BufferPlacement.cpp 44.5 KB
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//===- BufferPlacement.cpp - the impl for buffer placement ---------------===//
//
// 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 computing correct alloc and dealloc positions.
// Furthermore, buffer placement also adds required new alloc and copy
// operations to ensure that all buffers are deallocated.The main class is the
// BufferPlacementPass class that implements the underlying algorithm. In order
// to put allocations and deallocations at safe positions, it is significantly
// important to put them into the correct blocks. However, the liveness analysis
// does not pay attention to aliases, which can occur due to branches (and their
// associated block arguments) in general. For this purpose, BufferPlacement
// firstly finds all possible aliases for a single value (using the
// BufferPlacementAliasAnalysis class). Consider the following example:
//
// ^bb0(%arg0):
//   cond_br %cond, ^bb1, ^bb2
// ^bb1:
//   br ^exit(%arg0)
// ^bb2:
//   %new_value = ...
//   br ^exit(%new_value)
// ^exit(%arg1):
//   return %arg1;
//
// Using liveness information on its own would cause us to place the allocs and
// deallocs in the wrong block. This is due to the fact that %new_value will not
// be liveOut of its block. Instead, we can place the alloc for %new_value
// in bb0 and its associated dealloc in exit. Alternatively, the alloc can stay
// (or even has to stay due to additional dependencies) at this location and we
// have to free the buffer in the same block, because it cannot be freed in the
// post dominator. However, this requires a new copy buffer for %arg1 that will
// contain the actual contents. Using the class BufferPlacementAliasAnalysis, we
// will find out that %new_value has a potential alias %arg1. In order to find
// the dealloc position we have to find all potential aliases, iterate over
// their uses and find the common post-dominator block (note that additional
// copies and buffers remove potential aliases and will influence the placement
// of the deallocs). In all cases, the computed block can be safely used to free
// the %new_value buffer (may be exit or bb2) as it will die and we can use
// liveness information to determine the exact operation after which we have to
// insert the dealloc. Finding the alloc position is similar and non-obvious.
// However, the algorithm supports moving allocs to other places and introducing
// copy buffers and placing deallocs in safe places to ensure that all buffers
// will be freed in the end.
//
// TODO:
// The current implementation does not support explicit-control-flow loops and
// the resulting code will be invalid with respect to program semantics.
// However, structured control-flow loops are fully supported. Furthermore, it
// doesn't accept functions which return buffers already.
//
//===----------------------------------------------------------------------===//

#include "mlir/Transforms/BufferPlacement.h"
#include "PassDetail.h"
#include "mlir/Dialect/Linalg/IR/LinalgOps.h"
#include "mlir/IR/Operation.h"
#include "mlir/Pass/Pass.h"
#include "mlir/Transforms/Passes.h"
#include "llvm/ADT/SetOperations.h"

using namespace mlir;

/// Walks over all immediate return-like terminators in the given region.
template <typename FuncT>
static void walkReturnOperations(Region *region, const FuncT &func) {
  for (Block &block : *region)
    for (Operation &operation : block) {
      // Skip non-return-like terminators.
      if (operation.hasTrait<OpTrait::ReturnLike>())
        func(&operation);
    }
}

/// Wrapper for the actual `RegionBranchOpInterface.getSuccessorRegions`
/// function that initializes the required `operandAttributes` array.
static void getSuccessorRegions(RegionBranchOpInterface regionInterface,
                                llvm::Optional<unsigned> index,
                                SmallVectorImpl<RegionSuccessor> &successors) {
  // Create a list of null attributes for each operand to comply with the
  // `getSuccessorRegions` interface definition that requires a single
  // attribute per operand.
  SmallVector<Attribute, 2> operandAttributes(
      regionInterface.getOperation()->getNumOperands());

  // Get all successor regions using the temporarily allocated
  // `operandAttributes`.
  regionInterface.getSuccessorRegions(index, operandAttributes, successors);
}

namespace {
//===----------------------------------------------------------------------===//
// BufferPlacementAliasAnalysis
//===----------------------------------------------------------------------===//

/// A straight-forward alias analysis which ensures that all aliases of all
/// values will be determined. This is a requirement for the BufferPlacement
/// class since you need to determine safe positions to place alloc and
/// deallocs.
class BufferPlacementAliasAnalysis {
public:
  using ValueSetT = SmallPtrSet<Value, 16>;
  using ValueMapT = llvm::DenseMap<Value, ValueSetT>;

public:
  /// Constructs a new alias analysis using the op provided.
  BufferPlacementAliasAnalysis(Operation *op) { build(op); }

  /// Find all immediate aliases this value could potentially have.
  ValueMapT::const_iterator find(Value value) const {
    return aliases.find(value);
  }

  /// Returns the end iterator that can be used in combination with find.
  ValueMapT::const_iterator end() const { return aliases.end(); }

  /// Find all immediate and indirect aliases this value could potentially
  /// have. Note that the resulting set will also contain the value provided as
  /// it is an alias of itself.
  ValueSetT resolve(Value value) const {
    ValueSetT result;
    resolveRecursive(value, result);
    return result;
  }

