mlir/include/mlir/Analysis/Utils.h - llvm-project - Git at Google

 //===- Utils.h - General analysis utilities ---------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This header file defines prototypes for various transformation utilities for
 // memref's and non-loop IR structures. These are not passes by themselves but
 // are used either by passes, optimization sequences, or in turn by other
 // transformation utilities.
 //
 //===----------------------------------------------------------------------===//

 #ifndef MLIR_ANALYSIS_UTILS_H
 #define MLIR_ANALYSIS_UTILS_H

 #include "mlir/Analysis/AffineStructures.h"
 #include "mlir/IR/AffineMap.h"
 #include "mlir/IR/Block.h"
 #include "mlir/IR/Location.h"
 #include "mlir/Support/LLVM.h"
 #include "llvm/ADT/SmallVector.h"
 #include <memory>

 namespace mlir {

 class AffineForOp;
 class Block;
 class Location;
 struct MemRefAccess;
 class Operation;
 class Value;

 /// Populates 'loops' with IVs of the loops surrounding 'op' ordered from
 /// the outermost 'affine.for' operation to the innermost one.
 //  TODO: handle 'affine.if' ops.
 void getLoopIVs(Operation &op, SmallVectorImpl<AffineForOp> *loops);

 /// Populates 'ops' with IVs of the loops surrounding `op`, along with
 /// `affine.if` operations interleaved between these loops, ordered from the
 /// outermost `affine.for` or `affine.if` operation to the innermost one.
 void getEnclosingAffineForAndIfOps(Operation &op,
                                    SmallVectorImpl<Operation *> *ops);

 /// Returns the nesting depth of this operation, i.e., the number of loops
 /// surrounding this operation.
 unsigned getNestingDepth(Operation *op);

 /// Returns whether a loop is a parallel loop and contains a reduction loop.
 bool isLoopParallelAndContainsReduction(AffineForOp forOp);

 /// Returns in 'sequentialLoops' all sequential loops in loop nest rooted
 /// at 'forOp'.
 void getSequentialLoops(AffineForOp forOp,
                         llvm::SmallDenseSet<Value, 8> *sequentialLoops);

 /// Enumerates different result statuses of slice computation by
 /// `computeSliceUnion`
 // TODO: Identify and add different kinds of failures during slice computation.
 struct SliceComputationResult {
   enum ResultEnum {
     Success,
     IncorrectSliceFailure, // Slice is computed, but it is incorrect.
     GenericFailure,        // Unable to compute src loop computation slice.
   } value;
   SliceComputationResult(ResultEnum v) : value(v) {}
 };

 /// ComputationSliceState aggregates loop IVs, loop bound AffineMaps and their
 /// associated operands for a set of loops within a loop nest (typically the
 /// set of loops surrounding a store operation). Loop bound AffineMaps which
 /// are non-null represent slices of that loop's iteration space.
 struct ComputationSliceState {
   // List of sliced loop IVs (ordered from outermost to innermost).
   // EX: 'ivs[i]' has lower bound 'lbs[i]' and upper bound 'ubs[i]'.
   SmallVector<Value, 4> ivs;
   // List of lower bound AffineMaps.
   SmallVector<AffineMap, 4> lbs;
   // List of upper bound AffineMaps.
   SmallVector<AffineMap, 4> ubs;
   // List of lower bound operands (lbOperands[i] are used by 'lbs[i]').
   std::vector<SmallVector<Value, 4>> lbOperands;
   // List of upper bound operands (ubOperands[i] are used by 'ubs[i]').
   std::vector<SmallVector<Value, 4>> ubOperands;
   // Slice loop nest insertion point in target loop nest.
   Block::iterator insertPoint;
   // Adds to 'cst' with constraints which represent the slice bounds on 'ivs'
   // in 'this'. Specifically, the values in 'ivs' are added to 'cst' as dim
   // identifiers and the values in 'lb/ubOperands' are added as symbols.
   // Constraints are added for all loop IV bounds (dim or symbol), and
   // constraints are added for slice bounds in 'lbs'/'ubs'.
   // Returns failure if we cannot add loop bounds because of unsupported cases.
   LogicalResult getAsConstraints(FlatAffineValueConstraints *cst);

   /// Adds to 'cst' constraints which represent the original loop bounds on
   /// 'ivs' in 'this'. This corresponds to the original domain of the loop nest
   /// from which the slice is being computed. Returns failure if we cannot add
   /// loop bounds because of unsupported cases.
   LogicalResult getSourceAsConstraints(FlatAffineValueConstraints &cst);

   // Clears all bounds and operands in slice state.
   void clearBounds();

