mirror of https://github.com/llvm/torch-mlir
368 lines
14 KiB
C++
368 lines
14 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 "./MhloLegalizeUtils.h"
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#include "mlir-hlo/Dialect/mhlo/IR/hlo_ops.h"
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#include "mlir/Dialect/Arith/IR/Arith.h"
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#include "mlir/Dialect/Tensor/IR/Tensor.h"
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#include "torch-mlir/Conversion/TorchToMhlo/TorchToMhlo.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 <numeric>
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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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namespace mlir {
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namespace mhlo {
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// Create a 32-bit float constant operator from a float
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Value getMhloConstTensorSingleF32(PatternRewriter &rewriter, Operation *op,
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float val) {
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auto const_type = RankedTensorType::get({}, rewriter.getF32Type());
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auto const_attr = DenseElementsAttr::get(const_type, val);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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// Create a 64-bit float constant operator from a double
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Value getMhloConstTensorSingleF64(PatternRewriter &rewriter, Operation *op,
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double val) {
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auto const_type = RankedTensorType::get({}, rewriter.getF64Type());
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auto const_attr = DenseElementsAttr::get(const_type, val);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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// Templated function to create a constant op for given type and shape.
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// T: storage C type.
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// Default template creates a constant tensor in T.
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template <typename T>
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llvm::Optional<Value> getConstTensor(PatternRewriter &rewriter, Operation *op,
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ArrayRef<T> vec, ArrayRef<int64_t> shape) {
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uint64_t num_total_elements = 1;
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for (int64_t a : shape) {
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num_total_elements *= a;
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}
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if (vec.size() != num_total_elements) {
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op->emitOpError("getConstTensor(): number of elements mismatch.");
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return llvm::None;
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}
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auto const_type =
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RankedTensorType::get(shape, rewriter.getIntegerType(sizeof(T) * 8));
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auto const_attr = DenseElementsAttr::get(const_type, vec);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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// Template specialization for APInt
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template <>
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llvm::Optional<Value> getConstTensor<APInt>(PatternRewriter &rewriter,
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Operation *op, ArrayRef<APInt> vec,
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ArrayRef<int64_t> shape) {
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uint64_t num_total_elements = 1;
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for (int64_t a : shape) {
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num_total_elements *= a;
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}
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if (vec.size() != num_total_elements) {
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op->emitOpError("getConstTensor(): number of elements mismatch.");
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return llvm::None;
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}
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auto const_type = RankedTensorType::get(
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shape, rewriter.getIntegerType(vec[0].getBitWidth()));
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auto const_attr = DenseElementsAttr::get(const_type, vec);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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// Template specialization for float
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template <>
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llvm::Optional<Value> getConstTensor<float>(PatternRewriter &rewriter,
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Operation *op, ArrayRef<float> vec,
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ArrayRef<int64_t> shape) {
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uint64_t num_total_elements = 1;
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for (int64_t a : shape) {
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num_total_elements *= a;
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}
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if (vec.size() != num_total_elements) {
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op->emitOpError("getConstTensor(): number of elements mismatch.");
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return llvm::None;
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}
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auto const_type = RankedTensorType::get(shape, rewriter.getF32Type());
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auto const_attr = DenseElementsAttr::get(const_type, vec);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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template <>
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llvm::Optional<Value>
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getConstTensor<double>(PatternRewriter &rewriter, Operation *op,
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ArrayRef<double> vec, ArrayRef<int64_t> shape) {
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uint64_t num_total_elements = 1;
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for (int64_t a : shape) {
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num_total_elements *= a;
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}
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if (vec.size() != num_total_elements) {
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op->emitOpError("getConstTensor(): number of elements mismatch.");
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return llvm::None;
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}
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auto const_type = RankedTensorType::get(shape, rewriter.getF64Type());
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auto const_attr = DenseElementsAttr::get(const_type, vec);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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// Template instantiation
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template llvm::Optional<Value> getConstTensor<int32_t>(PatternRewriter &,
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Operation *,
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ArrayRef<int32_t> vec,
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ArrayRef<int64_t> shape);
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template llvm::Optional<Value> getConstTensor<int64_t>(PatternRewriter &,
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Operation *,
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ArrayRef<int64_t> vec,
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ArrayRef<int64_t> shape);
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template <typename T>
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static bool isInValidRange(bool isFloat, const double &doubleValue, bool isInt,
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const int64_t &intValue) {
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if (isFloat) {
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// Do a round-trip check here instead of numeric limits due to
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// compiler warnings around double <-> int conversion.