  /// Removes the given values from all alias sets.
  void remove(const SmallPtrSetImpl<Value> &aliasValues) {
    for (auto &entry : aliases)
      llvm::set_subtract(entry.second, aliasValues);
  }

private:
  /// Recursively determines alias information for the given value. It stores
  /// all newly found potential aliases in the given result set.
  void resolveRecursive(Value value, ValueSetT &result) const {
    if (!result.insert(value).second)
      return;
    auto it = aliases.find(value);
    if (it == aliases.end())
      return;
    for (Value alias : it->second)
      resolveRecursive(alias, result);
  }

  /// This function constructs a mapping from values to its immediate aliases.
  /// It iterates over all blocks, gets their predecessors, determines the
  /// values that will be passed to the corresponding block arguments and
  /// inserts them into the underlying map. Furthermore, it wires successor
  /// regions and branch-like return operations from nested regions.
  void build(Operation *op) {
    // Registers all aliases of the given values.
    auto registerAliases = [&](auto values, auto aliases) {
      for (auto entry : llvm::zip(values, aliases))
        this->aliases[std::get<0>(entry)].insert(std::get<1>(entry));
    };

    // Add additional aliases created by view changes to the alias list.
    op->walk([&](ViewLikeOpInterface viewInterface) {
      aliases[viewInterface.getViewSource()].insert(
          viewInterface.getOperation()->getResult(0));
    });

    // Query all branch interfaces to link block argument aliases.
    op->walk([&](BranchOpInterface branchInterface) {
      Block *parentBlock = branchInterface.getOperation()->getBlock();
      for (auto it = parentBlock->succ_begin(), e = parentBlock->succ_end();
           it != e; ++it) {
        // Query the branch op interface to get the successor operands.
        auto successorOperands =
            branchInterface.getSuccessorOperands(it.getIndex());
        if (!successorOperands.hasValue())
          continue;
        // Build the actual mapping of values to their immediate aliases.
        registerAliases(successorOperands.getValue(), (*it)->getArguments());
      }
    });

    // Query the RegionBranchOpInterface to find potential successor regions.
    op->walk([&](RegionBranchOpInterface regionInterface) {
      // Extract all entry regions and wire all initial entry successor inputs.
      SmallVector<RegionSuccessor, 2> entrySuccessors;
      getSuccessorRegions(regionInterface, /*index=*/llvm::None,
                          entrySuccessors);
      for (RegionSuccessor &entrySuccessor : entrySuccessors) {
        // Wire the entry region's successor arguments with the initial
        // successor inputs.
        assert(entrySuccessor.getSuccessor() &&
               "Invalid entry region without an attached successor region");
        registerAliases(regionInterface.getSuccessorEntryOperands(
                            entrySuccessor.getSuccessor()->getRegionNumber()),
                        entrySuccessor.getSuccessorInputs());
      }

      // Wire flow between regions and from region exits.
      for (Region &region : regionInterface.getOperation()->getRegions()) {
        // Iterate over all successor region entries that are reachable from the
        // current region.
        SmallVector<RegionSuccessor, 2> successorRegions;
        getSuccessorRegions(regionInterface, region.getRegionNumber(),
                            successorRegions);
        for (RegionSuccessor &successorRegion : successorRegions) {
          // Iterate over all immediate terminator operations and wire the
          // successor inputs with the operands of each terminator.
          walkReturnOperations(&region, [&](Operation *terminator) {
            registerAliases(terminator->getOperands(),
                            successorRegion.getSuccessorInputs());
          });
        }
      }
    });
  }

  /// Maps values to all immediate aliases this value can have.
  ValueMapT aliases;
};

//===----------------------------------------------------------------------===//
// Backedges
//===----------------------------------------------------------------------===//

/// A straight-forward program analysis which detects loop backedges induced by
/// explicit control flow.
class Backedges {
public:
  using BlockSetT = SmallPtrSet<Block *, 16>;
  using BackedgeSetT = llvm::DenseSet<std::pair<Block *, Block *>>;

public:
  /// Constructs a new backedges analysis using the op provided.
  Backedges(Operation *op) { recurse(op, op->getBlock()); }

  /// Returns the number of backedges formed by explicit control flow.
  size_t size() const { return edgeSet.size(); }

  /// Returns the start iterator to loop over all backedges.
  BackedgeSetT::const_iterator begin() const { return edgeSet.begin(); }

  /// Returns the end iterator to loop over all backedges.
  BackedgeSetT::const_iterator end() const { return edgeSet.end(); }

private:
  /// Enters the current block and inserts a backedge into the `edgeSet` if we
  /// have already visited the current block. The inserted edge links the given
  /// `predecessor` with the `current` block.
  bool enter(Block &current, Block *predecessor) {
    bool inserted = visited.insert(&current).second;
    if (!inserted)
      edgeSet.insert(std::make_pair(predecessor, &current));
    return inserted;
  }

  /// Leaves the current block.
  void exit(Block &current) { visited.erase(&current); }