   /// Returns true if the computation slice is empty.
   bool isEmpty() const { return ivs.empty(); }

   /// Returns true if the computation slice encloses all the iterations of the
   /// sliced loop nest. Returns false if it does not. Returns llvm::None if it
   /// cannot determine if the slice is maximal or not.
   // TODO: Cache 'isMaximal' so that we don't recompute it when the slice
   // information hasn't changed.
   Optional<bool> isMaximal() const;

   /// Checks the validity of the slice computed. This is done using the
   /// following steps:
   /// 1. Get the new domain of the slice that would be created if fusion
   /// succeeds. This domain gets constructed with source loop IVS and
   /// destination loop IVS as dimensions.
   /// 2. Project out the dimensions of the destination loop from the domain
   /// above calculated in step(1) to express it purely in terms of the source
   /// loop IVs.
   /// 3. Calculate a set difference between the iterations of the new domain and
   /// the original domain of the source loop.
   /// If this difference is empty, the slice is declared to be valid. Otherwise,
   /// return false as it implies that the effective fusion results in at least
   /// one iteration of the slice that was not originally in the source's domain.
   /// If the validity cannot be determined, returns llvm:None.
   Optional<bool> isSliceValid();

   void dump() const;

 private:
   /// Fast check to determine if the computation slice is maximal. Returns true
   /// if each slice dimension maps to an existing dst dimension and both the src
   /// and the dst loops for those dimensions have the same bounds. Returns false
   /// if both the src and the dst loops don't have the same bounds. Returns
   /// llvm::None if none of the above can be proven.
   Optional<bool> isSliceMaximalFastCheck() const;
 };

 /// Computes the computation slice loop bounds for one loop nest as affine maps
 /// of the other loop nest's IVs and symbols, using 'dependenceConstraints'
 /// computed between 'depSourceAccess' and 'depSinkAccess'.
 /// If 'isBackwardSlice' is true, a backwards slice is computed in which the
 /// slice bounds of loop nest surrounding 'depSourceAccess' are computed in
 /// terms of loop IVs and symbols of the loop nest surrounding 'depSinkAccess'
 /// at 'loopDepth'.
 /// If 'isBackwardSlice' is false, a forward slice is computed in which the
 /// slice bounds of loop nest surrounding 'depSinkAccess' are computed in terms
 /// of loop IVs and symbols of the loop nest surrounding 'depSourceAccess' at
 /// 'loopDepth'.
 /// The slice loop bounds and associated operands are returned in 'sliceState'.
 //
 //  Backward slice example:
 //
 //    affine.for %i0 = 0 to 10 {
 //      affine.store %cst, %0[%i0] : memref<100xf32>  // 'depSourceAccess'
 //    }
 //    affine.for %i1 = 0 to 10 {
 //      %v = affine.load %0[%i1] : memref<100xf32>    // 'depSinkAccess'
 //    }
 //
 //    // Backward computation slice of loop nest '%i0'.
 //    affine.for %i0 = (d0) -> (d0)(%i1) to (d0) -> (d0 + 1)(%i1) {
 //      affine.store %cst, %0[%i0] : memref<100xf32>  // 'depSourceAccess'
 //    }
 //
 //  Forward slice example:
 //
 //    affine.for %i0 = 0 to 10 {
 //      affine.store %cst, %0[%i0] : memref<100xf32>  // 'depSourceAccess'
 //    }
 //    affine.for %i1 = 0 to 10 {
 //      %v = affine.load %0[%i1] : memref<100xf32>    // 'depSinkAccess'
 //    }
 //
 //    // Forward computation slice of loop nest '%i1'.
 //    affine.for %i1 = (d0) -> (d0)(%i0) to (d0) -> (d0 + 1)(%i0) {
 //      %v = affine.load %0[%i1] : memref<100xf32>    // 'depSinkAccess'
 //    }
 //
 void getComputationSliceState(Operation *depSourceOp, Operation *depSinkOp,
                               FlatAffineValueConstraints *dependenceConstraints,
                               unsigned loopDepth, bool isBackwardSlice,
                               ComputationSliceState *sliceState);

 /// Return the number of iterations for the `slicetripCountMap` provided.
 uint64_t getSliceIterationCount(
     const llvm::SmallDenseMap<Operation *, uint64_t, 8> &sliceTripCountMap);

 /// Builds a map 'tripCountMap' from AffineForOp to constant trip count for
 /// loop nest surrounding represented by slice loop bounds in 'slice'. Returns
 /// true on success, false otherwise (if a non-constant trip count was
 /// encountered).
 bool buildSliceTripCountMap(
     const ComputationSliceState &slice,
     llvm::SmallDenseMap<Operation *, uint64_t, 8> *tripCountMap);

