mirror of https://github.com/llvm/torch-mlir
2373 lines
101 KiB
C++
2373 lines
101 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 "torch-mlir/Conversion/TorchToLinalg/TorchToLinalg.h"
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#include "../PassDetail.h"
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#include "mlir/Dialect/Linalg/IR/LinalgOps.h"
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#include "mlir/Dialect/Math/IR/Math.h"
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#include "mlir/Dialect/Tensor/IR/Tensor.h"
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#include "mlir/Dialect/Traits.h"
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#include "mlir/IR/Matchers.h"
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#include "mlir/Transforms/DialectConversion.h"
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#include "torch-mlir/Dialect/Torch/IR/TorchOps.h"
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#include "torch-mlir/Dialect/Torch/Utils/Utils.h"
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#include "torch-mlir/Dialect/TorchConversion/IR/TorchConversionDialect.h"
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#include "torch-mlir/Dialect/TorchConversion/Transforms/BackendTypeConversion.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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// -----------------------------------------------------------------------------
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// Patterns (as this grows, it should be organized into multiple files)
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// -----------------------------------------------------------------------------
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// This is going to eventually be O(#aten ops), which is in the 100s.
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//
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// Most of these patterns consist of:
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// 1. Checking that the operand/result types and other static properties are
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// good-enough to create a valid linalg op (such as operands being of
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// ranks/dtypes acceptable to the linalg op).
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// 2. Creating dynamic error guards, usually checking a predicate on the
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// compatibility of operand shapes.
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// 3. Creating init tensors for the computation op. Usually this involves
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// reifying IR for a shape transfer function based on the operand shapes.
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// 4. Creating a named linalg op to replace the original op.
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//
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// TODO: Use linalg OpDSL to autogenerate at least 1)/2)/3) such
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// that these patterns become mostly mechanical associations of
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// "aten.foo -> linalg.foo".
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static LogicalResult verifyLinalgCompatibleTypes(Operation *op,
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PatternRewriter &rewriter) {
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// Check the value tensor is ranked as expected by Linalg.
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// TODO: Remove this check but use a separate verification pass to verify the
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// invariants expected by later passes.
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auto isValidLinalgType = [](Type type) {
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auto tensor = type.dyn_cast<ValueTensorType>();
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return !tensor ||
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tensor.toBuiltinTensor().dyn_cast_or_null<RankedTensorType>();
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};
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bool valid = llvm::all_of(op->getOperandTypes(), isValidLinalgType) &&
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llvm::all_of(op->getResultTypes(), isValidLinalgType);
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if (!valid)
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return rewriter.notifyMatchFailure(op, "type cannot be lowered to linalg");
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return success();
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}
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static LogicalResult checkNotNone(PatternRewriter &rewriter, Operation *op,
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Value v) {
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Type type = v.getType();
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if (type.isa<OptionalType>() || type.isa<Torch::NoneType>() ||
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type.isa<mlir::NoneType>())
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return rewriter.notifyMatchFailure(op, "unimplemented None type arg");
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return success();
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}
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// Generate IR: dim = dim >= 0 ? dim : dim + inputRank
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static Value toPositiveDimDynamic(OpBuilder &b, Location loc, Value dim,
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Value inputRank) {
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assert(dim.getType().isa<IntegerType>() &&
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"dim arg of toPositiveDim must be integer type");
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Value dimAddInputRank = b.create<arith::AddIOp>(loc, dim, inputRank);
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Value cst0 = b.create<arith::ConstantOp>(loc, b.getZeroAttr(inputRank.getType()));
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Value predDimGEZero =
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b.create<arith::CmpIOp>(loc, arith::CmpIPredicate::sge, dim, cst0);
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Value dimInt = b.create<SelectOp>(loc, predDimGEZero, dim, dimAddInputRank);
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return dimInt;
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}
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// Generate IR: assert(dim >= 0 && dim < inputRank)
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static void assertIsValidDim(OpBuilder &b, Location loc, Value dim,
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Value inputRank) {
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assert(dim.getType().isa<IntegerType>() &&
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"dim arg of assertIsValidDim must be integer type");
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Value cst0 = b.create<arith::ConstantOp>(loc, b.getZeroAttr(inputRank.getType()));
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Value predGEZero =
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b.create<arith::CmpIOp>(loc, arith::CmpIPredicate::sge, dim, cst0);
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b.create<AssertOp>(loc, predGEZero,
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b.getStringAttr("dim must be greater or equal to zero"));
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Value predLTInputRank =
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b.create<arith::CmpIOp>(loc, arith::CmpIPredicate::slt, dim, inputRank);
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b.create<AssertOp>(loc, predLTInputRank,
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b.getStringAttr("dim must be smaller than inputRank"));
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}
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// Hack to deal with the Torch list type arguments which is not supported end
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// to end. Constant values can be be extracted directly and non constant
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// list values are not supported.
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// TODO: loose this constraint when properly support list type
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static bool isConstantIntListMatching(Value value,
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SmallVectorImpl<int64_t> &expects) {
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SmallVector<int64_t> intValues;
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if (!matchPattern(value, m_TorchConstantIntList(intValues)))
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return false;
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if (intValues.size() != expects.size())
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return false;
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for (auto it : llvm::zip(intValues, expects)) {
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if (std::get<0>(it) != std::get<1>(it))
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return false;
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}
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return true;
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}
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static Value castIntToIndex(OpBuilder &b, Location loc, Value v) {
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assert(v.getType().isa<IntegerType>() && "must be called with integer type");
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return b.create<arith::IndexCastOp>(loc, b.getIndexType(), v);
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}
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static Value castIndexToInt(OpBuilder &b, Location loc, Value idx) {
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assert(idx.getType().isa<IndexType>() && "must be called with integer type");
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return b.create<arith::IndexCastOp>(loc, b.getI64Type(), idx);
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}
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static Value getDimOp(OpBuilder &b, Location loc, Value v, int dimension) {
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return b.create<tensor::DimOp>(loc, v, dimension);
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}
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static void checkDimEqualHelper(OpBuilder &b, Location loc, Value lhsDim,
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Value rhsDim) {
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Type lhsType = lhsDim.getType();
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Type rhsType = rhsDim.getType();
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auto checkIntOrIndex = [](Type type) {
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assert(type.isa<IntegerType>() ||
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type.isa<IndexType>() && "must be either integer or index type");
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};
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checkIntOrIndex(lhsType);
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checkIntOrIndex(rhsType);
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Value lhsDimInt = lhsType.isIndex() ? castIndexToInt(b, loc, lhsDim) : lhsDim;
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Value rhsDimInt = rhsType.isIndex() ? castIndexToInt(b, loc, rhsDim) : rhsDim;
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Value contractingDimEqual = b.create<arith::CmpIOp>(
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loc, arith::CmpIPredicate::eq, lhsDimInt, rhsDimInt);
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b.create<AssertOp>(loc, contractingDimEqual,
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b.getStringAttr("mismatching contracting dimension"));
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}
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static SmallVector<Value> getTensorSizesUntilDim(OpBuilder &b, Location loc,
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Value tensor, int dim) {
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RankedTensorType type = tensor.getType().cast<RankedTensorType>();
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assert(dim < type.getRank() &&
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"The given dim must be smaller than tensor rank");
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(void)type;
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SmallVector<Value> sizes;
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for (int i = 0; i <= dim; i++)
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sizes.push_back(getDimOp(b, loc, tensor, i));
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return sizes;
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}
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static SmallVector<Value> getTensorSizes(OpBuilder &b, Location loc,
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Value tensor) {
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RankedTensorType type = tensor.getType().cast<RankedTensorType>();
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return getTensorSizesUntilDim(b, loc, tensor, type.getRank() - 1);
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}
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static Value createZeroInitTensor(OpBuilder &b, Location loc, ValueRange sizes,
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Type elemTy) {
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Value initTensor = b.create<linalg::InitTensorOp>(loc, sizes, elemTy);
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RankedTensorType type = initTensor.getType().cast<RankedTensorType>();
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Value c0 =
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b.create<arith::ConstantOp>(loc, b.getZeroAttr(type.getElementType()));
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return b.create<linalg::FillOp>(loc, c0, initTensor).getResult(0);
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}
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// Helper function to caculate the output tensor dims for convolution-like ops.
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// Along each dim:
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// dim_out =
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// floor((dim_in + 2 * padding - dilation * (kernelSize - 1) - 1) / stride) + 1
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static Value getOutputDimForConvOps(OpBuilder &b, Location loc, Value in,
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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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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, castIndexToInt(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 = 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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static SmallVector<Value>
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getAsConstantIntValues(OpBuilder &b, Location loc,
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SmallVectorImpl<int64_t> &ints) {
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return llvm::to_vector<4>(llvm::map_range(ints, [&](int64_t val) -> Value {
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return b.create<arith::ConstantOp>(loc,
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b.getIntegerAttr(b.getI64Type(), val));
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}));
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}
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static SmallVector<Value>
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getAsConstantIndexValues(OpBuilder &b, Location loc,
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SmallVectorImpl<int64_t> &ints) {
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return llvm::to_vector<4>(llvm::map_range(ints, [&](int64_t val) -> Value {
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return b.create<arith::ConstantOp>(loc, b.getIndexAttr(val));
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}));
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}
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static SmallVector<OpFoldResult>
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getAsOpFoldResult(OpBuilder &b, Location loc, 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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// This is a temporary solution to deal with types that are not fully supported
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// like list, dict. For those container tyes, this helper can be used to
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// convert their elements to valid target type.
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// TODO: remove this when list gets full support.
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static SmallVector<Value> getTypeConvertedValues(OpBuilder &b, Location loc,
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TypeConverter *converter,
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SmallVectorImpl<Value> &vs) {
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return llvm::to_vector<4>(llvm::map_range(vs, [&](Value v) {
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return converter->materializeTargetConversion(
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b, loc, converter->convertType(v.getType()), v);
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}));
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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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static Value getPaddedTensor(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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SmallVector<OpFoldResult> paddings = getAsOpFoldResult(b, loc, paddingInts);
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Type ranked4DTensorType = linalg::PadTensorOp::inferResultType(
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input.getType().cast<RankedTensorType>(), paddingInts, paddingInts);
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Value paddedInput = linalg::PadTensorOp::createPadScalarOp(
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ranked4DTensorType, input, c0, /*low=*/paddings, /*high=*/paddings,
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/*packing=*/false, loc, b);
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return paddedInput;
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}
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static bool getListConstructElements(Value v, SmallVectorImpl<Value> &elems) {
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auto listConstruct = v.getDefiningOp<PrimListConstructOp>();
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if (!listConstruct)
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return false;
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elems = llvm::to_vector<4>(listConstruct.elements());
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return true;
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}
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namespace {
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class ConvertAtenAdaptiveAvgPool2dOp
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: public OpConversionPattern<AtenAdaptiveAvgPool2dOp> {
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public:
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using OpConversionPattern::OpConversionPattern;
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LogicalResult
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matchAndRewrite(AtenAdaptiveAvgPool2dOp op, ArrayRef<Value> operands,
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ConversionPatternRewriter &rewriter) const override {
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Location loc = op->getLoc();
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MLIRContext *context = op->getContext();
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AtenAdaptiveAvgPool2dOp::Adaptor adaptor(operands);
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Value input = adaptor.self(); /* in form of N*C*H*W */
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RankedTensorType inputType = input.getType().cast<RankedTensorType>();
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Type elementType = inputType.getElementType();
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if (!elementType.isa<mlir::FloatType>())
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return op.emitError("unimplemented: non-floating point type");
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auto inputRank = inputType.getRank();
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if (inputRank != 4)
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return rewriter.notifyMatchFailure(op, "input should be rank 4");
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SmallVector<int64_t, 2> expects{1, 1};
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// Pattern match against the op's original operands, because otherwise we
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// will get the lowered version of the operands which is harder to pattern
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// match.
