mirror of https://github.com/llvm/torch-mlir
374 lines
16 KiB
C++
374 lines
16 KiB
C++
//===----------------------------------------------------------------------===//
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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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// Also available under a BSD-style license. See LICENSE.
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//
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//===----------------------------------------------------------------------===//
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#include "Utils.h"
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#include "../PassDetail.h"
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#include "PopulatePatterns.h"
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#include "mlir/Dialect/Arith/IR/Arith.h"
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#include "mlir/Dialect/ControlFlow/IR/ControlFlowOps.h"
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#include "mlir/Dialect/Linalg/IR/Linalg.h"
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#include "mlir/Dialect/Tensor/IR/Tensor.h"
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#include "mlir/Dialect/Tensor/Utils/Utils.h"
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#include "mlir/IR/Matchers.h"
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#include "torch-mlir/Conversion/Utils/Utils.h"
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#include "torch-mlir/Dialect/Torch/IR/TorchDialect.h"
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#include "torch-mlir/Dialect/Torch/IR/TorchOps.h"
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#include "torch-mlir/Dialect/Torch/Utils/TorchUpstream.h"
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#include "torch-mlir/Dialect/Torch/Utils/Utils.h"
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using namespace mlir;
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using namespace mlir::torch;
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using namespace mlir::torch::Torch;
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static SmallVector<OpFoldResult>
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getIndexIntsAsOpFoldResult(OpBuilder &b, SmallVectorImpl<int64_t> &ints) {
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return llvm::to_vector<4>(llvm::map_range(
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ints, [&](int64_t val) -> OpFoldResult { return b.getIndexAttr(val); }));
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}
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// Helper function to get the padding tensor given the padding int values.
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Value torch_to_linalg::getPaddedTensor(
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Operation *op, OpBuilder &b, Value &input,
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SmallVectorImpl<int64_t> &lowPaddingInts,
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SmallVectorImpl<int64_t> &highPaddingInts, Value pad) {
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Location loc = op->getLoc();
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Type rankedTensorType =
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tensor::PadOp::inferResultType(input.getType().cast<RankedTensorType>(),
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lowPaddingInts, highPaddingInts);
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SmallVector<OpFoldResult> lowPaddings =
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getIndexIntsAsOpFoldResult(b, lowPaddingInts);
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SmallVector<OpFoldResult> highPaddings =
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getIndexIntsAsOpFoldResult(b, highPaddingInts);
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Value paddedInput = tensor::createPadScalarOp(
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rankedTensorType, input, pad, /*low=*/lowPaddings, /*high=*/highPaddings,
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/*packing=*/false, loc, b);
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return paddedInput;
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}
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// Helper function to get the padding tensor given the padding int values.
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// It's assumed that the padding on the low end and high end are the same,
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// and that zero padding is required.
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Value torch_to_linalg::getZeroPaddedTensor(
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Operation *op, OpBuilder &b, Value &input,
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SmallVectorImpl<int64_t> &paddingInts) {
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assert(input.getType().isa<RankedTensorType>() &&
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"input must be RankedTensorType");
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Location loc = op->getLoc();
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Value c0 = b.create<arith::ConstantOp>(
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loc,
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b.getZeroAttr(input.getType().cast<RankedTensorType>().getElementType()));
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return getPaddedTensor(op, b, input, paddingInts, paddingInts, c0);
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}
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Value torch_to_linalg::getOutputDimForConvOps(OpBuilder &b, Location loc,
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Value in, Value paddingInt,
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Value dilationInt,
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Value kernelSizeInt,
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Value strideInt, bool ceilMode) {
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Value c1 = b.create<arith::ConstantOp>(loc, b.getI64IntegerAttr(1));
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Value c2 = b.create<arith::ConstantOp>(loc, b.getI64IntegerAttr(2));
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Value doublePadding = b.create<arith::MulIOp>(loc, paddingInt, c2);
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// in + 2 * padding
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Value inAddDoublePadding =
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b.create<arith::AddIOp>(loc, castIndexToInt64(b, loc, in), doublePadding);
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// dilation * (kernelSize - 1)
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Value kernelSizeSub1 = b.create<arith::SubIOp>(loc, kernelSizeInt, c1);
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Value dilationTimesKernelSize =
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b.create<arith::MulIOp>(loc, dilationInt, kernelSizeSub1);
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Value temp =
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b.create<arith::SubIOp>(loc, inAddDoublePadding, dilationTimesKernelSize);
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Value dividend = b.create<arith::SubIOp>(loc, temp, c1);
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Value division;
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if (ceilMode)
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division = b.create<arith::CeilDivSIOp>(loc, dividend, strideInt);
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else
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division = b.create<arith::FloorDivSIOp>(loc, dividend, strideInt);
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Value out = b.create<arith::AddIOp>(loc, division, c1);
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return castIntToIndex(b, loc, out);
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}
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Value torch_to_linalg::getOutputDimForConvTransposeOps(