 /// Computes in 'sliceUnion' the union of all slice bounds computed at
 /// 'loopDepth' between all dependent pairs of ops in 'opsA' and 'opsB', and
 /// then verifies if it is valid. The parameter 'numCommonLoops' is the number
 /// of loops common to the operations in 'opsA' and 'opsB'. If 'isBackwardSlice'
 /// is true, computes slice bounds for loop nest surrounding ops in 'opsA', as a
 /// function of IVs and symbols of loop nest surrounding ops in 'opsB' at
 /// 'loopDepth'. If 'isBackwardSlice' is false, computes slice bounds for loop
 /// nest surrounding ops in 'opsB', as a function of IVs and symbols of loop
 /// nest surrounding ops in 'opsA' at 'loopDepth'. Returns
 /// 'SliceComputationResult::Success' if union was computed correctly, an
 /// appropriate 'failure' otherwise.
 // TODO: Change this API to take 'forOpA'/'forOpB'.
 SliceComputationResult
 computeSliceUnion(ArrayRef<Operation *> opsA, ArrayRef<Operation *> opsB,
                   unsigned loopDepth, unsigned numCommonLoops,
                   bool isBackwardSlice, ComputationSliceState *sliceUnion);

 /// Creates a clone of the computation contained in the loop nest surrounding
 /// 'srcOpInst', slices the iteration space of src loop based on slice bounds
 /// in 'sliceState', and inserts the computation slice at the beginning of the
 /// operation block of the loop at 'dstLoopDepth' in the loop nest surrounding
 /// 'dstOpInst'. Returns the top-level loop of the computation slice on
 /// success, returns nullptr otherwise.
 // Loop depth is a crucial optimization choice that determines where to
 // materialize the results of the backward slice - presenting a trade-off b/w
 // storage and redundant computation in several cases.
 // TODO: Support computation slices with common surrounding loops.
 AffineForOp insertBackwardComputationSlice(Operation *srcOpInst,
                                            Operation *dstOpInst,
                                            unsigned dstLoopDepth,
                                            ComputationSliceState *sliceState);

 /// A region of a memref's data space; this is typically constructed by
 /// analyzing load/store op's on this memref and the index space of loops
 /// surrounding such op's.
 // For example, the memref region for a load operation at loop depth = 1:
 //
 //    affine.for %i = 0 to 32 {
 //      affine.for %ii = %i to (d0) -> (d0 + 8) (%i) {
 //        affine.load %A[%ii]
 //      }
 //    }
 //
 // Region:  {memref = %A, write = false, {%i <= m0 <= %i + 7} }
 // The last field is a 2-d FlatAffineValueConstraints symbolic in %i.
 //
 struct MemRefRegion {
   explicit MemRefRegion(Location loc) : loc(loc) {}

   /// Computes the memory region accessed by this memref with the region
   /// represented as constraints symbolic/parametric in 'loopDepth' loops
   /// surrounding opInst. The computed region's 'cst' field has exactly as many
   /// dimensional identifiers as the rank of the memref, and *potentially*
   /// additional symbolic identifiers which could include any of the loop IVs
   /// surrounding opInst up until 'loopDepth' and another additional Function
   /// symbols involved with the access (for eg., those appear in affine.apply's,
   /// loop bounds, etc.). If 'sliceState' is non-null, operands from
   /// 'sliceState' are added as symbols, and the following constraints are added
   /// to the system:
   /// *) Inequality constraints which represent loop bounds for 'sliceState'
   ///    operands which are loop IVS (these represent the destination loop IVs
   ///    of the slice, and are added as symbols to MemRefRegion's constraint
   ///    system).
   /// *) Inequality constraints for the slice bounds in 'sliceState', which
   ///    represent the bounds on the loop IVs in this constraint system w.r.t
   ///    to slice operands (which correspond to symbols).
   /// If 'addMemRefDimBounds' is true, constant upper/lower bounds
   /// [0, memref.getDimSize(i)) are added for each MemRef dimension 'i'.
   ///
   ///  For example, the memref region for this operation at loopDepth = 1 will
   ///  be:
   ///
   ///    affine.for %i = 0 to 32 {
   ///      affine.for %ii = %i to (d0) -> (d0 + 8) (%i) {
   ///        load %A[%ii]
   ///      }
   ///    }
   ///
   ///   {memref = %A, write = false, {%i <= m0 <= %i + 7} }
   /// The last field is a 2-d FlatAffineValueConstraints symbolic in %i.
   ///
   LogicalResult compute(Operation *op, unsigned loopDepth,
                         const ComputationSliceState *sliceState = nullptr,
                         bool addMemRefDimBounds = true);

