2020-09-17 08:31:40 +08:00
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//===----------------------------------------------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "PassDetail.h"
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#include "npcomp/E2E/E2E.h"
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#include "mlir/Dialect/SCF/SCF.h"
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#include "mlir/Dialect/Shape/IR/Shape.h"
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#include "mlir/Dialect/StandardOps/IR/Ops.h"
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#include "mlir/IR/PatternMatch.h"
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#include "mlir/Pass/Pass.h"
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#include "mlir/Pass/PassRegistry.h"
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using namespace mlir;
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using namespace mlir::NPCOMP;
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namespace {
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class LowerCstrBroadcastableOp
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: public OpRewritePattern<shape::CstrBroadcastableOp> {
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public:
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using OpRewritePattern::OpRewritePattern;
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LogicalResult matchAndRewrite(shape::CstrBroadcastableOp op,
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PatternRewriter &rewriter) const override {
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// A shape.cstr_* op should be the result of lowering a !shape.shape; it
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// should not itself ever consume or produce a !shape.shape.
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//
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// There is no way to "sink" a !shape.shape type, because one cannot inspect
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// if it is an error. The only way to use it safely is to lower the op that
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// produced the value to a set of constraints and then use the witness to
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// guard a shape.assuming.
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//
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// Consider for example what we do when lowering TCF to TCP: we need to do a
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// shape calculation for the broadcasting. But we create the
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// shape.cstr_broadcastable and use its witness to guard a `shape.assuming {
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// ... shape.broadcast ...}`. There's never any need to create a
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// !shape.shape.
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//
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// The use of !shape.shape should be restricted to contexts like
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// declarations of shape transfer functions, with automatic utilities to
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// lower !shape.shape types to corresponding constraints + shape.assuming +
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// tensors. In this (npcomp e2e) lowering flow, we don't have any such
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// "declarative shape transfer functions" or utilities to expand them to
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// constraints. So !shape.shape should never exist in our IR.
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//
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// Historically, we used !shape.shape type for everything, and
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// shape.to_extent_tensor would abort in case of an error. But that's not a
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// useful semantics for lowering, since the error is defined to happen as
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// part of the shape.to_extent_tensor op, which requires materializing an
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// "is error" bit in the IR and carrying it around everywhere that the
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// original !shape.shape value was being used. In practice, nobody respects
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// that, which opens us up to miscompilations. That is, the lowering
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// strategy is either "not emit errors at all" or "emit errors as part of
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// lowering e.g. the shape.broadcast op itself" (which technically puts the
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// errors in some random location in the IR that is not the
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// shape.to_extent_tensor op). E.g. the following code would miscompile with
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// either of those ways that these ops get lowered in practice:
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// ```
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// %shape = shape.broadcast %lhs, %rhs : !shape.shape
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// if %cond:
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// shape.to_extent_tensor(%shape)
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// ```
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// It's not possible to correctly compile this code without significant
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// contortions (such as carrying an "is error" bit). And to boot, we
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// shouldn't be getting into that situation in the first place! But the
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// `shape.to_extent_tensor : !shape.shape -> tensor<?xindex>` abstraction
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// opens up that possibility.
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//
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// shape.to_extent_tensor should not really be a thing, since it creates
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// these ill-defined situations about where errors are observed. A
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// !shape.shape type should only exist (for this compilation flow) as part
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// of a utility, something like "I want to do this shape calculation on
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// !shape.shape type, create IR that uses tensor<?xindex> and witnesses to
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// implement it, on the assumption that the error can be
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// observed anywhere inside the shape calculation".
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//
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// !shape.shape type would still be useful for lowerings that actually
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// result in a runtime type that carries an "is error" bit inside it, though
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// TBD if such use cases arise.
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if (op.getType().isa<shape::ShapeType>() ||
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op.lhs().getType().isa<shape::ShapeType>() ||
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op.rhs().getType().isa<shape::ShapeType>()) {
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return op.emitError() << "Error shapes should not exist at this point";
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}
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auto loc = op.getLoc();
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Value zero = rewriter.create<ConstantIndexOp>(loc, 0);
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Value one = rewriter.create<ConstantIndexOp>(loc, 1);
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// Find smaller and greater rank and extent tensor.
