentOp))
	break;
	// Move to our parent block by notifying the current StateT
	// implementation.
	currentBlock = parentBlock;
	state.recordMoveToParent(currentBlock);
	}
	}
	// Return the finally determined placement block.
	return state.placementBlock;
	}

	/// The dominator info to find the appropriate start operation to move the
	/// allocs.
	DominanceInfo dominators;

	/// The post dominator info to move the dependent allocs in the right
	/// position.
	PostDominanceInfo postDominators;

	/// The map storing the final placement blocks of a given alloc value.
	llvm::DenseMap<Value, Block *> placementBlocks;

	/// The operation that this transformation is working on. It is used to also
	/// gather allocas.
	Operation *scopeOp;
	};

	/// A state implementation compatible with the `BufferAllocationHoisting` class
	/// that hoists allocations into dominator blocks while keeping them inside of
	/// loops.
	struct BufferAllocationHoistingState : BufferAllocationHoistingStateBase {
	using BufferAllocationHoistingStateBase::BufferAllocationHoistingStateBase;

	/// Computes the upper bound for the placement block search.
	Block computeUpperBound(Block dominatorBlock, Block *dependencyBlock) {
	// If we do not have a dependency block, the upper bound is given by the
	// dominator block.
	if (!dependencyBlock)
	return dominatorBlock;

	// Find the "lower" block of the dominator and the dependency block to
	// ensure that we do not move allocations above this block.
	return dominators->properlyDominates(dominatorBlock, dependencyBlock)
	? dependencyBlock
	: dominatorBlock;
	}

	/// Returns true if the given operation does not represent a loop.
	bool isLegalPlacement(Operation *op) {
	return !BufferPlacementTransformationBase::isLoop(op);
	}

	/// Returns true if the given operation should be considered for hoisting.
	static bool shouldHoistOpType(Operation *op) {
	return llvm::isa<memref::AllocOp>(op);
	}

	/// Sets the current placement block to the given block.
	void recordMoveToDominator(Block *block) { placementBlock = block; }

	/// Sets the current placement block to the given block.
	void recordMoveToParent(Block *block) { recordMoveToDominator(block); }
	};

	/// A state implementation compatible with the `BufferAllocationHoisting` class
	/// that hoists allocations out of loops.
	struct BufferAllocationLoopHoistingState : BufferAllocationHoistingStateBase {
	using BufferAllocationHoistingStateBase::BufferAllocationHoistingStateBase;

	/// Remembers the dominator block of all aliases.
	Block *aliasDominatorBlock;

	/// Computes the upper bound for the placement block search.
	Block computeUpperBound(Block dominatorBlock, Block *dependencyBlock) {
	aliasDominatorBlock = dominatorBlock;
	// If there is a dependency block, we have to use this block as an upper
	// bound to satisfy all allocation value dependencies.
	return dependencyBlock ? dependencyBlock : nullptr;
	}

	/// Returns true if the given operation represents a loop and one of the
	/// aliases caused the `aliasDominatorBlock` to be "above" the block of the
	/// given loop operation. If this is the case, it indicates that the
	/// allocation is passed via a back edge.
	bool isLegalPlacement(Operation *op) {
	return BufferPlacementTransformationBase::isLoop(op) &&
	!dominators->dominates(aliasDominatorBlock, op->getBlock());
	}

	/// Returns true if the given operation should be considered for hoisting.
	static bool shouldHoistOpType(Operation *op) {
	return llvm::isa<memref::AllocOp, memref::AllocaOp>(op);
	}

	/// Does not change the internal placement block, as we want to move
	/// operations out of loops only.
	void recordMoveToDominator(Block *block) {}

	/// Sets the current placement block to the given block.
	void recordMoveToParent(Block *block) { placementBlock = block; }
	};

	//===----------------------------------------------------------------------===//
	// BufferPlacementPromotion
	//===----------------------------------------------------------------------===//

	/// Promotes heap-based allocations to stack-based allocations (if possible).
	class BufferPlacementPromotion : BufferPlacementTransformationBase {
	public:
	BufferPlacementPromotion(Operation *op)
	: BufferPlacementTransformationBase(op) {}

