| //===- OptimizedBufferization.cpp - special cases for bufferization -------===// |
| // |
| // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. |
| // See https://llvm.org/LICENSE.txt for license information. |
| // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception |
| // |
| //===----------------------------------------------------------------------===// |
| // In some special cases we can bufferize hlfir expressions in a more optimal |
| // way so as to avoid creating temporaries. This pass handles these. It should |
| // be run before the catch-all bufferization pass. |
| // |
| // This requires constant subexpression elimination to have already been run. |
| //===----------------------------------------------------------------------===// |
| |
| #include "flang/Optimizer/Analysis/AliasAnalysis.h" |
| #include "flang/Optimizer/Builder/FIRBuilder.h" |
| #include "flang/Optimizer/Builder/HLFIRTools.h" |
| #include "flang/Optimizer/Dialect/FIROps.h" |
| #include "flang/Optimizer/Dialect/FIRType.h" |
| #include "flang/Optimizer/HLFIR/HLFIRDialect.h" |
| #include "flang/Optimizer/HLFIR/HLFIROps.h" |
| #include "flang/Optimizer/HLFIR/Passes.h" |
| #include "flang/Optimizer/Transforms/Utils.h" |
| #include "mlir/Dialect/Func/IR/FuncOps.h" |
| #include "mlir/IR/Dominance.h" |
| #include "mlir/IR/PatternMatch.h" |
| #include "mlir/Interfaces/SideEffectInterfaces.h" |
| #include "mlir/Pass/Pass.h" |
| #include "mlir/Support/LLVM.h" |
| #include "mlir/Transforms/GreedyPatternRewriteDriver.h" |
| #include "llvm/ADT/TypeSwitch.h" |
| #include <iterator> |
| #include <memory> |
| #include <mlir/Analysis/AliasAnalysis.h> |
| #include <optional> |
| |
| namespace hlfir { |
| #define GEN_PASS_DEF_OPTIMIZEDBUFFERIZATION |
| #include "flang/Optimizer/HLFIR/Passes.h.inc" |
| } // namespace hlfir |
| |
| #define DEBUG_TYPE "opt-bufferization" |
| |
| namespace { |
| |
| /// This transformation should match in place modification of arrays. |
| /// It should match code of the form |
| /// %array = some.operation // array has shape %shape |
| /// %expr = hlfir.elemental %shape : [...] { |
| /// bb0(%arg0: index) |
| /// %0 = hlfir.designate %array(%arg0) |
| /// [...] // no other reads or writes to %array |
| /// hlfir.yield_element %element |
| /// } |
| /// hlfir.assign %expr to %array |
| /// hlfir.destroy %expr |
| /// |
| /// Or |
| /// |
| /// %read_array = some.operation // shape %shape |
| /// %expr = hlfir.elemental %shape : [...] { |
| /// bb0(%arg0: index) |
| /// %0 = hlfir.designate %read_array(%arg0) |
| /// [...] |
| /// hlfir.yield_element %element |
| /// } |
| /// %write_array = some.operation // with shape %shape |
| /// [...] // operations which don't effect write_array |
| /// hlfir.assign %expr to %write_array |
| /// hlfir.destroy %expr |
| /// |
| /// In these cases, it is safe to turn the elemental into a do loop and modify |
| /// elements of %array in place without creating an extra temporary for the |
| /// elemental. We must check that there are no reads from the array at indexes |
| /// which might conflict with the assignment or any writes. For now we will keep |
| /// that strict and say that all reads must be at the elemental index (it is |
| /// probably safe to read from higher indices if lowering to an ordered loop). |
| class ElementalAssignBufferization |
| : public mlir::OpRewritePattern<hlfir::ElementalOp> { |
| private: |
| struct MatchInfo { |
| mlir::Value array; |
| hlfir::AssignOp assign; |
| hlfir::DestroyOp destroy; |
| }; |
| /// determines if the transformation can be applied to this elemental |
| static std::optional<MatchInfo> findMatch(hlfir::ElementalOp elemental); |
| |
| public: |
| using mlir::OpRewritePattern<hlfir::ElementalOp>::OpRewritePattern; |
| |
| mlir::LogicalResult |
| matchAndRewrite(hlfir::ElementalOp elemental, |
| mlir::PatternRewriter &rewriter) const override; |
| }; |
| |
| /// recursively collect all effects between start and end (including start, not |
| /// including end) start must properly dominate end, start and end must be in |
| /// the same block. If any operations with unknown effects are found, |
| /// std::nullopt is returned |
| static std::optional<mlir::SmallVector<mlir::MemoryEffects::EffectInstance>> |
| getEffectsBetween(mlir::Operation *start, mlir::Operation *end) { |
| mlir::SmallVector<mlir::MemoryEffects::EffectInstance> ret; |
| if (start == end) |
| return ret; |
| assert(start->getBlock() && end->getBlock() && "TODO: block arguments"); |
| assert(start->getBlock() == end->getBlock()); |
| assert(mlir::DominanceInfo{}.properlyDominates(start, end)); |
| |
| mlir::Operation *nextOp = start; |
| while (nextOp && nextOp != end) { |
| std::optional<mlir::SmallVector<mlir::MemoryEffects::EffectInstance>> |
| effects = mlir::getEffectsRecursively(nextOp); |
| if (!effects) |
| return std::nullopt; |
| ret.append(*effects); |
| nextOp = nextOp->getNextNode(); |
| } |
| return ret; |
| } |
| |
| /// If effect is a read or write on val, return whether it aliases. |
| /// Otherwise return mlir::AliasResult::NoAlias |
| static mlir::AliasResult |
| containsReadOrWriteEffectOn(const mlir::MemoryEffects::EffectInstance &effect, |
| mlir::Value val) { |
| fir::AliasAnalysis aliasAnalysis; |
| |
| if (mlir::isa<mlir::MemoryEffects::Read, mlir::MemoryEffects::Write>( |
| effect.getEffect())) { |
| mlir::Value accessedVal = effect.getValue(); |
| if (mlir::isa<fir::DebuggingResource>(effect.getResource())) |