  /// Recurses into the given operation while taking all attached regions into
  /// account.
  void recurse(Operation *op, Block *predecessor) {
    Block *current = op->getBlock();
    // If the current op implements the `BranchOpInterface`, there can be
    // cycles in the scope of all successor blocks.
    if (isa<BranchOpInterface>(op)) {
      for (Block *succ : current->getSuccessors())
        recurse(*succ, current);
    }
    // Recurse into all distinct regions and check for explicit control-flow
    // loops.
    for (Region &region : op->getRegions())
      recurse(region.front(), current);
  }

  /// Recurses into explicit control-flow structures that are given by
  /// the successor relation defined on the block level.
  void recurse(Block &block, Block *predecessor) {
    // Try to enter the current block. If this is not possible, we are
    // currently processing this block and can safely return here.
    if (!enter(block, predecessor))
      return;

    // Recurse into all operations and successor blocks.
    for (auto &op : block.getOperations())
      recurse(&op, predecessor);

    // Leave the current block.
    exit(block);
  }

  /// Stores all blocks that are currently visited and on the processing stack.
  BlockSetT visited;

  /// Stores all backedges in the format (source, target).
  BackedgeSetT edgeSet;
};

//===----------------------------------------------------------------------===//
// BufferPlacement
//===----------------------------------------------------------------------===//

// The main buffer placement analysis used to place allocs, copies and deallocs.
class BufferPlacement {
public:
  using ValueSetT = BufferPlacementAliasAnalysis::ValueSetT;

  /// An intermediate representation of a single allocation node.
  struct AllocEntry {
    /// A reference to the associated allocation node.
    Value allocValue;

    /// The associated placement block in which the allocation should be
    /// performed.
    Block *placementBlock;

    /// The associated dealloc operation (if any).
    Operation *deallocOperation;
  };

  using AllocEntryList = SmallVector<AllocEntry, 8>;

public:
  BufferPlacement(Operation *op)
      : operation(op), aliases(op), liveness(op), dominators(op),
        postDominators(op) {
    // Gather all allocation nodes
    initBlockMapping();
  }

  /// Performs the actual placement/creation of all alloc, copy and dealloc
  /// nodes.
  void place() {
    // Place all allocations.
    placeAllocs();
    // Add additional allocations and copies that are required.
    introduceCopies();
    // Find all associated dealloc nodes.
    findDeallocs();
    // Place deallocations for all allocation entries.
    placeDeallocs();
  }

private:
  /// Initializes the internal block mapping by discovering allocation nodes. It
  /// maps all allocation nodes to their initial block in which they can be
  /// safely allocated.
  void initBlockMapping() {
    operation->walk([&](MemoryEffectOpInterface opInterface) {
      // Try to find a single allocation result.
      SmallVector<MemoryEffects::EffectInstance, 2> effects;
      opInterface.getEffects(effects);

      SmallVector<MemoryEffects::EffectInstance, 2> allocateResultEffects;
      llvm::copy_if(
          effects, std::back_inserter(allocateResultEffects),
          [=](MemoryEffects::EffectInstance &it) {
            Value value = it.getValue();
            return isa<MemoryEffects::Allocate>(it.getEffect()) && value &&
                   value.isa<OpResult>() &&
                   it.getResource() !=
                       SideEffects::AutomaticAllocationScopeResource::get();
          });
      // If there is one result only, we will be able to move the allocation and
      // (possibly existing) deallocation ops.
      if (allocateResultEffects.size() != 1)
        return;
      // Get allocation result.
      auto allocResult = allocateResultEffects[0].getValue().cast<OpResult>();
      // Find the initial allocation block and register this result.
      allocs.push_back(
          {allocResult, getInitialAllocBlock(allocResult), nullptr});
    });
  }

  /// Computes a valid allocation position in a dominator (if possible) for the
  /// given allocation result.
  Block *getInitialAllocBlock(OpResult result) {
    // Get all allocation operands as these operands are important for the
    // allocation operation.
    Operation *owner = result.getOwner();
    auto operands = owner->getOperands();
    Block *dominator;
    if (operands.size() < 1)
      dominator =
          findCommonDominator(result, aliases.resolve(result), dominators);
    else {
      // If this node has dependencies, check all dependent nodes with respect
      // to a common post dominator in which all values are available.
      ValueSetT dependencies(++operands.begin(), operands.end());
      dominator =
          findCommonDominator(*operands.begin(), dependencies, postDominators);
    }

    // Do not move allocs out of their parent regions to keep them local.
    if (dominator->getParent() != owner->getParentRegion())
      return &owner->getParentRegion()->front();
    return dominator;
  }

  /// Finds correct alloc positions according to the algorithm described at
  /// the top of the file for all alloc nodes that can be handled by this
  /// analysis.
  void placeAllocs() const {
    for (const AllocEntry &entry : allocs) {
      Value alloc = entry.allocValue;
      // Get the actual block to place the alloc and get liveness information
      // for the placement block.
      Block *placementBlock = entry.placementBlock;
      // We have to ensure that we place the alloc before its first use in this
      // block.
      const LivenessBlockInfo *livenessInfo =
          liveness.getLiveness(placementBlock);
      Operation *startOperation = livenessInfo->getStartOperation(alloc);
      // Check whether the start operation lies in the desired placement block.
      // If not, we will use the terminator as this is the last operation in
      // this block.
      if (startOperation->getBlock() != placementBlock)
        startOperation = placementBlock->getTerminator();