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if (!isConstantIntListMatching(op.output_size(), expects))
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return rewriter.notifyMatchFailure(
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op, "only support output_size with H and W both equal to constant 1");
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Value N = getDimOp(rewriter, loc, input, 0);
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Value C = getDimOp(rewriter, loc, input, 1);
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Value initTensor = rewriter.create<linalg::InitTensorOp>(
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loc, ValueRange{N, C}, elementType);
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Value c0 = rewriter.create<arith::ConstantOp>(
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loc, FloatAttr::get(elementType, 0.0));
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Value initTensor0 =
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rewriter.create<linalg::FillOp>(loc, c0, initTensor).getResult(0);
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SmallVector<AffineExpr, 2> ncExprs;
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ncExprs.push_back(mlir::getAffineDimExpr(0, context));
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ncExprs.push_back(mlir::getAffineDimExpr(1, context));
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auto ncIndexingMap = AffineMap::get(
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/*dimCount=*/4,
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/*symbolCount=*/0, ncExprs, context);
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SmallVector<AffineMap, 2> indexingMaps = {
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rewriter.getMultiDimIdentityMap(4), // input
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ncIndexingMap, // output
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};
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SmallVector<StringRef, 4> iteratorTypesSum{"parallel", "parallel",
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"reduction", "reduction"};
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Value sumPool2d = rewriter
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.create<linalg::GenericOp>(
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loc, initTensor0.getType(), input, initTensor0,
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/*indexingMaps=*/indexingMaps,
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/*iteratorTypes=*/iteratorTypesSum,
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[&](OpBuilder &b, Location loc, ValueRange args) {
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Value input = args[0], sum = args[1];
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Value result = rewriter.create<arith::AddFOp>(
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loc, sum, input);
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b.create<linalg::YieldOp>(loc, result);
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})
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.getResult(0);
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// Calculate H*W so that avg can be got from sum / (H*W)
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Value H = getDimOp(rewriter, loc, input, 2);
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Value W = getDimOp(rewriter, loc, input, 3);
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auto castIndexToInt = [&](Value v) {
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return rewriter.create<arith::IndexCastOp>(
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loc, IntegerType::get(context, 64), v);
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};
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Value HtimesW = rewriter.create<arith::MulIOp>(loc, castIndexToInt(H),
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castIndexToInt(W));
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Value HtimesWf =
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rewriter.create<arith::SIToFPOp>(loc, elementType, HtimesW);
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Value c1Index = rewriter.create<arith::ConstantIndexOp>(loc, /*value=*/1);
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Value outputTensor = rewriter.create<linalg::InitTensorOp>(
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loc, ValueRange{N, C, c1Index, c1Index}, elementType);
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SmallVector<AffineMap, 2> indexingMapsAvg{
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ncIndexingMap, rewriter.getMultiDimIdentityMap(4)};
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SmallVector<StringRef, 4> iteratorTypesAvg(4, "parallel");
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Value avgPool2d =
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rewriter
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.create<linalg::GenericOp>(
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loc, outputTensor.getType(), sumPool2d, outputTensor,
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/*indexingMaps=*/indexingMapsAvg,
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/*iteratorTypes=*/iteratorTypesAvg,
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[&](OpBuilder &b, Location loc, ValueRange args) {
|
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Value avg = b.create<arith::DivFOp>(loc, args[0], HtimesWf);
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b.create<linalg::YieldOp>(loc, avg);
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})
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.getResult(0);
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Type newResultType = getTypeConverter()->convertType(op.getType());
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rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, avgPool2d);
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return success();
|
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}
|
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};
|
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} // namespace
|
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|
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namespace {
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class ConvertAtenConv2dOp : public OpConversionPattern<AtenConv2dOp> {
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public:
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using OpConversionPattern::OpConversionPattern;
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LogicalResult
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matchAndRewrite(AtenConv2dOp op, ArrayRef<Value> operands,
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ConversionPatternRewriter &rewriter) const override {
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Location loc = op->getLoc();
|
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MLIRContext *context = op->getContext();
|
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AtenConv2dOp::Adaptor adaptor(operands);
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Value input = adaptor.input(); /* in form of N*C*H*W */
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Value weight = adaptor.weight(); /* in form of F*C*H*W */
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Value groups = adaptor.groups();
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|
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Type elementType =
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input.getType().cast<RankedTensorType>().getElementType();
|
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if (!elementType.isa<mlir::FloatType>())
|
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return op.emitError("unimplemented: non-floating point type");
|
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|
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Type intType = IntegerType::get(context, 64);
|
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auto castIndexToInt = [&](Value v) {
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return rewriter.create<arith::IndexCastOp>(loc, intType, v);
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};
|
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Value N = getDimOp(rewriter, loc, input, 0);
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Value Hin = getDimOp(rewriter, loc, input, 2);
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Value Win = getDimOp(rewriter, loc, input, 3);
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Value F = getDimOp(rewriter, loc, weight, 0);
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Value weightH = getDimOp(rewriter, loc, weight, 2);
|
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Value weightW = getDimOp(rewriter, loc, weight, 3);
|
||
|
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// Pattern match against the op's original operands, because otherwise we
|
||
// will get the lowered version of the operands which is harder to pattern
|
||
// match.
|
||
SmallVector<int64_t> paddingInts;
|
||
if (!matchPattern(op.padding(), m_TorchConstantIntList(paddingInts))) {
|
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return rewriter.notifyMatchFailure(
|
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op, "only support constant padding values");
|
||
}
|
||
|
||
SmallVector<int64_t, 2> strideInts;
|
||
if (!matchPattern(op.stride(), m_TorchConstantIntList(strideInts)))
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only support constant int strides");
|
||
SmallVector<int64_t, 2> dilationInts;
|
||
if (!matchPattern(op.dilation(), m_TorchConstantIntList(dilationInts)))
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only support constant int dilations");
|
||
if (!op.bias().getType().isa<Torch::NoneType>())
|
||
return rewriter.notifyMatchFailure(op, "only support None bias");
|
||
|
||
Value c1 =
|
||
rewriter.create<arith::ConstantOp>(loc, IntegerAttr::get(intType, 1));
|
||
Value groupEqual1 = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, groups, c1);
|
||
rewriter.create<AssertOp>(loc, groupEqual1,
|
||
rewriter.getStringAttr("expect groups to be 1"));
|
||
|
||
// Pad the input tensor according to padding.
|
||
SmallVector<int64_t, 4> paddingIncludingNC = {0, 0};
|
||
paddingIncludingNC.insert(paddingIncludingNC.end(), paddingInts.begin(),
|
||
paddingInts.end());
|
||
Value paddedInput =
|
||
getPaddedTensor(op, rewriter, input, paddingIncludingNC);
|
||
|
||
SmallVector<Value> paddingIntValues =
|
||
getAsConstantIntValues(rewriter, loc, paddingInts);
|
||
SmallVector<Value> dilationIntValues =
|
||
getAsConstantIntValues(rewriter, loc, dilationInts);
|
||
SmallVector<Value> strideIntValues =
|
||
getAsConstantIntValues(rewriter, loc, strideInts);
|
||
|
||
Value Hout = getOutputDimForConvOps(
|
||
rewriter, loc, Hin, paddingIntValues[0], dilationIntValues[0],
|
||
castIndexToInt(weightH), strideIntValues[0]);
|
||
Value Wout = getOutputDimForConvOps(
|
||
rewriter, loc, Win, paddingIntValues[1], dilationIntValues[1],
|
||
castIndexToInt(weightW), strideIntValues[1]);
|
||
|
||
Value c0float = rewriter.create<arith::ConstantOp>(
|
||
loc,
|
||
FloatAttr::get(
|
||
input.getType().cast<RankedTensorType>().getElementType(), 0.0));
|
||
Value initTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, ValueRange{N, F, Hout, Wout}, elementType);
|
||
Value initTensor0 =
|
||
rewriter.create<linalg::FillOp>(loc, c0float, initTensor).getResult(0);
|
||
|
||
auto stridesAttr = rewriter.getI64VectorAttr(strideInts);
|
||
auto dilationAttr = rewriter.getI64VectorAttr(dilationInts);
|
||
Value conv2d =
|
||
rewriter
|
||
.create<linalg::Conv2DNchwFchwOp>(
|
||
loc, initTensor0.getType(), ValueRange{paddedInput, weight},
|
||
initTensor0, stridesAttr, dilationAttr)
|
||
.getResult(0);
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, conv2d);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
// Normalization formula:
|
||
// ((input - mean) / sqrt(var + eps)) * weight + bias
|
||
static Value createLinalgPayloadCalculationForNormOps(
|
||
OpBuilder &b, Location loc, Type elemTy, Value input, Value mean, Value var,
|
||
Value eps, Value weight, Value bias) {
|
||
Value inputSubMean = b.create<arith::SubFOp>(loc, input, mean);
|
||
// The eps is always f64.
|
||
Value truncatedEps = b.create<arith::TruncFOp>(loc, elemTy, eps);
|
||
Value varPlusEps = b.create<arith::AddFOp>(loc, var, truncatedEps);
|
||
Value rSTD = b.create<math::RsqrtOp>(loc, varPlusEps);
|
||
Value temp = b.create<arith::MulFOp>(loc, inputSubMean, rSTD);
|
||
Value timesWeight = b.create<arith::MulFOp>(loc, temp, weight);
|
||
Value plusBias = b.create<arith::AddFOp>(loc, timesWeight, bias);
|
||
return plusBias;
|
||
}
|
||
|
||
static void createLinalgPayloadCalculationForGatherOps(
|
||
OpBuilder &b, Location loc, Value input, int64_t inputRank, Value index,
|
||
int64_t dim, int64_t outputRank) {
|
||
SmallVector<Value> indices;
|
||
for (int i = 0; i < inputRank; i++) {
|
||
if (i == dim) {
|
||
indices.push_back(castIntToIndex(b, loc, index));
|
||
} else {
|
||
// `outputRank` might be larger than `inputRank`. The `linalg::IndexOp`
|
||
// takes in the dimension of the output. Add `inputDimOffset` to
|
||
// related to the correct dimension of the output for dimension larger
|
||
// than the given `dim`.
|
||
int64_t inputDimOffset = i < dim ? 0 : outputRank - inputRank;
|
||
indices.push_back(b.create<linalg::IndexOp>(loc, i + inputDimOffset));
|
||
}
|
||
}
|
||
|
||
// Assert index < input.sizes[dim]
|
||
Value indexLTInputDim = b.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::slt, index,
|
||
castIndexToInt(b, loc, getDimOp(b, loc, input, dim)));
|
||
b.create<AssertOp>(loc, indexLTInputDim,
|
||
b.getStringAttr("index must be smaller than dim size"));
|
||
|
||
// Assert index >= 0
|
||
Value cst0 = b.create<arith::ConstantOp>(loc, b.getZeroAttr(index.getType()));
|
||
Value indexGEThanZero =
|
||
b.create<arith::CmpIOp>(loc, arith::CmpIPredicate::sge, index, cst0);
|
||
b.create<AssertOp>(loc, indexGEThanZero,
|
||
b.getStringAttr("index must be larger or equal to 0"));
|
||
|
||
Value extract = b.create<tensor::ExtractOp>(loc, input, indices);
|
||
b.create<linalg::YieldOp>(loc, extract);
|
||
}
|
||
|
||
namespace {
|
||
class ConvertAtenBatchNormOp : public OpConversionPattern<AtenBatchNormOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenBatchNormOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
AtenBatchNormOp::Adaptor adaptor(operands);
|
||
MLIRContext *context = op->getContext();
|
||
Location loc = op->getLoc();
|
||
Value input = adaptor.input();
|
||
Value weight = adaptor.weight();
|
||
Value bias = adaptor.bias();
|
||
Value runningMean = adaptor.running_mean();
|
||
Value runningVar = adaptor.running_var();
|
||
Value training = adaptor.training();
|
||
Value eps = adaptor.eps();
|
||
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
|
||
// TODO: Handle the None cases for the optional parameters:
|
||
// weight, bias.
|
||
if (failed(checkNotNone(rewriter, op, weight)) ||
|
||
failed(checkNotNone(rewriter, op, bias)) ||
|
||
failed(checkNotNone(rewriter, op, runningMean)) ||
|
||
failed(checkNotNone(rewriter, op, runningVar)))
|
||
return failure();
|
||
|
||
auto inputType = input.getType().cast<RankedTensorType>();
|
||
auto weightType = weight.getType().cast<RankedTensorType>();
|
||
auto biasType = bias.getType().cast<RankedTensorType>();
|
||
auto runningMeanType = runningMean.getType().cast<RankedTensorType>();
|
||
auto runningVarType = runningVar.getType().cast<RankedTensorType>();
|
||
|
||
auto inputRank = inputType.getRank();
|
||
if (inputRank <= 2)
|
||
return rewriter.notifyMatchFailure(
|
||
op, "input should have rank larger than 2");
|
||
|
||
if (weightType.getRank() != 1 || biasType.getRank() != 1 ||
|
||
runningMeanType.getRank() != 1 || runningVarType.getRank() != 1) {
|
||
return rewriter.notifyMatchFailure(
|
||
op, "expect weight, bias, running_mean and running_var to be rank 1");
|
||
}
|
||
|
||
// TODO: Add support for training.
|
||
auto constFalse = rewriter.create<arith::ConstantOp>(
|
||
loc, IntegerAttr::get(IntegerType::get(context, 1), 0));
|
||
auto trainingFalse = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, training, constFalse);
|
||
rewriter.create<AssertOp>(
|
||
loc, trainingFalse,
|
||
rewriter.getStringAttr("training is not supported for now"));
|
||
|
||
// num_features – C from an expected input of size (N,C,D,H,W ...)