| return mlir::AliasResult::NoAlias; |
| if (!accessedVal) |
| return mlir::AliasResult::MayAlias; |
| if (accessedVal == val) |
| return mlir::AliasResult::MustAlias; |
| |
| // if the accessed value might alias val |
| mlir::AliasResult res = aliasAnalysis.alias(val, accessedVal); |
| if (!res.isNo()) |
| return res; |
| |
| // FIXME: alias analysis of fir.load |
| // follow this common pattern: |
| // %ref = hlfir.designate %array(%index) |
| // %val = fir.load $ref |
| if (auto designate = accessedVal.getDefiningOp<hlfir::DesignateOp>()) { |
| if (designate.getMemref() == val) |
| return mlir::AliasResult::MustAlias; |
| |
| // if the designate is into an array that might alias val |
| res = aliasAnalysis.alias(val, designate.getMemref()); |
| if (!res.isNo()) |
| return res; |
| } |
| } |
| return mlir::AliasResult::NoAlias; |
| } |
| |
| // Returns true if the given array references represent identical |
| // or completely disjoint array slices. The callers may use this |
| // method when the alias analysis reports an alias of some kind, |
| // so that we can run Fortran specific analysis on the array slices |
| // to see if they are identical or disjoint. Note that the alias |
| // analysis are not able to give such an answer about the references. |
| static bool areIdenticalOrDisjointSlices(mlir::Value ref1, mlir::Value ref2) { |
| if (ref1 == ref2) |
| return true; |
| |
| auto des1 = ref1.getDefiningOp<hlfir::DesignateOp>(); |
| auto des2 = ref2.getDefiningOp<hlfir::DesignateOp>(); |
| // We only support a pair of designators right now. |
| if (!des1 || !des2) |
| return false; |
| |
| if (des1.getMemref() != des2.getMemref()) { |
| // If the bases are different, then there is unknown overlap. |
| LLVM_DEBUG(llvm::dbgs() << "No identical base for:\n" |
| << des1 << "and:\n" |
| << des2 << "\n"); |
| return false; |
| } |
| |
| // Require all components of the designators to be the same. |
| // It might be too strict, e.g. we may probably allow for |
| // different type parameters. |
| if (des1.getComponent() != des2.getComponent() || |
| des1.getComponentShape() != des2.getComponentShape() || |
| des1.getSubstring() != des2.getSubstring() || |
| des1.getComplexPart() != des2.getComplexPart() || |
| des1.getTypeparams() != des2.getTypeparams()) { |
| LLVM_DEBUG(llvm::dbgs() << "Different designator specs for:\n" |
| << des1 << "and:\n" |
| << des2 << "\n"); |
| return false; |
| } |
| |
| if (des1.getIsTriplet() != des2.getIsTriplet()) { |
| LLVM_DEBUG(llvm::dbgs() << "Different sections for:\n" |
| << des1 << "and:\n" |
| << des2 << "\n"); |
| return false; |
| } |
| |
| // Analyze the subscripts. |
| // For example: |
| // hlfir.designate %6#0 (%c2:%c7999:%c1, %c1:%c120:%c1, %0) shape %9 |
| // hlfir.designate %6#0 (%c2:%c7999:%c1, %c1:%c120:%c1, %1) shape %9 |
| // |
| // If all the triplets (section speficiers) are the same, then |
| // we do not care if %0 is equal to %1 - the slices are either |
| // identical or completely disjoint. |
| auto des1It = des1.getIndices().begin(); |
| auto des2It = des2.getIndices().begin(); |
| bool identicalTriplets = true; |
| for (bool isTriplet : des1.getIsTriplet()) { |
| if (isTriplet) { |
| for (int i = 0; i < 3; ++i) |
| if (*des1It++ != *des2It++) { |
| LLVM_DEBUG(llvm::dbgs() << "Triplet mismatch for:\n" |
| << des1 << "and:\n" |
| << des2 << "\n"); |
| identicalTriplets = false; |
| break; |
| } |
| } else { |
| ++des1It; |
| ++des2It; |
| } |
| } |
| if (identicalTriplets) |
| return true; |
| |
| // See if we can prove that any of the triplets do not overlap. |
| // This is mostly a Polyhedron/nf performance hack that looks for |
| // particular relations between the lower and upper bounds |
| // of the array sections, e.g. for any positive constant C: |
| // X:Y does not overlap with (Y+C):Z |
| // X:Y does not overlap with Z:(X-C) |
| auto displacedByConstant = [](mlir::Value v1, mlir::Value v2) { |
| auto removeConvert = [](mlir::Value v) -> mlir::Operation * { |
| auto *op = v.getDefiningOp(); |
| while (auto conv = mlir::dyn_cast_or_null<fir::ConvertOp>(op)) |
| op = conv.getValue().getDefiningOp(); |
| return op; |
| }; |
| |
| auto isPositiveConstant = [](mlir::Value v) -> bool { |
| if (auto conOp = |
| mlir::dyn_cast<mlir::arith::ConstantOp>(v.getDefiningOp())) |
| if (auto iattr = mlir::dyn_cast<mlir::IntegerAttr>(conOp.getValue())) |
| return iattr.getInt() > 0; |
| return false; |
| }; |
| |
| auto *op1 = removeConvert(v1); |
| auto *op2 = removeConvert(v2); |
| if (!op1 || !op2) |
| return false; |
| if (auto addi = mlir::dyn_cast<mlir::arith::AddIOp>(op2)) |
| if ((addi.getLhs().getDefiningOp() == op1 && |
| isPositiveConstant(addi.getRhs())) || |
| (addi.getRhs().getDefiningOp() == op1 && |
| isPositiveConstant(addi.getLhs()))) |
| return true; |
| if (auto subi = mlir::dyn_cast<mlir::arith::SubIOp>(op1)) |
| if (subi.getLhs().getDefiningOp() == op2 && |
| isPositiveConstant(subi.getRhs())) |
| return true; |
| return false; |
| }; |
| |
| des1It = des1.getIndices().begin(); |
| des2It = des2.getIndices().begin(); |
| for (bool isTriplet : des1.getIsTriplet()) { |
| if (isTriplet) { |
| mlir::Value des1Lb = *des1It++; |
| mlir::Value des1Ub = *des1It++; |
| mlir::Value des2Lb = *des2It++; |
| mlir::Value des2Ub = *des2It++; |
| // Ignore strides. |
| ++des1It; |
| ++des2It; |
| if (displacedByConstant(des1Ub, des2Lb) || |
| displacedByConstant(des2Ub, des1Lb)) |
| return true; |
| } else { |
| ++des1It; |
| ++des2It; |
