mlir/lib/Dialect/Linalg/Transforms/HoistPadding.cpp - llvm-project - Git at Google

 //===- HoistPadding.cpp - Hoisting transformation for PadTensorOp ---------===//
 //
 // 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 functions concerned with hoisting padding operations.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Dialect/Linalg/Transforms/HoistPadding.h"
 #include "mlir/Analysis/SliceAnalysis.h"
 #include "mlir/Dialect/Affine/Utils.h"
 #include "mlir/Dialect/Linalg/IR/LinalgOps.h"
 #include "mlir/Dialect/Linalg/Transforms/Transforms.h"
 #include "mlir/Dialect/SCF/SCF.h"
 #include "mlir/Dialect/SCF/Utils.h"
 #include "mlir/Dialect/StandardOps/IR/Ops.h"
 #include "mlir/Dialect/Tensor/IR/Tensor.h"
 #include "mlir/Dialect/Vector/VectorOps.h"
 #include "mlir/Dialect/Vector/VectorUtils.h"
 #include "mlir/IR/AsmState.h"
 #include "mlir/IR/BuiltinOps.h"
 #include "mlir/IR/Dominance.h"
 #include "mlir/Transforms/LoopUtils.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Debug.h"

 using llvm::dbgs;

 #define DEBUG_TYPE "hoist-padding"

 #define DBGS() (dbgs() << '[' << DEBUG_TYPE << "] ")

 using namespace mlir;
 using namespace mlir::linalg;

 /// Analysis class to support PadTensorOp hoisting across multiple enclosing
 /// loops. The failure conditions are:
 ///   1. Pad op has a use that is not an input of a LinalgOp.
 ///   2. Pad op does not have a constant padding value.
 ///   3. There is no immediately enclosing scf::ForOp.
 ///   4. The backward slice from the pad op to the scf::ForOp to hoist above
 ///      contains an unknown op with non index type operands, a region, or a
 ///      memory effect.
 ///   5. The backward slice from the pad op to the scf::ForOp to hoist above is
 ///      empty.
 ///   6. The source tensor of pad op is not defined by an extract slice op.
 ///   7. The source tensor of the extract slice op is not defined outside of
 ///      the outermost enclosing scf::ForOp.
 ///   8. There is no enclosing scf::ForOp that indexes the padded data.
 /// Other cases succeed and will trigger hoisting of the pad op.
 struct HoistingAnalysis {
   HoistingAnalysis(PadTensorOp padTensorOp, int numLoops);

   bool isValid() { return valid; }

   /// Footprint of the packedTensor, computed from the packingLoops.
   SmallVector<Value> getPackedTensorSizes(ImplicitLocOpBuilder &b);

   /// The outermost loop, determined by `nLevels` above which `padTensorOp` will
   /// be hoisted.
   scf::ForOp outermostEnclosingForOp;

   /// Backward slice rooted at `padTensorOp` and nested under
   /// `outermostEnclosingForOp`.
   SetVector<Operation *> backwardSlice;

   /// The scf::ForOp immediately enclosing `padTensorOp` such that:
   ///  1. they are nested under `outermostEnclosingForOp` (inclusive)
   ///  2. whose induction variable is used, directly or indirectly, in the
   ///     computation of `padTensorOp`.
   /// The span of these loops determines the footprint of the packed tensor.
   SmallVector<scf::ForOp> packingLoops;

 private:
   /// Drop any non-index dependencies of `padTensorOp` and `sliceOp` from
   /// `backwardSlice`. The method follows the use-def chains of the index
   /// operands consumed by `padTensorOp` and `sliceOp` and drops the operations
   /// not part of this index computation. Afterwards, the filtered
   /// `backwardSlice` contains only the loops whose induction variable is used,
   /// directly or indirectly, to index the padded tensor. The method returns
   /// failure if the filtered backward slice contains an unexpected operation.
   ///
   /// Example:
   /// ```
   /// %source = linalg.fill(%cst, %arg0)
   /// scf.for %i
   ///   %unrelated = linalg.fill(%cst, %arg1)    // not used to index %source!
   ///   scf.for %j (%arg2 = %unrelated)
   ///     scf.for %k                             // not used to index %source!
   ///       %ubi = affine.min #map(%i)
   ///       %ubj = affine.min #map(%j)
   ///       %slice = tensor.extract_slice %source [%i, %j] [%ubi, %ubj]
   ///       %padded_slice = linalg.pad_tensor %slice
   /// ```
   /// dropNonIndexDependencies(%padded_slice, %slice)
   /// removes [scf.for %k, linalg.fill(%cst, %arg1)] from backwardSlice.
   LogicalResult dropNonIndexDependencies(PadTensorOp padTensorOp,
                                          tensor::ExtractSliceOp sliceOp);

   /// Encodes whether the analysis is valid and hoisting can proceed.
   bool valid;
 };

 /// Return true if all uses of `padTensorOp` are an input tensor of some
 /// LinalgOp.
 static bool isOnlyUsedAsInputOfLinalgOp(PadTensorOp padTensorOp) {
   for (OpOperand &use : padTensorOp.result().getUses()) {
     auto linalgUser = dyn_cast<linalg::LinalgOp>(use.getOwner());
     if (!linalgUser || !linalgUser.isInputTensor(&use)) {
       LLVM_DEBUG(DBGS() << "Found a use of " << *(padTensorOp)
                         << "\nthat is not an input tensor of a LinalgOp, "
                         << "cannot hoist\n"
                         << *(use.getOwner()) << "\n");
       return false;
     }
   }
   return true;
 }