|
||
Value numFeatures = rewriter.create<tensor::DimOp>(loc, input, 1);
|
||
auto contractingDim0EqualsNumFeatures = [&](Value v) {
|
||
auto dim0 = rewriter.create<tensor::DimOp>(loc, v, 0);
|
||
auto dim0Equal = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, numFeatures, dim0);
|
||
rewriter.create<AssertOp>(
|
||
loc, dim0Equal,
|
||
rewriter.getStringAttr(
|
||
"expect the size of dim 0 equal to the number of features"));
|
||
};
|
||
contractingDim0EqualsNumFeatures(weight);
|
||
contractingDim0EqualsNumFeatures(bias);
|
||
contractingDim0EqualsNumFeatures(runningMean);
|
||
contractingDim0EqualsNumFeatures(runningVar);
|
||
|
||
auto indexingMap = AffineMap::get(
|
||
/*dimCount=*/inputRank,
|
||
/*symbolCount=*/0, rewriter.getAffineDimExpr(1), context);
|
||
SmallVector<AffineMap> indexingMaps = {
|
||
rewriter.getMultiDimIdentityMap(inputRank), // input
|
||
indexingMap, // weight
|
||
indexingMap, // bias
|
||
indexingMap, // runningMean
|
||
indexingMap, // runningVar
|
||
rewriter.getMultiDimIdentityMap(inputRank), // output
|
||
};
|
||
SmallVector<StringRef> iteratorTypes(inputRank, "parallel");
|
||
Value batchNorm =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, input.getType(),
|
||
ValueRange{input, weight, bias, runningMean, runningVar}, input,
|
||
/*indexingMaps=*/indexingMaps,
|
||
/*iteratorTypes=*/iteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value input = args[0], weight = args[1], bias = args[2],
|
||
mean = args[3], var = args[4];
|
||
Value result = createLinalgPayloadCalculationForNormOps(
|
||
b, loc, var.getType(), input, mean, var, eps, weight,
|
||
bias);
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
})
|
||
.getResult(0);
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, batchNorm);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
// For layernorm, the mean and standard-deviation are calculated separately over
|
||
// the last certain number dimensions which have to be of the shape specified by
|
||
// normalized_shape.
|
||
//
|
||
// The shapes of different parts are as the following:
|
||
// +-------------------+--------------------+
|
||
// | meanAndVarShape | normalizedShape |
|
||
// +-------------------+---------------------
|
||
// <------------+ inputShape +-------------->
|
||
|
||
// There are the following steps:
|
||
// Step 1. Check if all the arguments meet the requirements.
|
||
// Step 2. Common parts to be used for getting mean and var.
|
||
// This includes elements count, affineMap and iteratorTypes.
|
||
// Step 3. Get mean.
|
||
// Step 4. Get var.
|
||
// Step 5. Get layernorm.
|
||
namespace {
|
||
class ConvertAtenLayerNormOp : public OpConversionPattern<AtenLayerNormOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenLayerNormOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
AtenLayerNormOp::Adaptor adaptor(operands);
|
||
MLIRContext *context = op->getContext();
|
||
Location loc = op->getLoc();
|
||
Value input = adaptor.input();
|
||
Value weight = adaptor.weight();
|
||
Value bias = adaptor.bias();
|
||
Value eps = adaptor.eps();
|
||
Value normalizedShape = op.normalized_shape();
|
||
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
|
||
// TODO: Handle the None cases for the optional parameters:
|
||
// weight, bias.
|
||
if (failed(checkNotNone(rewriter, op, weight)) ||
|
||
failed(checkNotNone(rewriter, op, bias)))
|
||
return failure();
|
||
|
||
auto inputType = input.getType().cast<RankedTensorType>();
|
||
auto weightType = weight.getType().cast<RankedTensorType>();
|
||
auto biasType = bias.getType().cast<RankedTensorType>();
|
||
int64_t inputRank = inputType.getRank();
|
||
Type elemTy = inputType.getElementType();
|
||
|
||
// Step 1. Check if all the arguments meet the requirements.
|
||
SmallVector<Value> normalizedShapeSizesTorchInt;
|
||
if (!getListConstructElements(normalizedShape,
|
||
normalizedShapeSizesTorchInt)) {
|
||
return rewriter.notifyMatchFailure(op,
|
||
"Unimplemented normalized_shape not"
|
||
"constructed from ListConstruct");
|
||
}
|
||
SmallVector<Value> normalizedShapeSizesInt = getTypeConvertedValues(
|
||
rewriter, loc, getTypeConverter(), normalizedShapeSizesTorchInt);
|
||
int64_t normalizedShapeRank = normalizedShapeSizesInt.size();
|
||
if (weightType.getRank() != normalizedShapeRank ||
|
||
biasType.getRank() != normalizedShapeRank ||
|
||
inputRank < normalizedShapeRank || normalizedShapeRank < 1)
|
||
return rewriter.notifyMatchFailure(op, "Input or weight or bias shape or"
|
||
"normalized shape not compatible");
|
||
|
||
// Check all the dimensions match the normalized_shape
|
||
int64_t meanAndVarShapeRank = inputRank - normalizedShapeSizesInt.size();
|
||
for (auto en : enumerate((normalizedShapeSizesInt))) {
|
||
auto index = en.index();
|
||
auto inputDim =
|
||
getDimOp(rewriter, loc, input, index + meanAndVarShapeRank);
|
||
auto weightDim = getDimOp(rewriter, loc, weight, index);
|
||
auto biasDim = getDimOp(rewriter, loc, bias, index);
|
||
|
||
auto expectedSize = en.value();
|
||
checkDimEqualHelper(rewriter, loc, inputDim, expectedSize);
|
||
checkDimEqualHelper(rewriter, loc, weightDim, expectedSize);
|
||
checkDimEqualHelper(rewriter, loc, biasDim, expectedSize);
|
||
}
|
||
|
||
// Get iterator types for input shape.
|
||
SmallVector<StringRef> normalizedShapeIteratorTypes(
|
||
normalizedShapeRank, getReductionIteratorTypeName());
|
||
SmallVector<StringRef> meanAndVarIterationTypes(
|
||
meanAndVarShapeRank, getParallelIteratorTypeName());
|
||
SmallVector<StringRef> inputShapeIteratorTypes = meanAndVarIterationTypes;
|
||
inputShapeIteratorTypes.append(normalizedShapeIteratorTypes);
|
||
|
||
// Step 2. Common parts to be used for getting mean and var.
|
||
|
||
// Get sizes and affineMaps needed for mean and var.
|
||
AffineMap inputShapeAffineMap = rewriter.getMultiDimIdentityMap(inputRank);
|
||
SmallVector<AffineExpr> meanAndVarShapeExprs;
|
||
for (int i = 0; i < meanAndVarShapeRank; i++)
|
||
meanAndVarShapeExprs.push_back(mlir::getAffineDimExpr(i, context));
|
||
auto meanAndVarShapeAffineMap = AffineMap::get(
|
||
/*dimCount=*/inputRank,
|
||
/*symbolCount=*/0, meanAndVarShapeExprs, context);
|
||
SmallVector<Value> meanAndVarShapeSizes =
|
||
getTensorSizesUntilDim(rewriter, loc, input, meanAndVarShapeRank - 1);
|
||
|
||
// Get number of elements to be used for calculating mean and var.
|
||
Value elemCnts = normalizedShapeSizesInt[0];
|
||
for (int i = 1; i < normalizedShapeRank; i++) {
|
||
elemCnts = rewriter.create<arith::MulIOp>(loc, elemCnts,
|
||
normalizedShapeSizesInt[i]);
|
||
}
|
||
Value elemCntsFloat =
|
||
rewriter.create<arith::SIToFPOp>(loc, elemTy, elemCnts);
|
||
|
||
// Helper to calculate mean and var.
|
||
auto genMeanOrVarCalculation = [&](Value sumOrSquareSum) {
|
||
SmallVector<AffineMap> indexingMaps(
|
||
2, rewriter.getMultiDimIdentityMap(meanAndVarShapeRank));
|
||
Value initShapeTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, meanAndVarShapeSizes, elemTy);
|
||
return rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initShapeTensor.getType(), sumOrSquareSum, initShapeTensor,
|
||
/*indexingMaps=*/indexingMaps,
|
||
/*iteratorTypes=*/meanAndVarIterationTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value sumOrSqureSum = args[0];
|
||
Value result =
|
||
b.create<arith::DivFOp>(loc, sumOrSqureSum, elemCntsFloat);
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
})
|
||
.getResult(0);
|
||
};
|
||
|
||
// Step 3. Get mean.
|
||
|
||
// Get sum to be used for calculating mean.
|
||
SmallVector<AffineMap, 2> sumIndexingMaps = {
|
||
inputShapeAffineMap, // input
|
||
meanAndVarShapeAffineMap, // output
|
||
};
|
||
auto initSumTensor =
|
||
createZeroInitTensor(rewriter, loc, meanAndVarShapeSizes, elemTy);
|
||
Value sum = rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initSumTensor.getType(), input, initSumTensor,
|
||
/*indexingMaps=*/sumIndexingMaps,
|
||
/*iteratorTypes=*/inputShapeIteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value input = args[0], sum = args[1];
|
||
Value result =
|
||
rewriter.create<arith::AddFOp>(loc, sum, input);
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
})
|
||
.getResult(0);
|
||
Value mean = genMeanOrVarCalculation(sum);
|
||
|
||
// Step 4. Get var.
|
||
|
||
// Calculate squareSum for the layer.
|
||
SmallVector<AffineMap> squareSumIndexingMaps{
|
||
inputShapeAffineMap,
|
||
meanAndVarShapeAffineMap,
|
||
meanAndVarShapeAffineMap,
|
||
};
|
||
auto initSquareSumTensor =
|
||
createZeroInitTensor(rewriter, loc, meanAndVarShapeSizes, elemTy);
|
||
Value squareSum =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initSquareSumTensor.getType(), ValueRange{input, mean},
|
||
initSquareSumTensor,
|
||
/*indexingMaps=*/squareSumIndexingMaps,
|
||
/*iteratorTypes=*/inputShapeIteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value input = args[0], mean = args[1], squareSum = args[2];
|
||
Value sub = rewriter.create<arith::SubFOp>(loc, input, mean);
|
||
Value square = rewriter.create<arith::MulFOp>(loc, sub, sub);
|
||
Value result =
|
||
rewriter.create<arith::AddFOp>(loc, squareSum, square);
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
})
|
||
.getResult(0);
|
||
Value var = genMeanOrVarCalculation(squareSum);
|
||
|
||
// Step 5. Get layernorm.
|
||
|
||
// Get affineMap for normalized shape.
|
||
SmallVector<AffineExpr> normalizedShapeExprs;
|
||
for (int i = meanAndVarShapeRank; i < inputRank; i++)
|
||
normalizedShapeExprs.push_back(mlir::getAffineDimExpr(i, context));
|
||
auto normalizedShapeAffineMap = AffineMap::get(
|
||
/*dimCount=*/inputRank,
|
||
/*symbolCount=*/0, normalizedShapeExprs, context);
|
||
|
||
auto inputSizes = getTensorSizes(rewriter, loc, input);
|
||
Value initLayerNormTensor =
|
||
rewriter.create<linalg::InitTensorOp>(loc, inputSizes, elemTy);
|
||
SmallVector<AffineMap> indexingMaps(1, inputShapeAffineMap);
|
||
indexingMaps.resize(3, meanAndVarShapeAffineMap);
|
||
indexingMaps.resize(5, normalizedShapeAffineMap);
|
||
indexingMaps.push_back(inputShapeAffineMap);
|
||
SmallVector<StringRef> layerNormIterationTypes(
|
||
inputRank, getParallelIteratorTypeName());
|
||
Value layerNorm =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initLayerNormTensor.getType(),
|
||
ValueRange{input, mean, var, weight, bias}, initLayerNormTensor,
|
||
/*indexingMaps=*/indexingMaps,
|
||
/*iteratorTypes=*/layerNormIterationTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value input = args[0], mean = args[1], var = args[2],
|
||
weight = args[3], bias = args[4];
|
||
Value result = createLinalgPayloadCalculationForNormOps(
|
||
b, loc, elemTy, input, mean, var, eps, weight, bias);
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
})
|
||
.getResult(0);
|
||
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, layerNorm);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenMmOp : public OpConversionPattern<AtenMmOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenMmOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
Location loc = op->getLoc();
|
||
Value lhs = operands[0];
|
||
Value rhs = operands[1];
|
||
|
||
// A user can write an errorneous program where `aten.mm` is in fact called
|
||
// with operands of invalid rank or dtype. We cannot convert to linalg in
|
||
// this case or we will get a verifier error, which corresponds to breaking
|
||
// of *internal* compiler invariants, and for a user manifests as a compiler
|
||
// crash in the worst case (such as we try to canonicalize/fold/print the
|
||
// invalid op before the verifier gets to see it -- also release builds of a
|
||
// mature compiler usually have the verifier turned off for compile time
|
||
// reasons).
|
||
//
|
||
// The compiler cannot crash even if the user wrote an erroneous program!