| } |
| } |
| |
| return false; |
| } |
| |
| std::optional<ElementalAssignBufferization::MatchInfo> |
| ElementalAssignBufferization::findMatch(hlfir::ElementalOp elemental) { |
| mlir::Operation::user_range users = elemental->getUsers(); |
| // the only uses of the elemental should be the assignment and the destroy |
| if (std::distance(users.begin(), users.end()) != 2) { |
| LLVM_DEBUG(llvm::dbgs() << "Too many uses of the elemental\n"); |
| return std::nullopt; |
| } |
| |
| // If the ElementalOp must produce a temporary (e.g. for |
| // finalization purposes), then we cannot inline it. |
| if (hlfir::elementalOpMustProduceTemp(elemental)) { |
| LLVM_DEBUG(llvm::dbgs() << "ElementalOp must produce a temp\n"); |
| return std::nullopt; |
| } |
| |
| MatchInfo match; |
| for (mlir::Operation *user : users) |
| mlir::TypeSwitch<mlir::Operation *, void>(user) |
| .Case([&](hlfir::AssignOp op) { match.assign = op; }) |
| .Case([&](hlfir::DestroyOp op) { match.destroy = op; }); |
| |
| if (!match.assign || !match.destroy) { |
| LLVM_DEBUG(llvm::dbgs() << "Couldn't find assign or destroy\n"); |
| return std::nullopt; |
| } |
| |
| // the array is what the elemental is assigned into |
| // TODO: this could be extended to also allow hlfir.expr by first bufferizing |
| // the incoming expression |
| match.array = match.assign.getLhs(); |
| mlir::Type arrayType = mlir::dyn_cast<fir::SequenceType>( |
| fir::unwrapPassByRefType(match.array.getType())); |
| if (!arrayType) |
| return std::nullopt; |
| |
| // require that the array elements are trivial |
| // TODO: this is just to make the pass easier to think about. Not an inherent |
| // limitation |
| mlir::Type eleTy = hlfir::getFortranElementType(arrayType); |
| if (!fir::isa_trivial(eleTy)) |
| return std::nullopt; |
| |
| // the array must have the same shape as the elemental. CSE should have |
| // deduplicated the fir.shape operations where they are provably the same |
| // so we just have to check for the same ssa value |
| // TODO: add more ways of getting the shape of the array |
| mlir::Value arrayShape; |
| if (match.array.getDefiningOp()) |
| arrayShape = |
| mlir::TypeSwitch<mlir::Operation *, mlir::Value>( |
| match.array.getDefiningOp()) |
| .Case([](hlfir::DesignateOp designate) { |
| return designate.getShape(); |
| }) |
| .Case([](hlfir::DeclareOp declare) { return declare.getShape(); }) |
| .Default([](mlir::Operation *) { return mlir::Value{}; }); |
| if (!arrayShape) { |
| LLVM_DEBUG(llvm::dbgs() << "Can't get shape of " << match.array << " at " |
| << elemental->getLoc() << "\n"); |
| return std::nullopt; |
| } |
| if (arrayShape != elemental.getShape()) { |
| // f2018 10.2.1.2 (3) requires the lhs and rhs of an assignment to be |
| // conformable unless the lhs is an allocatable array. In HLFIR we can |
| // see this from the presence or absence of the realloc attribute on |
| // hlfir.assign. If it is not a realloc assignment, we can trust that |
| // the shapes do conform |
| if (match.assign.getRealloc()) |
| return std::nullopt; |
| } |
| |
| // the transformation wants to apply the elemental in a do-loop at the |
| // hlfir.assign, check there are no effects which make this unsafe |
| |
| // keep track of any values written to in the elemental, as these can't be |
| // read from between the elemental and the assignment |
| // likewise, values read in the elemental cannot be written to between the |
| // elemental and the assign |
| mlir::SmallVector<mlir::Value, 1> notToBeAccessedBeforeAssign; |
| // any accesses to the array between the array and the assignment means it |
| // would be unsafe to move the elemental to the assignment |
| notToBeAccessedBeforeAssign.push_back(match.array); |
| |
| // 1) side effects in the elemental body - it isn't sufficient to just look |
| // for ordered elementals because we also cannot support out of order reads |
| std::optional<mlir::SmallVector<mlir::MemoryEffects::EffectInstance>> |
| effects = getEffectsBetween(&elemental.getBody()->front(), |
| elemental.getBody()->getTerminator()); |
| if (!effects) { |
| LLVM_DEBUG(llvm::dbgs() |
| << "operation with unknown effects inside elemental\n"); |
| return std::nullopt; |
| } |
| for (const mlir::MemoryEffects::EffectInstance &effect : *effects) { |
| mlir::AliasResult res = containsReadOrWriteEffectOn(effect, match.array); |
| if (res.isNo()) { |
| if (mlir::isa<mlir::MemoryEffects::Write, mlir::MemoryEffects::Read>( |
| effect.getEffect())) |
| if (effect.getValue()) |
| notToBeAccessedBeforeAssign.push_back(effect.getValue()); |
| |
| // this is safe in the elemental |
| continue; |
| } |
| |
| // don't allow any aliasing writes in the elemental |
| if (mlir::isa<mlir::MemoryEffects::Write>(effect.getEffect())) { |
| LLVM_DEBUG(llvm::dbgs() << "write inside the elemental body\n"); |
| return std::nullopt; |
| } |
| |
| // allow if and only if the reads are from the elemental indices, in order |
| // => each iteration doesn't read values written by other iterations |
| // don't allow reads from a different value which may alias: fir alias |
| // analysis isn't precise enough to tell us if two aliasing arrays overlap |
| // exactly or only partially. If they overlap partially, a designate at the |
| // elemental indices could be accessing different elements: e.g. we could |
| // designate two slices of the same array at different start indexes. These |
| // two MustAlias but index 1 of one array isn't the same element as index 1 |