 /// Return at most nLevels of immediately enclosing scf::ForOp loops.
 /// Stops at the first parent that is not an scf::ForOp.
 /// Multi-loops such as scf.parallel or linalg.tiled_loop are not modeled atm.
 /// Control-flow and other containing ops with regions are not modeled atm.
 static void
 getAtMostNEnclosingLoops(PadTensorOp padTensorOp, int nLevels,
                          SmallVector<scf::ForOp> &reverseEnclosingLoops) {
   AsmState state(padTensorOp->getParentOfType<mlir::FuncOp>());
   (void)state;
   scf::ForOp outermostEnclosingForOp = nullptr;
   Operation *nextEnclosingOp = padTensorOp->getParentOp();
   while (nLevels-- > 0 &&
          (outermostEnclosingForOp = dyn_cast<scf::ForOp>(nextEnclosingOp))) {
     LLVM_DEBUG(
         DBGS() << "loops: ";
         outermostEnclosingForOp.getInductionVar().printAsOperand(dbgs(), state);
         dbgs() << "\n");
     reverseEnclosingLoops.push_back(outermostEnclosingForOp);
     nextEnclosingOp = outermostEnclosingForOp->getParentOp();
   }
 }

 HoistingAnalysis::HoistingAnalysis(PadTensorOp padTensorOp, int numLoops) {
   valid = false;

   // Bail on any use that isn't an input of a Linalg op.
   // Hoisting of inplace updates happens after vectorization.
   if (!isOnlyUsedAsInputOfLinalgOp(padTensorOp))
     return;

   // Get at most `numLoops` of immediately enclosing loops.
   SmallVector<scf::ForOp> reverseEnclosingLoops;
   getAtMostNEnclosingLoops(padTensorOp, numLoops, reverseEnclosingLoops);
   if (reverseEnclosingLoops.empty()) {
     LLVM_DEBUG(DBGS() << "No immediately enclosing loop -> skip\n");
     return;
   }

   outermostEnclosingForOp = reverseEnclosingLoops.back();

   // Get the `sliceOp` that defines the source tensor of `padTensorOp` and
   // check its source is defined outside of the outermost loop. This check
   // ensures the padded data is available for packing before entering the
   // outermost enclosing loop.
   //
   // Example:
   // ```
   // %source = linalg.fill(%cst, %arg0)
   // // %source is available for packing here!
   // scf.for %i
   //   scf.for %j
   //     scf.for %k
   //       %slice = tensor.extract_slice %source [%i, %j]
   //       %padded_slice = linalg.pad_tensor %slice
   // ```
   auto sliceOp = padTensorOp.source().getDefiningOp<tensor::ExtractSliceOp>();
   if (!sliceOp) {
     LLVM_DEBUG(DBGS() << "Cannot find the extract slice op -> skip\n");
     return;
   }
   if (!outermostEnclosingForOp.isDefinedOutsideOfLoop(sliceOp.source())) {
     LLVM_DEBUG(DBGS() << "Source not defined outside of loops -> skip\n");
     return;
   }

   // Check the region of `padTensorOp` depends on a constant only. Adding
   // hoisting support for arbitrary padding regions would require cloning all
   // dependencies captured by the padding region.
   Value paddingValue = padTensorOp.getConstantPaddingValue();
   if (!paddingValue ||
       !isa_and_nonnull<arith::ConstantOp>(paddingValue.getDefiningOp())) {
     LLVM_DEBUG(DBGS() << "Cannot find constant padding value -> skip\n");
     return;
   }

   // Get all the ops in the backwards slice starting from `padTensorOp` and that
   // are dominated by the outermost enclosing loop.
   DominanceInfo domInfo(outermostEnclosingForOp);
   getBackwardSlice(padTensorOp.getOperation(), &backwardSlice,
                    [&](Operation *op) {
                      return domInfo.dominates(outermostEnclosingForOp, op);
                    });
   if (backwardSlice.empty())
     return;
   // Add `padTensorOp` itself to the backward slice.
   backwardSlice.insert(padTensorOp.getOperation());

   // Remove all ops in the backward slice that are not used to index the padded
   // tensor. In particular, keep `padTensorOp`, `sliceOp`, and the loop and
   // affine operations used for the index computation.
   if (failed(dropNonIndexDependencies(padTensorOp, sliceOp)))
     return;

   // Add only the loops part of the filtered `backwardSlice` to the packing
   // loops. All other loops are not used to index the padded data and
   // consequently access the same data in every loop iteration. Adding them to
   // the packing loops would increase the cache footprint of the packed data
   // by storing the same data multiple times.
   for (scf::ForOp forOp : llvm::reverse(reverseEnclosingLoops))
     if (backwardSlice.contains(forOp))
       packingLoops.push_back(forOp);
   if (packingLoops.empty()) {
     LLVM_DEBUG(DBGS() << "Cannot find a packing loop -> skip\n");
     return;
   }

   // The analysis is valid and hoisting can occur.
   valid = true;
 }

 LogicalResult
 HoistingAnalysis::dropNonIndexDependencies(PadTensorOp padTensorOp,
                                            tensor::ExtractSliceOp sliceOp) {
   // Set of all values used for index computation.
   SetVector<Value> indexEdges;

   // Add all index operands of `operation` to `indexEdges`. An index operand is
   // an operand of type index.
   auto addIndexOperandsToIndexEdges = [&](Operation *operation) {
     for (Value operand : operation->getOperands())
       if (operand.getType().isIndex())
         indexEdges.insert(operand);
   };

   // Check if any operation result is contained in `indexEdges`.
   auto hasIndexResult = [&](Operation *operation) {
     return llvm::any_of(operation->getResults(), [&](Value result) {
       return indexEdges.contains(result);
     });
   };