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
if (lhs.getType().cast<RankedTensorType>().getRank() != 2 ||
|
||
rhs.getType().cast<RankedTensorType>().getRank() != 2) {
|
||
return rewriter.notifyMatchFailure(
|
||
op, "expected both operands to aten.mm to be rank 2");
|
||
}
|
||
|
||
Value lhsDim0 = rewriter.create<tensor::DimOp>(loc, lhs, 0);
|
||
Value lhsDim1 = rewriter.create<tensor::DimOp>(loc, lhs, 1);
|
||
Value rhsDim0 = rewriter.create<tensor::DimOp>(loc, rhs, 0);
|
||
Value rhsDim1 = rewriter.create<tensor::DimOp>(loc, rhs, 1);
|
||
Value contractingDimEqual = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, lhsDim1, rhsDim0);
|
||
rewriter.create<AssertOp>(
|
||
loc, contractingDimEqual,
|
||
rewriter.getStringAttr(
|
||
"mismatching contracting dimension for torch.aten.mm"));
|
||
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
Type elementType = newResultType.cast<TensorType>().getElementType();
|
||
Value initTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, ValueRange{lhsDim0, rhsDim1}, elementType);
|
||
Value c0 = rewriter.create<arith::ConstantOp>(
|
||
loc, FloatAttr::get(elementType, 0.0));
|
||
Value zeroFill =
|
||
rewriter.create<linalg::FillOp>(loc, c0, initTensor).getResult(0);
|
||
Value matmul = rewriter
|
||
.create<linalg::MatmulOp>(loc, zeroFill.getType(),
|
||
ValueRange{lhs, rhs}, zeroFill)
|
||
.getResult(0);
|
||
// When constructed with just dynamic sizes, InitTensorOp will have a result
|
||
// type which has all `?`'s for dimensions, which might not be the result
|
||
// type of `op`. The constraints on later linalg ops means that the result
|
||
// of the MatmulOp will have this type too. So cast it to the desired type
|
||
// so that in the end we have the original result type.
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, matmul);
|
||
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenBmmOp : public OpConversionPattern<AtenBmmOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenBmmOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
Location loc = op->getLoc();
|
||
Value lhs = operands[0];
|
||
Value rhs = operands[1];
|
||
RankedTensorType lhsType = lhs.getType().cast<RankedTensorType>();
|
||
RankedTensorType rhsType = rhs.getType().cast<RankedTensorType>();
|
||
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
if (lhsType.getRank() != 3 || rhsType.getRank() != 3) {
|
||
return rewriter.notifyMatchFailure(
|
||
op, "expected both operands to aten.bmm to be rank 3");
|
||
}
|
||
if (!lhsType.getElementType().isa<mlir::FloatType>() ||
|
||
lhsType.getElementType() != rhsType.getElementType())
|
||
return op.emitError(
|
||
"unimplemented: non floating point operands or operands of "
|
||
"different types");
|
||
|
||
Value lhsDim0 = getDimOp(rewriter, loc, lhs, 0);
|
||
Value lhsDim1 = getDimOp(rewriter, loc, lhs, 1);
|
||
Value lhsDim2 = getDimOp(rewriter, loc, lhs, 2);
|
||
Value rhsDim0 = getDimOp(rewriter, loc, rhs, 0);
|
||
Value rhsDim1 = getDimOp(rewriter, loc, rhs, 1);
|
||
Value rhsDim2 = getDimOp(rewriter, loc, rhs, 2);
|
||
|
||
// Check the batch numbers are equal.
|
||
checkDimEqualHelper(rewriter, loc, lhsDim0, rhsDim0);
|
||
|
||
// Check the matrixs shapes are valid for mulplication.
|
||
checkDimEqualHelper(rewriter, loc, lhsDim2, rhsDim1);
|
||
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
Type elementType = newResultType.cast<TensorType>().getElementType();
|
||
Value initTensor0 = createZeroInitTensor(
|
||
rewriter, loc, ValueRange{lhsDim0, lhsDim1, rhsDim2}, elementType);
|
||
|
||
Value bmm =
|
||
rewriter
|
||
.create<linalg::BatchMatmulOp>(loc, initTensor0.getType(),
|
||
ValueRange{lhs, rhs}, initTensor0)
|
||
.getResult(0);
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, bmm);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
// See comments at in convertMmOp and the heading for this section for general
|
||
// considerations. This function needs to be auto-generated.
|
||
class ConvertAtenLinearOp : public OpConversionPattern<AtenLinearOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenLinearOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
AtenLinearOp::Adaptor adaptor(operands);
|
||
MLIRContext *context = op->getContext();
|
||
Location loc = op->getLoc();
|
||
Value input = adaptor.input();
|
||
Value weight = adaptor.weight();
|
||
Value bias = adaptor.bias();
|
||
// TODO: Handle the case of bias being None (bias is optional).
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
auto inputType = input.getType().cast<RankedTensorType>();
|
||
auto weightType = weight.getType().cast<RankedTensorType>();
|
||
auto biasType = bias.getType().cast<RankedTensorType>();
|
||
// Only handle the case of rank 2 `input` for now.
|
||
// TODO: Insert the appropriate reshape to collapse any leading dimensions.
|
||
if (inputType.getRank() != 2 || weightType.getRank() != 2 ||
|
||
biasType.getRank() != 1) {
|
||
return rewriter.notifyMatchFailure(
|
||
op,
|
||
"expected both input and weight to be rank 2 and bias to be rank 1");
|
||
}
|
||
// TODO: Handle type promotion. What are ATen's promotion rules?
|
||
if (inputType.getElementType() != weightType.getElementType() ||
|
||
inputType.getElementType() != biasType.getElementType()) {
|
||
return rewriter.notifyMatchFailure(op, "unimplemented: type promotion");
|
||
}
|
||
|
||
// TODO: We can handle a static size 1 here at some complexity cost, but the
|
||
// dynamic case is not representable in linalg. We don't handle either for
|
||
// now. Biases are generally statically shaped for most models (since for
|
||
// inference they are constants, and for training they don't change shape
|
||
// typically), so this is not too constraining.
|
||
auto biasSize = bias.getType().cast<RankedTensorType>().getShape()[0];
|
||
if (biasSize == 1 || biasSize == ShapedType::kDynamicSize)
|
||
return rewriter.notifyMatchFailure(
|
||
op, "unimplemented: size-1 broadcasting for aten::LinearOp");
|
||
|
||
Value inputDim0 = getDimOp(rewriter, loc, input, 0);
|
||
Value inputDim1 = getDimOp(rewriter, loc, input, 1);
|
||
Value weightDim0 = getDimOp(rewriter, loc, weight, 0);
|
||
Value weightDim1 = getDimOp(rewriter, loc, weight, 1);
|
||
Value biasDim0 = getDimOp(rewriter, loc, bias, 0);
|
||
Value contractingDimEqual = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, inputDim1, weightDim1);
|
||
rewriter.create<AssertOp>(
|
||
loc, contractingDimEqual,
|
||
rewriter.getStringAttr(
|
||
"mismatching contracting dimension for aten.linear"));
|
||
// Here we take advantage of ruling out the size-1 case above.
|
||
// In the static-size-1 case, we will not emit this check at all.
|
||
Value biasSizeCorrect = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, weightDim0, biasDim0);
|
||
rewriter.create<AssertOp>(
|
||
loc, biasSizeCorrect,
|
||
rewriter.getStringAttr("mismatching bias size for aten.linear"));
|
||
|
||
Value initTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, ValueRange{inputDim0, weightDim0}, inputType.getElementType());
|
||
SmallVector<AffineMap> broadcastIndexingMaps = {
|
||
AffineMap::get(
|
||
/*dimCount=*/2, /*symbolCount=*/0, rewriter.getAffineDimExpr(1)),
|
||
rewriter.getMultiDimIdentityMap(2)};
|
||
SmallVector<StringRef> iteratorTypes(2, "parallel");
|
||
Value broadcasted =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initTensor.getType(), bias, initTensor,
|
||
/*indexingMaps=*/broadcastIndexingMaps,
|
||
/*iteratorTypes=*/iteratorTypes,
|
||
[](OpBuilder &b, Location loc, ValueRange args) {
|
||
b.create<linalg::YieldOp>(loc, args[0]);
|
||
})
|
||
.getResult(0);
|
||
// We need a matmul with dimension ordering (N, K) * (M, K), so transpose
|
||
// the weights to fit into linalg::MatmulOp which is (N, K) * (K, M).
|
||
// TODO: This whole aten.linear lowering should eventually be generated from
|
||
// a single linalg ODS generator statement. Both the bias and matmul part.
|
||
SmallVector<AffineMap> transposeIndexingMaps = {
|
||
AffineMap::get(
|
||
/*dimCount=*/2, /*symbolCount=*/0,
|
||
{rewriter.getAffineDimExpr(1), rewriter.getAffineDimExpr(0)},
|
||
context),
|
||
rewriter.getMultiDimIdentityMap(2)};
|
||
Value transposedWeightInitTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, ValueRange{weightDim1, weightDim0}, weightType.getElementType());
|
||
Value transposedWeights =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, transposedWeightInitTensor.getType(), weight,
|
||
transposedWeightInitTensor,
|
||
/*indexingMaps=*/transposeIndexingMaps,
|
||
/*iteratorTypes=*/iteratorTypes,
|
||
[](OpBuilder &b, Location loc, ValueRange args) {
|
||
b.create<linalg::YieldOp>(loc, args[0]);
|
||
})
|
||
.getResult(0);
|
||
Value matmul = rewriter
|
||
.create<linalg::MatmulOp>(
|
||
loc, broadcasted.getType(),
|
||
ValueRange{input, transposedWeights}, broadcasted)
|
||
.getResult(0);
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, matmul);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
static Value createLinalgPayloadCalculationForElementwiseOp(
|
||
OpBuilder &b, Location loc, ValueRange payloadArgs, Operation *op,
|
||
ArrayRef<Value> operands) {
|
||
if (isa<AtenTanhOp>(op))
|
||
return b.create<math::TanhOp>(loc, payloadArgs[0]);
|
||
if (isa<AtenExpOp>(op))
|
||
return b.create<math::ExpOp>(loc, payloadArgs[0]);
|
||
if (isa<AtenSigmoidOp>(op)) {
|
||
Type elementType = payloadArgs[0].getType();
|
||
auto one = b.create<arith::ConstantOp>(loc, FloatAttr::get(elementType, 1));
|
||
auto negate = b.create<arith::NegFOp>(loc, payloadArgs[0]);
|
||
auto exp = b.create<math::ExpOp>(loc, negate);
|
||
auto added = b.create<arith::AddFOp>(loc, exp, one);
|
||
return b.create<arith::DivFOp>(loc, one, added);
|
||
}
|
||
if (auto relu = dyn_cast<AtenReluOp>(op)) {
|
||
if (!relu.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
relu.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
Type elementType = payloadArgs[0].getType();
|
||
Value constZero =
|
||
b.create<arith::ConstantOp>(loc, FloatAttr::get(elementType, 0.0));
|
||
Value pred = b.create<arith::CmpFOp>(loc, arith::CmpFPredicate::UGT,
|
||
payloadArgs[0], constZero);
|
||
return b.create<SelectOp>(loc, pred, payloadArgs[0], constZero);
|
||
}
|
||
if (auto add = dyn_cast<AtenAddTensorOp>(op)) {
|
||
AtenAddTensorOp::Adaptor adaptor(operands);
|
||
if (add.alpha().getType().isa<Torch::FloatType>()) {
|
||
add.emitError("unimplemented: !torch.float 'alpha'");
|
||
return nullptr;
|
||
}
|
||
if (!add.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
add.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
Value alphaFloat = b.create<arith::SIToFPOp>(loc, payloadArgs[0].getType(),
|
||
adaptor.alpha());
|
||
Value scaled = b.create<arith::MulFOp>(loc, payloadArgs[1], alphaFloat);
|
||
return b.create<arith::AddFOp>(loc, payloadArgs[0], scaled);
|
||
}
|
||
if (auto sub = dyn_cast<AtenSubTensorOp>(op)) {
|
||
AtenSubTensorOp::Adaptor adaptor(operands);
|
||
if (sub.alpha().getType().isa<Torch::FloatType>()) {
|
||
sub.emitError("unimplemented: !torch.float 'alpha'");
|
||
return nullptr;
|
||
}
|
||
if (!sub.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
sub.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
Value alphaFloat = b.create<arith::SIToFPOp>(loc, payloadArgs[0].getType(),
|
||
adaptor.alpha());
|
||
Value scaled = b.create<arith::MulFOp>(loc, payloadArgs[1], alphaFloat);
|
||
|
||
return b.create<arith::SubFOp>(loc, payloadArgs[0], scaled);
|
||
}
|
||
if (auto mul = dyn_cast<AtenMulTensorOp>(op)) {
|
||
if (!mul.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
mul.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
return b.create<arith::MulFOp>(loc, payloadArgs[0], payloadArgs[1]);
|
||
}
|
||
if (auto div = dyn_cast<AtenDivTensorOp>(op)) {
|
||
if (!div.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
div.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
return b.create<arith::DivFOp>(loc, payloadArgs[0], payloadArgs[1]);
|
||
}
|
||
if (auto lerp = dyn_cast<AtenLerpTensorOp>(op)) {
|
||
if (!lerp.getType()
|
||
.cast<ValueTensorType>()
|
||
.getDtype()
|
||
.isa<mlir::FloatType>()) {
|
||
lerp.emitError("unimplemented: non-floating point dtype");
|
||
return nullptr;
|
||
}
|
||
AtenLerpTensorOp::Adaptor adaptor(payloadArgs);
|
||
auto start = adaptor.self();
|
||
auto end = adaptor.end();
|
||
auto weight = adaptor.weight();
|
||
auto delta = b.create<arith::SubFOp>(loc, end, start);
|
||
auto weightedDelta = b.create<arith::MulFOp>(loc, delta, weight);
|
||
return b.create<arith::AddFOp>(loc, start, weightedDelta);
|
||
}
|
||
op->emitError("unimplemented lowering in "
|
||
"createLinalgPayloadCalculationForElementwiseOp");
|
||
return nullptr;
|
||
}
|
||
|
||
static Value createLinalgNeutralElementForReduceOp(OpBuilder &b, Location loc,
|
||
Operation *op,
|
||
Type elementType) {
|
||
if (isa<AtenSumOp, AtenSumDimIntListOp>(op) &&
|
||
elementType.isa<mlir::FloatType>())
|
||
return b.create<arith::ConstantOp>(loc, b.getFloatAttr(elementType, 0.0));
|
||
|
||
op->emitError("unimplemented lowering in "
|
||
"createLinalgNeutralElementForReduceOp");
|
||
return nullptr;
|
||
}
|
||
|
||
static Value createLinalgPayloadCalculationForReduceOp(
|
||
OpBuilder &b, Location loc, ValueRange payloadArgs, Operation *op,
|
||
ArrayRef<Value> operands, Type elementType) {
|
||
if (isa<AtenSumOp, AtenSumDimIntListOp>(op) &&
|
||
elementType.isa<mlir::FloatType>())
|
||
return b.create<arith::AddFOp>(loc, payloadArgs);
|
||
op->emitError("unimplemented lowering in "
|
||
"createLinalgPayloadCalculationForReduceOp");
|
||
return nullptr;
|
||
}
|
||
|
||
namespace {
|
||
// Aten argmax lowering represents the ArgMax op as an linalg.indexed_generic
|
||
// op, producing two output buffers.