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OpBuilder &b, Location loc, Value in, Value paddingInt, Value dilationInt,
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Value kernelSizeInt, Value strideInt) {
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Value c1 = b.create<arith::ConstantOp>(loc, b.getI64IntegerAttr(1));
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Value c2 = b.create<arith::ConstantOp>(loc, b.getI64IntegerAttr(2));
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// (in - 1) * stride
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Value inStrided =
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b.create<arith::SubIOp>(loc, castIndexToInt64(b, loc, in), c1);
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inStrided = b.create<arith::MulIOp>(loc, inStrided, strideInt);
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// 2 * padding
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Value doublePadding = b.create<arith::MulIOp>(loc, paddingInt, c2);
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// (kernelSize - 1) * dilation
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Value kernelDilated = b.create<arith::SubIOp>(loc, kernelSizeInt, c1);
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kernelDilated = b.create<arith::MulIOp>(loc, kernelDilated, dilationInt);
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Value out = b.create<arith::SubIOp>(loc, inStrided, doublePadding);
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out = b.create<arith::AddIOp>(loc, out, kernelDilated);
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out = b.create<arith::AddIOp>(loc, out, c1);
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return castIntToIndex(b, loc, out);
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}
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Value torch_to_linalg::createReductionLinalgGeneric(
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OpBuilder &b, Location loc, const ReductionOpInfo &opInfo, Value initElem,
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function_ref<void(OpBuilder &, Location, ValueRange)> bodyBuild) {
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auto inputType = opInfo.tensorOperand.getType().cast<RankedTensorType>();
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// Get the result shape by obtaining the size of each
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// dimension in the input tensor that is not getting reduced.
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// If `opInfo.keepDim` is true, the rank of the output tensor
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// is kept the same as the rank of the input tensor, and the
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// reduced dimensions are set to have size 1.
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auto c1 = b.create<arith::ConstantIndexOp>(loc, /*value=*/1);
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SmallVector<Value> resultShape;
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for (int64_t i = 0; i < inputType.getRank(); i++) {
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auto currentDimSize = b.create<tensor::DimOp>(loc, opInfo.tensorOperand, i);
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if (!opInfo.dimSet.contains(i))
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resultShape.push_back(currentDimSize);
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else if (opInfo.keepDim)
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resultShape.push_back(c1);
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}
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// Create the affine expressions that will be used to
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// iterate over the input and output tensors.
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// Here we also set the type of iterator: parallel or reduction.
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SmallVector<AffineExpr> exprs;
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SmallVector<StringRef> iteratorTypes;
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SmallVector<AffineExpr> resultExprs;
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for (auto size : llvm::enumerate(inputType.getShape())) {
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exprs.push_back(b.getAffineDimExpr(size.index()));
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if (opInfo.dimSet.contains(size.index())) {
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iteratorTypes.push_back(getReductionIteratorTypeName());
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// If `opInfo.keepDim`, create affine map to the first element
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// in the current dimension.
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if (opInfo.keepDim)
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resultExprs.push_back(b.getAffineConstantExpr(0));
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} else {
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iteratorTypes.push_back(getParallelIteratorTypeName());
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resultExprs.push_back(b.getAffineDimExpr(size.index()));
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}
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}
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auto indexingMaps = AffineMap::inferFromExprList({exprs, resultExprs});
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Value accumulator =
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createInitTensor(b, loc, resultShape, initElem.getType(), initElem);
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return b
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.create<linalg::GenericOp>(
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loc, /*resultTensorTypes=*/accumulator.getType(),
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/*inputs=*/opInfo.tensorOperand,
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/*outputs=*/accumulator, indexingMaps, iteratorTypes, bodyBuild)
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.getResult(0);
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}
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Value torch_to_linalg::createElementwiseLinalgGeneric(
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OpBuilder &b, Location loc, ValueRange tensorOperands,
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Type resultElementType,
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function_ref<void(OpBuilder &, Location, ValueRange)> bodyBuild) {
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// The overall error handling strategy here is best viewed by thinking about
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// what happens for a single result dimension. This loop not structured that
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// way because it is hard to create the affine maps for each operand unless
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// we structure the loop to iterate over tensor operands as the outer loop
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// instead of inner loop. This pseudocode gives better intuition:
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// ```
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// for each result dimension:
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// for each tensor operand:
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// if it doesn't even have high enough rank relative to the result:
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// continue
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// if it is a static size-1 along this result dimension:
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// continue
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// if this is the first tensor operand that didn't continue above:
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// take its dimension size as the size of the non-broadcasted
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// traversal along this dimension (this may include a dynamic size-1,
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// **non-broadcasted** traversal!)