   // Starting from `padTensorOp` and `sliceOp` walk the use-def edges of index
   // type in `backwardSlice`. Add the index operands of an operation to
   // `indexEdges` and remove all operations from `backwardSlice` that are not
   // part of the index computation.
   //
   // Example:
   // ```
   // %source = linalg.fill(%cst, %arg0)
   // scf.for %i
   //   %unrelated = linalg.fill(%cst, %arg1)    // not used to index %source!
   //   scf.for %j (%arg2 = %unrelated)
   //     scf.for %k                             // not used to index %source!
   //       %ubi = affine.min #map(%i)
   //       %ubj = affine.min #map(%j)
   //       %slice = tensor.extract_slice %source [%i, %j] [%ubi, %ubj]
   //       %padded_slice = linalg.pad_tensor %slice
   // ```
   // After iterating `backwardSlice` we obtain:
   // indexEdges = [%i, %j, %ubi, %ubj]
   // backwardSlice = backwardSlice / [linalg.fill(%cst, %arg1), scf.for %k]
   SetVector<Operation *> operationsToRemove;
   for (Operation *op : llvm::reverse(backwardSlice)) {
     // Add the index operands of `padTensorOp` and `sliceOp` to start the
     // exploration of the index computation.
     if (op == padTensorOp || op == sliceOp) {
       addIndexOperandsToIndexEdges(op);
       continue;
     }
     // Add the index operands of the loop if its induction variable is
     // used for index computation.
     if (auto forOp = dyn_cast<scf::ForOp>(op)) {
       if (!hasIndexResult(op) && indexEdges.contains(forOp.getInductionVar())) {
         addIndexOperandsToIndexEdges(op);
         continue;
       }
     }
     // Add the index operands of all other operations if at least one result is
     // used for index computation.
     if (hasIndexResult(op)) {
       addIndexOperandsToIndexEdges(op);
       // Check the operands of the remaining operations all have index type.
       if (llvm::any_of(op->getOperandTypes(),
                        [](Type type) { return !type.isIndex(); })) {
         LLVM_DEBUG(DBGS() << "Unsupported op with non index type operands: "
                           << op << " -> skip\n");
         return failure();
       }
       // Check the remaining operations do not have regions or memory effects.
       auto effectInterface = dyn_cast<MemoryEffectOpInterface>(op);
       bool hasMemoryEffect = effectInterface && !effectInterface.hasNoEffect();
       if (hasMemoryEffect || op->getNumRegions() != 0) {
         LLVM_DEBUG(DBGS() << "Unsupported op with region or memory effect: "
                           << op << " -> skip\n");
         return failure();
       }
       continue;
     }
     // Remove all other operations not used by the index computation. An
     // exception are constant operations that may be used by `padTensorOp`.
     if (!isa<arith::ConstantOp>(op))
       operationsToRemove.insert(op);
   }
   backwardSlice.set_subtract(operationsToRemove);
   return success();
 }

 SmallVector<Value>
 HoistingAnalysis::getPackedTensorSizes(ImplicitLocOpBuilder &b) {
   SmallVector<Value> dynamicTensorSizes;

   // Upper bound the packing loop lengths to size the packed tensor. Taking
   // upper bounds can make the sizes of the packed tensor independent of the
   // enclosing loops. This independence is a prerequisite for reusing the same
   // buffer for all enclosing loop iterations and hoisting its allocation out of
   // the enclosing loops.
   for (auto forOp : packingLoops) {
     // Compute an upper bound `ubVal` for the upper bound of `forOp`.
     AffineMap boundMap;
     SmallVector<Value> boundOperands;
     getUpperBoundForIndex(forOp.upperBound(), boundMap, boundOperands);
     Value ubVal = b.createOrFold<AffineMinOp>(boundMap, boundOperands);
     // Compute the maximal packing loop length as (ub - lb).ceilDiv(step) and
     // store the result to `dynamicTensorSizes`.
     // TODO: instead of using the lower bound of `forOp` directly, implement a
     // lower bound computation similar to the upper bound computation.
     AffineExpr lb, ub, step;
     bindDims(b.getContext(), lb, ub);
     bindSymbols(b.getContext(), step);
     Value res = b.createOrFold<AffineApplyOp>(
         (ub - lb).ceilDiv(step),
         ValueRange{forOp.lowerBound(), ubVal, cast<scf::ForOp>(forOp).step()});
     dynamicTensorSizes.push_back(res);
   }

   return dynamicTensorSizes;
 }

 static bool isDefinedOutsideOrConstant(scf::ForOp outer, Value v) {
   return outer.isDefinedOutsideOfLoop(v) || v.getDefiningOp<ConstantOp>();
 }

 /// Return the current iteration number in the loop (iv - lb).ceilDiv(step).
 /// The returned Value is guaranteed not to depend on any loop comprised in
 /// [`outer`, `forOp`].
 /// Return null if such a loop-independent quantity cannot be computed.
 static Value buildLoopIterationCount(OpBuilder &b, scf::ForOp outer,
                                      scf::ForOp forOp) {
   MLIRContext *ctx = forOp->getContext();
   AffineExpr iv, lb, step;
   bindDims(ctx, iv, lb);
   bindSymbols(ctx, step);
   if (!isDefinedOutsideOrConstant(outer, forOp.lowerBound()) ||
       !isDefinedOutsideOrConstant(outer, forOp.step()))
     return Value();
   Value ivVal = forOp.getInductionVar(), lbVal = forOp.lowerBound(),
         stepVal = forOp.step();
   auto loc = forOp->getLoc();
   return b.createOrFold<AffineApplyOp>(loc, (iv - lb).ceilDiv(step),
                                        ValueRange{ivVal, lbVal, stepVal});
 }

 FailureOr<Value> mlir::linalg::hoistPaddingOnTensors(PadTensorOp opToHoist,
                                                      int numLoops,
                                                      PadTensorOp &hoistedOp) {
   LLVM_DEBUG(DBGS() << "Try to hoist " << *(opToHoist) << " by " << numLoops
                     << " loops\n");
   HoistingAnalysis analysis(opToHoist, numLoops);
   if (!analysis.isValid()) {
     LLVM_DEBUG(DBGS() << "Analysis failed -> Skip\n");
     return failure();
   }

   scf::ForOp outer = analysis.outermostEnclosingForOp;
   ImplicitLocOpBuilder b(outer->getLoc(), outer);

   SmallVector<Value> dynamicTensorSizes = analysis.getPackedTensorSizes(b);

   // Update actual number of loops, which may be smaller.
   int nPackedLoops = analysis.packingLoops.size();

   Location loc = opToHoist->getLoc();
   RankedTensorType paddedTensorType = opToHoist.getResultType();
   int paddedRank = paddedTensorType.getRank();