   FlatAffineValueConstraints *getConstraints() { return &cst; }
   const FlatAffineValueConstraints *getConstraints() const { return &cst; }
   bool isWrite() const { return write; }
   void setWrite(bool flag) { write = flag; }

   /// Returns a constant upper bound on the number of elements in this region if
   /// bounded by a known constant (always possible for static shapes), None
   /// otherwise. Note that the symbols of the region are treated specially,
   /// i.e., the returned bounding constant holds for *any given* value of the
   /// symbol identifiers. The 'shape' vector is set to the corresponding
   /// dimension-wise bounds major to minor. The number of elements and all the
   /// dimension-wise bounds are guaranteed to be non-negative. We use int64_t
   /// instead of uint64_t since index types can be at most int64_t. `lbs` are
   /// set to the lower bounds for each of the rank dimensions, and lbDivisors
   /// contains the corresponding denominators for floorDivs.
   Optional<int64_t> getConstantBoundingSizeAndShape(
       SmallVectorImpl<int64_t> *shape = nullptr,
       std::vector<SmallVector<int64_t, 4>> *lbs = nullptr,
       SmallVectorImpl<int64_t> *lbDivisors = nullptr) const;

   /// Gets the lower and upper bound map for the dimensional identifier at
   /// `pos`.
   void getLowerAndUpperBound(unsigned pos, AffineMap &lbMap,
                              AffineMap &ubMap) const;

   /// A wrapper around FlatAffineValueConstraints::getConstantBoundOnDimSize().
   /// 'pos' corresponds to the position of the memref shape's dimension (major
   /// to minor) which matches 1:1 with the dimensional identifier positions in
   /// 'cst'.
   Optional<int64_t>
   getConstantBoundOnDimSize(unsigned pos,
                             SmallVectorImpl<int64_t> *lb = nullptr,
                             int64_t *lbFloorDivisor = nullptr) const {
     assert(pos < getRank() && "invalid position");
     return cst.getConstantBoundOnDimSize(pos, lb);
   }

   /// Returns the size of this MemRefRegion in bytes.
   Optional<int64_t> getRegionSize();

   // Wrapper around FlatAffineValueConstraints::unionBoundingBox.
   LogicalResult unionBoundingBox(const MemRefRegion &other);

   /// Returns the rank of the memref that this region corresponds to.
   unsigned getRank() const;

   /// Memref that this region corresponds to.
   Value memref;

   /// Read or write.
   bool write;

   /// If there is more than one load/store op associated with the region, the
   /// location information would correspond to one of those op's.
   Location loc;

   /// Region (data space) of the memref accessed. This set will thus have at
   /// least as many dimensional identifiers as the shape dimensionality of the
   /// memref, and these are the leading dimensions of the set appearing in that
   /// order (major to minor / outermost to innermost). There may be additional
   /// identifiers since getMemRefRegion() is called with a specific loop depth,
   /// and thus the region is symbolic in the outer surrounding loops at that
   /// depth.
   // TODO: Replace this to exploit HyperRectangularSet.
   FlatAffineValueConstraints cst;
 };

 /// Returns the size of memref data in bytes if it's statically shaped, None
 /// otherwise.
 Optional<uint64_t> getMemRefSizeInBytes(MemRefType memRefType);

 /// Checks a load or store op for an out of bound access; returns failure if the
 /// access is out of bounds along any of the dimensions, success otherwise.
 /// Emits a diagnostic error (with location information) if emitError is true.
 template <typename LoadOrStoreOpPointer>
 LogicalResult boundCheckLoadOrStoreOp(LoadOrStoreOpPointer loadOrStoreOp,
                                       bool emitError = true);

 /// Returns the number of surrounding loops common to both A and B.
 unsigned getNumCommonSurroundingLoops(Operation &A, Operation &B);

 /// Gets the memory footprint of all data touched in the specified memory space
 /// in bytes; if the memory space is unspecified, considers all memory spaces.
 Optional<int64_t> getMemoryFootprintBytes(AffineForOp forOp,
                                           int memorySpace = -1);

 /// Simplify the integer set by simplifying the underlying affine expressions by
 /// flattening and some simple inference. Also, drop any duplicate constraints.
 /// Returns the simplified integer set. This method runs in time linear in the
 /// number of constraints.
 IntegerSet simplifyIntegerSet(IntegerSet set);

 /// Returns the innermost common loop depth for the set of operations in 'ops'.
 unsigned getInnermostCommonLoopDepth(
     ArrayRef<Operation *> ops,
     SmallVectorImpl<AffineForOp> *surroundingLoops = nullptr);