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Value lhsRank = rewriter.create<DimOp>(loc, op.lhs(), zero);
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Value rhsRank = rewriter.create<DimOp>(loc, op.rhs(), zero);
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Value lhsSmaller =
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rewriter.create<CmpIOp>(loc, CmpIPredicate::ule, lhsRank, rhsRank);
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Type indexTy = rewriter.getIndexType();
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Type extentTensorTy = op.lhs().getType();
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auto ifOp = rewriter.create<scf::IfOp>(
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loc, TypeRange{indexTy, extentTensorTy, indexTy, extentTensorTy},
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lhsSmaller,
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[&](OpBuilder &b, Location loc) {
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b.create<scf::YieldOp>(
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loc, ValueRange{lhsRank, op.lhs(), rhsRank, op.rhs()});
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},
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[&](OpBuilder &b, Location loc) {
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b.create<scf::YieldOp>(
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loc, ValueRange{rhsRank, op.rhs(), lhsRank, op.lhs()});
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});
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Value lesserRank = ifOp.getResult(0);
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Value lesserRankOperand = ifOp.getResult(1);
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Value greaterRank = ifOp.getResult(2);
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Value greaterRankOperand = ifOp.getResult(3);
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Value rankDiff =
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rewriter.create<SubIOp>(loc, indexTy, greaterRank, lesserRank);
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// Compare the shapes extent by extent, and emit errors for
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// non-broadcast-compatible shapes.
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// Two extents are broadcast-compatible if
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// 1. they are both equal, or
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// 2. at least one of them is 1.
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rewriter.create<scf::ForOp>(
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loc, rankDiff, greaterRank, one, llvm::None,
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[&](OpBuilder &b, Location loc, Value iv, ValueRange) {
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Value greaterRankOperandExtent = b.create<ExtractElementOp>(
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loc, greaterRankOperand, ValueRange{iv});
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Value ivShifted = b.create<SubIOp>(loc, indexTy, iv, rankDiff);
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Value lesserRankOperandExtent = b.create<ExtractElementOp>(
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loc, lesserRankOperand, ValueRange{ivShifted});
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Value greaterRankOperandExtentIsOne = b.create<CmpIOp>(
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loc, CmpIPredicate::eq, greaterRankOperandExtent, one);
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Value lesserRankOperandExtentIsOne = b.create<CmpIOp>(
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loc, CmpIPredicate::eq, lesserRankOperandExtent, one);
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Value extentsAgree =
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b.create<CmpIOp>(loc, CmpIPredicate::eq, greaterRankOperandExtent,
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lesserRankOperandExtent);
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auto broadcastIsValid =
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b.create<OrOp>(loc, b.getI1Type(), extentsAgree,
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b.create<OrOp>(loc, greaterRankOperandExtentIsOne,
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lesserRankOperandExtentIsOne));
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b.create<AssertOp>(loc, broadcastIsValid, "invalid broadcast");
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b.create<scf::YieldOp>(loc);
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});
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// Now that we have emitted all the assertions, the witness is trivially
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// satisfied.
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rewriter.replaceOpWithNewOp<shape::ConstWitnessOp>(op, true);
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return success();
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}
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};
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} // namespace
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2020-09-18 09:56:01 +08:00
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namespace {
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class LowerCstrRequireOp : public OpRewritePattern<shape::CstrRequireOp> {
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public:
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using OpRewritePattern::OpRewritePattern;
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LogicalResult matchAndRewrite(shape::CstrRequireOp op,
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PatternRewriter &rewriter) const override {
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rewriter.create<AssertOp>(op.getLoc(), op.pred(), op.msgAttr());
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rewriter.replaceOpWithNewOp<shape::ConstWitnessOp>(op, true);
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return success();
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}
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};
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} // namespace
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2020-09-17 08:31:40 +08:00
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namespace {
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// This pass eliminates shape constraints from the program.
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//
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// After this pass finishes, there are no !shape.witness types in the program,
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// no shape.assuming, no shape.cstr_*.
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//
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// TODO: This should move to upstream ShapeToStandard conversions.
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class LowerShapeConstraints
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: public LowerShapeConstraintsBase<LowerShapeConstraints> {
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void runOnOperation() {
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auto func = getOperation();
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auto *context = &getContext();
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OwningRewritePatternList patterns;
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patterns.insert<LowerCstrBroadcastableOp>(context);
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2020-09-18 09:56:01 +08:00
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patterns.insert<LowerCstrRequireOp>(context);
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2020-09-17 08:31:40 +08:00
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// Add in the canonicalization patterns for shape.assuming so that it gets
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// inlined when its witness becomes a true constant witness.
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shape::AssumingOp::getCanonicalizationPatterns(patterns, context);
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if (failed(applyPatternsAndFoldGreedily(func, patterns)))
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return signalPassFailure();
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// TODO: Check that there are no remaining !shape.witness, shape.assuming,
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// shape.cstr_* ops, etc.
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}
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};
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} // namespace
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std::unique_ptr<OperationPass<FuncOp>>
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mlir::NPCOMP::createLowerShapeConstraintsPass() {
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return std::make_unique<LowerShapeConstraints>();
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}
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