   // Create the packed tensor<?x?x..?xpadded_shape> into which we amortize
   // padding.
   SmallVector<int64_t> packedShape(nPackedLoops, ShapedType::kDynamicSize);
   // TODO: go grab dims when necessary, for now PadTensorOp returns a static
   // tensor.
   llvm::append_range(packedShape, paddedTensorType.getShape());
   auto packedTensorType =
       RankedTensorType::get(packedShape, paddedTensorType.getElementType());
   Value packedTensor = b.create<linalg::InitTensorOp>(
       loc, dynamicTensorSizes, packedTensorType.getShape(),
       packedTensorType.getElementType());

   // Clone the operations involved in the backward slice, iteratively stepping
   // into the loops that we encounter.
   // The implementation proceeds in a stack-like fashion:
   //   1. Iteratively clone and step into the loops, pushing the `packedTensor`
   //      deeper in the stack.
   //   2. Create a InsertSliceOp at the top of the stack.
   //   3. Iteratively pop and yield the result of the InsertSliceOp across
   //     the cloned loops.
   SmallVector<Value> clonedLoopIvs, leadingPackedTensorIndexings;
   clonedLoopIvs.reserve(nPackedLoops);
   leadingPackedTensorIndexings.reserve(nPackedLoops);
   BlockAndValueMapping bvm;
   // Stack step 1. iteratively clone loops and push `packedTensor`.
   for (Operation *op : analysis.backwardSlice) {
     // Specifically sit out in the extract_slice(packedTensor) case: this is the
     // piece we seek to replace.
     if (auto sliceOp = dyn_cast<tensor::ExtractSliceOp>(op))
       if (bvm.lookupOrDefault(sliceOp.source()) == packedTensor)
         continue;
     // Clone all operations except it is a loop.
     auto forOp = dyn_cast<scf::ForOp>(op);
     if (!forOp) {
       b.clone(*op, bvm);
       continue;
     }
     // Create a packing loop that takes `packedTensor` as iteration argument.
     auto clonedForOp =
         b.create<scf::ForOp>(loc, bvm.lookupOrDefault(forOp.lowerBound()),
                              bvm.lookupOrDefault(forOp.upperBound()),
                              bvm.lookupOrDefault(forOp.step()), packedTensor);
     // Map the induction var, region args and results to the `clonedForOp`.
     bvm.map(forOp.getInductionVar(), clonedForOp.getInductionVar());
     bvm.map(forOp.getRegionIterArgs(), clonedForOp.getRegionIterArgs());
     bvm.map(forOp.getResults(), clonedForOp.getResults());
     assert(clonedForOp->getNumRegions() == 1);
     clonedLoopIvs.push_back(clonedForOp.getInductionVar());

     b.setInsertionPointToStart(&clonedForOp->getRegion(0).front());
     Value loopIndependentIterationCount =
         buildLoopIterationCount(b, outer, clonedForOp);
     // Assert the loop-independent iteration count can be computed.
     if (!loopIndependentIterationCount)
       llvm_unreachable("loop independence prerequisite not met");
     leadingPackedTensorIndexings.push_back(loopIndependentIterationCount);
     packedTensor = clonedForOp.getRegionIterArgs().front();
   }

   // Stack step 2. create InsertSliceOp at the top of the stack.
   // offsets = [clonedLoopIvs, 0 .. 0].
   SmallVector<OpFoldResult> offsets(leadingPackedTensorIndexings.begin(),
                                     leadingPackedTensorIndexings.end());
   offsets.append(paddedRank, b.getIndexAttr(0));
   // sizes = [1 .. 1, paddedShape].
   SmallVector<OpFoldResult> sizes(nPackedLoops, b.getIndexAttr(1));
   for (int64_t sz : paddedTensorType.getShape()) {
     // TODO: go grab dims when necessary, for now PadTensorOp returns a static
     // tensor.
     assert(!ShapedType::isDynamic(sz) && "padded tensor needs static sizes");
     sizes.push_back(b.getIndexAttr(sz));
   }
   // strides = [1 .. 1].
   SmallVector<OpFoldResult> strides(nPackedLoops + paddedRank,
                                     b.getIndexAttr(1));

   Value inserted =
       b.create<tensor::InsertSliceOp>(loc, bvm.lookup(opToHoist.result()),
                                       packedTensor, offsets, sizes, strides);

   // Stack step 3. iteratively pop the stack and propagate the yield.
   Value valueToYield = inserted;
   for (Value iv : llvm::reverse(clonedLoopIvs)) {
     auto forOp = scf::getForInductionVarOwner(iv);
     b.setInsertionPointToEnd(&forOp.getRegion().front());
     b.create<scf::YieldOp>(loc, valueToYield);
     valueToYield = forOp.getResult(0);
   }

   // Now the packed tensor is ready, replace the original padding op by a
   // 1x..x1 slice [originalLoopIvs, 0 .. 0][1 .. 1, paddedShape][1 .. 1].
   b.setInsertionPoint(opToHoist);
   SmallVector<Value> loopIterationCounts = llvm::to_vector<4>(
       llvm::map_range(analysis.packingLoops, [&](Operation *loop) {
         return buildLoopIterationCount(b, outer, cast<scf::ForOp>(loop));
       }));
   // Assert all loop iteration counts can be computed.
   if (llvm::any_of(loopIterationCounts, [](Value v) { return !v; }))
     llvm_unreachable("loop independence prerequisite not met");
   // offsets = [originalLoopIvs, 0 .. 0].
   offsets.assign(loopIterationCounts.begin(), loopIterationCounts.end());
   offsets.append(paddedRank, b.getIndexAttr(0));
   // sizes = [1 .. 1, paddedShape] (definedabove).
   // strides = [1 .. 1] (defined above)
   packedTensor =
       scf::getForInductionVarOwner(clonedLoopIvs.front())->getResult(0);
   Value newResult = b.create<tensor::ExtractSliceOp>(
       loc, opToHoist.getResultType(), packedTensor, offsets, sizes, strides);

