torch-mlir/lib/Conversion/TorchToTosa/TosaLegalizeUtils.cpp

//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
// Also available under a BSD-style license. See LICENSE.
//
//===----------------------------------------------------------------------===//

#include "torch-mlir/Conversion/TorchToTosa/TosaLegalizeUtils.h"
#include "mlir/Dialect/Tosa/IR/TosaOps.h"       // from @llvm-project
#include "mlir/Dialect/Tosa/Utils/QuantUtils.h" // from @llvm-project
#include "torch-mlir/Conversion/TorchToTosa/TosaLegalizeCommon.h"

namespace mlir {
namespace tosa {

// Create a TOSA rescale op from input framework tensor, zero points and
// rounding mode
Value buildRescale(PatternRewriter &rewriter, Operation *op,
                   ShapedType output_type, Value input_val, double scale,
                   int64_t input_zp, int64_t output_zp, bool double_round,
                   bool scale32) {
  int32_t multiplier;
  int32_t shift;

  int32_t scale_width = scale32 ? 32 : 16;

  computeMultiplierAndShift(scale, multiplier, shift, scale_width);

  auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(
      rewriter, op->getLoc(), output_type, input_val,
      rewriter.getI32IntegerAttr(static_cast<int32_t>(input_zp)),
      rewriter.getI32IntegerAttr(static_cast<int32_t>(output_zp)),
      rewriter.getI32ArrayAttr({multiplier}), rewriter.getI32ArrayAttr({shift}),
      rewriter.getBoolAttr(scale32), rewriter.getBoolAttr(double_round),
      rewriter.getBoolAttr(false));

  return rescale_op.getResult();
}

// Creates TOSA rescale op with int32 output
Value buildRescaleToInt32(PatternRewriter &rewriter, Operation *op,
                          Value input_val, double input_scale,
                          int64_t input_zp) {
  // Output is always int32 type
  auto input_type = input_val.getType().dyn_cast<mlir::ShapedType>();
  assert(input_type);
  auto output_type = input_type.clone(rewriter.getI32Type());

  return buildRescale(rewriter, op, output_type, input_val, input_scale,
                      input_zp, 0, false, true);
}

// Creates a TOSA rescale op based on conv2d parameters.
Value buildRescaleOpConvOutput(PatternRewriter &rewriter, Operation *op,
                               Value conv_val, ShapedType input_type,
                               ShapedType weight_type, ShapedType output_type) {
  auto input_qtype =
      input_type.getElementType().dyn_cast<mlir::quant::UniformQuantizedType>();
  auto output_qtype = output_type.getElementType()
                          .dyn_cast<mlir::quant::UniformQuantizedType>();

  double input_scale = input_qtype.getScale();

  int64_t output_zp = output_qtype.getZeroPoint();
  double output_scale = output_qtype.getScale();

  bool scale32 = isScale32(output_qtype);
  int32_t scale_width = scale32 ? 32 : 16;

  if (auto weight_per_tensor_qtype =
          weight_type.getElementType()
              .dyn_cast<mlir::quant::UniformQuantizedType>()) {
    // Per-tensor quantization
    double weight_scale = weight_per_tensor_qtype.getScale();

    int32_t multiplier;
    int32_t shift;

    double op_tensor_scale = (input_scale * weight_scale) / output_scale;

    computeMultiplierAndShift(op_tensor_scale, multiplier, shift, scale_width);

    auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(
        rewriter, op->getLoc(), output_type, conv_val,
        rewriter.getI32IntegerAttr(0), rewriter.getI32IntegerAttr(output_zp),
        rewriter.getI32ArrayAttr({multiplier}),
        rewriter.getI32ArrayAttr({shift}), rewriter.getBoolAttr(scale32),
        rewriter.getBoolAttr(true), rewriter.getBoolAttr(false));

    return rescale_op.getResult();

  } else if (auto weight_per_channel_qtype =
                 weight_type.getElementType()
                     .dyn_cast<mlir::quant::UniformQuantizedPerAxisType>()) {
    // Per-channel quantization
    SmallVector<int32_t> multiplier_arr;
    SmallVector<int32_t> shift_arr;