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

  /// Introduces required allocs and copy operations to avoid memory leaks.
  void introduceCopies() {
    // Initialize the set of values that require a dedicated memory free
    // operation since their operands cannot be safely deallocated in a post
    // dominator.
    SmallPtrSet<Value, 8> valuesToFree;
    llvm::SmallDenseSet<std::tuple<Value, Block *>> visitedValues;
    SmallVector<std::tuple<Value, Block *>, 8> toProcess;

    // Check dominance relation for proper dominance properties. If the given
    // value node does not dominate an alias, we will have to create a copy in
    // order to free all buffers that can potentially leak into a post
    // dominator.
    auto findUnsafeValues = [&](Value source, Block *definingBlock) {
      auto it = aliases.find(source);
      if (it == aliases.end())
        return;
      for (Value value : it->second) {
        if (valuesToFree.count(value) > 0)
          continue;
        Block *parentBlock = value.getParentBlock();
        // Check whether we have to free this particular block argument or
        // generic value. We have to free the current alias if it is either
        // defined in a non-dominated block or it is defined in the same block
        // but the current value is not dominated by the source value.
        if (!dominators.dominates(definingBlock, parentBlock) ||
            (definingBlock == parentBlock && value.isa<BlockArgument>())) {
          toProcess.emplace_back(value, parentBlock);
          valuesToFree.insert(value);
        } else if (visitedValues.insert(std::make_tuple(value, definingBlock))
                       .second)
          toProcess.emplace_back(value, definingBlock);
      }
    };

    // Detect possibly unsafe aliases starting from all allocations.
    for (auto &entry : allocs)
      findUnsafeValues(entry.allocValue, entry.placementBlock);

    // Try to find block arguments that require an explicit free operation
    // until we reach a fix point.
    while (!toProcess.empty()) {
      auto current = toProcess.pop_back_val();
      findUnsafeValues(std::get<0>(current), std::get<1>(current));
    }

    // Update buffer aliases to ensure that we free all buffers and block
    // arguments at the correct locations.
    aliases.remove(valuesToFree);

    // Add new allocs and additional copy operations.
    for (Value value : valuesToFree) {
      if (auto blockArg = value.dyn_cast<BlockArgument>())
        introduceBlockArgCopy(blockArg);
      else
        introduceValueCopyForRegionResult(value);

      // Register the value to require a final dealloc. Note that we do not have
      // to assign a block here since we do not want to move the allocation node
      // to another location.
      allocs.push_back({value, nullptr, nullptr});
    }
  }

  /// Introduces temporary allocs in all predecessors and copies the source
  /// values into the newly allocated buffers.
  void introduceBlockArgCopy(BlockArgument blockArg) {
    // Allocate a buffer for the current block argument in the block of
    // the associated value (which will be a predecessor block by
    // definition).
    Block *block = blockArg.getOwner();
    for (auto it = block->pred_begin(), e = block->pred_end(); it != e; ++it) {
      // Get the terminator and the value that will be passed to our
      // argument.
      Operation *terminator = (*it)->getTerminator();
      auto branchInterface = cast<BranchOpInterface>(terminator);
      // Query the associated source value.
      Value sourceValue =
          branchInterface.getSuccessorOperands(it.getSuccessorIndex())
              .getValue()[blockArg.getArgNumber()];
      // Create a new alloc and copy at the current location of the terminator.
      Value alloc = introduceBufferCopy(sourceValue, terminator);
      // Wire new alloc and successor operand.
      auto mutableOperands =
          branchInterface.getMutableSuccessorOperands(it.getSuccessorIndex());
      if (!mutableOperands.hasValue())
        terminator->emitError() << "terminators with immutable successor "
                                   "operands are not supported";
      else
        mutableOperands.getValue()
            .slice(blockArg.getArgNumber(), 1)
            .assign(alloc);
    }

    // Check whether the block argument has implicitly defined predecessors via
    // the RegionBranchOpInterface. This can be the case if the current block
    // argument belongs to the first block in a region and the parent operation
    // implements the RegionBranchOpInterface.
    Region *argRegion = block->getParent();
    Operation *parentOp = argRegion->getParentOp();
    RegionBranchOpInterface regionInterface;
    if (!argRegion || &argRegion->front() != block ||
        !(regionInterface = dyn_cast<RegionBranchOpInterface>(parentOp)))
      return;

    introduceCopiesForRegionSuccessors(
        regionInterface, argRegion->getParentOp()->getRegions(), blockArg,
        [&](RegionSuccessor &successorRegion) {
          // Find a predecessor of our argRegion.
          return successorRegion.getSuccessor() == argRegion;
        });