   // Make the newly cloned `opToHoist` available to the caller.
   hoistedOp = cast<PadTensorOp>(bvm.lookup(opToHoist.result()).getDefiningOp());
   return newResult;
 }
	//===- HoistPadding.cpp - Hoisting transformation for PadTensorOp ---------===//
	//
	// 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 functions concerned with hoisting padding operations.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Dialect/Linalg/Transforms/HoistPadding.h"
	#include "mlir/Analysis/SliceAnalysis.h"
	#include "mlir/Dialect/Affine/Utils.h"
	#include "mlir/Dialect/Linalg/IR/LinalgOps.h"
	#include "mlir/Dialect/Linalg/Transforms/Transforms.h"
	#include "mlir/Dialect/SCF/SCF.h"
	#include "mlir/Dialect/SCF/Utils.h"
	#include "mlir/Dialect/StandardOps/IR/Ops.h"
	#include "mlir/Dialect/Tensor/IR/Tensor.h"
	#include "mlir/Dialect/Vector/VectorOps.h"
	#include "mlir/Dialect/Vector/VectorUtils.h"
	#include "mlir/IR/AsmState.h"
	#include "mlir/IR/BuiltinOps.h"
	#include "mlir/IR/Dominance.h"
	#include "mlir/Transforms/LoopUtils.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Debug.h"

	using llvm::dbgs;

	#define DEBUG_TYPE "hoist-padding"

	#define DBGS() (dbgs() << '[' << DEBUG_TYPE << "] ")

	using namespace mlir;
	using namespace mlir::linalg;

	/// Analysis class to support PadTensorOp hoisting across multiple enclosing
	/// loops. The failure conditions are:
	/// 1. Pad op has a use that is not an input of a LinalgOp.
	/// 2. Pad op does not have a constant padding value.
	/// 3. There is no immediately enclosing scf::ForOp.
	/// 4. The backward slice from the pad op to the scf::ForOp to hoist above
	/// contains an unknown op with non index type operands, a region, or a
	/// memory effect.
	/// 5. The backward slice from the pad op to the scf::ForOp to hoist above is
	/// empty.
	/// 6. The source tensor of pad op is not defined by an extract slice op.
	/// 7. The source tensor of the extract slice op is not defined outside of
	/// the outermost enclosing scf::ForOp.
	/// 8. There is no enclosing scf::ForOp that indexes the padded data.
	/// Other cases succeed and will trigger hoisting of the pad op.
	struct HoistingAnalysis {
	HoistingAnalysis(PadTensorOp padTensorOp, int numLoops);

	bool isValid() { return valid; }

	/// Footprint of the packedTensor, computed from the packingLoops.
	SmallVector<Value> getPackedTensorSizes(ImplicitLocOpBuilder &b);

	/// The outermost loop, determined by `nLevels` above which `padTensorOp` will
	/// be hoisted.
	scf::ForOp outermostEnclosingForOp;

	/// Backward slice rooted at `padTensorOp` and nested under
	/// `outermostEnclosingForOp`.
	SetVector<Operation *> backwardSlice;

	/// The scf::ForOp immediately enclosing `padTensorOp` such that:
	/// 1. they are nested under `outermostEnclosingForOp` (inclusive)
	/// 2. whose induction variable is used, directly or indirectly, in the
	/// computation of `padTensorOp`.
	/// The span of these loops determines the footprint of the packed tensor.
	SmallVector<scf::ForOp> packingLoops;

	private:
	/// Drop any non-index dependencies of `padTensorOp` and `sliceOp` from
	/// `backwardSlice`. The method follows the use-def chains of the index
	/// operands consumed by `padTensorOp` and `sliceOp` and drops the operations
	/// not part of this index computation. Afterwards, the filtered
	/// `backwardSlice` contains only the loops whose induction variable is used,
	/// directly or indirectly, to index the padded tensor. The method returns
	/// failure if the filtered backward slice contains an unexpected operation.
	///
	/// Example:
	/// ```
	/// %source = linalg.fill(%cst, %arg0)
	/// scf.for %i
	/// %unrelated = linalg.fill(%cst, %arg1) // not used to index %source!
	/// scf.for %j (%arg2 = %unrelated)
	/// scf.for %k // not used to index %source!
	/// %ubi = affine.min #map(%i)
	/// %ubj = affine.min #map(%j)
	/// %slice = tensor.extract_slice %source [%i, %j] [%ubi, %ubj]
	/// %padded_slice = linalg.pad_tensor %slice
	/// ```
	/// dropNonIndexDependencies(%padded_slice, %slice)
	/// removes [scf.for %k, linalg.fill(%cst, %arg1)] from backwardSlice.
	LogicalResult dropNonIndexDependencies(PadTensorOp padTensorOp,
	tensor::ExtractSliceOp sliceOp);

	/// Encodes whether the analysis is valid and hoisting can proceed.
	bool valid;
	};

	/// Return true if all uses of `padTensorOp` are an input tensor of some
	/// LinalgOp.
	static bool isOnlyUsedAsInputOfLinalgOp(PadTensorOp padTensorOp) {
	for (OpOperand &use : padTensorOp.result().getUses()) {
	auto linalgUser = dyn_cast<linalg::LinalgOp>(use.getOwner());
	if (!linalgUser \|\| !linalgUser.isInputTensor(&use)) {
	LLVM_DEBUG(DBGS() << "Found a use of " << *(padTensorOp)
	<< "\nthat is not an input tensor of a LinalgOp, "
	<< "cannot hoist\n"
	<< *(use.getOwner()) << "\n");
	return false;
	}
	}
	return true;
	}