|
||
//
|
||
// The first output buffer contains the index of the found maximum value. It is
|
||
// initialized to 0 and is resulting integer type.
|
||
//
|
||
// The second output buffer contains the maximum value found. It is initialized
|
||
// to the minimum representable value of the input element type. After being
|
||
// populated by indexed_generic, this buffer is disgarded as only the index is
|
||
// requested.
|
||
//
|
||
// The indexed_generic op updates both the maximum value and index if the
|
||
// current value exceeds the running max.
|
||
class ConvertAtenArgmaxOp : public OpConversionPattern<AtenArgmaxOp> {
|
||
public:
|
||
using OpConversionPattern<AtenArgmaxOp>::OpConversionPattern;
|
||
|
||
LogicalResult
|
||
matchAndRewrite(AtenArgmaxOp argmaxOp, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
|
||
Location loc = argmaxOp.getLoc();
|
||
AtenArgmaxOp::Adaptor adaptor(operands);
|
||
Value input = adaptor.self();
|
||
RankedTensorType resultType =
|
||
getTypeConverter()
|
||
->convertType(argmaxOp.getResult().getType())
|
||
.cast<RankedTensorType>();
|
||
RankedTensorType inputType = input.getType().cast<RankedTensorType>();
|
||
Type outElementType = resultType.getElementType();
|
||
if (!outElementType.isa<IntegerType>())
|
||
return rewriter.notifyMatchFailure(
|
||
argmaxOp,
|
||
"aten.arg_max to linalg.* requires integer-like result type");
|
||
|
||
bool keepDim = false;
|
||
if (!matchPattern(argmaxOp.keepdim(), m_TorchConstantBool(&keepDim)))
|
||
return failure();
|
||
|
||
int64_t dim;
|
||
if (!matchPattern(argmaxOp.dim(), m_TorchConstantInt(&dim))) {
|
||
if (!argmaxOp.dim().getType().isa<Torch::NoneType>())
|
||
return rewriter.notifyMatchFailure(
|
||
argmaxOp,
|
||
"aten.arg_max to linalg.* requires int or NoneType value for Dim");
|
||
// For pytorch, if the value of Dim is None, argmax
|
||
// returns the index of the max value of the flattened input tensor,
|
||
// so here we flatten the input tensor.
|
||
SmallVector<ReassociationIndices> reassociation(1);
|
||
for (auto i : llvm::seq<int64_t>(0, inputType.getRank()))
|
||
reassociation[0].push_back(i);
|
||
input = rewriter.create<linalg::TensorCollapseShapeOp>(
|
||
argmaxOp->getLoc(), input, reassociation);
|
||
// Becomes 0 for flattened tensor.
|
||
dim = 0;
|
||
// Recast to fix shape.
|
||
inputType = input.getType().cast<RankedTensorType>();
|
||
}
|
||
Type inElementType = inputType.getElementType();
|
||
if (!inElementType.isa<mlir::FloatType>()) {
|
||
return rewriter.notifyMatchFailure(
|
||
argmaxOp,
|
||
"aten.arg_max to linalg.* requires Float input element type");
|
||
}
|
||
|
||
// Constant op to account for the reduction along dim.
|
||
auto c1 = rewriter.create<arith::ConstantIndexOp>(loc, /*value=*/1);
|
||
SmallVector<Value> resultShape;
|
||
for (int64_t i = 0; i < inputType.getRank(); i++) {
|
||
if (dim != i) {
|
||
auto currentDimSize = rewriter.create<tensor::DimOp>(loc, input, i);
|
||
resultShape.push_back(currentDimSize);
|
||
} else if (keepDim)
|
||
resultShape.push_back(c1);
|
||
}
|
||
// First fill the output buffer for the index.
|
||
Value filledTensorIdx =
|
||
createZeroInitTensor(rewriter, loc, resultShape, outElementType);
|
||
|
||
// Second fill the output buffer for the running max.
|
||
Value initTensorMax =
|
||
rewriter.create<linalg::InitTensorOp>(loc, resultShape, inElementType)
|
||
.result();
|
||
|
||
FloatAttr fillValueMaxAttr = rewriter.getFloatAttr(
|
||
inElementType,
|
||
APFloat::getLargest(
|
||
inElementType.cast<mlir::FloatType>().getFloatSemantics(), true));
|
||
|
||
Value fillValueMax =
|
||
rewriter.create<arith::ConstantOp>(loc, fillValueMaxAttr);
|
||
Value filledTensorMax =
|
||
rewriter.create<linalg::FillOp>(loc, fillValueMax, initTensorMax)
|
||
.result();
|
||
|
||
// Create the affine expressions that will be used to
|
||
// iterate over the input and output tensors.
|
||
// Here we also set the type of iterator: parallel or reduction.
|
||
SmallVector<AffineExpr> exprs;
|
||
SmallVector<StringRef> iteratorTypes;
|
||
SmallVector<AffineExpr> resultExprs;
|
||
for (auto size : llvm::enumerate(inputType.getShape())) {
|
||
exprs.push_back(rewriter.getAffineDimExpr(size.index()));
|
||
|
||
if (unsigned(dim) == size.index()) {
|
||
iteratorTypes.push_back(getReductionIteratorTypeName());
|
||
// If `keepDim`, create affine map to the first element
|
||
// in the current dimension.
|
||
if (keepDim)
|
||
resultExprs.push_back(rewriter.getAffineConstantExpr(0));
|
||
} else {
|
||
iteratorTypes.push_back(getParallelIteratorTypeName());
|
||
resultExprs.push_back(rewriter.getAffineDimExpr(size.index()));
|
||
}
|
||
}
|
||
auto maps = AffineMap::inferFromExprList({exprs, resultExprs, resultExprs});
|
||
auto linalgOp = rewriter.create<linalg::GenericOp>(
|
||
loc,
|
||
ArrayRef<Type>({filledTensorIdx.getType(), filledTensorMax.getType()}),
|
||
input, ValueRange({filledTensorIdx, filledTensorMax}), maps,
|
||
iteratorTypes,
|
||
[&](OpBuilder &nestedBuilder, Location nestedLoc,
|
||
ValueRange blockArgs) {
|
||
Value newValue = blockArgs[0];
|
||
Value oldIndex = blockArgs[1];
|
||
Value oldValue = blockArgs[2];
|
||
|
||
Value newIndex = rewriter.create<arith::IndexCastOp>(
|
||
nestedLoc, oldIndex.getType(),
|
||
rewriter.create<linalg::IndexOp>(loc, dim));
|
||
|
||
Value predicate;
|
||
if (inElementType.isa<mlir::FloatType>())
|
||
predicate = rewriter.create<arith::CmpFOp>(
|
||
nestedLoc, arith::CmpFPredicate::OGT, newValue, oldValue);
|
||
auto resultMax = rewriter.create<mlir::SelectOp>(nestedLoc, predicate,
|
||
newValue, oldValue);
|
||
auto resultIndex = rewriter.create<mlir::SelectOp>(
|
||
nestedLoc, predicate, newIndex, oldIndex);
|
||
nestedBuilder.create<linalg::YieldOp>(
|
||
nestedLoc, ValueRange({resultIndex, resultMax}));
|
||
});
|
||
|
||
// This cast is required to fix the shape in the case of keepDim=True
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(argmaxOp, resultType,
|
||
linalgOp.getResult(0));
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
namespace {
|
||
|
||
// Converts an elementwise op.
|
||
// This specifically includes:
|
||
// - converting elementwise ops of any tensor arity
|
||
// - converting elementwise ops with any number of scalar captures (such as a
|
||
// scalar alpha to torch.aten.Add)
|
||
// - broadcasting of static size-1 dimensions
|
||
//
|
||
// Currently, we adopt the behavior that "size 1" broadcasting is a runtime
|
||
// error if it happens dynamically.
|
||
//
|
||
// Looking forward a bit, eventually, it probably makes sense to have
|
||
// a "linalg.generic-like" op for modeling a fused subgraph of numpy-broadcasted
|
||
// operands. Modeling elementwise ops that way is potentially useful to allow a
|
||
// more centralized reasoning about multiversioning. However a cost model will
|
||
// be needed for "pre-fusing" elementwise ops that way, as it can potentially be
|
||
// a pessimization. A mild extension of this pattern should work for such a
|
||
// general op.
|
||
struct ConvertElementwiseOp : ConversionPattern {
|
||
ConvertElementwiseOp(TypeConverter &typeConverter, MLIRContext *context)
|
||
: ConversionPattern(typeConverter, MatchAnyOpTypeTag(), /*benefit=*/1,
|
||
context) {}
|
||
|
||
LogicalResult
|
||
matchAndRewrite(Operation *op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (!isa<AtenTanhOp, AtenReluOp, AtenAddTensorOp, AtenMulTensorOp,
|
||
AtenDivTensorOp, AtenSubTensorOp, AtenLerpTensorOp, AtenSigmoidOp,
|
||
AtenExpOp>(op))
|
||
return rewriter.notifyMatchFailure(op, "not a supported elementwise op");
|
||
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
|
||
Location loc = op->getLoc();
|
||
auto tensorOperands = llvm::to_vector<6>(llvm::make_filter_range(
|
||
operands, [](Value v) { return v.getType().isa<RankedTensorType>(); }));
|
||
auto resultType = getTypeConverter()
|
||
->convertType(op->getResult(0).getType())
|
||
.cast<RankedTensorType>();
|
||
auto resultRank = resultType.getRank();
|
||
|
||
auto c1 = rewriter.create<arith::ConstantIndexOp>(loc, /*value=*/1);
|
||
// The overall error handling strategy here is best viewed by thinking about
|
||
// what happens for a single result dimension. This loop not structured that
|
||
// way because it is hard to create the affine maps for each operand unless
|
||
// we structure the loop to iterate over tensor operands as the outer loop
|
||
// instead of inner loop. This pseudocode gives better intuition:
|
||
// ```
|
||
// for each result dimension:
|
||
// for each tensor operand:
|
||
// if it doesn't even have high enough rank relative to the result:
|
||
// continue
|
||
// if it is a static size-1 along this result dimension:
|
||
// continue
|
||
// if this is the first tensor operand that didn't continue above:
|
||
// take its dimension size as the size of the non-broadcasted
|
||
// traversal along this dimension (this may include a dynamic size-1,
|
||
// **non-broadcasted** traversal!)
|
||
// emit error check "if the size does not match the non-broadcasted
|
||
// traversal size along this dimension, error"
|
||
// ```
|
||
// Initialize the resultShape to all 1's, as a fallback in case
|
||
// all sizes along that result dimension are statically 1.
|
||
SmallVector<Value> resultShape(resultRank, c1);
|
||
SmallVector<AffineMap> indexingMaps;
|
||
for (Value tensorOperand : tensorOperands) {
|
||
SmallVector<AffineExpr> exprs;
|
||
auto type = tensorOperand.getType().cast<RankedTensorType>();
|
||
for (auto size : llvm::enumerate(type.getShape())) {
|
||
// If the size is statically known to be 1, we don't want any
|
||
// error guards to be spuriously emitted, since we are specifically
|
||
// allowing size-1 broadcasts in this case, as they correspond to a
|
||
// constant-0 indexing map.
|
||
if (size.value() == 1) {
|
||
exprs.push_back(rewriter.getAffineConstantExpr(0));
|
||
continue;
|
||
}
|
||
|
||
// The rank of this operand might be smaller than the overall rank of
|
||
// the broadcast. Add an offset to correlate it to the correct
|
||
// dimension of the result.