| // of the other array. |
| if (!res.isPartial()) { |
| if (auto designate = |
| effect.getValue().getDefiningOp<hlfir::DesignateOp>()) { |
| if (!areIdenticalOrDisjointSlices(match.array, designate.getMemref())) { |
| LLVM_DEBUG(llvm::dbgs() << "possible read conflict: " << designate |
| << " at " << elemental.getLoc() << "\n"); |
| return std::nullopt; |
| } |
| auto indices = designate.getIndices(); |
| auto elementalIndices = elemental.getIndices(); |
| if (indices.size() != elementalIndices.size()) { |
| LLVM_DEBUG(llvm::dbgs() << "possible read conflict: " << designate |
| << " at " << elemental.getLoc() << "\n"); |
| return std::nullopt; |
| } |
| if (std::equal(indices.begin(), indices.end(), elementalIndices.begin(), |
| elementalIndices.end())) |
| continue; |
| } |
| } |
| LLVM_DEBUG(llvm::dbgs() << "disallowed side-effect: " << effect.getValue() |
| << " for " << elemental.getLoc() << "\n"); |
| return std::nullopt; |
| } |
| |
| // 2) look for conflicting effects between the elemental and the assignment |
| effects = getEffectsBetween(elemental->getNextNode(), match.assign); |
| if (!effects) { |
| LLVM_DEBUG( |
| llvm::dbgs() |
| << "operation with unknown effects between elemental and assign\n"); |
| return std::nullopt; |
| } |
| for (const mlir::MemoryEffects::EffectInstance &effect : *effects) { |
| // not safe to access anything written in the elemental as this write |
| // will be moved to the assignment |
| for (mlir::Value val : notToBeAccessedBeforeAssign) { |
| mlir::AliasResult res = containsReadOrWriteEffectOn(effect, val); |
| if (!res.isNo()) { |
| LLVM_DEBUG(llvm::dbgs() |
| << "diasllowed side-effect: " << effect.getValue() << " for " |
| << elemental.getLoc() << "\n"); |
| return std::nullopt; |
| } |
| } |
| } |
| |
| return match; |
| } |
| |
| mlir::LogicalResult ElementalAssignBufferization::matchAndRewrite( |
| hlfir::ElementalOp elemental, mlir::PatternRewriter &rewriter) const { |
| std::optional<MatchInfo> match = findMatch(elemental); |
| if (!match) |
| return rewriter.notifyMatchFailure( |
| elemental, "cannot prove safety of ElementalAssignBufferization"); |
| |
| mlir::Location loc = elemental->getLoc(); |
| fir::FirOpBuilder builder(rewriter, elemental.getOperation()); |
| auto extents = hlfir::getIndexExtents(loc, builder, elemental.getShape()); |
| |
| // create the loop at the assignment |
| builder.setInsertionPoint(match->assign); |
| |
| // Generate a loop nest looping around the hlfir.elemental shape and clone |
| // hlfir.elemental region inside the inner loop |
| hlfir::LoopNest loopNest = |
| hlfir::genLoopNest(loc, builder, extents, !elemental.isOrdered()); |
| builder.setInsertionPointToStart(loopNest.innerLoop.getBody()); |
| auto yield = hlfir::inlineElementalOp(loc, builder, elemental, |
| loopNest.oneBasedIndices); |
| hlfir::Entity elementValue{yield.getElementValue()}; |
| rewriter.eraseOp(yield); |
| |
| // Assign the element value to the array element for this iteration. |
| auto arrayElement = hlfir::getElementAt( |
| loc, builder, hlfir::Entity{match->array}, loopNest.oneBasedIndices); |
| builder.create<hlfir::AssignOp>( |
| loc, elementValue, arrayElement, /*realloc=*/false, |
| /*keep_lhs_length_if_realloc=*/false, match->assign.getTemporaryLhs()); |
| |
| rewriter.eraseOp(match->assign); |
| rewriter.eraseOp(match->destroy); |
| rewriter.eraseOp(elemental); |
| return mlir::success(); |
| } |
| |
| /// Expand hlfir.assign of a scalar RHS to array LHS into a loop nest |
| /// of element-by-element assignments: |
| /// hlfir.assign %cst to %0 : f32, !fir.ref<!fir.array<6x6xf32>> |
| /// into: |
| /// fir.do_loop %arg0 = %c1 to %c6 step %c1 unordered { |
| /// fir.do_loop %arg1 = %c1 to %c6 step %c1 unordered { |
| /// %1 = hlfir.designate %0 (%arg1, %arg0) : |
| /// (!fir.ref<!fir.array<6x6xf32>>, index, index) -> !fir.ref<f32> |
| /// hlfir.assign %cst to %1 : f32, !fir.ref<f32> |
| /// } |
| /// } |
| class BroadcastAssignBufferization |
| : public mlir::OpRewritePattern<hlfir::AssignOp> { |
| private: |
| public: |
| using mlir::OpRewritePattern<hlfir::AssignOp>::OpRewritePattern; |
| |
| mlir::LogicalResult |
| matchAndRewrite(hlfir::AssignOp assign, |
| mlir::PatternRewriter &rewriter) const override; |
| }; |
| |
| mlir::LogicalResult BroadcastAssignBufferization::matchAndRewrite( |
| hlfir::AssignOp assign, mlir::PatternRewriter &rewriter) const { |
| // Since RHS is a scalar and LHS is an array, LHS must be allocated |
| // in a conforming Fortran program, and LHS cannot be reallocated |
| // as a result of the assignment. So we can ignore isAllocatableAssignment |
| // and do the transformation always. |
| mlir::Value rhs = assign.getRhs(); |
| if (!fir::isa_trivial(rhs.getType())) |
| return rewriter.notifyMatchFailure( |
| assign, "AssignOp's RHS is not a trivial scalar"); |
| |
| hlfir::Entity lhs{assign.getLhs()}; |
| if (!lhs.isArray()) |
| return rewriter.notifyMatchFailure(assign, |
| "AssignOp's LHS is not an array"); |
| |
| mlir::Type eleTy = lhs.getFortranElementType(); |
| if (!fir::isa_trivial(eleTy)) |
| return rewriter.notifyMatchFailure( |
| assign, "AssignOp's LHS data type is not trivial"); |
| |
| mlir::Location loc = assign->getLoc(); |
| fir::FirOpBuilder builder(rewriter, assign.getOperation()); |
| builder.setInsertionPoint(assign); |
| lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs); |
| mlir::Value shape = hlfir::genShape(loc, builder, lhs); |
| llvm::SmallVector<mlir::Value> extents = |