    SmallVector<double> weight_scale_arr(
        weight_per_channel_qtype.getScales().begin(),
        weight_per_channel_qtype.getScales().end());

    int64_t output_zp = output_qtype.getZeroPoint();
    double output_scale = output_qtype.getScale();

    for (double weight_scale : weight_scale_arr) {
      int32_t multiplier;
      int32_t shift;

      double op_channel_scale = (input_scale * weight_scale) / output_scale;

      computeMultiplierAndShift(op_channel_scale, multiplier, shift,
                                scale_width);

      multiplier_arr.push_back(multiplier);
      shift_arr.push_back(shift);
    }

    auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(
        rewriter, op->getLoc(), output_type, conv_val,
        rewriter.getI32IntegerAttr(0), rewriter.getI32IntegerAttr(output_zp),
        rewriter.getI32ArrayAttr(multiplier_arr),
        rewriter.getI32ArrayAttr(shift_arr), rewriter.getBoolAttr(scale32),
        rewriter.getBoolAttr(true), rewriter.getBoolAttr(true));

    return rescale_op.getResult();

  } else {
    op->emitOpError("buildConvRescaleOp: unknown weight quantized type");
    return nullptr;
  }
}

// Check if scale32 mode is used for given output_element_type
bool isScale32(mlir::quant::UniformQuantizedType output_element_type) {
  return (output_element_type.getStorageTypeIntegralWidth() == 8);
}

// Create a 32-bit float constant operator from a float
Value getTosaConstTensorSingleF32(PatternRewriter &rewriter, Operation *op,
                                  float val) {
  auto const_type = RankedTensorType::get({}, rewriter.getF32Type());
  auto const_attr = DenseElementsAttr::get(const_type, val);

  auto const_op =
      rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);
  return const_op.getResult();
}

// Templated function to create a constant op for given type and shape.
// T: storage C type.
// Default template creates a constant tensor in T.
template <typename T>
llvm::Optional<Value> getConstTensor(PatternRewriter &rewriter, Operation *op,
                                     ArrayRef<T> vec, ArrayRef<int64_t> shape) {
  uint64_t num_total_elements = 1;
  for (int64_t a : shape) {
    num_total_elements *= a;
  }

  if (vec.size() != num_total_elements) {
    op->emitOpError("getConstTensor(): number of elements mismatch.");
    return llvm::None;
  }

  auto const_type =
      RankedTensorType::get(shape, rewriter.getIntegerType(sizeof(T) * 8));
  auto const_attr = DenseElementsAttr::get(const_type, vec);

  auto const_op =
      rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);
  return const_op.getResult();
}

// Template specialization for APInt
template <>
llvm::Optional<Value> getConstTensor<APInt>(PatternRewriter &rewriter,
                                            Operation *op, ArrayRef<APInt> vec,
                                            ArrayRef<int64_t> shape) {
  uint64_t num_total_elements = 1;
  for (int64_t a : shape) {
    num_total_elements *= a;
  }

  if (vec.size() != num_total_elements) {
    op->emitOpError("getConstTensor(): number of elements mismatch.");
    return llvm::None;
  }

  auto const_type = RankedTensorType::get(
      shape, rewriter.getIntegerType(vec[0].getBitWidth()));
  auto const_attr = DenseElementsAttr::get(const_type, vec);

  auto const_op =
      rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);
  return const_op.getResult();
}

// Template specialization for float
template <>
llvm::Optional<Value> getConstTensor<float>(PatternRewriter &rewriter,
                                            Operation *op, ArrayRef<float> vec,
                                            ArrayRef<int64_t> shape) {
  uint64_t num_total_elements = 1;
  for (int64_t a : shape) {
    num_total_elements *= a;
  }

  if (vec.size() != num_total_elements) {
    op->emitOpError("getConstTensor(): number of elements mismatch.");
    return llvm::None;
  }

  auto const_type = RankedTensorType::get(shape, rewriter.getF32Type());
  auto const_attr = DenseElementsAttr::get(const_type, vec);

  auto const_op =
      rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);
  return const_op.getResult();
}