|
||
auto resultDim = size.index() + (resultRank - type.getRank());
|
||
|
||
// The generated linalg op will now be iterating along the full size
|
||
// of this dimension. Record that fact.
|
||
exprs.push_back(rewriter.getAffineDimExpr(resultDim));
|
||
|
||
// Now, we need to ensure that such iteration is not going to trigger
|
||
// undefined behavior, by doing appropriate checks against the current
|
||
// dimension size.
|
||
auto currentDimSize =
|
||
rewriter.create<tensor::DimOp>(loc, tensorOperand, size.index());
|
||
|
||
// If the result size of this dimension has so far only hit the
|
||
// statically-known-to-be-1 case above (i.e., we have not yet assigned a
|
||
// new Value to `resultShape[resultDim]`), then we have no other dynamic
|
||
// values to check against, and merely need to record the current
|
||
// dimension size.
|
||
if (resultShape[resultDim] == c1) {
|
||
resultShape[resultDim] = currentDimSize;
|
||
continue;
|
||
}
|
||
|
||
// We prohibit the size-1 dynamic broadcasting scenario, so just check
|
||
// for exact equality with the running result size.
|
||
// This is the check which protects against the undefined behavior of
|
||
// the generated linalg op in the case of iterating two operands with
|
||
// dimensions sizes that are expected to match.
|
||
auto equalToRunning = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, resultShape[resultDim],
|
||
currentDimSize);
|
||
rewriter.create<AssertOp>(loc, equalToRunning,
|
||
"mismatched size for broadcast");
|
||
}
|
||
indexingMaps.push_back(AffineMap::get(
|
||
/*dimCount=*/resultRank, /*symbolCount=*/0, exprs, getContext()));
|
||
}
|
||
|
||
SmallVector<StringRef> iteratorTypes(resultRank, "parallel");
|
||
// Add the indexing map for the outs init tensor.
|
||
indexingMaps.push_back(rewriter.getMultiDimIdentityMap(resultRank));
|
||
|
||
Value initTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, resultShape, resultType.getElementType());
|
||
bool hadErrorCreatingPayload = false;
|
||
auto generic = rewriter.create<linalg::GenericOp>(
|
||
loc, /*resultTensorTypes=*/initTensor.getType(),
|
||
/*inputs=*/tensorOperands,
|
||
/*outputs=*/initTensor,
|
||
/*indexingMaps=*/indexingMaps,
|
||
/*iteratorTypes=*/iteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange payloadArgs) {
|
||
Value result = createLinalgPayloadCalculationForElementwiseOp(
|
||
b, loc, payloadArgs, op, operands);
|
||
if (!result) {
|
||
hadErrorCreatingPayload = true;
|
||
return;
|
||
}
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
});
|
||
if (hadErrorCreatingPayload)
|
||
return failure();
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, resultType,
|
||
generic.getResult(0));
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
struct ConvertReductionOp : ConversionPattern {
|
||
ConvertReductionOp(TypeConverter &typeConverter, MLIRContext *context)
|
||
: ConversionPattern(typeConverter, MatchAnyOpTypeTag(), /*benefit=*/1,
|
||
context) {}
|
||
|
||
// This function is in charge of all the rewriting that will take
|
||
// place in `matchAndRewrite`. In particular, it converts
|
||
// the reduce operation into an `linalg.generic` operation
|
||
// to reduce the input tensor along the dimensions specified in
|
||
// `dimeSet`.
|
||
LogicalResult
|
||
createReductionLinalgGeneric(Operation *op, ArrayRef<Value> operands,
|
||
const DenseSet<int64_t> &dimSet, bool keepDim,
|
||
ConversionPatternRewriter &rewriter) const {
|
||
Location loc = op->getLoc();
|
||
auto tensorOperand = operands[0];
|
||
auto inputType = tensorOperand.getType().cast<RankedTensorType>();
|
||
auto resultType = getTypeConverter()
|
||
->convertType(op->getResult(0).getType())
|
||
.cast<RankedTensorType>();
|
||
|
||
// Get the result shape by obtaining the size of each
|
||
// dimension in the input tensor that is not getting reduced.
|
||
// If `keepDim` is true, the rank of the output tensor
|
||
// is kept the same as the rank of the input tensor, and the
|
||
// reduced dimensions are set to have size 1.
|
||
auto c1 = rewriter.create<arith::ConstantIndexOp>(loc, /*value=*/1);
|
||
SmallVector<Value> resultShape;
|
||
for (int64_t i = 0; i < inputType.getRank(); i++) {
|
||
auto currentDimSize =
|
||
rewriter.create<tensor::DimOp>(loc, tensorOperand, i);
|
||
if (!dimSet.contains(i))
|
||
resultShape.push_back(currentDimSize);
|
||
else if (keepDim)
|
||
resultShape.push_back(c1);
|
||
}
|
||
|
||
// Create the affine expressions that will be used to
|
||
// iterate over the input and output tensors.
|
||
// Here we also set the type of iterator: parallel or reduction.
|
||
SmallVector<AffineExpr> exprs;
|
||
SmallVector<StringRef> iteratorTypes;
|
||
SmallVector<AffineExpr> resultExprs;
|
||
for (auto size : llvm::enumerate(inputType.getShape())) {
|
||
exprs.push_back(rewriter.getAffineDimExpr(size.index()));
|
||
|
||
if (dimSet.contains(size.index())) {
|
||
iteratorTypes.push_back(getReductionIteratorTypeName());
|
||
// If `keepDim`, create affine map to the first element
|
||
// in the current dimension.
|
||
if (keepDim)
|
||
resultExprs.push_back(rewriter.getAffineConstantExpr(0));
|
||
} else {
|
||
iteratorTypes.push_back(getParallelIteratorTypeName());
|
||
resultExprs.push_back(rewriter.getAffineDimExpr(size.index()));
|
||
}
|
||
}
|
||
|
||
auto indexingMaps = AffineMap::inferFromExprList({exprs, resultExprs});
|
||
Value initTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, resultShape, resultType.getElementType());
|
||
Value initValue = createLinalgNeutralElementForReduceOp(
|
||
rewriter, loc, op, resultType.getElementType());
|
||
Value accumulator =
|
||
rewriter.create<linalg::FillOp>(loc, initValue, initTensor)
|
||
.getResult(0);
|
||
bool hadErrorCreatingPayload = false;
|
||
auto generic = rewriter.create<linalg::GenericOp>(
|
||
loc, /*resultTensorTypes=*/accumulator.getType(),
|
||
/*inputs=*/tensorOperand,
|
||
/*outputs=*/accumulator,
|
||
/*indexingMaps=*/indexingMaps,
|
||
/*iteratorTypes=*/iteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange payloadArgs) {
|
||
Value result = createLinalgPayloadCalculationForReduceOp(
|
||
b, loc, payloadArgs, op, operands, resultType.getElementType());
|
||
if (!result) {
|
||
hadErrorCreatingPayload = true;
|
||
return;
|
||
}
|
||
b.create<linalg::YieldOp>(loc, result);
|
||
});
|
||
|
||
if (hadErrorCreatingPayload)
|
||
return failure();
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, resultType,
|
||
generic.getResult(0));
|
||
return success();
|
||
}
|
||
|
||
LogicalResult
|
||
matchAndRewrite(Operation *op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
|
||
// Every reduce operation must set a value for the `dimSet` and
|
||
// `keepDim` in accordance with their specification.
|
||
DenseSet<int64_t> dimSet;
|
||
bool keepDim = false;
|
||
if (isa<AtenSumOp>(op)) {
|
||
auto tensorOperand = operands[0];
|
||
auto inputType = tensorOperand.getType().cast<RankedTensorType>();
|
||
|
||
// `AtenSumOp` reduces along all the dimensiosn of the input tensor.
|
||
for (int64_t i = 0; i < inputType.getRank(); i++)
|
||
dimSet.insert(i);
|
||
} else if (auto sumDimIntListOp = dyn_cast<AtenSumDimIntListOp>(op)) {
|
||
auto tensorOperand = operands[0];
|
||
auto inputType = tensorOperand.getType().cast<RankedTensorType>();
|
||
|
||
if (!matchPattern(sumDimIntListOp.keepdim(),
|
||
m_TorchConstantBool(&keepDim)))
|
||
return failure();
|
||
|
||
SmallVector<int64_t> dimList;
|
||
if (!matchPattern(sumDimIntListOp.dim(), m_TorchConstantIntList(dimList)))
|
||
return failure();
|
||
for (auto dim : dimList) {
|
||
// Torch allows for negative values in dimSet to go in reverse
|
||
// order in the dimensions of the input tensor.
|
||
dim = dim >= 0 ? dim : dim + inputType.getRank();
|
||
// Drop invalid dimensions
|
||
if (dim < inputType.getRank())
|
||
dimSet.insert(dim);
|
||
}
|
||
} else {
|
||
return rewriter.notifyMatchFailure(op, "not a supported reduce op");
|
||
}
|
||
|
||
return createReductionLinalgGeneric(op, operands, dimSet, keepDim,
|
||
rewriter);
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenMaxPool2dOp : public OpConversionPattern<AtenMaxPool2dOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenMaxPool2dOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
Location loc = op->getLoc();
|
||
AtenMaxPool2dOp::Adaptor adaptor(operands);
|
||
Value self = adaptor.self();
|
||
Value ceilMode = adaptor.ceil_mode();
|
||
|
||
Type elementType = self.getType().cast<RankedTensorType>().getElementType();
|
||
if (!elementType.isa<mlir::FloatType>())
|
||
return op.emitError("unimplemented: non-floating point type");
|
||
|
||
// Pattern match against the op's original operands, because otherwise we
|
||
// will get the lowered version of the operands which is harder to pattern
|
||
// match.