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// emit error check "if the size does not match the non-broadcasted
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// traversal size along this dimension, error"
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// ```
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SmallVector<int64_t> operandRanks;
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operandRanks.resize(tensorOperands.size());
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llvm::transform(tensorOperands, operandRanks.begin(), [](Value tensor) {
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return tensor.getType().dyn_cast<RankedTensorType>().getRank();
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});
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auto resultRankIt =
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std::max_element(operandRanks.begin(), operandRanks.end());
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assert(resultRankIt != operandRanks.end() && "Unable to get result rank.");
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int64_t resultRank = *resultRankIt;
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// Initialize the resultShape to all 1's, as a fallback in case
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// all sizes along that result dimension are statically 1.
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auto c1 = b.create<arith::ConstantIndexOp>(loc, /*value=*/1);
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SmallVector<Value> resultShape(resultRank, c1);
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SmallVector<AffineMap> indexingMaps;
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for (Value tensorOperand : tensorOperands) {
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SmallVector<AffineExpr> exprs;
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auto type = tensorOperand.getType().cast<RankedTensorType>();
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for (auto size : llvm::enumerate(type.getShape())) {
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// If the size is statically known to be 1, we don't want any
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// error guards to be spuriously emitted, since we are specifically
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// allowing size-1 broadcasts in this case, as they correspond to a
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// constant-0 indexing map.
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if (size.value() == 1) {
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exprs.push_back(b.getAffineConstantExpr(0));
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continue;
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}
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// The rank of this operand might be smaller than the overall rank of
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// the broadcast. Add an offset to correlate it to the correct
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// dimension of the result.
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auto resultDim = size.index() + (resultRank - type.getRank());
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// The generated linalg op will now be iterating along the full size
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// of this dimension. Record that fact.
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exprs.push_back(b.getAffineDimExpr(resultDim));
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// Now, we need to ensure that such iteration is not going to trigger
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// undefined behavior, by doing appropriate checks against the current
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// dimension size.
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auto currentDimSize = getDimOp(b, loc, tensorOperand, size.index());
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// If the result size of this dimension has so far only hit the
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// statically-known-to-be-1 case above (i.e., we have not yet assigned a
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// new Value to `resultShape[resultDim]`), then we have no other dynamic
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// values to check against, and merely need to record the current
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// dimension size.
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if (resultShape[resultDim] == c1) {
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resultShape[resultDim] = currentDimSize;
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continue;
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}
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// We prohibit the size-1 dynamic broadcasting scenario, so just check
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// for exact equality with the running result size.
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// This is the check which protects against the undefined behavior of
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// the generated linalg op in the case of iterating two operands with
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// dimensions sizes that are expected to match.
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auto equalToRunning =
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b.create<arith::CmpIOp>(loc, arith::CmpIPredicate::eq,
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resultShape[resultDim], currentDimSize);
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b.create<cf::AssertOp>(loc, equalToRunning,
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"mismatched size for broadcast");
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}
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indexingMaps.push_back(AffineMap::get(
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/*dimCount=*/resultRank, /*symbolCount=*/0, exprs, b.getContext()));
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}
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SmallVector<StringRef> iteratorTypes(resultRank,
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getParallelIteratorTypeName());
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// Add the indexing map for the outs init tensor.
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indexingMaps.push_back(b.getMultiDimIdentityMap(resultRank));
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Value initTensor = b.create<linalg::InitTensorOp>(
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loc, getAsOpFoldResult(resultShape), resultElementType);
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return b
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.create<linalg::GenericOp>(loc,
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/*resultTensorTypes=*/initTensor.getType(),
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/*inputs=*/tensorOperands,
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/*outputs=*/initTensor, indexingMaps,
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iteratorTypes, bodyBuild)
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.getResult(0);
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}
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// Broadcasts input tensor based on the broadcastToShape.