// Template instantiation
template llvm::Optional<Value> getConstTensor<int32_t>(PatternRewriter &,
                                                       Operation *,
                                                       ArrayRef<int32_t> vec,
                                                       ArrayRef<int64_t> shape);

template llvm::Optional<Value> getConstTensor<int64_t>(PatternRewriter &,
                                                       Operation *,
                                                       ArrayRef<int64_t> vec,
                                                       ArrayRef<int64_t> shape);
} // namespace tosa
} // namespace mlir
[tosa] Add Torch reduction operators - Supports variants with multiple dims, one dim, all dime - Leverages legalize_common and legalize_utils code from TensorFlow-TOSA work Signed-off-by: Suraj Sudhir <suraj.sudhir@arm.com> 2021-12-03 08:52:01 +08:00			`//===----------------------------------------------------------------------===//`
			`//`
			`// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.`
			`// See https://llvm.org/LICENSE.txt for license information.`
			`// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception`
			`// Also available under a BSD-style license. See LICENSE.`
			`//`
			`//===----------------------------------------------------------------------===//`

			`#include "torch-mlir/Conversion/TorchToTosa/TosaLegalizeUtils.h"`
			`#include "mlir/Dialect/Tosa/IR/TosaOps.h" // from @llvm-project`
			`#include "mlir/Dialect/Tosa/Utils/QuantUtils.h" // from @llvm-project`
			`#include "torch-mlir/Conversion/TorchToTosa/TosaLegalizeCommon.h"`

			`namespace mlir {`
			`namespace tosa {`

			`// Create a TOSA rescale op from input framework tensor, zero points and`
			`// rounding mode`
			`Value buildRescale(PatternRewriter &rewriter, Operation *op,`
			`ShapedType output_type, Value input_val, double scale,`
			`int64_t input_zp, int64_t output_zp, bool double_round,`
			`bool scale32) {`
			`int32_t multiplier;`
			`int32_t shift;`

			`int32_t scale_width = scale32 ? 32 : 16;`

			`computeMultiplierAndShift(scale, multiplier, shift, scale_width);`

			`auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(`
			`rewriter, op->getLoc(), output_type, input_val,`
			`rewriter.getI32IntegerAttr(static_cast<int32_t>(input_zp)),`
			`rewriter.getI32IntegerAttr(static_cast<int32_t>(output_zp)),`
			`rewriter.getI32ArrayAttr({multiplier}), rewriter.getI32ArrayAttr({shift}),`
			`rewriter.getBoolAttr(scale32), rewriter.getBoolAttr(double_round),`
			`rewriter.getBoolAttr(false));`

			`return rescale_op.getResult();`
			`}`

			`// Creates TOSA rescale op with int32 output`
			`Value buildRescaleToInt32(PatternRewriter &rewriter, Operation *op,`
			`Value input_val, double input_scale,`
			`int64_t input_zp) {`
			`// Output is always int32 type`
			`auto input_type = input_val.getType().dyn_cast<mlir::ShapedType>();`
			`assert(input_type);`
			`auto output_type = input_type.clone(rewriter.getI32Type());`

			`return buildRescale(rewriter, op, output_type, input_val, input_scale,`
			`input_zp, 0, false, true);`
			`}`

[tosa] Implement conv2d support (#541) Signed-off-by: Suraj Sudhir <suraj.sudhir@arm.com> 2022-01-27 11:16:13 +08:00			`// Creates a TOSA rescale op based on conv2d parameters.`
			`Value buildRescaleOpConvOutput(PatternRewriter &rewriter, Operation *op,`
			`Value conv_val, ShapedType input_type,`
			`ShapedType weight_type, ShapedType output_type) {`
			`auto input_qtype =`
			`input_type.getElementType().dyn_cast<mlir::quant::UniformQuantizedType>();`
			`auto output_qtype = output_type.getElementType()`
			`.dyn_cast<mlir::quant::UniformQuantizedType>();`

			`double input_scale = input_qtype.getScale();`

			`int64_t output_zp = output_qtype.getZeroPoint();`
			`double output_scale = output_qtype.getScale();`