|
||
SmallVector<int64_t, 2> strideInts;
|
||
if (!matchPattern(op.stride(), m_TorchConstantIntList(strideInts)))
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only support constant int strides");
|
||
SmallVector<int64_t, 2> dilationInts;
|
||
if (!matchPattern(op.dilation(), m_TorchConstantIntList(dilationInts)))
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only support constant int dilations");
|
||
SmallVector<int64_t, 2> paddingInts;
|
||
if (!matchPattern(op.padding(), m_TorchConstantIntList(paddingInts)))
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only support constant int paddings");
|
||
SmallVector<int64_t, 2> kernelSizeInts;
|
||
if (!matchPattern(op.kernel_size(), m_TorchConstantIntList(kernelSizeInts)))
|
||
return rewriter.notifyMatchFailure(op, "only support kernel size ints");
|
||
|
||
Value falseValue = rewriter.create<arith::ConstantOp>(
|
||
loc, IntegerAttr::get(rewriter.getIntegerType(1), 0));
|
||
Value ceilModeFalse = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, ceilMode, falseValue);
|
||
rewriter.create<AssertOp>(
|
||
loc, ceilModeFalse,
|
||
rewriter.getStringAttr("only ceil_mode false is supported"));
|
||
|
||
SmallVector<int64_t, 4> paddingIncludingNC = {0, 0};
|
||
paddingIncludingNC.insert(paddingIncludingNC.end(), paddingInts.begin(),
|
||
paddingInts.end());
|
||
Value paddedInput = getPaddedTensor(op, rewriter, self, paddingIncludingNC);
|
||
|
||
Value N = getDimOp(rewriter, loc, self, 0);
|
||
Value C = getDimOp(rewriter, loc, self, 1);
|
||
Value H = getDimOp(rewriter, loc, self, 2);
|
||
Value W = getDimOp(rewriter, loc, self, 3);
|
||
|
||
SmallVector<Value> paddingIntValues =
|
||
getAsConstantIntValues(rewriter, loc, paddingInts);
|
||
SmallVector<Value> dilationIntValues =
|
||
getAsConstantIntValues(rewriter, loc, dilationInts);
|
||
SmallVector<Value> kernelSizeIntValues =
|
||
getAsConstantIntValues(rewriter, loc, kernelSizeInts);
|
||
SmallVector<Value> strideIntValues =
|
||
getAsConstantIntValues(rewriter, loc, strideInts);
|
||
|
||
Value Hout = getOutputDimForConvOps(
|
||
rewriter, loc, H, paddingIntValues[0], dilationIntValues[0],
|
||
kernelSizeIntValues[0], strideIntValues[0]);
|
||
Value Wout = getOutputDimForConvOps(
|
||
rewriter, loc, W, paddingIntValues[1], dilationIntValues[1],
|
||
kernelSizeIntValues[1], strideIntValues[1]);
|
||
|
||
// Initialize output tensor with smallest floating point value
|
||
Value outTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, ValueRange{N, C, Hout, Wout}, elementType);
|
||
auto initialAttr = rewriter.getFloatAttr(
|
||
elementType,
|
||
APFloat::getSmallest(
|
||
elementType.cast<mlir::FloatType>().getFloatSemantics(),
|
||
/*Negative*/ true));
|
||
Value initValue = rewriter.create<arith::ConstantOp>(loc, initialAttr);
|
||
Value outTensorInitialized =
|
||
rewriter.create<linalg::FillOp>(loc, initValue, outTensor).getResult(0);
|
||
|
||
auto stridesAttr = rewriter.getI64VectorAttr(strideInts);
|
||
auto dilationAttr = rewriter.getI64VectorAttr(dilationInts);
|
||
Value windowTensor = rewriter.create<linalg::InitTensorOp>(
|
||
loc, getAsConstantIndexValues(rewriter, loc, kernelSizeInts),
|
||
elementType);
|
||
|
||
Value maxPool2d = rewriter
|
||
.create<linalg::PoolingNchwMaxOp>(
|
||
loc, outTensorInitialized.getType(),
|
||
ValueRange{paddedInput, windowTensor},
|
||
outTensorInitialized, stridesAttr, dilationAttr)
|
||
.getResult(0);
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, maxPool2d);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenFlattenUsingIntsOp
|
||
: public OpConversionPattern<AtenFlattenUsingIntsOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenFlattenUsingIntsOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
int64_t startDim;
|
||
if (!matchPattern(op.start_dim(), m_TorchConstantInt(&startDim)))
|
||
return rewriter.notifyMatchFailure(op, "start_dim must be constant");
|
||
int64_t endDim;
|
||
if (!matchPattern(op.end_dim(), m_TorchConstantInt(&endDim)))
|
||
return rewriter.notifyMatchFailure(op, "start_dim must be constant");
|
||
auto type = operands[0].getType().cast<RankedTensorType>();
|
||
auto inputRank = type.getRank();
|
||
auto resultType =
|
||
getTypeConverter()->convertType(op.getType()).cast<RankedTensorType>();
|
||
if (startDim < 0)
|
||
startDim += inputRank;
|
||
if (endDim < 0)
|
||
endDim += inputRank;
|
||
|
||
if (inputRank == 0) {
|
||
SmallVector<ReassociationIndices> reassociation;
|
||
if (!(startDim >= -1 && startDim <= 0 && endDim >= -1 && endDim <= 0))
|
||
return rewriter.notifyMatchFailure(
|
||
op, "start_dim and end_dim must be in [-1, 0] when inputRank is 0");
|
||
rewriter.replaceOpWithNewOp<linalg::TensorExpandShapeOp>(
|
||
op, resultType, operands[0], reassociation);
|
||
return success();
|
||
}
|
||
|
||
if (startDim < 0 || startDim >= inputRank || endDim < 0 ||
|
||
endDim >= inputRank || startDim > endDim)
|
||
return rewriter.notifyMatchFailure(
|
||
op, "statically invalid flattening dim range");
|
||
|
||
SmallVector<ReassociationIndices> reassociation(resultType.getRank());
|
||
int j = 0;
|
||
for (auto i : llvm::seq<int64_t>(0, inputRank)) {
|
||
reassociation[j].push_back(i);
|
||
if (i < startDim || i >= endDim)
|
||
j++;
|
||
}
|
||
Value collapsedTensor = rewriter.create<linalg::TensorCollapseShapeOp>(
|
||
op->getLoc(), operands[0], reassociation);
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, resultType,
|
||
collapsedTensor);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenUnsqueezeOp : public OpConversionPattern<AtenUnsqueezeOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenUnsqueezeOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
int64_t dim;
|
||
if (!matchPattern(op.dim(), m_TorchConstantInt(&dim)))
|
||
return rewriter.notifyMatchFailure(op, "dim must be constant");
|
||
auto inputRank = operands[0].getType().cast<RankedTensorType>().getRank();
|
||
if (dim < 0)
|
||
dim += inputRank + 1;
|
||
if (!(0 <= dim && dim <= inputRank))
|
||
return rewriter.notifyMatchFailure(op, "statically invalid");
|
||
|
||
SmallVector<ReassociationIndices> reassociationMap(inputRank);
|
||
// From the perspective of the reassociation map, the situation of
|
||
// unsqueezing before or after the last dimension is symmetrical.
|
||
// Normalize it to the "before" case.
|
||
// The 0 case is special here, since there is no last dimension to insert
|
||
// before -- we simply rely on the loop below iterating 0 times.
|
||
if (dim == inputRank && inputRank != 0)
|
||
dim = inputRank - 1;
|
||
bool alreadyCrossedExpandedDim = false;
|
||
for (int i = 0; i != inputRank; i++) {
|
||
if (alreadyCrossedExpandedDim) {
|
||
reassociationMap[i].push_back(i + 1);
|
||
} else {
|
||
reassociationMap[i].push_back(i);
|
||
if (i == dim) {
|
||
reassociationMap[i].push_back(i + 1);
|
||
alreadyCrossedExpandedDim = true;
|
||
}
|
||
}
|
||
}
|
||
auto resultType = getTypeConverter()
|
||
->convertType(op->getResult(0).getType())
|
||
.cast<RankedTensorType>();
|
||
rewriter.replaceOpWithNewOp<linalg::TensorExpandShapeOp>(
|
||
op, resultType, operands[0], reassociationMap);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenTransposeIntOp
|
||
: public OpConversionPattern<AtenTransposeIntOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenTransposeIntOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
AtenTransposeIntOp::Adaptor adaptor(operands);
|
||
|
||
int64_t dim0;
|
||
if (!matchPattern(op.dim0(), m_TorchConstantInt(&dim0)))
|
||
return rewriter.notifyMatchFailure(op, "dim0 must be constant");
|
||
int64_t dim1;
|
||
if (!matchPattern(op.dim1(), m_TorchConstantInt(&dim1)))
|
||
return rewriter.notifyMatchFailure(op, "dim1 must be constant");
|
||
|
||
auto inVector = adaptor.self();
|
||
auto inType = inVector.getType().cast<RankedTensorType>();
|
||
auto inputRank = inType.getRank();
|
||
auto outType = getTypeConverter()
|
||
->convertType(op->getResult(0).getType())
|
||
.cast<RankedTensorType>();
|
||
auto elementType = inType.getElementType();
|
||
|
||
if (dim0 < 0)
|
||
dim0 += inputRank + 1;
|
||
if (dim0 < 0 || dim0 >= inputRank)
|
||
return rewriter.notifyMatchFailure(op, "dim0 out of range");
|
||
if (dim1 < 0)
|
||
dim1 += inputRank + 1;
|
||
if (dim1 < 0 || dim1 >= inputRank)
|
||
return rewriter.notifyMatchFailure(op, "dim1 out of range");
|
||
|
||
auto loc = op.getLoc();
|
||
|
||
SmallVector<Value> outputDims;
|
||
for (auto i = 0; i < inputRank; i++)
|
||
outputDims.push_back(getDimOp(rewriter, loc, adaptor.self(), i));
|
||
std::swap(outputDims[dim0], outputDims[dim1]);
|
||
|
||
Value outVector =
|
||
rewriter.create<linalg::InitTensorOp>(loc, outputDims, elementType);
|
||
SmallVector<AffineExpr> idExprs;
|
||
SmallVector<AffineExpr> swapExprs;
|
||
for (auto i = 0; i < inputRank; i++)
|
||
idExprs.push_back(getAffineDimExpr(i, rewriter.getContext()));
|
||
for (auto i = 0; i < inputRank; i++) {
|
||
if (i == dim0)
|
||
swapExprs.push_back(idExprs[dim1]);
|
||
else if (i == dim1)
|
||
swapExprs.push_back(idExprs[dim0]);
|
||
else
|
||
swapExprs.push_back(idExprs[i]);
|
||
}
|
||
|
||
SmallVector<AffineMap> indexingMaps = {
|
||
AffineMap::get(inputRank, 0, idExprs, op.getContext()),
|
||
AffineMap::get(inputRank, 0, swapExprs, op.getContext())};
|
||
SmallVector<StringRef> iteratorTypes(inputRank, "parallel");
|
||
auto transpose = rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, outVector.getType(), inVector, outVector,
|
||
indexingMaps, iteratorTypes,
|
||
[](OpBuilder &b, Location loc, ValueRange args) {
|
||
b.create<linalg::YieldOp>(loc, args[0]);
|
||
})
|
||
.getResult(0);
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, outType, transpose);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenCatOp : public OpConversionPattern<AtenCatOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenCatOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
Location loc = op.getLoc();
|
||
TypeConverter *typeConverter = getTypeConverter();
|
||
AtenCatOp::Adaptor adaptor(operands);
|
||
|
||
Value dimValue = op.dim();
|
||
int64_t dim;
|
||
if (!matchPattern(dimValue, m_TorchConstantInt(&dim)))
|
||
return op.emitError("unimplemented: dim is not constant");
|
||
|
||
// Collect all the tensors to be concatenated.
|
||
auto tensorList = op.tensors();
|
||
SmallVector<Value> tensorsTorchType;
|
||
if (!getListConstructElements(tensorList, tensorsTorchType))
|
||
return op.emitError(
|
||
"unimplemented: the tensor list is not from list construct");
|
||
auto tensors =
|
||
getTypeConvertedValues(rewriter, loc, typeConverter, tensorsTorchType);
|
||
|
||
RankedTensorType newResultType =
|
||
typeConverter->convertType(op.getType()).cast<RankedTensorType>();
|
||
int rank = newResultType.getRank();
|
||
SmallVector<Value> offsets, sizes, strides;
|
||
sizes.reserve(rank);
|
||
strides.resize(rank, rewriter.create<arith::ConstantIndexOp>(loc, 1));
|
||
offsets.resize(rank, rewriter.create<arith::ConstantIndexOp>(loc, 0));
|
||
|
||
for (int i = 0; i < rank; ++i)
|
||
sizes.push_back(rewriter.create<tensor::DimOp>(loc, tensors[0], i));
|
||
|
||
// Calculate the size of the `dim` result dimension by adding the dim size
|
||
// of each tensor together.