 } // end namespace mlir

 #endif // MLIR_ANALYSIS_UTILS_H
	//===- Utils.h - General analysis utilities ---------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This header file defines prototypes for various transformation utilities for
	// memref's and non-loop IR structures. These are not passes by themselves but
	// are used either by passes, optimization sequences, or in turn by other
	// transformation utilities.
	//
	//===----------------------------------------------------------------------===//

	#ifndef MLIR_ANALYSIS_UTILS_H
	#define MLIR_ANALYSIS_UTILS_H

	#include "mlir/Analysis/AffineStructures.h"
	#include "mlir/IR/AffineMap.h"
	#include "mlir/IR/Block.h"
	#include "mlir/IR/Location.h"
	#include "mlir/Support/LLVM.h"
	#include "llvm/ADT/SmallVector.h"
	#include <memory>

	namespace mlir {

	class AffineForOp;
	class Block;
	class Location;
	struct MemRefAccess;
	class Operation;
	class Value;

	/// Populates 'loops' with IVs of the loops surrounding 'op' ordered from
	/// the outermost 'affine.for' operation to the innermost one.
	// TODO: handle 'affine.if' ops.
	void getLoopIVs(Operation &op, SmallVectorImpl<AffineForOp> *loops);

	/// Populates 'ops' with IVs of the loops surrounding `op`, along with
	/// `affine.if` operations interleaved between these loops, ordered from the
	/// outermost `affine.for` or `affine.if` operation to the innermost one.
	void getEnclosingAffineForAndIfOps(Operation &op,
	SmallVectorImpl<Operation > ops);

	/// Returns the nesting depth of this operation, i.e., the number of loops
	/// surrounding this operation.
	unsigned getNestingDepth(Operation *op);

	/// Returns whether a loop is a parallel loop and contains a reduction loop.
	bool isLoopParallelAndContainsReduction(AffineForOp forOp);

	/// Returns in 'sequentialLoops' all sequential loops in loop nest rooted
	/// at 'forOp'.
	void getSequentialLoops(AffineForOp forOp,
	llvm::SmallDenseSet<Value, 8> *sequentialLoops);

	/// Enumerates different result statuses of slice computation by
	/// `computeSliceUnion`
	// TODO: Identify and add different kinds of failures during slice computation.
	struct SliceComputationResult {
	enum ResultEnum {
	Success,
	IncorrectSliceFailure, // Slice is computed, but it is incorrect.
	GenericFailure, // Unable to compute src loop computation slice.
	} value;
	SliceComputationResult(ResultEnum v) : value(v) {}
	};

	/// ComputationSliceState aggregates loop IVs, loop bound AffineMaps and their
	/// associated operands for a set of loops within a loop nest (typically the
	/// set of loops surrounding a store operation). Loop bound AffineMaps which
	/// are non-null represent slices of that loop's iteration space.
	struct ComputationSliceState {
	// List of sliced loop IVs (ordered from outermost to innermost).
	// EX: 'ivs[i]' has lower bound 'lbs[i]' and upper bound 'ubs[i]'.
	SmallVector<Value, 4> ivs;
	// List of lower bound AffineMaps.
	SmallVector<AffineMap, 4> lbs;
	// List of upper bound AffineMaps.
	SmallVector<AffineMap, 4> ubs;
	// List of lower bound operands (lbOperands[i] are used by 'lbs[i]').
	std::vector<SmallVector<Value, 4>> lbOperands;
	// List of upper bound operands (ubOperands[i] are used by 'ubs[i]').
	std::vector<SmallVector<Value, 4>> ubOperands;
	// Slice loop nest insertion point in target loop nest.
	Block::iterator insertPoint;
	// Adds to 'cst' with constraints which represent the slice bounds on 'ivs'
	// in 'this'. Specifically, the values in 'ivs' are added to 'cst' as dim
	// identifiers and the values in 'lb/ubOperands' are added as symbols.
	// Constraints are added for all loop IV bounds (dim or symbol), and
	// constraints are added for slice bounds in 'lbs'/'ubs'.
	// Returns failure if we cannot add loop bounds because of unsupported cases.
	LogicalResult getAsConstraints(FlatAffineValueConstraints *cst);

	/// Adds to 'cst' constraints which represent the original loop bounds on
	/// 'ivs' in 'this'. This corresponds to the original domain of the loop nest
	/// from which the slice is being computed. Returns failure if we cannot add
	/// loop bounds because of unsupported cases.
	LogicalResult getSourceAsConstraints(FlatAffineValueConstraints &cst);