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LogicalResult torch_to_linalg::broadcastToGivenShape(
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Operation *op, PatternRewriter &rewriter, Value input,
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SmallVector<Value> broadcastToShape, Value &result) {
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RankedTensorType inputType = input.getType().cast<RankedTensorType>();
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ArrayRef<int64_t> inputShape = inputType.getShape();
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if (broadcastToShape.size() < inputShape.size()) {
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return rewriter.notifyMatchFailure(
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op, "invalid shape: broadcastToShape size must not be smaller than the "
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"size of the input shape");
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}
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Type elementType = inputType.getElementType();
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Location loc = op->getLoc();
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MLIRContext *context = op->getContext();
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SmallVector<Value> outShape;
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// Create affine map and shapes for tensor initialization.
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SmallVector<AffineExpr> outExpr;
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Value zero =
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rewriter.create<arith::ConstantOp>(loc, rewriter.getI64IntegerAttr(0));
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size_t diff = broadcastToShape.size() - inputShape.size();
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for (size_t i = 0; i < broadcastToShape.size(); i++) {
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Value shapeValue = broadcastToShape[i];
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size_t j = i - diff;
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if (i < diff) {
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Value isValid = rewriter.create<arith::CmpIOp>(
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loc, arith::CmpIPredicate::sge, shapeValue, zero);
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rewriter.create<cf::AssertOp>(
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loc, isValid,
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rewriter.getStringAttr(
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"negative values not allowed in new dimensions"));
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outShape.push_back(castIntToIndex(rewriter, loc, shapeValue));
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continue;
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}
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if (inputShape[j] == 1) {
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// Broadcast singleton dimension
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Value one =
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rewriter.create<arith::ConstantOp>(loc, rewriter.getIndexAttr(1));
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Value isNegative = rewriter.create<arith::CmpIOp>(
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loc, arith::CmpIPredicate::slt, shapeValue, zero);
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Value select = rewriter.create<arith::SelectOp>(
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loc, isNegative, one, castIntToIndex(rewriter, loc, shapeValue));
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outShape.push_back(select);
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outExpr.push_back(mlir::getAffineConstantExpr(0, context));
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continue;
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}
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// Non-broadcast case
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Value dim = getDimOp(rewriter, loc, input, j);
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Value isNegative = rewriter.create<arith::CmpIOp>(
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loc, arith::CmpIPredicate::slt, shapeValue, zero);
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Value isEqual = rewriter.create<arith::CmpIOp>(
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loc, arith::CmpIPredicate::eq, castIndexToInt64(rewriter, loc, dim),
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shapeValue);
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Value isValid = rewriter.create<arith::OrIOp>(loc, isNegative, isEqual);
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rewriter.create<cf::AssertOp>(
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loc, isValid,
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rewriter.getStringAttr(
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"only broadcasting singleton dimensions supported"));
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outShape.push_back(dim);
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outExpr.push_back(mlir::getAffineDimExpr(i, context));
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}
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Value outTensor =
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rewriter.create<linalg::InitTensorOp>(loc, outShape, elementType);
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SmallVector<AffineMap> indexingMaps = {
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AffineMap::get(broadcastToShape.size(), 0, outExpr, context),
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rewriter.getMultiDimIdentityMap(broadcastToShape.size())};
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SmallVector<StringRef> iteratorTypes(broadcastToShape.size(), "parallel");
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result = rewriter
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.create<linalg::GenericOp>(
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loc, outTensor.getType(), input, outTensor, indexingMaps,
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iteratorTypes,
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[](OpBuilder &b, Location loc, ValueRange args) {
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b.create<linalg::YieldOp>(loc, args[0]);
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})
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.getResult(0);
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return success();
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}
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Value torch_to_linalg::removeSizeInformation(OpBuilder &b, Location loc,
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Value tensor) {
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auto tensorType = tensor.getType().cast<RankedTensorType>();
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auto rank = tensorType.getRank();
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SmallVector<int64_t> unknownSizes(rank, kUnknownSize);
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return b.create<tensor::CastOp>(loc, tensorType.clone(unknownSizes), tensor);
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}
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