	/// Return at most nLevels of immediately enclosing scf::ForOp loops.
	/// Stops at the first parent that is not an scf::ForOp.
	/// Multi-loops such as scf.parallel or linalg.tiled_loop are not modeled atm.
	/// Control-flow and other containing ops with regions are not modeled atm.
	static void
	getAtMostNEnclosingLoops(PadTensorOp padTensorOp, int nLevels,
	SmallVector<scf::ForOp> &reverseEnclosingLoops) {
	AsmState state(padTensorOp->getParentOfType<mlir::FuncOp>());
	(void)state;
	scf::ForOp outermostEnclosingForOp = nullptr;
	Operation *nextEnclosingOp = padTensorOp->getParentOp();
	while (nLevels-- > 0 &&
	(outermostEnclosingForOp = dyn_cast<scf::ForOp>(nextEnclosingOp))) {
	LLVM_DEBUG(
	DBGS() << "loops: ";
	outermostEnclosingForOp.getInductionVar().printAsOperand(dbgs(), state);
	dbgs() << "\n");
	reverseEnclosingLoops.push_back(outermostEnclosingForOp);
	nextEnclosingOp = outermostEnclosingForOp->getParentOp();
	}
	}

	HoistingAnalysis::HoistingAnalysis(PadTensorOp padTensorOp, int numLoops) {
	valid = false;

	// Bail on any use that isn't an input of a Linalg op.
	// Hoisting of inplace updates happens after vectorization.
	if (!isOnlyUsedAsInputOfLinalgOp(padTensorOp))
	return;

	// Get at most `numLoops` of immediately enclosing loops.
	SmallVector<scf::ForOp> reverseEnclosingLoops;
	getAtMostNEnclosingLoops(padTensorOp, numLoops, reverseEnclosingLoops);
	if (reverseEnclosingLoops.empty()) {
	LLVM_DEBUG(DBGS() << "No immediately enclosing loop -> skip\n");
	return;
	}

	outermostEnclosingForOp = reverseEnclosingLoops.back();

	// Get the `sliceOp` that defines the source tensor of `padTensorOp` and
	// check its source is defined outside of the outermost loop. This check
	// ensures the padded data is available for packing before entering the
	// outermost enclosing loop.
	//
	// Example:
	// ```
	// %source = linalg.fill(%cst, %arg0)
	// // %source is available for packing here!
	// scf.for %i
	// scf.for %j
	// scf.for %k
	// %slice = tensor.extract_slice %source [%i, %j]
	// %padded_slice = linalg.pad_tensor %slice
	// ```
	auto sliceOp = padTensorOp.source().getDefiningOp<tensor::ExtractSliceOp>();
	if (!sliceOp) {
	LLVM_DEBUG(DBGS() << "Cannot find the extract slice op -> skip\n");
	return;
	}
	if (!outermostEnclosingForOp.isDefinedOutsideOfLoop(sliceOp.source())) {
	LLVM_DEBUG(DBGS() << "Source not defined outside of loops -> skip\n");
	return;
	}

	// Check the region of `padTensorOp` depends on a constant only. Adding
	// hoisting support for arbitrary padding regions would require cloning all
	// dependencies captured by the padding region.
	Value paddingValue = padTensorOp.getConstantPaddingValue();
	if (!paddingValue \|\|
	!isa_and_nonnull<arith::ConstantOp>(paddingValue.getDefiningOp())) {
	LLVM_DEBUG(DBGS() << "Cannot find constant padding value -> skip\n");
	return;
	}

	// Get all the ops in the backwards slice starting from `padTensorOp` and that
	// are dominated by the outermost enclosing loop.
	DominanceInfo domInfo(outermostEnclosingForOp);
	getBackwardSlice(padTensorOp.getOperation(), &backwardSlice,
	[&](Operation *op) {
	return domInfo.dominates(outermostEnclosingForOp, op);
	});
	if (backwardSlice.empty())
	return;
	// Add `padTensorOp` itself to the backward slice.
	backwardSlice.insert(padTensorOp.getOperation());

	// Remove all ops in the backward slice that are not used to index the padded
	// tensor. In particular, keep `padTensorOp`, `sliceOp`, and the loop and
	// affine operations used for the index computation.
	if (failed(dropNonIndexDependencies(padTensorOp, sliceOp)))
	return;

	// Add only the loops part of the filtered `backwardSlice` to the packing
	// loops. All other loops are not used to index the padded data and
	// consequently access the same data in every loop iteration. Adding them to
	// the packing loops would increase the cache footprint of the packed data
	// by storing the same data multiple times.
	for (scf::ForOp forOp : llvm::reverse(reverseEnclosingLoops))
	if (backwardSlice.contains(forOp))
	packingLoops.push_back(forOp);
	if (packingLoops.empty()) {
	LLVM_DEBUG(DBGS() << "Cannot find a packing loop -> skip\n");
	return;
	}

	// The analysis is valid and hoisting can occur.
	valid = true;
	}

	LogicalResult
	HoistingAnalysis::dropNonIndexDependencies(PadTensorOp padTensorOp,
	tensor::ExtractSliceOp sliceOp) {
	// Set of all values used for index computation.
	SetVector<Value> indexEdges;

	// Add all index operands of `operation` to `indexEdges`. An index operand is
	// an operand of type index.
	auto addIndexOperandsToIndexEdges = [&](Operation *operation) {
	for (Value operand : operation->getOperands())
	if (operand.getType().isIndex())
	indexEdges.insert(operand);
	};

	// Check if any operation result is contained in `indexEdges`.
	auto hasIndexResult = [&](Operation *operation) {
	return llvm::any_of(operation->getResults(), [&](Value result) {
	return indexEdges.contains(result);
	});
	};