    // Check whether the block argument belongs to an entry region of the
    // parent operation. In this case, we have to introduce an additional copy
    // for buffer that is passed to the argument.
    SmallVector<RegionSuccessor, 2> successorRegions;
    getSuccessorRegions(regionInterface, llvm::None, successorRegions);
    auto *it =
        llvm::find_if(successorRegions, [&](RegionSuccessor &successorRegion) {
          return successorRegion.getSuccessor() == argRegion;
        });
    if (it == successorRegions.end())
      return;

    // Determine the actual operand to introduce a copy for and rewire the
    // operand to point to the copy instead.
    Value operand =
        regionInterface.getSuccessorEntryOperands(argRegion->getRegionNumber())
            [llvm::find(it->getSuccessorInputs(), blockArg).getIndex()];
    Value copy = introduceBufferCopy(operand, parentOp);

    auto op = llvm::find(parentOp->getOperands(), operand);
    assert(op != parentOp->getOperands().end() &&
           "parentOp does not contain operand");
    parentOp->setOperand(op.getIndex(), copy);
  }

  /// Introduces temporary allocs in front of all associated nested-region
  /// terminators and copies the source values into the newly allocated buffers.
  void introduceValueCopyForRegionResult(Value value) {
    // Get the actual result index in the scope of the parent terminator.
    Operation *operation = value.getDefiningOp();
    auto regionInterface = cast<RegionBranchOpInterface>(operation);
    // Filter successors that return to the parent operation.
    auto regionPredicate = [&](RegionSuccessor &successorRegion) {
      // If the RegionSuccessor has no associated successor, it will return to
      // its parent operation.
      return !successorRegion.getSuccessor();
    };
    // Introduce a copy for all region "results" that are returned to the parent
    // operation. This is required since the parent's result value has been
    // considered critical. Therefore, the algorithm assumes that a copy of a
    // previously allocated buffer is returned by the operation (like in the
    // case of a block argument).
    introduceCopiesForRegionSuccessors(regionInterface, operation->getRegions(),
                                       value, regionPredicate);
  }

  /// Introduces buffer copies for all terminators in the given regions. The
  /// regionPredicate is applied to every successor region in order to restrict
  /// the copies to specific regions.
  template <typename TPredicate>
  void introduceCopiesForRegionSuccessors(
      RegionBranchOpInterface regionInterface, MutableArrayRef<Region> regions,
      Value argValue, const TPredicate &regionPredicate) {
    for (Region &region : regions) {
      // Query the regionInterface to get all successor regions of the current
      // one.
      SmallVector<RegionSuccessor, 2> successorRegions;
      getSuccessorRegions(regionInterface, region.getRegionNumber(),
                          successorRegions);
      // Try to find a matching region successor.
      RegionSuccessor *regionSuccessor =
          llvm::find_if(successorRegions, regionPredicate);
      if (regionSuccessor == successorRegions.end())
        continue;
      // Get the operand index in the context of the current successor input
      // bindings.
      size_t operandIndex =
          llvm::find(regionSuccessor->getSuccessorInputs(), argValue)
              .getIndex();

      // Iterate over all immediate terminator operations to introduce
      // new buffer allocations. Thereby, the appropriate terminator operand
      // will be adjusted to point to the newly allocated buffer instead.
      walkReturnOperations(&region, [&](Operation *terminator) {
        // Extract the source value from the current terminator.
        Value sourceValue = terminator->getOperand(operandIndex);
        // Create a new alloc at the current location of the terminator.
        Value alloc = introduceBufferCopy(sourceValue, terminator);
        // Wire alloc and terminator operand.
        terminator->setOperand(operandIndex, alloc);
      });
    }
  }

  /// Creates a new memory allocation for the given source value and copies
  /// its content into the newly allocated buffer. The terminator operation is
  /// used to insert the alloc and copy operations at the right places.
  Value introduceBufferCopy(Value sourceValue, Operation *terminator) {
    // Avoid multiple copies of the same source value. This can happen in the
    // presence of loops when a branch acts as a backedge while also having
    // another successor that returns to its parent operation. Note: that
    // copying copied buffers can introduce memory leaks since the invariant of
    // BufferPlacement assumes that a buffer will be only copied once into a
    // temporary buffer. Hence, the construction of copy chains introduces
    // additional allocations that are not tracked automatically by the
    // algorithm.
    if (copiedValues.contains(sourceValue))
      return sourceValue;
    // Create a new alloc at the current location of the terminator.
    auto memRefType = sourceValue.getType().cast<MemRefType>();
    OpBuilder builder(terminator);

    // Extract information about dynamically shaped types by
    // extracting their dynamic dimensions.
    SmallVector<Value, 4> dynamicOperands;
    for (auto shapeElement : llvm::enumerate(memRefType.getShape())) {
      if (!ShapedType::isDynamic(shapeElement.value()))
        continue;
      dynamicOperands.push_back(builder.create<DimOp>(
          terminator->getLoc(), sourceValue, shapeElement.index()));
    }

    // TODO: provide a generic interface to create dialect-specific
    // Alloc and CopyOp nodes.
    auto alloc = builder.create<AllocOp>(terminator->getLoc(), memRefType,
                                         dynamicOperands);