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return (doubleValue == static_cast<double>(static_cast<T>(doubleValue)));
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} else {
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assert(isInt);
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return (intValue >= std::numeric_limits<T>::min()) &&
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(intValue <= std::numeric_limits<T>::max());
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}
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return true;
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}
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template <typename T>
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Value getSplatConstTensor(ConversionPatternRewriter &rewriter, Operation *op,
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T val, Type dtype, llvm::ArrayRef<int64_t> dshape) {
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auto const_type = RankedTensorType::get(dshape, dtype);
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auto const_attr = SplatElementsAttr::get(const_type, val);
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auto const_op =
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rewriter.create<mhlo::ConstantOp>(op->getLoc(), const_type, const_attr);
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return const_op.getResult();
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}
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Value scalarToMhloTensor(ConversionPatternRewriter &rewriter, Operation *op,
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Value scalarValue, Type dtype) {
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auto tensor = rewriter.create<tensor::FromElementsOp>(
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op->getLoc(), ArrayRef<Value>{scalarValue});
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auto dtype_tensor =
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rewriter.create<mhlo::ConvertOp>(op->getLoc(), tensor, dtype);
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return rewriter.create<mhlo::ReshapeOp>(
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op->getLoc(), RankedTensorType::get(mlir::ArrayRef<int64_t>{}, dtype),
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dtype_tensor);
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}
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Value promoteType(PatternRewriter &rewriter, Value input, TensorType outType) {
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Operation *op = input.getDefiningOp();
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TensorType in_type = input.getType().dyn_cast<TensorType>();
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if (in_type.getElementType() != outType.getElementType()) {
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TensorType promotedType =
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in_type.cloneWith(in_type.getShape(), outType.getElementType());
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return rewriter.create<mhlo::ConvertOp>(op->getLoc(), promotedType, input);
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}
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return input;
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}
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Value promoteAndBroadcast(ConversionPatternRewriter &rewriter, Value input,
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TensorType outType) {
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// Two tensors are “broadcastable” if the following rules hold:
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// - Each tensor has at least one dimension.
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// - When iterating over the dimension sizes, starting at the trailing
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// dimension, the dimension sizes must either be equal, one of them is 1, or
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// one of them does not exist.
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Operation *op = input.getDefiningOp();
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TensorType in_type = input.getType().dyn_cast<TensorType>();
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if (in_type.getElementType() != outType.getElementType()) {
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TensorType promoted_type =
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in_type.cloneWith(in_type.getShape(), outType.getElementType());
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input =
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rewriter.create<mhlo::ConvertOp>(op->getLoc(), promoted_type, input);
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}
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ArrayRef<int64_t> inShape = in_type.getShape();
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ArrayRef<int64_t> outShape = outType.getShape();
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bool do_bcast = (inShape.size() != outShape.size());
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SmallVector<int64_t> bcastDims;
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for (size_t i = 0; i < inShape.size(); ++i) {
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// iterating over the dimension sizes, starting at the trailing dimension
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size_t outPos = outShape.size() - 1 - i;
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size_t inPos = inShape.size() - 1 - i;
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int64_t outDim = outShape[outPos];
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int64_t inDim = inShape[inPos];
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if (inDim == outDim) {
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bcastDims.push_back(outPos);
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} else if (inDim != outDim && inDim == 1) {
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bcastDims.push_back(outPos);
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do_bcast = true;
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} else {
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op->emitError("The size of tensor a (")
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<< inDim << ")"
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<< "must match the size of tensor b (" << outDim << ")"
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<< "at non-singleton dimension " << inPos;
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}
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}
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std::reverse(bcastDims.begin(), bcastDims.end());
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if (!do_bcast) {
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return input;
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}
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DenseIntElementsAttr bcast_attr = DenseIntElementsAttr::get(
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RankedTensorType::get({static_cast<long int>(bcastDims.size())},
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rewriter.getI64Type()),
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bcastDims);
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auto bcast_op = rewriter.create<mhlo::BroadcastInDimOp>(op->getLoc(), outType,
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input, bcast_attr);
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return bcast_op.getResult();
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}
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SmallVector<size_t> toPositiveDims(ArrayRef<int64_t> dims, int64_t rank) {
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SmallVector<size_t> posDims;
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posDims.reserve(rank);
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std::transform(
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dims.begin(), dims.end(), std::back_inserter(posDims),
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[rank](int64_t d) -> size_t { return toPositiveDim(d, rank); });
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return posDims;
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}
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FailureOr<SmallVector<Value, 4>> getDimSizesOfTensor(PatternRewriter &rewriter,