			`bool scale32 = isScale32(output_qtype);`
			`int32_t scale_width = scale32 ? 32 : 16;`

			`if (auto weight_per_tensor_qtype =`
			`weight_type.getElementType()`
			`.dyn_cast<mlir::quant::UniformQuantizedType>()) {`
			`// Per-tensor quantization`
			`double weight_scale = weight_per_tensor_qtype.getScale();`

			`int32_t multiplier;`
			`int32_t shift;`

			`double op_tensor_scale = (input_scale * weight_scale) / output_scale;`

			`computeMultiplierAndShift(op_tensor_scale, multiplier, shift, scale_width);`

			`auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(`
			`rewriter, op->getLoc(), output_type, conv_val,`
			`rewriter.getI32IntegerAttr(0), rewriter.getI32IntegerAttr(output_zp),`
			`rewriter.getI32ArrayAttr({multiplier}),`
			`rewriter.getI32ArrayAttr({shift}), rewriter.getBoolAttr(scale32),`
			`rewriter.getBoolAttr(true), rewriter.getBoolAttr(false));`

			`return rescale_op.getResult();`

			`} else if (auto weight_per_channel_qtype =`
			`weight_type.getElementType()`
			`.dyn_cast<mlir::quant::UniformQuantizedPerAxisType>()) {`
			`// Per-channel quantization`
			`SmallVector<int32_t> multiplier_arr;`
			`SmallVector<int32_t> shift_arr;`

			`SmallVector<double> weight_scale_arr(`
			`weight_per_channel_qtype.getScales().begin(),`
			`weight_per_channel_qtype.getScales().end());`

			`int64_t output_zp = output_qtype.getZeroPoint();`
			`double output_scale = output_qtype.getScale();`

			`for (double weight_scale : weight_scale_arr) {`
			`int32_t multiplier;`
			`int32_t shift;`

			`double op_channel_scale = (input_scale * weight_scale) / output_scale;`

			`computeMultiplierAndShift(op_channel_scale, multiplier, shift,`
			`scale_width);`

			`multiplier_arr.push_back(multiplier);`
			`shift_arr.push_back(shift);`
			`}`

			`auto rescale_op = CreateOpAndInfer<tosa::RescaleOp>(`
			`rewriter, op->getLoc(), output_type, conv_val,`
			`rewriter.getI32IntegerAttr(0), rewriter.getI32IntegerAttr(output_zp),`
			`rewriter.getI32ArrayAttr(multiplier_arr),`
			`rewriter.getI32ArrayAttr(shift_arr), rewriter.getBoolAttr(scale32),`
			`rewriter.getBoolAttr(true), rewriter.getBoolAttr(true));`

			`return rescale_op.getResult();`

			`} else {`
			`op->emitOpError("buildConvRescaleOp: unknown weight quantized type");`
			`return nullptr;`
			`}`
			`}`

			`// Check if scale32 mode is used for given output_element_type`
			`bool isScale32(mlir::quant::UniformQuantizedType output_element_type) {`
			`return (output_element_type.getStorageTypeIntegralWidth() == 8);`
			`}`

[tosa] Add Torch reduction operators - Supports variants with multiple dims, one dim, all dime - Leverages legalize_common and legalize_utils code from TensorFlow-TOSA work Signed-off-by: Suraj Sudhir <suraj.sudhir@arm.com> 2021-12-03 08:52:01 +08:00			`// Create a 32-bit float constant operator from a float`
			`Value getTosaConstTensorSingleF32(PatternRewriter &rewriter, Operation *op,`
			`float val) {`
			`auto const_type = RankedTensorType::get({}, rewriter.getF32Type());`
			`auto const_attr = DenseElementsAttr::get(const_type, val);`

			`auto const_op =`
			`rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);`
			`return const_op.getResult();`
			`}`