|
||
Value resultDimSize = sizes[dim];
|
||
Value dimIndex = rewriter.create<arith::IndexCastOp>(
|
||
loc, rewriter.getIndexType(), adaptor.dim());
|
||
for (auto tensor : makeArrayRef(tensors).drop_front()) {
|
||
auto size = rewriter.create<tensor::DimOp>(loc, tensor, dimIndex);
|
||
resultDimSize = rewriter.create<arith::AddIOp>(loc, resultDimSize, size);
|
||
}
|
||
sizes[dim] = resultDimSize;
|
||
|
||
Value result = rewriter.create<linalg::InitTensorOp>(
|
||
loc, sizes, newResultType.getElementType());
|
||
for (auto tensor : tensors) {
|
||
sizes[dim] = rewriter.create<tensor::DimOp>(loc, tensor, dimIndex);
|
||
result = rewriter.create<tensor::InsertSliceOp>(loc, tensor, result,
|
||
offsets, sizes, strides);
|
||
offsets[dim] =
|
||
rewriter.create<arith::AddIOp>(loc, offsets[dim], sizes[dim]);
|
||
}
|
||
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, result);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenGatherOp : public OpConversionPattern<AtenGatherOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenGatherOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
Location loc = op->getLoc();
|
||
AtenGatherOp::Adaptor adaptor(operands);
|
||
|
||
Value dimValue = op.dim();
|
||
int64_t dim;
|
||
if (!matchPattern(dimValue, m_TorchConstantInt(&dim)))
|
||
return op.emitError("unimplemented: dim is not constant");
|
||
|
||
Value indices = adaptor.index();
|
||
Value self = adaptor.self();
|
||
RankedTensorType newResultTy =
|
||
getTypeConverter()->convertType(op.getType()).cast<RankedTensorType>();
|
||
int64_t rank = newResultTy.getRank();
|
||
|
||
SmallVector<Value> sizes = getTensorSizes(rewriter, loc, indices);
|
||
Value result = createZeroInitTensor(rewriter, loc, sizes,
|
||
newResultTy.getElementType());
|
||
|
||
SmallVector<AffineMap, 2> affineMaps(2,
|
||
rewriter.getMultiDimIdentityMap(rank));
|
||
SmallVector<StringRef> iteratorTypes(rank, getParallelIteratorTypeName());
|
||
auto genericOp = rewriter.create<linalg::GenericOp>(
|
||
loc, newResultTy, indices, result, affineMaps, iteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
auto index = args[0];
|
||
createLinalgPayloadCalculationForGatherOps(b, loc, self, rank, index,
|
||
dim, rank);
|
||
});
|
||
rewriter.replaceOp(op, genericOp.getResult(0));
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenEmbeddingOp : public OpConversionPattern<AtenEmbeddingOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenEmbeddingOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
Location loc = op->getLoc();
|
||
AtenEmbeddingOp::Adaptor adaptor(operands);
|
||
Value weight = adaptor.weight();
|
||
Value indices = adaptor.indices();
|
||
RankedTensorType newResultType =
|
||
typeConverter->convertType(op.getType()).cast<RankedTensorType>();
|
||
|
||
auto weightTy = weight.getType().cast<RankedTensorType>();
|
||
if (weightTy.getRank() != 2)
|
||
return rewriter.notifyMatchFailure(op, "weight must be rank 2");
|
||
Value embeddingDim = getDimOp(rewriter, loc, weight, 1);
|
||
Type elemTy = weightTy.getElementType();
|
||
|
||
SmallVector<Value> sizes = getTensorSizes(rewriter, loc, indices);
|
||
sizes.push_back(embeddingDim);
|
||
int64_t resultRank = sizes.size();
|
||
|
||
auto indicesTy = weight.getType().cast<RankedTensorType>();
|
||
int64_t indicesRank = indicesTy.getRank();
|
||
SmallVector<AffineExpr> indicesExprs;
|
||
for (int i = 0; i < indicesRank; i++)
|
||
indicesExprs.push_back(rewriter.getAffineDimExpr(i));
|
||
auto indicesAffineMap = AffineMap::get(
|
||
/*dimCount=*/resultRank,
|
||
/*symbolCount=*/0, indicesExprs, op->getContext());
|
||
SmallVector<AffineMap, 2> indexingMaps = {
|
||
indicesAffineMap,
|
||
rewriter.getMultiDimIdentityMap(resultRank),
|
||
};
|
||
SmallVector<StringRef> iteratorTypes(sizes.size(),
|
||
getParallelIteratorTypeName());
|
||
Value initTensor =
|
||
rewriter.create<linalg::InitTensorOp>(loc, sizes, elemTy);
|
||
Value embeddingResult =
|
||
rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, initTensor.getType(), indices, initTensor,
|
||
/*indexingMaps=*/indexingMaps, /*iteratorTypes=*/iteratorTypes,
|
||
[&](OpBuilder &b, Location loc, ValueRange args) {
|
||
Value index = args[0];
|
||
createLinalgPayloadCalculationForGatherOps(
|
||
b, loc, weight, weightTy.getRank(), index, /*dim=*/0,
|
||
resultRank);
|
||
})
|
||
.getResult(0);
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType,
|
||
embeddingResult);
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenSizeIntOp : public OpConversionPattern<AtenSizeIntOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenSizeIntOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
Location loc = op->getLoc();
|
||
AtenSizeIntOp::Adaptor adaptor(operands);
|
||
Value self = adaptor.self();
|
||
Value dim = adaptor.dim();
|
||
auto type = self.getType().cast<RankedTensorType>();
|
||
Value inputRank = rewriter.create<arith::ConstantOp>(
|
||
loc, rewriter.getI64IntegerAttr(type.getRank()));
|
||
Value dimPositive = toPositiveDimDynamic(rewriter, loc, dim, inputRank);
|
||
assertIsValidDim(rewriter, loc, dimPositive, inputRank);
|
||
Value size = rewriter.create<tensor::DimOp>(
|
||
loc, adaptor.self(), castIntToIndex(rewriter, loc, dimPositive));
|
||
rewriter.replaceOp(op, castIndexToInt(rewriter, loc, size));
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenBroadcastToOp : public OpConversionPattern<AtenBroadcastToOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenBroadcastToOp op, llvm::ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
AtenBroadcastToOp::Adaptor adaptor(operands);
|
||
Value self = adaptor.self();
|
||
auto selfType = self.getType().cast<RankedTensorType>();
|
||
ArrayRef<int64_t> selfShape = selfType.getShape();
|
||
Type elementType = selfType.getElementType();
|
||
Location loc = op.getLoc();
|
||
MLIRContext *context = op->getContext();
|
||
|
||
SmallVector<Value> inShape, outShape;
|
||
if (!getListConstructElements(adaptor.size(), inShape)) {
|
||
return rewriter.notifyMatchFailure(
|
||
op, "unimplemented: the size list is not from list construct");
|
||
}
|
||
SmallVector<Value> inShapeConverted =
|
||
getTypeConvertedValues(rewriter, loc, getTypeConverter(), inShape);
|
||
if (inShape.size() < selfShape.size())
|
||
return rewriter.notifyMatchFailure(
|
||
op, "invalid shape: must not be smaller than rank of tensor");
|
||
size_t diff = inShape.size() - selfShape.size();
|
||
|
||
// Create affine map and shapes for tensor initialization.
|
||
SmallVector<AffineExpr> outExpr;
|
||
Value zero =
|
||
rewriter.create<arith::ConstantOp>(loc, rewriter.getI64IntegerAttr(0));
|
||
for (size_t i = 0; i < inShape.size(); i++) {
|
||
Value shapeValue = inShapeConverted[i];
|
||
size_t j = i - diff;
|
||
if (i < diff) {
|
||
Value isValid = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::sge, shapeValue, zero);
|
||
rewriter.create<AssertOp>(
|
||
loc, isValid,
|
||
rewriter.getStringAttr(
|
||
"negative values not allowed in new dimensions"));
|
||
outShape.push_back(castIntToIndex(rewriter, loc, shapeValue));
|
||
continue;
|
||
}
|
||
if (selfShape[j] == 1) {
|
||
// Broadcast singleton dimension
|
||
Value one =
|
||
rewriter.create<arith::ConstantOp>(loc, rewriter.getIndexAttr(1));
|
||
Value isNegative = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::slt, shapeValue, zero);
|
||
Value select = rewriter.create<SelectOp>(
|
||
loc, isNegative, one, castIntToIndex(rewriter, loc, shapeValue));
|
||
outShape.push_back(select);
|
||
outExpr.push_back(mlir::getAffineConstantExpr(0, context));
|
||
continue;
|
||
}
|
||
// Non-broadcast case
|
||
Value dim = getDimOp(rewriter, loc, self, j);
|
||
Value isNegative = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::slt, shapeValue, zero);
|
||
Value isEqual = rewriter.create<arith::CmpIOp>(
|
||
loc, arith::CmpIPredicate::eq, castIndexToInt(rewriter, loc, dim),
|
||
shapeValue);
|
||
Value isValid = rewriter.create<arith::OrIOp>(loc, isNegative, isEqual);
|
||
rewriter.create<AssertOp>(
|
||
loc, isValid,
|
||
rewriter.getStringAttr(
|
||
"only broadcasting singleton dimensions supported"));
|
||
outShape.push_back(dim);
|
||
outExpr.push_back(mlir::getAffineDimExpr(i, context));
|
||
}
|
||
|
||
Value outTensor =
|
||
rewriter.create<linalg::InitTensorOp>(loc, outShape, elementType);
|
||
|
||
SmallVector<AffineMap> indexingMaps = {
|
||
AffineMap::get(inShape.size(), 0, outExpr, context),
|
||
rewriter.getMultiDimIdentityMap(inShape.size())};
|
||
SmallVector<StringRef> iteratorTypes(inShape.size(), "parallel");
|
||
Value result = rewriter
|
||
.create<linalg::GenericOp>(
|
||
loc, outTensor.getType(), self, outTensor,
|
||
indexingMaps, iteratorTypes,
|
||
[](OpBuilder &b, Location loc, ValueRange args) {
|
||
b.create<linalg::YieldOp>(loc, args[0]);
|
||
})
|
||
.getResult(0);
|
||
|
||
Type newResultType = getTypeConverter()->convertType(op.getType());
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, result);
|
||
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
namespace {
|
||
class ConvertAtenOnesOp : public OpConversionPattern<AtenOnesOp> {
|
||
public:
|
||
using OpConversionPattern::OpConversionPattern;
|
||
LogicalResult
|
||
matchAndRewrite(AtenOnesOp op, ArrayRef<Value> operands,
|
||
ConversionPatternRewriter &rewriter) const override {
|
||
if (failed(verifyLinalgCompatibleTypes(op, rewriter)))
|
||
return failure();
|
||
AtenOnesOp::Adaptor adaptor(operands);
|
||
Location loc = op.getLoc();
|
||
|
||
// We ignore device, but add simple asserts for unimplemented kwargs
|
||
if (!adaptor.layout().getType().isa<Torch::NoneType>())
|
||
return rewriter.notifyMatchFailure(op,
|
||
"only default layout is supported");
|
||
bool pinMemory;
|
||
if (!adaptor.pin_memory().getType().isa<Torch::NoneType>() &&
|
||
!matchPattern(adaptor.pin_memory(), m_TorchConstantBool(&pinMemory)))
|
||
return rewriter.notifyMatchFailure(op, "memory pinning not supported");
|
||
|
||
SmallVector<Value> size, sizeIndex;
|
||
if (!getListConstructElements(adaptor.size(), size)) {
|
||
return rewriter.notifyMatchFailure(
|
||
op, "size must be created by ListConstruct");
|
||
}
|
||
size = getTypeConvertedValues(rewriter, loc, getTypeConverter(), size);
|
||
for (size_t i = 0; i < size.size(); i++)
|
||
sizeIndex.push_back(castIntToIndex(rewriter, loc, size[i]));
|
||
|
||
RankedTensorType newResultType =
|
||
getTypeConverter()->convertType(op.getType()).cast<RankedTensorType>();
|
||
Type outElementType = newResultType.getElementType();
|
||
|
||
Value one = rewriter.create<arith::ConstantOp>(
|
||
loc, outElementType,
|
||
(outElementType.isa<mlir::FloatType>()
|
||
? rewriter.getFloatAttr(outElementType, 1).cast<mlir::Attribute>()
|
||
: rewriter.getIntegerAttr(outElementType, 1)
|
||
.cast<mlir::Attribute>()));
|
||
Value outTensor = rewriter
|
||
.create<linalg::InitTensorOp>(
|
||
loc, sizeIndex, newResultType.getElementType())
|
||
.getResult();
|
||
Value fillOp =
|
||
rewriter.create<linalg::FillOp>(loc, one, outTensor).getResult(0);
|
||
|
||
rewriter.replaceOpWithNewOp<tensor::CastOp>(op, newResultType, fillOp);
|
||
|
||
return success();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
// -----------------------------------------------------------------------------
|
||
// The pass
|
||
// -----------------------------------------------------------------------------
|
||
|
||
namespace {
|
||
class ConvertTorchToLinalg
|
||
: public ConvertTorchToLinalgBase<ConvertTorchToLinalg> {
|
||
public:
|
||
void getDependentDialects(DialectRegistry ®istry) const override {
|
||
registry.insert<linalg::LinalgDialect>();
|
||
registry.insert<math::MathDialect>();
|
||
registry.insert<StandardOpsDialect>();
|
||
registry.insert<tensor::TensorDialect>();
|
||
registry.insert<arith::ArithmeticDialect>();
|
||
TorchConversion::getBackendTypeConversionDependentDialects(registry);
|
||
}
|
||
|
||
void runOnOperation() override {
|
||
MLIRContext *context = &getContext();
|
||
ConversionTarget target(*context);
|
||
target.addLegalDialect<linalg::LinalgDialect, StandardOpsDialect,
|
||
math::MathDialect, tensor::TensorDialect,
|
||
arith::ArithmeticDialect>();
|
||
|
||
TypeConverter typeConverter;
|
||
typeConverter.addConversion([](Type type) { return type; });
|
||
TorchConversion::setupBackendTypeConversion(target, typeConverter);
|
||
|
||
RewritePatternSet patterns(context);
|
||
target.addIllegalOp<AtenMmOp>();
|
||
patterns.add<ConvertAtenMmOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenBmmOp>();
|
||
patterns.add<ConvertAtenBmmOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenLinearOp>();
|
||
patterns.add<ConvertAtenLinearOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenBatchNormOp>();
|
||
patterns.add<ConvertAtenBatchNormOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenTanhOp, AtenReluOp, AtenAddTensorOp,
|
||
AtenMulTensorOp, AtenDivTensorOp, AtenSubTensorOp,
|
||
AtenLerpTensorOp, AtenSigmoidOp>();
|
||
patterns.add<ConvertElementwiseOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenUnsqueezeOp>();
|
||
patterns.add<ConvertAtenUnsqueezeOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenConv2dOp>();
|
||
patterns.add<ConvertAtenConv2dOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenAdaptiveAvgPool2dOp>();
|
||
patterns.add<ConvertAtenAdaptiveAvgPool2dOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenFlattenUsingIntsOp>();
|
||
patterns.add<ConvertAtenFlattenUsingIntsOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenMaxPool2dOp>();
|
||
patterns.add<ConvertAtenMaxPool2dOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenSumOp>();
|
||
patterns.add<ConvertReductionOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenTransposeIntOp>();
|
||
patterns.add<ConvertAtenTransposeIntOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenCatOp>();
|
||
patterns.add<ConvertAtenCatOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenGatherOp>();
|
||
patterns.add<ConvertAtenGatherOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenLayerNormOp>();
|
||
patterns.add<ConvertAtenLayerNormOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenBroadcastToOp>();
|
||
patterns.add<ConvertAtenBroadcastToOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenArgmaxOp>();
|
||
patterns.add<ConvertAtenArgmaxOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenSizeIntOp>();
|
||
patterns.add<ConvertAtenSizeIntOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenEmbeddingOp>();
|
||
patterns.add<ConvertAtenEmbeddingOp>(typeConverter, context);
|
||
target.addIllegalOp<AtenOnesOp>();
|
||
patterns.add<ConvertAtenOnesOp>(typeConverter, context);
|
||
|
||
if (failed(applyPartialConversion(getOperation(), target,
|
||
std::move(patterns))))
|
||
return signalPassFailure();
|
||
}
|
||
};
|
||
} // namespace
|
||
|
||
std::unique_ptr<OperationPass<FuncOp>>
|
||
mlir::torch::createConvertTorchToLinalgPass() {
|
||
return std::make_unique<ConvertTorchToLinalg>();
|
||
}
|