    // Create a new copy operation that copies to contents of the old
    // allocation to the new one.
    builder.create<linalg::CopyOp>(terminator->getLoc(), sourceValue, alloc);

    // Remember the copy of original source value.
    copiedValues.insert(alloc);
    return alloc;
  }

  /// Finds associated deallocs that can be linked to our allocation nodes (if
  /// any).
  void findDeallocs() {
    for (auto &entry : allocs) {
      auto userIt =
          llvm::find_if(entry.allocValue.getUsers(), [&](Operation *user) {
            auto effectInterface = dyn_cast<MemoryEffectOpInterface>(user);
            if (!effectInterface)
              return false;
            // Try to find a free effect that is applied to one of our values
            // that will be automatically freed by our pass.
            SmallVector<MemoryEffects::EffectInstance, 2> effects;
            effectInterface.getEffectsOnValue(entry.allocValue, effects);
            return llvm::any_of(
                effects, [&](MemoryEffects::EffectInstance &it) {
                  return isa<MemoryEffects::Free>(it.getEffect());
                });
          });
      // Assign the associated dealloc operation (if any).
      if (userIt != entry.allocValue.user_end())
        entry.deallocOperation = *userIt;
    }
  }

  /// Finds correct dealloc positions according to the algorithm described at
  /// the top of the file for all alloc nodes and block arguments that can be
  /// handled by this analysis.
  void placeDeallocs() const {
    // Move or insert deallocs using the previously computed information.
    // These deallocations will be linked to their associated allocation nodes
    // since they don't have any aliases that can (potentially) increase their
    // liveness.
    for (const AllocEntry &entry : allocs) {
      Value alloc = entry.allocValue;
      auto aliasesSet = aliases.resolve(alloc);
      assert(aliasesSet.size() > 0 && "must contain at least one alias");

      // Determine the actual block to place the dealloc and get liveness
      // information.
      Block *placementBlock =
          findCommonDominator(alloc, aliasesSet, postDominators);
      const LivenessBlockInfo *livenessInfo =
          liveness.getLiveness(placementBlock);

      // We have to ensure that the dealloc will be after the last use of all
      // aliases of the given value. We first assume that there are no uses in
      // the placementBlock and that we can safely place the dealloc at the
      // beginning.
      Operation *endOperation = &placementBlock->front();
      // Iterate over all aliases and ensure that the endOperation will point
      // to the last operation of all potential aliases in the placementBlock.
      for (Value alias : aliasesSet) {
        Operation *aliasEndOperation =
            livenessInfo->getEndOperation(alias, endOperation);
        // Check whether the aliasEndOperation lies in the desired block and
        // whether it is behind the current endOperation. If yes, this will be
        // the new endOperation.
        if (aliasEndOperation->getBlock() == placementBlock &&
            endOperation->isBeforeInBlock(aliasEndOperation))
          endOperation = aliasEndOperation;
      }
      // endOperation is the last operation behind which we can safely store
      // the dealloc taking all potential aliases into account.

      // If there is an existing dealloc, move it to the right place.
      if (entry.deallocOperation) {
        entry.deallocOperation->moveAfter(endOperation);
      } else {
        // If the Dealloc position is at the terminator operation of the
        // block, then the value should escape from a deallocation.
        Operation *nextOp = endOperation->getNextNode();
        if (!nextOp)
          continue;
        // If there is no dealloc node, insert one in the right place.
        OpBuilder builder(nextOp);
        builder.create<DeallocOp>(alloc.getLoc(), alloc);
      }
    }
  }

  /// Finds a common dominator for the given value while taking the positions
  /// of the values in the value set into account. It supports dominator and
  /// post-dominator analyses via template arguments.
  template <typename DominatorT>
  Block *findCommonDominator(Value value, const ValueSetT &values,
                             const DominatorT &doms) const {
    // Start with the current block the value is defined in.
    Block *dom = value.getParentBlock();
    // Iterate over all aliases and their uses to find a safe placement block
    // according to the given dominator information.
    for (Value childValue : values)
      for (Operation *user : childValue.getUsers()) {
        // Move upwards in the dominator tree to find an appropriate
        // dominator block that takes the current use into account.
        dom = doms.findNearestCommonDominator(dom, user->getBlock());
      }
    return dom;
  }

  /// The operation this transformation was constructed from.
  Operation *operation;

  /// Alias information that can be updated during the insertion of copies.
  BufferPlacementAliasAnalysis aliases;

  /// Maps allocation nodes to their associated blocks.
  AllocEntryList allocs;

  // Stores already copied allocations to avoid additional copies of copies.
  ValueSetT copiedValues;

  /// The underlying liveness analysis to compute fine grained information
  /// about alloc and dealloc positions.
  Liveness liveness;

  /// The dominator analysis to place deallocs in the appropriate blocks.
  DominanceInfo dominators;

  /// The post dominator analysis to place deallocs in the appropriate blocks.
  PostDominanceInfo postDominators;
};

//===----------------------------------------------------------------------===//
// BufferPlacementPass
//===----------------------------------------------------------------------===//