	// Clears all bounds and operands in slice state.
	void clearBounds();

	/// Returns true if the computation slice is empty.
	bool isEmpty() const { return ivs.empty(); }

	/// Returns true if the computation slice encloses all the iterations of the
	/// sliced loop nest. Returns false if it does not. Returns llvm::None if it
	/// cannot determine if the slice is maximal or not.
	// TODO: Cache 'isMaximal' so that we don't recompute it when the slice
	// information hasn't changed.
	Optional<bool> isMaximal() const;

	/// Checks the validity of the slice computed. This is done using the
	/// following steps:
	/// 1. Get the new domain of the slice that would be created if fusion
	/// succeeds. This domain gets constructed with source loop IVS and
	/// destination loop IVS as dimensions.
	/// 2. Project out the dimensions of the destination loop from the domain
	/// above calculated in step(1) to express it purely in terms of the source
	/// loop IVs.
	/// 3. Calculate a set difference between the iterations of the new domain and
	/// the original domain of the source loop.
	/// If this difference is empty, the slice is declared to be valid. Otherwise,
	/// return false as it implies that the effective fusion results in at least
	/// one iteration of the slice that was not originally in the source's domain.
	/// If the validity cannot be determined, returns llvm:None.
	Optional<bool> isSliceValid();

	void dump() const;

	private:
	/// Fast check to determine if the computation slice is maximal. Returns true
	/// if each slice dimension maps to an existing dst dimension and both the src
	/// and the dst loops for those dimensions have the same bounds. Returns false
	/// if both the src and the dst loops don't have the same bounds. Returns
	/// llvm::None if none of the above can be proven.
	Optional<bool> isSliceMaximalFastCheck() const;
	};

	/// Computes the computation slice loop bounds for one loop nest as affine maps
	/// of the other loop nest's IVs and symbols, using 'dependenceConstraints'
	/// computed between 'depSourceAccess' and 'depSinkAccess'.
	/// If 'isBackwardSlice' is true, a backwards slice is computed in which the
	/// slice bounds of loop nest surrounding 'depSourceAccess' are computed in
	/// terms of loop IVs and symbols of the loop nest surrounding 'depSinkAccess'
	/// at 'loopDepth'.
	/// If 'isBackwardSlice' is false, a forward slice is computed in which the
	/// slice bounds of loop nest surrounding 'depSinkAccess' are computed in terms
	/// of loop IVs and symbols of the loop nest surrounding 'depSourceAccess' at
	/// 'loopDepth'.
	/// The slice loop bounds and associated operands are returned in 'sliceState'.
	//
	// Backward slice example:
	//
	// affine.for %i0 = 0 to 10 {
	// affine.store %cst, %0[%i0] : memref<100xf32> // 'depSourceAccess'
	// }
	// affine.for %i1 = 0 to 10 {
	// %v = affine.load %0[%i1] : memref<100xf32> // 'depSinkAccess'
	// }
	//
	// // Backward computation slice of loop nest '%i0'.
	// affine.for %i0 = (d0) -> (d0)(%i1) to (d0) -> (d0 + 1)(%i1) {
	// affine.store %cst, %0[%i0] : memref<100xf32> // 'depSourceAccess'
	// }
	//
	// Forward slice example:
	//
	// affine.for %i0 = 0 to 10 {
	// affine.store %cst, %0[%i0] : memref<100xf32> // 'depSourceAccess'
	// }
	// affine.for %i1 = 0 to 10 {
	// %v = affine.load %0[%i1] : memref<100xf32> // 'depSinkAccess'
	// }
	//
	// // Forward computation slice of loop nest '%i1'.
	// affine.for %i1 = (d0) -> (d0)(%i0) to (d0) -> (d0 + 1)(%i0) {
	// %v = affine.load %0[%i1] : memref<100xf32> // 'depSinkAccess'
	// }
	//
	void getComputationSliceState(Operation depSourceOp, Operation depSinkOp,
	FlatAffineValueConstraints *dependenceConstraints,
	unsigned loopDepth, bool isBackwardSlice,
	ComputationSliceState *sliceState);

	/// Return the number of iterations for the `slicetripCountMap` provided.
	uint64_t getSliceIterationCount(
	const llvm::SmallDenseMap<Operation *, uint64_t, 8> &sliceTripCountMap);

	/// Builds a map 'tripCountMap' from AffineForOp to constant trip count for
	/// loop nest surrounding represented by slice loop bounds in 'slice'. Returns
	/// true on success, false otherwise (if a non-constant trip count was
	/// encountered).
	bool buildSliceTripCountMap(
	const ComputationSliceState &slice,
	llvm::SmallDenseMap<Operation , uint64_t, 8> tripCountMap);