	// Starting from `padTensorOp` and `sliceOp` walk the use-def edges of index
	// type in `backwardSlice`. Add the index operands of an operation to
	// `indexEdges` and remove all operations from `backwardSlice` that are not
	// part of the index computation.
	//
	// Example:
	// ```
	// %source = linalg.fill(%cst, %arg0)
	// scf.for %i
	// %unrelated = linalg.fill(%cst, %arg1) // not used to index %source!
	// scf.for %j (%arg2 = %unrelated)
	// scf.for %k // not used to index %source!
	// %ubi = affine.min #map(%i)
	// %ubj = affine.min #map(%j)
	// %slice = tensor.extract_slice %source [%i, %j] [%ubi, %ubj]
	// %padded_slice = linalg.pad_tensor %slice
	// ```
	// After iterating `backwardSlice` we obtain:
	// indexEdges = [%i, %j, %ubi, %ubj]
	// backwardSlice = backwardSlice / [linalg.fill(%cst, %arg1), scf.for %k]
	SetVector<Operation *> operationsToRemove;
	for (Operation *op : llvm::reverse(backwardSlice)) {
	// Add the index operands of `padTensorOp` and `sliceOp` to start the
	// exploration of the index computation.
	if (op == padTensorOp \|\| op == sliceOp) {
	addIndexOperandsToIndexEdges(op);
	continue;
	}
	// Add the index operands of the loop if its induction variable is
	// used for index computation.
	if (auto forOp = dyn_cast<scf::ForOp>(op)) {
	if (!hasIndexResult(op) && indexEdges.contains(forOp.getInductionVar())) {
	addIndexOperandsToIndexEdges(op);
	continue;
	}
	}
	// Add the index operands of all other operations if at least one result is
	// used for index computation.
	if (hasIndexResult(op)) {
	addIndexOperandsToIndexEdges(op);
	// Check the operands of the remaining operations all have index type.
	if (llvm::any_of(op->getOperandTypes(),
	[](Type type) { return !type.isIndex(); })) {
	LLVM_DEBUG(DBGS() << "Unsupported op with non index type operands: "
	<< op << " -> skip\n");
	return failure();
	}
	// Check the remaining operations do not have regions or memory effects.
	auto effectInterface = dyn_cast<MemoryEffectOpInterface>(op);
	bool hasMemoryEffect = effectInterface && !effectInterface.hasNoEffect();
	if (hasMemoryEffect \|\| op->getNumRegions() != 0) {
	LLVM_DEBUG(DBGS() << "Unsupported op with region or memory effect: "
	<< op << " -> skip\n");
	return failure();
	}
	continue;
	}
	// Remove all other operations not used by the index computation. An
	// exception are constant operations that may be used by `padTensorOp`.
	if (!isa<arith::ConstantOp>(op))
	operationsToRemove.insert(op);
	}
	backwardSlice.set_subtract(operationsToRemove);
	return success();
	}

	SmallVector<Value>
	HoistingAnalysis::getPackedTensorSizes(ImplicitLocOpBuilder &b) {
	SmallVector<Value> dynamicTensorSizes;

	// Upper bound the packing loop lengths to size the packed tensor. Taking
	// upper bounds can make the sizes of the packed tensor independent of the
	// enclosing loops. This independence is a prerequisite for reusing the same
	// buffer for all enclosing loop iterations and hoisting its allocation out of
	// the enclosing loops.
	for (auto forOp : packingLoops) {
	// Compute an upper bound `ubVal` for the upper bound of `forOp`.
	AffineMap boundMap;
	SmallVector<Value> boundOperands;
	getUpperBoundForIndex(forOp.upperBound(), boundMap, boundOperands);
	Value ubVal = b.createOrFold<AffineMinOp>(boundMap, boundOperands);
	// Compute the maximal packing loop length as (ub - lb).ceilDiv(step) and
	// store the result to `dynamicTensorSizes`.
	// TODO: instead of using the lower bound of `forOp` directly, implement a
	// lower bound computation similar to the upper bound computation.
	AffineExpr lb, ub, step;
	bindDims(b.getContext(), lb, ub);
	bindSymbols(b.getContext(), step);
	Value res = b.createOrFold<AffineApplyOp>(
	(ub - lb).ceilDiv(step),
	ValueRange{forOp.lowerBound(), ubVal, cast<scf::ForOp>(forOp).step()});
	dynamicTensorSizes.push_back(res);
	}

	return dynamicTensorSizes;
	}

	static bool isDefinedOutsideOrConstant(scf::ForOp outer, Value v) {
	return outer.isDefinedOutsideOfLoop(v) \|\| v.getDefiningOp<ConstantOp>();
	}

	/// Return the current iteration number in the loop (iv - lb).ceilDiv(step).
	/// The returned Value is guaranteed not to depend on any loop comprised in
	/// [`outer`, `forOp`].
	/// Return null if such a loop-independent quantity cannot be computed.
	static Value buildLoopIterationCount(OpBuilder &b, scf::ForOp outer,
	scf::ForOp forOp) {
	MLIRContext *ctx = forOp->getContext();
	AffineExpr iv, lb, step;
	bindDims(ctx, iv, lb);
	bindSymbols(ctx, step);
	if (!isDefinedOutsideOrConstant(outer, forOp.lowerBound()) \|\|
	!isDefinedOutsideOrConstant(outer, forOp.step()))
	return Value();
	Value ivVal = forOp.getInductionVar(), lbVal = forOp.lowerBound(),
	stepVal = forOp.step();
	auto loc = forOp->getLoc();
	return b.createOrFold<AffineApplyOp>(loc, (iv - lb).ceilDiv(step),
	ValueRange{ivVal, lbVal, stepVal});
	}

	FailureOr<Value> mlir::linalg::hoistPaddingOnTensors(PadTensorOp opToHoist,
	int numLoops,
	PadTensorOp &hoistedOp) {
	LLVM_DEBUG(DBGS() << "Try to hoist " << *(opToHoist) << " by " << numLoops
	<< " loops\n");
	HoistingAnalysis analysis(opToHoist, numLoops);
	if (!analysis.isValid()) {
	LLVM_DEBUG(DBGS() << "Analysis failed -> Skip\n");
	return failure();
	}

	scf::ForOp outer = analysis.outermostEnclosingForOp;
	ImplicitLocOpBuilder b(outer->getLoc(), outer);

	SmallVector<Value> dynamicTensorSizes = analysis.getPackedTensorSizes(b);

	// Update actual number of loops, which may be smaller.
	int nPackedLoops = analysis.packingLoops.size();

	Location loc = opToHoist->getLoc();
	RankedTensorType paddedTensorType = opToHoist.getResultType();
	int paddedRank = paddedTensorType.getRank();