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Operation *op, Value value,
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ArrayRef<int64_t> inpDims,
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size_t dimSizeIndexBits) {
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auto valueTy = value.getType().dyn_cast<RankedTensorType>();
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if (!valueTy) {
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return rewriter.notifyMatchFailure(
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op, "getDimSizesOfTensor(): the input is not a ranked tensor");
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}
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auto rank = valueTy.getRank();
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auto dims = toPositiveDims(inpDims, rank);
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SmallVector<Value, 4> dimSizes;
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dimSizes.reserve(dims.size());
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auto loc = op->getLoc();
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for (auto d : dims) {
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dimSizes.emplace_back(rewriter.create<arith::IndexCastOp>(
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loc, rewriter.getIntegerType(dimSizeIndexBits),
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rewriter.create<tensor::DimOp>(loc, value, d)));
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}
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return dimSizes;
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}
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FailureOr<SmallVector<Value, 4>> getDimSizesOfTensor(PatternRewriter &rewriter,
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Operation *op, Value value,
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size_t dimSizeIndexBits) {
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auto valueTy = value.getType().dyn_cast<RankedTensorType>();
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if (!valueTy) {
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return rewriter.notifyMatchFailure(
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op, "getDimSizesOfTensor(): the input is not a ranked tensor");
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}
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auto rank = valueTy.getRank();
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// Get int vector [0, 1, ..., rank-1]
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std::vector<int64_t> dims(rank);
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std::iota(dims.begin(), dims.end(), 0);
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return getDimSizesOfTensor(rewriter, op, value, dims, dimSizeIndexBits);
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}
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FailureOr<Value> unsqueezeTensor(PatternRewriter &rewriter, Operation *op,
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Value tensor, ArrayRef<int64_t> inputUnsqzDims,
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size_t dimSizeIndexBits) {
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// Returns a new tensor with dims of size 1 inserted at the specified
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// position.
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//
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// The position indices (must be high to low dimension number of the returned
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// tensor) are specified with unsqzDims. Indices must be in-order, and in
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// range of tensor rank. Thus, unsqueeze a rank 1 tensor with {0, 2}, {0, 1,
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// 3}, {0, 1, 2} are all valid dimension sets, but {0, 3}, {2} are not.
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auto dimSizesInfo =
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getDimSizesOfTensor(rewriter, op, tensor, dimSizeIndexBits);
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if (failed(dimSizesInfo))
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return rewriter.notifyMatchFailure(
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op, "failed to get dimension sizes of the input");
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auto dimSizes = *dimSizesInfo;
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auto rank = dimSizes.size();
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size_t newRank = rank + inputUnsqzDims.size();
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auto unsqzDims = toPositiveDims(inputUnsqzDims, newRank);
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for (size_t k = 0, sz = unsqzDims.size(); k < sz; ++k)
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if (k > 1 && unsqzDims[k] <= unsqzDims[k - 1])
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return rewriter.notifyMatchFailure(
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op, "unsqueeze dimensions must be specified in order");
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auto loc = op->getLoc();
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auto rankTy = tensor.getType().dyn_cast<RankedTensorType>();
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auto oldShape = rankTy.getShape();
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Type intType = rewriter.getIntegerType(dimSizeIndexBits);
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auto one = rewriter.create<arith::ConstantOp>(
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loc, rewriter.getIntegerAttr(intType, 1));
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std::vector<Value> newDimSizes;
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std::vector<int64_t> newShape;
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newDimSizes.reserve(newRank);
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newShape.reserve(newRank);
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for (size_t k = 0, i = 0, j = 0; k < newRank; ++k) {
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if (j < unsqzDims.size() && unsqzDims[j] == k) {
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newDimSizes.push_back(one);
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newShape.push_back(1);
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j++;
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} else {
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newDimSizes.push_back(dimSizes[i]);
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newShape.push_back(oldShape[i]);
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i++;
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}
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}
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auto outTy = RankedTensorType::get(newShape, rankTy.getElementType());
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auto mhloShape = rewriter.create<tensor::FromElementsOp>(loc, newDimSizes);
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return rewriter.create<mhlo::DynamicReshapeOp>(loc, outTy, tensor, mhloShape)
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.getResult();
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}
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Value getConstantOfShape(PatternRewriter &rewriter, Location loc,
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const APFloat &constant, Value shape,
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TensorType outType) {
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auto constAttr = rewriter.getFloatAttr(outType.getElementType(), constant);
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auto constTensor = rewriter.create<mhlo::ConstantOp>(loc, constAttr);
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return rewriter
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.create<mhlo::DynamicBroadcastInDimOp>(loc, outType, constTensor, shape,
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rewriter.getI64TensorAttr({}))
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.getResult();
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}
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} // namespace mhlo
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} // namespace mlir
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