| hlfir::getIndexExtents(loc, builder, shape); |
| hlfir::LoopNest loopNest = |
| hlfir::genLoopNest(loc, builder, extents, /*isUnordered=*/true); |
| builder.setInsertionPointToStart(loopNest.innerLoop.getBody()); |
| auto arrayElement = |
| hlfir::getElementAt(loc, builder, lhs, loopNest.oneBasedIndices); |
| builder.create<hlfir::AssignOp>(loc, rhs, arrayElement); |
| rewriter.eraseOp(assign); |
| return mlir::success(); |
| } |
| |
| /// Expand hlfir.assign of array RHS to array LHS into a loop nest |
| /// of element-by-element assignments: |
| /// hlfir.assign %4 to %5 : !fir.ref<!fir.array<3x3xf32>>, |
| /// !fir.ref<!fir.array<3x3xf32>> |
| /// into: |
| /// fir.do_loop %arg1 = %c1 to %c3 step %c1 unordered { |
| /// fir.do_loop %arg2 = %c1 to %c3 step %c1 unordered { |
| /// %6 = hlfir.designate %4 (%arg2, %arg1) : |
| /// (!fir.ref<!fir.array<3x3xf32>>, index, index) -> !fir.ref<f32> |
| /// %7 = fir.load %6 : !fir.ref<f32> |
| /// %8 = hlfir.designate %5 (%arg2, %arg1) : |
| /// (!fir.ref<!fir.array<3x3xf32>>, index, index) -> !fir.ref<f32> |
| /// hlfir.assign %7 to %8 : f32, !fir.ref<f32> |
| /// } |
| /// } |
| /// |
| /// The transformation is correct only when LHS and RHS do not alias. |
| /// This transformation does not support runtime checking for |
| /// non-conforming LHS/RHS arrays' shapes currently. |
| class VariableAssignBufferization |
| : public mlir::OpRewritePattern<hlfir::AssignOp> { |
| private: |
| public: |
| using mlir::OpRewritePattern<hlfir::AssignOp>::OpRewritePattern; |
| |
| mlir::LogicalResult |
| matchAndRewrite(hlfir::AssignOp assign, |
| mlir::PatternRewriter &rewriter) const override; |
| }; |
| |
| mlir::LogicalResult VariableAssignBufferization::matchAndRewrite( |
| hlfir::AssignOp assign, mlir::PatternRewriter &rewriter) const { |
| if (assign.isAllocatableAssignment()) |
| return rewriter.notifyMatchFailure(assign, "AssignOp may imply allocation"); |
| |
| hlfir::Entity rhs{assign.getRhs()}; |
| // TODO: ExprType check is here to avoid conflicts with |
| // ElementalAssignBufferization pattern. We need to combine |
| // these matchers into a single one that applies to AssignOp. |
| if (mlir::isa<hlfir::ExprType>(rhs.getType())) |
| return rewriter.notifyMatchFailure(assign, "RHS is not in memory"); |
| |
| if (!rhs.isArray()) |
| return rewriter.notifyMatchFailure(assign, |
| "AssignOp's RHS is not an array"); |
| |
| mlir::Type rhsEleTy = rhs.getFortranElementType(); |
| if (!fir::isa_trivial(rhsEleTy)) |
| return rewriter.notifyMatchFailure( |
| assign, "AssignOp's RHS data type is not trivial"); |
| |
| hlfir::Entity lhs{assign.getLhs()}; |
| if (!lhs.isArray()) |
| return rewriter.notifyMatchFailure(assign, |
| "AssignOp's LHS is not an array"); |
| |
| mlir::Type lhsEleTy = lhs.getFortranElementType(); |
| if (!fir::isa_trivial(lhsEleTy)) |
| return rewriter.notifyMatchFailure( |
| assign, "AssignOp's LHS data type is not trivial"); |
| |
| if (lhsEleTy != rhsEleTy) |
| return rewriter.notifyMatchFailure(assign, |
| "RHS/LHS element types mismatch"); |
| |
| fir::AliasAnalysis aliasAnalysis; |
| mlir::AliasResult aliasRes = aliasAnalysis.alias(lhs, rhs); |
| // TODO: use areIdenticalOrDisjointSlices() to check if |
| // we can still do the expansion. |
| if (!aliasRes.isNo()) { |
| LLVM_DEBUG(llvm::dbgs() << "VariableAssignBufferization:\n" |
| << "\tLHS: " << lhs << "\n" |
| << "\tRHS: " << rhs << "\n" |
| << "\tALIAS: " << aliasRes << "\n"); |
| return rewriter.notifyMatchFailure(assign, "RHS/LHS may alias"); |
| } |
| |
| mlir::Location loc = assign->getLoc(); |
| fir::FirOpBuilder builder(rewriter, assign.getOperation()); |
| builder.setInsertionPoint(assign); |
| rhs = hlfir::derefPointersAndAllocatables(loc, builder, rhs); |
| lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs); |
| mlir::Value shape = hlfir::genShape(loc, builder, lhs); |
| llvm::SmallVector<mlir::Value> extents = |
| hlfir::getIndexExtents(loc, builder, shape); |
| hlfir::LoopNest loopNest = |
| hlfir::genLoopNest(loc, builder, extents, /*isUnordered=*/true); |
| builder.setInsertionPointToStart(loopNest.innerLoop.getBody()); |
| auto rhsArrayElement = |
| hlfir::getElementAt(loc, builder, rhs, loopNest.oneBasedIndices); |
| rhsArrayElement = hlfir::loadTrivialScalar(loc, builder, rhsArrayElement); |
| auto lhsArrayElement = |
| hlfir::getElementAt(loc, builder, lhs, loopNest.oneBasedIndices); |
| builder.create<hlfir::AssignOp>(loc, rhsArrayElement, lhsArrayElement); |
| rewriter.eraseOp(assign); |
| return mlir::success(); |
| } |
| |
| using GenBodyFn = |
| std::function<mlir::Value(fir::FirOpBuilder &, mlir::Location, mlir::Value, |
| const llvm::SmallVectorImpl<mlir::Value> &)>; |
| static mlir::Value generateReductionLoop(fir::FirOpBuilder &builder, |
| mlir::Location loc, mlir::Value init, |
| mlir::Value shape, GenBodyFn genBody) { |
| auto extents = hlfir::getIndexExtents(loc, builder, shape); |
| mlir::Value reduction = init; |
| mlir::IndexType idxTy = builder.getIndexType(); |
| mlir::Value oneIdx = builder.createIntegerConstant(loc, idxTy, 1); |
| |
| // Create a reduction loop nest. We use one-based indices so that they can be |
| // passed to the elemental, and reverse the order so that they can be |
| // generated in column-major order for better performance. |
| llvm::SmallVector<mlir::Value> indices(extents.size(), mlir::Value{}); |
| for (unsigned i = 0; i < extents.size(); ++i) { |
| auto loop = builder.create<fir::DoLoopOp>( |