[tosa] Add more common utility functions (#525) - Common code as TF repository, being moved to MLIR core. - Will support further legalizations to be published. Signed-off-by: Suraj Sudhir <suraj.sudhir@arm.com> 2022-01-15 05:57:27 +08:00			`// Templated function to create a constant op for given type and shape.`
			`// T: storage C type.`
			`// Default template creates a constant tensor in T.`
			`template <typename T>`
			`llvm::Optional<Value> getConstTensor(PatternRewriter &rewriter, Operation *op,`
			`ArrayRef<T> vec, ArrayRef<int64_t> shape) {`
			`uint64_t num_total_elements = 1;`
			`for (int64_t a : shape) {`
			`num_total_elements *= a;`
			`}`

			`if (vec.size() != num_total_elements) {`
			`op->emitOpError("getConstTensor(): number of elements mismatch.");`
			`return llvm::None;`
			`}`

			`auto const_type =`
			`RankedTensorType::get(shape, rewriter.getIntegerType(sizeof(T) * 8));`
			`auto const_attr = DenseElementsAttr::get(const_type, vec);`

			`auto const_op =`
			`rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);`
			`return const_op.getResult();`
			`}`

			`// Template specialization for APInt`
			`template <>`
			`llvm::Optional<Value> getConstTensor<APInt>(PatternRewriter &rewriter,`
			`Operation *op, ArrayRef<APInt> vec,`
			`ArrayRef<int64_t> shape) {`
			`uint64_t num_total_elements = 1;`
			`for (int64_t a : shape) {`
			`num_total_elements *= a;`
			`}`

			`if (vec.size() != num_total_elements) {`
			`op->emitOpError("getConstTensor(): number of elements mismatch.");`
			`return llvm::None;`
			`}`

			`auto const_type = RankedTensorType::get(`
			`shape, rewriter.getIntegerType(vec[0].getBitWidth()));`
			`auto const_attr = DenseElementsAttr::get(const_type, vec);`

			`auto const_op =`
			`rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);`
			`return const_op.getResult();`
			`}`

			`// Template specialization for float`
			`template <>`
			`llvm::Optional<Value> getConstTensor<float>(PatternRewriter &rewriter,`
			`Operation *op, ArrayRef<float> vec,`
			`ArrayRef<int64_t> shape) {`
			`uint64_t num_total_elements = 1;`
			`for (int64_t a : shape) {`
			`num_total_elements *= a;`
			`}`

			`if (vec.size() != num_total_elements) {`
			`op->emitOpError("getConstTensor(): number of elements mismatch.");`
			`return llvm::None;`
			`}`

			`auto const_type = RankedTensorType::get(shape, rewriter.getF32Type());`
			`auto const_attr = DenseElementsAttr::get(const_type, vec);`

			`auto const_op =`
			`rewriter.create<tosa::ConstOp>(op->getLoc(), const_type, const_attr);`
			`return const_op.getResult();`
			`}`

			`// Template instantiation`
			`template llvm::Optional<Value> getConstTensor<int32_t>(PatternRewriter &,`
			`Operation *,`
			`ArrayRef<int32_t> vec,`
			`ArrayRef<int64_t> shape);`

* [tosa] Support for AtenRsubScalarOp for scalar constants (#531) * [tosa] Support for AtenCeilOp and AtenReciprocalOp * [tosa] Support for comparator ops, Aten[Gt\|Lt\|Eq][Tensor\|Scalar]Op with scalar constant * [tosa] Support for Scalar variants of Aten[Mul\|Div\|Add\|Sub] Ops with scalar constants Signed-off-by: Anup Gangwar <anup.gangwar@arm.com> Co-authored-by: Anup Gangwar <anup.gangwar@arm.com> 2022-01-21 02:58:30 +08:00			`template llvm::Optional<Value> getConstTensor<int64_t>(PatternRewriter &,`
			`Operation *,`
			`ArrayRef<int64_t> vec,`
			`ArrayRef<int64_t> shape);`
[tosa] Add Torch reduction operators - Supports variants with multiple dims, one dim, all dime - Leverages legalize_common and legalize_utils code from TensorFlow-TOSA work Signed-off-by: Suraj Sudhir <suraj.sudhir@arm.com> 2021-12-03 08:52:01 +08:00			`} // namespace tosa`
			`} // namespace mlir`