/// The actual buffer placement pass that moves alloc and dealloc nodes into
/// the right positions. It uses the algorithm described at the top of the
/// file.
struct BufferPlacementPass : BufferPlacementBase<BufferPlacementPass> {

  void runOnFunction() override {
    // Ensure that there are supported loops only.
    Backedges backedges(getFunction());
    if (backedges.size()) {
      getFunction().emitError(
          "Structured control-flow loops are supported only.");
      return;
    }

    // Place all required alloc, copy and dealloc nodes.
    BufferPlacement placement(getFunction());
    placement.place();
  }
};

} // end anonymous namespace

//===----------------------------------------------------------------------===//
// BufferAssignmentTypeConverter
//===----------------------------------------------------------------------===//

/// Registers conversions into BufferAssignmentTypeConverter
BufferAssignmentTypeConverter::BufferAssignmentTypeConverter() {
  // Keep all types unchanged.
  addConversion([](Type type) { return type; });
  // Convert RankedTensorType to MemRefType.
  addConversion([](RankedTensorType type) {
    return (Type)MemRefType::get(type.getShape(), type.getElementType());
  });
  // Convert UnrankedTensorType to UnrankedMemRefType.
  addConversion([](UnrankedTensorType type) {
    return (Type)UnrankedMemRefType::get(type.getElementType(), 0);
  });
}

/// This method tries to decompose a value of a certain type using provided
/// decompose callback functions. If it is unable to do so, the original value
/// is returned.
void BufferAssignmentTypeConverter::tryDecomposeValue(
    OpBuilder &builder, Location loc, Type type, Value value,
    SmallVectorImpl<Value> &results) {
  for (auto conversion : decomposeValueConversions)
    if (conversion(builder, loc, type, value, results) != llvm::None)
      return;
  results.push_back(value);
}

/// This method tries to decompose a type using provided decompose callback
/// functions. If it is unable to do so, the original type is returned.
void BufferAssignmentTypeConverter::tryDecomposeType(
    Type type, SmallVectorImpl<Type> &types) {
  for (auto conversion : decomposeTypeConversions)
    if (conversion(type, types) != llvm::None)
      return;
  types.push_back(type);
}

/// This method returns ResultConversionKind for the input type.
BufferAssignmentTypeConverter::ResultConversionKind
BufferAssignmentTypeConverter::getResultConversionKind(Type origin,
                                                       Type converted) {
  for (auto conversion : resultTypeConversions) {
    auto res = conversion(origin, converted);
    if (res != llvm::None)
      return res.getValue();
  }
  return KeepAsFunctionResult;
}

//===----------------------------------------------------------------------===//
// BufferAssignmentFuncOpConverter
//===----------------------------------------------------------------------===//

/// Performs the actual function signature rewriting step.
LogicalResult BufferAssignmentFuncOpConverter::matchAndRewrite(
    mlir::FuncOp funcOp, ArrayRef<Value> operands,
    ConversionPatternRewriter &rewriter) const {
  auto funcType = funcOp.getType();

  // Convert function arguments using the provided TypeConverter.
  TypeConverter::SignatureConversion conversion(funcType.getNumInputs());
  for (auto argType : llvm::enumerate(funcType.getInputs())) {
    SmallVector<Type, 2> decomposedTypes, convertedTypes;
    converter->tryDecomposeType(argType.value(), decomposedTypes);
    converter->convertTypes(decomposedTypes, convertedTypes);
    conversion.addInputs(argType.index(), convertedTypes);
  }

  // Convert the result types of the function.
  SmallVector<Type, 2> newResultTypes;
  newResultTypes.reserve(funcOp.getNumResults());
  for (Type resultType : funcType.getResults()) {
    SmallVector<Type, 2> originTypes;
    converter->tryDecomposeType(resultType, originTypes);
    for (auto origin : originTypes) {
      Type converted = converter->convertType(origin);
      auto kind = converter->getResultConversionKind(origin, converted);
      if (kind == BufferAssignmentTypeConverter::AppendToArgumentsList)
        conversion.addInputs(converted);
      else
        // kind = BufferAssignmentTypeConverter::KeepAsFunctionResult
        newResultTypes.push_back(converted);
    }
  }

  if (failed(rewriter.convertRegionTypes(&funcOp.getBody(), *converter,
                                         &conversion)))
    return failure();

  // Update the signature of the function.
  rewriter.updateRootInPlace(funcOp, [&] {
    funcOp.setType(rewriter.getFunctionType(conversion.getConvertedTypes(),
                                            newResultTypes));
  });
  return success();
}

//===----------------------------------------------------------------------===//
// BufferAssignmentCallOpConverter
//===----------------------------------------------------------------------===//

/// Performs the actual rewriting step.
LogicalResult BufferAssignmentCallOpConverter::matchAndRewrite(
    CallOp callOp, ArrayRef<Value> operands,
    ConversionPatternRewriter &rewriter) const {

  // This class represents a mapping from a result to a list of values and some
  // results that have not yet constructed. Instead, the indices of these
  // results in the operation that will be constructed are known. They will be
  // replaced with the actual values when they are available. The order of
  // adding to this mapping is important.
  class ResultMapping {
  public:
    ResultMapping() { order = 0; };