| loc, oneIdx, extents[extents.size() - i - 1], oneIdx, false, |
| /*finalCountValue=*/false, reduction); |
| reduction = loop.getRegionIterArgs()[0]; |
| indices[extents.size() - i - 1] = loop.getInductionVar(); |
| // Set insertion point to the loop body so that the next loop |
| // is inserted inside the current one. |
| builder.setInsertionPointToStart(loop.getBody()); |
| } |
| |
| // Generate the body |
| reduction = genBody(builder, loc, reduction, indices); |
| |
| // Unwind the loop nest. |
| for (unsigned i = 0; i < extents.size(); ++i) { |
| auto result = builder.create<fir::ResultOp>(loc, reduction); |
| auto loop = mlir::cast<fir::DoLoopOp>(result->getParentOp()); |
| reduction = loop.getResult(0); |
| // Set insertion point after the loop operation that we have |
| // just processed. |
| builder.setInsertionPointAfter(loop.getOperation()); |
| } |
| |
| return reduction; |
| } |
| |
| /// Given a reduction operation with an elemental mask, attempt to generate a |
| /// do-loop to perform the operation inline. |
| /// %e = hlfir.elemental %shape unordered |
| /// %r = hlfir.count %e |
| /// => |
| /// %r = for.do_loop %arg = 1 to bound(%shape) step 1 iter_args(%arg2 = init) |
| /// %i = <inline elemental> |
| /// %c = <reduce count> %i |
| /// fir.result %c |
| template <typename Op> |
| class ReductionElementalConversion : public mlir::OpRewritePattern<Op> { |
| public: |
| using mlir::OpRewritePattern<Op>::OpRewritePattern; |
| |
| mlir::LogicalResult |
| matchAndRewrite(Op op, mlir::PatternRewriter &rewriter) const override { |
| mlir::Location loc = op.getLoc(); |
| hlfir::ElementalOp elemental = |
| op.getMask().template getDefiningOp<hlfir::ElementalOp>(); |
| if (!elemental || op.getDim()) |
| return rewriter.notifyMatchFailure(op, "Did not find valid elemental"); |
| |
| fir::KindMapping kindMap = |
| fir::getKindMapping(op->template getParentOfType<mlir::ModuleOp>()); |
| fir::FirOpBuilder builder{op, kindMap}; |
| |
| mlir::Value init; |
| GenBodyFn genBodyFn; |
| if constexpr (std::is_same_v<Op, hlfir::AnyOp>) { |
| init = builder.createIntegerConstant(loc, builder.getI1Type(), 0); |
| genBodyFn = [elemental](fir::FirOpBuilder builder, mlir::Location loc, |
| mlir::Value reduction, |
| const llvm::SmallVectorImpl<mlir::Value> &indices) |
| -> mlir::Value { |
| // Inline the elemental and get the condition from it. |
| auto yield = inlineElementalOp(loc, builder, elemental, indices); |
| mlir::Value cond = builder.create<fir::ConvertOp>( |
| loc, builder.getI1Type(), yield.getElementValue()); |
| yield->erase(); |
| |
| // Conditionally set the reduction variable. |
| return builder.create<mlir::arith::OrIOp>(loc, reduction, cond); |
| }; |
| } else if constexpr (std::is_same_v<Op, hlfir::AllOp>) { |
| init = builder.createIntegerConstant(loc, builder.getI1Type(), 1); |
| genBodyFn = [elemental](fir::FirOpBuilder builder, mlir::Location loc, |
| mlir::Value reduction, |
| const llvm::SmallVectorImpl<mlir::Value> &indices) |
| -> mlir::Value { |
| // Inline the elemental and get the condition from it. |
| auto yield = inlineElementalOp(loc, builder, elemental, indices); |
| mlir::Value cond = builder.create<fir::ConvertOp>( |
| loc, builder.getI1Type(), yield.getElementValue()); |
| yield->erase(); |
| |
| // Conditionally set the reduction variable. |
| return builder.create<mlir::arith::AndIOp>(loc, reduction, cond); |
| }; |
| } else if constexpr (std::is_same_v<Op, hlfir::CountOp>) { |
| init = builder.createIntegerConstant(loc, op.getType(), 0); |
| genBodyFn = [elemental](fir::FirOpBuilder builder, mlir::Location loc, |
| mlir::Value reduction, |
| const llvm::SmallVectorImpl<mlir::Value> &indices) |
| -> mlir::Value { |
| // Inline the elemental and get the condition from it. |
| auto yield = inlineElementalOp(loc, builder, elemental, indices); |
| mlir::Value cond = builder.create<fir::ConvertOp>( |
| loc, builder.getI1Type(), yield.getElementValue()); |
| yield->erase(); |
| |
| // Conditionally add one to the current value |
| mlir::Value one = |
| builder.createIntegerConstant(loc, reduction.getType(), 1); |
| mlir::Value add1 = |
| builder.create<mlir::arith::AddIOp>(loc, reduction, one); |
| return builder.create<mlir::arith::SelectOp>(loc, cond, add1, |
| reduction); |
| }; |
| } else { |
| return mlir::failure(); |
| } |
| |
| mlir::Value res = generateReductionLoop(builder, loc, init, |
| elemental.getOperand(0), genBodyFn); |
| if (res.getType() != op.getType()) |
| res = builder.create<fir::ConvertOp>(loc, op.getType(), res); |
| |
| // Check if the op was the only user of the elemental (apart from a |
| // destroy), and remove it if so. |
| mlir::Operation::user_range elemUsers = elemental->getUsers(); |
| hlfir::DestroyOp elemDestroy; |
| if (std::distance(elemUsers.begin(), elemUsers.end()) == 2) { |
| elemDestroy = mlir::dyn_cast<hlfir::DestroyOp>(*elemUsers.begin()); |
| if (!elemDestroy) |
| elemDestroy = mlir::dyn_cast<hlfir::DestroyOp>(*++elemUsers.begin()); |
| } |
| |
| rewriter.replaceOp(op, res); |
| if (elemDestroy) { |
| rewriter.eraseOp(elemDestroy); |
| rewriter.eraseOp(elemental); |
| } |
| return mlir::success(); |
| } |
| }; |
| |
| // Look for minloc(mask=elemental) and generate the minloc loop with |
| // inlined elemental. |
| // %e = hlfir.elemental %shape ({ ... }) |
| // %m = hlfir.minloc %array mask %e |
| template <typename Op> |
| class MinMaxlocElementalConversion : public mlir::OpRewritePattern<Op> { |
| public: |