	/// Computes in 'sliceUnion' the union of all slice bounds computed at
	/// 'loopDepth' between all dependent pairs of ops in 'opsA' and 'opsB', and
	/// then verifies if it is valid. The parameter 'numCommonLoops' is the number
	/// of loops common to the operations in 'opsA' and 'opsB'. If 'isBackwardSlice'
	/// is true, computes slice bounds for loop nest surrounding ops in 'opsA', as a
	/// function of IVs and symbols of loop nest surrounding ops in 'opsB' at
	/// 'loopDepth'. If 'isBackwardSlice' is false, computes slice bounds for loop
	/// nest surrounding ops in 'opsB', as a function of IVs and symbols of loop
	/// nest surrounding ops in 'opsA' at 'loopDepth'. Returns
	/// 'SliceComputationResult::Success' if union was computed correctly, an
	/// appropriate 'failure' otherwise.
	// TODO: Change this API to take 'forOpA'/'forOpB'.
	SliceComputationResult
	computeSliceUnion(ArrayRef<Operation > opsA, ArrayRef<Operation > opsB,
	unsigned loopDepth, unsigned numCommonLoops,
	bool isBackwardSlice, ComputationSliceState *sliceUnion);

	/// Creates a clone of the computation contained in the loop nest surrounding
	/// 'srcOpInst', slices the iteration space of src loop based on slice bounds
	/// in 'sliceState', and inserts the computation slice at the beginning of the
	/// operation block of the loop at 'dstLoopDepth' in the loop nest surrounding
	/// 'dstOpInst'. Returns the top-level loop of the computation slice on
	/// success, returns nullptr otherwise.
	// Loop depth is a crucial optimization choice that determines where to
	// materialize the results of the backward slice - presenting a trade-off b/w
	// storage and redundant computation in several cases.
	// TODO: Support computation slices with common surrounding loops.
	AffineForOp insertBackwardComputationSlice(Operation *srcOpInst,
	Operation *dstOpInst,
	unsigned dstLoopDepth,
	ComputationSliceState *sliceState);

	/// A region of a memref's data space; this is typically constructed by
	/// analyzing load/store op's on this memref and the index space of loops
	/// surrounding such op's.
	// For example, the memref region for a load operation at loop depth = 1:
	//
	// affine.for %i = 0 to 32 {
	// affine.for %ii = %i to (d0) -> (d0 + 8) (%i) {
	// affine.load %A[%ii]
	// }
	// }
	//
	// Region: {memref = %A, write = false, {%i <= m0 <= %i + 7} }
	// The last field is a 2-d FlatAffineValueConstraints symbolic in %i.
	//
	struct MemRefRegion {
	explicit MemRefRegion(Location loc) : loc(loc) {}

	/// Computes the memory region accessed by this memref with the region
	/// represented as constraints symbolic/parametric in 'loopDepth' loops
	/// surrounding opInst. The computed region's 'cst' field has exactly as many
	/// dimensional identifiers as the rank of the memref, and potentially
	/// additional symbolic identifiers which could include any of the loop IVs
	/// surrounding opInst up until 'loopDepth' and another additional Function
	/// symbols involved with the access (for eg., those appear in affine.apply's,
	/// loop bounds, etc.). If 'sliceState' is non-null, operands from
	/// 'sliceState' are added as symbols, and the following constraints are added
	/// to the system:
	/// *) Inequality constraints which represent loop bounds for 'sliceState'
	/// operands which are loop IVS (these represent the destination loop IVs
	/// of the slice, and are added as symbols to MemRefRegion's constraint
	/// system).
	/// *) Inequality constraints for the slice bounds in 'sliceState', which
	/// represent the bounds on the loop IVs in this constraint system w.r.t
	/// to slice operands (which correspond to symbols).
	/// If 'addMemRefDimBounds' is true, constant upper/lower bounds
	/// [0, memref.getDimSize(i)) are added for each MemRef dimension 'i'.
	///
	/// For example, the memref region for this operation at loopDepth = 1 will
	/// be:
	///
	/// affine.for %i = 0 to 32 {
	/// affine.for %ii = %i to (d0) -> (d0 + 8) (%i) {
	/// load %A[%ii]
	/// }
	/// }
	///
	/// {memref = %A, write = false, {%i <= m0 <= %i + 7} }
	/// The last field is a 2-d FlatAffineValueConstraints symbolic in %i.
	///
	LogicalResult compute(Operation *op, unsigned loopDepth,
	const ComputationSliceState *sliceState = nullptr,
	bool addMemRefDimBounds = true);