    /// Add an available value to the mapping.
    void addMapping(Value value) {
      toValuesMapping.push_back({order++, value});
    }

    /// Add the index of unavailble result value to the mapping.
    void addMapping(unsigned index) {
      toIndicesMapping.push_back({order++, index});
    }

    /// This method returns the mapping values list. The unknown result values
    /// that only their indicies are available are replaced with their values.
    void getMappingValues(ValueRange valuesToReplaceIndices,
                          SmallVectorImpl<Value> &values) {
      // Append available values to the list.
      SmallVector<std::pair<unsigned, Value>, 2> res(toValuesMapping.begin(),
                                                     toValuesMapping.end());
      // Replace the indices with the actual values.
      llvm::for_each(
          toIndicesMapping, [&](const std::pair<unsigned, unsigned> &entry) {
            assert(entry.second < valuesToReplaceIndices.size() &&
                   "The value index is out of range.");
            res.push_back({entry.first, valuesToReplaceIndices[entry.second]});
          });
      // Sort the values based on their adding orders.
      llvm::sort(res, [](const std::pair<unsigned, Value> &v1,
                         const std::pair<unsigned, Value> &v2) {
        return v1.first < v2.first;
      });
      // Fill the values.
      llvm::for_each(res, [&](const std::pair<unsigned, Value> &entry) {
        values.push_back(entry.second);
      });
    }

  private:
    /// Keeping the inserting order of mapping values.
    int order;

    /// Containing the mapping values with their inserting orders.
    SmallVector<std::pair<unsigned, Value>, 2> toValuesMapping;

    /// Containing the indices of result values with their inserting orders.
    SmallVector<std::pair<unsigned, unsigned>, 2> toIndicesMapping;
  };

  Location loc = callOp.getLoc();
  OpBuilder builder(callOp);
  SmallVector<Value, 2> newOperands;

  // Create the operands list of the new `CallOp`. It unpacks the decomposable
  // values if a decompose callback function has been provided by the user.
  for (auto operand : operands) {
    SmallVector<Value, 2> values;
    this->converter->tryDecomposeValue(builder, loc, operand.getType(), operand,
                                       values);
    newOperands.append(values.begin(), values.end());
  }

  // Create the new result types for the new `CallOp` and a mapping from the old
  // result to new value(s).
  SmallVector<Type, 2> newResultTypes;
  SmallVector<ResultMapping, 4> mappings;
  mappings.resize(callOp.getNumResults());
  for (auto result : llvm::enumerate(callOp.getResults())) {
    SmallVector<Type, 2> originTypes;
    converter->tryDecomposeType(result.value().getType(), originTypes);
    auto &resultMapping = mappings[result.index()];
    for (Type origin : originTypes) {
      Type converted = converter->convertType(origin);
      auto kind = converter->getResultConversionKind(origin, converted);
      if (kind == BufferAssignmentTypeConverter::KeepAsFunctionResult) {
        newResultTypes.push_back(converted);
        // The result value is not yet available. Its index is kept and it is
        // replaced with the actual value of the new `CallOp` later.
        resultMapping.addMapping(newResultTypes.size() - 1);
      } else {
        // kind = BufferAssignmentTypeConverter::AppendToArgumentsList
        MemRefType memref = converted.dyn_cast<MemRefType>();
        if (!memref)
          return callOp.emitError("Cannot allocate for a non-Memref type");
        Value alloc = rewriter.create<AllocOp>(loc, memref);
        newOperands.push_back(alloc);
        resultMapping.addMapping(alloc);
      }
    }
  }

  CallOp newCallOp = rewriter.create<CallOp>(loc, callOp.getCallee(),
                                             newResultTypes, newOperands);

  // Build a replacing value for each result to replace its uses. If a result
  // has multiple mapping values, it needs to be packed to a single value.
  OpBuilder nextBuilder(callOp.getOperation()->getNextNode());
  SmallVector<Value, 2> replacedValues;
  replacedValues.reserve(callOp.getNumResults());
  for (unsigned i = 0, e = callOp.getNumResults(); i < e; ++i) {
    SmallVector<Value, 2> valuesToPack;
    mappings[i].getMappingValues(newCallOp.getResults(), valuesToPack);
    if (valuesToPack.empty()) {
      // No replacement is required.
      replacedValues.push_back(nullptr);
    } else if (valuesToPack.size() == 1) {
      replacedValues.push_back(valuesToPack.front());
    } else {
      // Values need to be packed using callback function. The same callback
      // that is used for materializeArgumentConversion is used for packing.
      Value packed = converter->materializeArgumentConversion(
          nextBuilder, loc, callOp.getType(i), valuesToPack);
      replacedValues.push_back(packed);
    }
  }
  rewriter.replaceOp(callOp, replacedValues);
  return success();
}

//===----------------------------------------------------------------------===//
// BufferPlacementPass construction
//===----------------------------------------------------------------------===//

std::unique_ptr<Pass> mlir::createBufferPlacementPass() {
  return std::make_unique<BufferPlacementPass>();
}