	/// Promote buffers to stack-based allocations.
	void promote(function_ref<bool(Value)> isSmallAlloc) {
	for (BufferPlacementAllocs::AllocEntry &entry : allocs) {
	Value alloc = std::get<0>(entry);
	Operation *dealloc = std::get<1>(entry);
	// Checking several requirements to transform an AllocOp into an AllocaOp.
	// The transformation is done if the allocation is limited to a given
	// size. Furthermore, a deallocation must not be defined for this
	// allocation entry and a parent allocation scope must exist.
	if (!isSmallAlloc(alloc) \|\| dealloc \|\|
	!hasAllocationScope(alloc, aliases))
	continue;

	Operation *startOperation = BufferPlacementAllocs::getStartOperation(
	alloc, alloc.getParentBlock(), liveness);
	// Build a new alloca that is associated with its parent
	// `AutomaticAllocationScope` determined during the initialization phase.
	OpBuilder builder(startOperation);
	Operation *allocOp = alloc.getDefiningOp();
	Operation *alloca = builder.create<memref::AllocaOp>(
	alloc.getLoc(), alloc.getType().cast<MemRefType>(),
	allocOp->getOperands());

	// Replace the original alloc by a newly created alloca.
	allocOp->replaceAllUsesWith(alloca);
	allocOp->erase();
	}
	}
	};

	//===----------------------------------------------------------------------===//
	// BufferOptimizationPasses
	//===----------------------------------------------------------------------===//

	/// The buffer hoisting pass that hoists allocation nodes into dominating
	/// blocks.
	struct BufferHoistingPass : BufferHoistingBase<BufferHoistingPass> {

	void runOnFunction() override {
	// Hoist all allocations into dominator blocks.
	BufferAllocationHoisting<BufferAllocationHoistingState> optimizer(
	getFunction());
	optimizer.hoist();
	}
	};

	/// The buffer loop hoisting pass that hoists allocation nodes out of loops.
	struct BufferLoopHoistingPass : BufferLoopHoistingBase<BufferLoopHoistingPass> {

	void runOnFunction() override {
	// Hoist all allocations out of loops.
	BufferAllocationHoisting<BufferAllocationLoopHoistingState> optimizer(
	getFunction());
	optimizer.hoist();
	}
	};

	/// The promote buffer to stack pass that tries to convert alloc nodes into
	/// alloca nodes.
	class PromoteBuffersToStackPass
	: public PromoteBuffersToStackBase<PromoteBuffersToStackPass> {
	public:
	PromoteBuffersToStackPass(unsigned maxAllocSizeInBytes,
	unsigned bitwidthOfIndexType,
	unsigned maxRankOfAllocatedMemRef) {
	this->maxAllocSizeInBytes = maxAllocSizeInBytes;
	this->bitwidthOfIndexType = bitwidthOfIndexType;
	this->maxRankOfAllocatedMemRef = maxRankOfAllocatedMemRef;
	}

	explicit PromoteBuffersToStackPass(std::function<bool(Value)> isSmallAlloc)
	: isSmallAlloc(std::move(isSmallAlloc)) {}

	LogicalResult initialize(MLIRContext *context) override {
	if (isSmallAlloc == nullptr) {
	isSmallAlloc = [=](Value alloc) {
	return defaultIsSmallAlloc(alloc, maxAllocSizeInBytes,
	bitwidthOfIndexType,
	maxRankOfAllocatedMemRef);
	};
	}
	return success();
	}

	void runOnFunction() override {
	// Move all allocation nodes and convert candidates into allocas.
	BufferPlacementPromotion optimizer(getFunction());
	optimizer.promote(isSmallAlloc);
	}

	private:
	std::function<bool(Value)> isSmallAlloc;
	};

	} // end anonymous namespace

	std::unique_ptr<Pass> mlir::createBufferHoistingPass() {
	return std::make_unique<BufferHoistingPass>();
	}

	std::unique_ptr<Pass> mlir::createBufferLoopHoistingPass() {
	return std::make_unique<BufferLoopHoistingPass>();
	}

	std::unique_ptr<Pass>
	mlir::createPromoteBuffersToStackPass(unsigned maxAllocSizeInBytes,
	unsigned bitwidthOfIndexType,
	unsigned maxRankOfAllocatedMemRef) {
	return std::make_unique<PromoteBuffersToStackPass>(
	maxAllocSizeInBytes, bitwidthOfIndexType, maxRankOfAllocatedMemRef);
	}

	std::unique_ptr<Pass>
	mlir::createPromoteBuffersToStackPass(std::function<bool(Value)> isSmallAlloc) {
	return std::make_unique<PromoteBuffersToStackPass>(std::move(isSmallAlloc));
	}