	FlatAffineValueConstraints *getConstraints() { return &cst; }
	const FlatAffineValueConstraints *getConstraints() const { return &cst; }
	bool isWrite() const { return write; }
	void setWrite(bool flag) { write = flag; }

	/// Returns a constant upper bound on the number of elements in this region if
	/// bounded by a known constant (always possible for static shapes), None
	/// otherwise. Note that the symbols of the region are treated specially,
	/// i.e., the returned bounding constant holds for any given value of the
	/// symbol identifiers. The 'shape' vector is set to the corresponding
	/// dimension-wise bounds major to minor. The number of elements and all the
	/// dimension-wise bounds are guaranteed to be non-negative. We use int64_t
	/// instead of uint64_t since index types can be at most int64_t. `lbs` are
	/// set to the lower bounds for each of the rank dimensions, and lbDivisors
	/// contains the corresponding denominators for floorDivs.
	Optional<int64_t> getConstantBoundingSizeAndShape(
	SmallVectorImpl<int64_t> *shape = nullptr,
	std::vector<SmallVector<int64_t, 4>> *lbs = nullptr,
	SmallVectorImpl<int64_t> *lbDivisors = nullptr) const;

	/// Gets the lower and upper bound map for the dimensional identifier at
	/// `pos`.
	void getLowerAndUpperBound(unsigned pos, AffineMap &lbMap,
	AffineMap &ubMap) const;

	/// A wrapper around FlatAffineValueConstraints::getConstantBoundOnDimSize().
	/// 'pos' corresponds to the position of the memref shape's dimension (major
	/// to minor) which matches 1:1 with the dimensional identifier positions in
	/// 'cst'.
	Optional<int64_t>
	getConstantBoundOnDimSize(unsigned pos,
	SmallVectorImpl<int64_t> *lb = nullptr,
	int64_t *lbFloorDivisor = nullptr) const {
	assert(pos < getRank() && "invalid position");
	return cst.getConstantBoundOnDimSize(pos, lb);
	}

	/// Returns the size of this MemRefRegion in bytes.
	Optional<int64_t> getRegionSize();

	// Wrapper around FlatAffineValueConstraints::unionBoundingBox.
	LogicalResult unionBoundingBox(const MemRefRegion &other);

	/// Returns the rank of the memref that this region corresponds to.
	unsigned getRank() const;

	/// Memref that this region corresponds to.
	Value memref;

	/// Read or write.
	bool write;

	/// If there is more than one load/store op associated with the region, the
	/// location information would correspond to one of those op's.
	Location loc;

	/// Region (data space) of the memref accessed. This set will thus have at
	/// least as many dimensional identifiers as the shape dimensionality of the
	/// memref, and these are the leading dimensions of the set appearing in that
	/// order (major to minor / outermost to innermost). There may be additional
	/// identifiers since getMemRefRegion() is called with a specific loop depth,
	/// and thus the region is symbolic in the outer surrounding loops at that
	/// depth.
	// TODO: Replace this to exploit HyperRectangularSet.
	FlatAffineValueConstraints cst;
	};

	/// Returns the size of memref data in bytes if it's statically shaped, None
	/// otherwise.
	Optional<uint64_t> getMemRefSizeInBytes(MemRefType memRefType);

	/// Checks a load or store op for an out of bound access; returns failure if the
	/// access is out of bounds along any of the dimensions, success otherwise.
	/// Emits a diagnostic error (with location information) if emitError is true.
	template <typename LoadOrStoreOpPointer>
	LogicalResult boundCheckLoadOrStoreOp(LoadOrStoreOpPointer loadOrStoreOp,
	bool emitError = true);

	/// Returns the number of surrounding loops common to both A and B.
	unsigned getNumCommonSurroundingLoops(Operation &A, Operation &B);

	/// Gets the memory footprint of all data touched in the specified memory space
	/// in bytes; if the memory space is unspecified, considers all memory spaces.
	Optional<int64_t> getMemoryFootprintBytes(AffineForOp forOp,
	int memorySpace = -1);

	/// Simplify the integer set by simplifying the underlying affine expressions by
	/// flattening and some simple inference. Also, drop any duplicate constraints.
	/// Returns the simplified integer set. This method runs in time linear in the
	/// number of constraints.
	IntegerSet simplifyIntegerSet(IntegerSet set);

	/// Returns the innermost common loop depth for the set of operations in 'ops'.
	unsigned getInnermostCommonLoopDepth(
	ArrayRef<Operation *> ops,
	SmallVectorImpl<AffineForOp> *surroundingLoops = nullptr);

	} // end namespace mlir

	#endif // MLIR_ANALYSIS_UTILS_H