| using mlir::OpRewritePattern<Op>::OpRewritePattern; |
| |
| mlir::LogicalResult |
| matchAndRewrite(Op mloc, mlir::PatternRewriter &rewriter) const override { |
| if (!mloc.getMask() || mloc.getDim() || mloc.getBack()) |
| return rewriter.notifyMatchFailure(mloc, |
| "Did not find valid minloc/maxloc"); |
| |
| bool isMax = std::is_same_v<Op, hlfir::MaxlocOp>; |
| |
| auto elemental = |
| mloc.getMask().template getDefiningOp<hlfir::ElementalOp>(); |
| if (!elemental || hlfir::elementalOpMustProduceTemp(elemental)) |
| return rewriter.notifyMatchFailure(mloc, "Did not find elemental"); |
| |
| mlir::Value array = mloc.getArray(); |
| |
| unsigned rank = mlir::cast<hlfir::ExprType>(mloc.getType()).getShape()[0]; |
| mlir::Type arrayType = array.getType(); |
| if (!mlir::isa<fir::BoxType>(arrayType)) |
| return rewriter.notifyMatchFailure( |
| mloc, "Currently requires a boxed type input"); |
| mlir::Type elementType = hlfir::getFortranElementType(arrayType); |
| if (!fir::isa_trivial(elementType)) |
| return rewriter.notifyMatchFailure( |
| mloc, "Character arrays are currently not handled"); |
| |
| mlir::Location loc = mloc.getLoc(); |
| fir::FirOpBuilder builder{rewriter, mloc.getOperation()}; |
| mlir::Value resultArr = builder.createTemporary( |
| loc, fir::SequenceType::get( |
| rank, hlfir::getFortranElementType(mloc.getType()))); |
| |
| auto init = [isMax](fir::FirOpBuilder builder, mlir::Location loc, |
| mlir::Type elementType) { |
| if (auto ty = mlir::dyn_cast<mlir::FloatType>(elementType)) { |
| const llvm::fltSemantics &sem = ty.getFloatSemantics(); |
| llvm::APFloat limit = llvm::APFloat::getInf(sem, /*Negative=*/isMax); |
| return builder.createRealConstant(loc, elementType, limit); |
| } |
| unsigned bits = elementType.getIntOrFloatBitWidth(); |
| int64_t limitInt = |
| isMax ? llvm::APInt::getSignedMinValue(bits).getSExtValue() |
| : llvm::APInt::getSignedMaxValue(bits).getSExtValue(); |
| return builder.createIntegerConstant(loc, elementType, limitInt); |
| }; |
| |
| auto genBodyOp = |
| [&rank, &resultArr, &elemental, isMax]( |
| fir::FirOpBuilder builder, mlir::Location loc, |
| mlir::Type elementType, mlir::Value array, mlir::Value flagRef, |
| mlir::Value reduction, |
| const llvm::SmallVectorImpl<mlir::Value> &indices) -> mlir::Value { |
| // We are in the innermost loop: generate the elemental inline |
| mlir::Value oneIdx = |
| builder.createIntegerConstant(loc, builder.getIndexType(), 1); |
| llvm::SmallVector<mlir::Value> oneBasedIndices; |
| llvm::transform( |
| indices, std::back_inserter(oneBasedIndices), [&](mlir::Value V) { |
| return builder.create<mlir::arith::AddIOp>(loc, V, oneIdx); |
| }); |
| hlfir::YieldElementOp yield = |
| hlfir::inlineElementalOp(loc, builder, elemental, oneBasedIndices); |
| mlir::Value maskElem = yield.getElementValue(); |
| yield->erase(); |
| |
| mlir::Type ifCompatType = builder.getI1Type(); |
| mlir::Value ifCompatElem = |
| builder.create<fir::ConvertOp>(loc, ifCompatType, maskElem); |
| |
| llvm::SmallVector<mlir::Type> resultsTy = {elementType, elementType}; |
| fir::IfOp maskIfOp = |
| builder.create<fir::IfOp>(loc, elementType, ifCompatElem, |
| /*withElseRegion=*/true); |
| builder.setInsertionPointToStart(&maskIfOp.getThenRegion().front()); |
| |
| // Set flag that mask was true at some point |
| mlir::Value flagSet = builder.createIntegerConstant( |
| loc, mlir::cast<fir::ReferenceType>(flagRef.getType()).getEleTy(), 1); |
| mlir::Value isFirst = builder.create<fir::LoadOp>(loc, flagRef); |
| mlir::Value addr = hlfir::getElementAt(loc, builder, hlfir::Entity{array}, |
| oneBasedIndices); |
| mlir::Value elem = builder.create<fir::LoadOp>(loc, addr); |
| |
| // Compare with the max reduction value |
| mlir::Value cmp; |
| if (mlir::isa<mlir::FloatType>(elementType)) { |
| // For FP reductions we want the first smallest value to be used, that |
| // is not NaN. A OGL/OLT condition will usually work for this unless all |
| // the values are Nan or Inf. This follows the same logic as |
| // NumericCompare for Minloc/Maxlox in extrema.cpp. |
| cmp = builder.create<mlir::arith::CmpFOp>( |
| loc, |
| isMax ? mlir::arith::CmpFPredicate::OGT |
| : mlir::arith::CmpFPredicate::OLT, |
| elem, reduction); |
| |
| mlir::Value cmpNan = builder.create<mlir::arith::CmpFOp>( |
| loc, mlir::arith::CmpFPredicate::UNE, reduction, reduction); |
| mlir::Value cmpNan2 = builder.create<mlir::arith::CmpFOp>( |
| loc, mlir::arith::CmpFPredicate::OEQ, elem, elem); |
| cmpNan = builder.create<mlir::arith::AndIOp>(loc, cmpNan, cmpNan2); |
| cmp = builder.create<mlir::arith::OrIOp>(loc, cmp, cmpNan); |
| } else if (mlir::isa<mlir::IntegerType>(elementType)) { |
| cmp = builder.create<mlir::arith::CmpIOp>( |
| loc, |
| isMax ? mlir::arith::CmpIPredicate::sgt |
| : mlir::arith::CmpIPredicate::slt, |
| elem, reduction); |
| } else { |
| llvm_unreachable("unsupported type"); |
| } |
| |
| // The condition used for the loop is isFirst || <the condition above>. |
| isFirst = builder.create<fir::ConvertOp>(loc, cmp.getType(), isFirst); |
| isFirst = builder.create<mlir::arith::XOrIOp>( |
| loc, isFirst, builder.createIntegerConstant(loc, cmp.getType(), 1)); |
| cmp = builder.create<mlir::arith::OrIOp>(loc, cmp, isFirst); |
| |
| // Set the new coordinate to the result |
| fir::IfOp ifOp = builder.create<fir::IfOp>(loc, elementType, cmp, |
| /*withElseRegion*/ true); |
| |
| builder.setInsertionPointToStart(&ifOp.getThenRegion().front()); |