	// Create the packed tensor<?x?x..?xpadded_shape> into which we amortize
	// padding.
	SmallVector<int64_t> packedShape(nPackedLoops, ShapedType::kDynamicSize);
	// TODO: go grab dims when necessary, for now PadTensorOp returns a static
	// tensor.
	llvm::append_range(packedShape, paddedTensorType.getShape());
	auto packedTensorType =
	RankedTensorType::get(packedShape, paddedTensorType.getElementType());
	Value packedTensor = b.create<linalg::InitTensorOp>(
	loc, dynamicTensorSizes, packedTensorType.getShape(),
	packedTensorType.getElementType());

	// Clone the operations involved in the backward slice, iteratively stepping
	// into the loops that we encounter.
	// The implementation proceeds in a stack-like fashion:
	// 1. Iteratively clone and step into the loops, pushing the `packedTensor`
	// deeper in the stack.
	// 2. Create a InsertSliceOp at the top of the stack.
	// 3. Iteratively pop and yield the result of the InsertSliceOp across
	// the cloned loops.
	SmallVector<Value> clonedLoopIvs, leadingPackedTensorIndexings;
	clonedLoopIvs.reserve(nPackedLoops);
	leadingPackedTensorIndexings.reserve(nPackedLoops);
	BlockAndValueMapping bvm;
	// Stack step 1. iteratively clone loops and push `packedTensor`.
	for (Operation *op : analysis.backwardSlice) {
	// Specifically sit out in the extract_slice(packedTensor) case: this is the
	// piece we seek to replace.
	if (auto sliceOp = dyn_cast<tensor::ExtractSliceOp>(op))
	if (bvm.lookupOrDefault(sliceOp.source()) == packedTensor)
	continue;
	// Clone all operations except it is a loop.
	auto forOp = dyn_cast<scf::ForOp>(op);
	if (!forOp) {
	b.clone(*op, bvm);
	continue;
	}
	// Create a packing loop that takes `packedTensor` as iteration argument.
	auto clonedForOp =
	b.create<scf::ForOp>(loc, bvm.lookupOrDefault(forOp.lowerBound()),
	bvm.lookupOrDefault(forOp.upperBound()),
	bvm.lookupOrDefault(forOp.step()), packedTensor);
	// Map the induction var, region args and results to the `clonedForOp`.
	bvm.map(forOp.getInductionVar(), clonedForOp.getInductionVar());
	bvm.map(forOp.getRegionIterArgs(), clonedForOp.getRegionIterArgs());
	bvm.map(forOp.getResults(), clonedForOp.getResults());
	assert(clonedForOp->getNumRegions() == 1);
	clonedLoopIvs.push_back(clonedForOp.getInductionVar());

	b.setInsertionPointToStart(&clonedForOp->getRegion(0).front());
	Value loopIndependentIterationCount =
	buildLoopIterationCount(b, outer, clonedForOp);
	// Assert the loop-independent iteration count can be computed.
	if (!loopIndependentIterationCount)
	llvm_unreachable("loop independence prerequisite not met");
	leadingPackedTensorIndexings.push_back(loopIndependentIterationCount);
	packedTensor = clonedForOp.getRegionIterArgs().front();
	}

	// Stack step 2. create InsertSliceOp at the top of the stack.
	// offsets = [clonedLoopIvs, 0 .. 0].
	SmallVector<OpFoldResult> offsets(leadingPackedTensorIndexings.begin(),
	leadingPackedTensorIndexings.end());
	offsets.append(paddedRank, b.getIndexAttr(0));
	// sizes = [1 .. 1, paddedShape].
	SmallVector<OpFoldResult> sizes(nPackedLoops, b.getIndexAttr(1));
	for (int64_t sz : paddedTensorType.getShape()) {
	// TODO: go grab dims when necessary, for now PadTensorOp returns a static
	// tensor.
	assert(!ShapedType::isDynamic(sz) && "padded tensor needs static sizes");
	sizes.push_back(b.getIndexAttr(sz));
	}
	// strides = [1 .. 1].
	SmallVector<OpFoldResult> strides(nPackedLoops + paddedRank,
	b.getIndexAttr(1));

	Value inserted =
	b.create<tensor::InsertSliceOp>(loc, bvm.lookup(opToHoist.result()),
	packedTensor, offsets, sizes, strides);

	// Stack step 3. iteratively pop the stack and propagate the yield.
	Value valueToYield = inserted;
	for (Value iv : llvm::reverse(clonedLoopIvs)) {
	auto forOp = scf::getForInductionVarOwner(iv);
	b.setInsertionPointToEnd(&forOp.getRegion().front());
	b.create<scf::YieldOp>(loc, valueToYield);
	valueToYield = forOp.getResult(0);
	}

	// Now the packed tensor is ready, replace the original padding op by a
	// 1x..x1 slice [originalLoopIvs, 0 .. 0][1 .. 1, paddedShape][1 .. 1].
	b.setInsertionPoint(opToHoist);
	SmallVector<Value> loopIterationCounts = llvm::to_vector<4>(
	llvm::map_range(analysis.packingLoops, [&](Operation *loop) {
	return buildLoopIterationCount(b, outer, cast<scf::ForOp>(loop));
	}));
	// Assert all loop iteration counts can be computed.
	if (llvm::any_of(loopIterationCounts, [](Value v) { return !v; }))
	llvm_unreachable("loop independence prerequisite not met");
	// offsets = [originalLoopIvs, 0 .. 0].
	offsets.assign(loopIterationCounts.begin(), loopIterationCounts.end());
	offsets.append(paddedRank, b.getIndexAttr(0));
	// sizes = [1 .. 1, paddedShape] (definedabove).
	// strides = [1 .. 1] (defined above)
	packedTensor =
	scf::getForInductionVarOwner(clonedLoopIvs.front())->getResult(0);
	Value newResult = b.create<tensor::ExtractSliceOp>(
	loc, opToHoist.getResultType(), packedTensor, offsets, sizes, strides);

	// Make the newly cloned `opToHoist` available to the caller.
	hoistedOp = cast<PadTensorOp>(bvm.lookup(opToHoist.result()).getDefiningOp());
	return newResult;
	}