| builder.create<fir::StoreOp>(loc, flagSet, flagRef); |
| mlir::Type resultElemTy = |
| hlfir::getFortranElementType(resultArr.getType()); |
| mlir::Type returnRefTy = builder.getRefType(resultElemTy); |
| mlir::IndexType idxTy = builder.getIndexType(); |
| |
| for (unsigned int i = 0; i < rank; ++i) { |
| mlir::Value index = builder.createIntegerConstant(loc, idxTy, i + 1); |
| mlir::Value resultElemAddr = builder.create<hlfir::DesignateOp>( |
| loc, returnRefTy, resultArr, index); |
| mlir::Value fortranIndex = builder.create<fir::ConvertOp>( |
| loc, resultElemTy, oneBasedIndices[i]); |
| builder.create<fir::StoreOp>(loc, fortranIndex, resultElemAddr); |
| } |
| builder.create<fir::ResultOp>(loc, elem); |
| builder.setInsertionPointToStart(&ifOp.getElseRegion().front()); |
| builder.create<fir::ResultOp>(loc, reduction); |
| builder.setInsertionPointAfter(ifOp); |
| |
| // Close the mask if |
| builder.create<fir::ResultOp>(loc, ifOp.getResult(0)); |
| builder.setInsertionPointToStart(&maskIfOp.getElseRegion().front()); |
| builder.create<fir::ResultOp>(loc, reduction); |
| builder.setInsertionPointAfter(maskIfOp); |
| |
| return maskIfOp.getResult(0); |
| }; |
| auto getAddrFn = [](fir::FirOpBuilder builder, mlir::Location loc, |
| const mlir::Type &resultElemType, mlir::Value resultArr, |
| mlir::Value index) { |
| mlir::Type resultRefTy = builder.getRefType(resultElemType); |
| mlir::Value oneIdx = |
| builder.createIntegerConstant(loc, builder.getIndexType(), 1); |
| index = builder.create<mlir::arith::AddIOp>(loc, index, oneIdx); |
| return builder.create<hlfir::DesignateOp>(loc, resultRefTy, resultArr, |
| index); |
| }; |
| |
| // Initialize the result |
| mlir::Type resultElemTy = hlfir::getFortranElementType(resultArr.getType()); |
| mlir::Type resultRefTy = builder.getRefType(resultElemTy); |
| mlir::Value returnValue = |
| builder.createIntegerConstant(loc, resultElemTy, 0); |
| for (unsigned int i = 0; i < rank; ++i) { |
| mlir::Value index = |
| builder.createIntegerConstant(loc, builder.getIndexType(), i + 1); |
| mlir::Value resultElemAddr = builder.create<hlfir::DesignateOp>( |
| loc, resultRefTy, resultArr, index); |
| builder.create<fir::StoreOp>(loc, returnValue, resultElemAddr); |
| } |
| |
| fir::genMinMaxlocReductionLoop(builder, array, init, genBodyOp, getAddrFn, |
| rank, elementType, loc, builder.getI1Type(), |
| resultArr, false); |
| |
| mlir::Value asExpr = builder.create<hlfir::AsExprOp>( |
| loc, resultArr, builder.createBool(loc, false)); |
| |
| // Check all the users - the destroy is no longer required, and any assign |
| // can use resultArr directly so that VariableAssignBufferization in this |
| // pass can optimize the results. Other operations are replaces with an |
| // AsExpr for the temporary resultArr. |
| llvm::SmallVector<hlfir::DestroyOp> destroys; |
| llvm::SmallVector<hlfir::AssignOp> assigns; |
| for (auto user : mloc->getUsers()) { |
| if (auto destroy = mlir::dyn_cast<hlfir::DestroyOp>(user)) |
| destroys.push_back(destroy); |
| else if (auto assign = mlir::dyn_cast<hlfir::AssignOp>(user)) |
| assigns.push_back(assign); |
| } |
| |
| // Check if the minloc/maxloc was the only user of the elemental (apart from |
| // a destroy), and remove it if so. |
| mlir::Operation::user_range elemUsers = elemental->getUsers(); |
| hlfir::DestroyOp elemDestroy; |
| if (std::distance(elemUsers.begin(), elemUsers.end()) == 2) { |
| elemDestroy = mlir::dyn_cast<hlfir::DestroyOp>(*elemUsers.begin()); |
| if (!elemDestroy) |
| elemDestroy = mlir::dyn_cast<hlfir::DestroyOp>(*++elemUsers.begin()); |
| } |
| |
| for (auto d : destroys) |
| rewriter.eraseOp(d); |
| for (auto a : assigns) |
| a.setOperand(0, resultArr); |
| rewriter.replaceOp(mloc, asExpr); |
| if (elemDestroy) { |
| rewriter.eraseOp(elemDestroy); |
| rewriter.eraseOp(elemental); |
| } |
| return mlir::success(); |
| } |
| }; |
| |
| class OptimizedBufferizationPass |
| : public hlfir::impl::OptimizedBufferizationBase< |
| OptimizedBufferizationPass> { |
| public: |
| void runOnOperation() override { |
| mlir::MLIRContext *context = &getContext(); |
| |
| mlir::GreedyRewriteConfig config; |
| // Prevent the pattern driver from merging blocks |
| config.enableRegionSimplification = false; |
| |
| mlir::RewritePatternSet patterns(context); |
| // TODO: right now the patterns are non-conflicting, |
| // but it might be better to run this pass on hlfir.assign |
| // operations and decide which transformation to apply |
| // at one place (e.g. we may use some heuristics and |
| // choose different optimization strategies). |
| // This requires small code reordering in ElementalAssignBufferization. |
| patterns.insert<ElementalAssignBufferization>(context); |
| patterns.insert<BroadcastAssignBufferization>(context); |
| patterns.insert<VariableAssignBufferization>(context); |
| patterns.insert<ReductionElementalConversion<hlfir::CountOp>>(context); |
| patterns.insert<ReductionElementalConversion<hlfir::AnyOp>>(context); |
| patterns.insert<ReductionElementalConversion<hlfir::AllOp>>(context); |
| patterns.insert<MinMaxlocElementalConversion<hlfir::MinlocOp>>(context); |
| patterns.insert<MinMaxlocElementalConversion<hlfir::MaxlocOp>>(context); |
| |
| if (mlir::failed(mlir::applyPatternsAndFoldGreedily( |
| getOperation(), std::move(patterns), config))) { |
| mlir::emitError(getOperation()->getLoc(), |
| "failure in HLFIR optimized bufferization"); |
| signalPassFailure(); |
| } |
| } |
| }; |
| } // namespace |