Gitiles
Code Review Sign In
review.mlplatform.org / ml / ComputeLibrary / ebcebf1dee7f8314976b1e0cabd62b4cf893d765 / . / src / core / NEON / kernels / NEWinogradConvolutionLayerKernel.h
blob: 2b87e512dc9562a41f782d530884daef2c918c09 [file] [log] [blame]
/*
* Copyright (c) 2017-2020 Arm Limited.
*
* SPDX-License-Identifier: MIT
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#ifndef ARM_COMPUTE_NEGEMMWINOGRADCONVOLUTIONLAYERKERNEL_H
#define ARM_COMPUTE_NEGEMMWINOGRADCONVOLUTIONLAYERKERNEL_H
#include "src/core/NEON/INEKernel.h"
#include "src/core/NEON/kernels/convolution/common/convolution.hpp"
#include "src/core/NEON/kernels/convolution/common/tensor.hpp"
#include "src/core/NEON/kernels/convolution/winograd/winograd_layer.hpp"
namespace arm_compute
{
// Forward declarations
class ITensor;
/** Interface for the NEON kernel to perform Winograd input transform. */
class INEWinogradLayerTransformInputKernel : public INEKernel
{
public:
/** Get the working space required to perform the transformation.
*
* Note, the working space is only required when performing the
* transformation - hence it can be reused whenever the transformation is
* not running.
*
* @param num_threads The greatest number of threads that will be used to execute the transform.
* @return Size of working space required in bytes.
*/
virtual unsigned int get_working_space_size(unsigned int num_threads) const = 0;
/** Determine how much memory (in units of TIn) to allocate for the
* transformed input.
*
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_channels Number of feature maps in the input tensor.
* @param[in] num_rows Number of rows in each feature map.
* @param[in] num_cols Number of columns in each feature map.
* @param[in] same_padding Use "SAME" padding, otherwise use "VALID".
*
* @return Storage size (in units of TIn) required.
*/
virtual unsigned int get_input_storage_size(int num_batches, int num_channels, int num_rows, int num_cols, bool same_padding) const = 0;
/** Gets the stride between matrices in the input worspace
*
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_channels Number of feature maps in the input tensor.
* @param[in] num_rows Number of rows in each feature map.
* @param[in] num_cols Number of columns in each feature map.
* @param[in] same_padding Use "SAME" padding, otherwise use "VALID".
*
* @return Stride expressed in bytes.
*/
virtual int get_matrix_stride(int num_batches, int num_channels, int num_rows, int num_cols, bool same_padding) const = 0;
/** Configure the output transform kernel.
*
* @param[in] input_nhwc Input tensor in NHWC data layout format.
* @param[in] num_batches Number of batches in input tensor.
* @param[in] num_rows Number of rows in input tensor.
* @param[in] num_cols Number of columns in input tensor.
* @param[in] num_channels Number of channels in input tensor.
* @param[in] padding Padding type.
* @param[out] output Base of output matrices.
* @param[in] matrix_stride Stride between output matrices.
* @param[in] workspace Tensor to be used as the working space during the computation.
*/
virtual void configure(const ITensor *input_nhwc, const int num_batches, const int num_rows, const int num_cols, const int num_channels,
const PaddingType padding, ITensor *output, const int matrix_stride, ITensor *workspace) = 0;
/** Destructor */
virtual ~INEWinogradLayerTransformInputKernel()
{
}
};
/** NEON kernel to perform Winograd input transform. */
template <typename T, int OutputTileRows, int OutputTileCols, int KernelRows, int KernelCols>
class NEWinogradLayerTransformInputKernel : public INEWinogradLayerTransformInputKernel
{
public:
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformInputKernel(const NEWinogradLayerTransformInputKernel &) = delete;
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformInputKernel &operator=(const NEWinogradLayerTransformInputKernel &) = delete;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformInputKernel(NEWinogradLayerTransformInputKernel &&) = default;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformInputKernel &operator=(NEWinogradLayerTransformInputKernel &&) = default;
/** Default destructor */
~NEWinogradLayerTransformInputKernel() = default;
/** Determine how much memory (in units of TIn) to allocate for the
* transformed input.
*
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_channels Number of feature maps in the input tensor.
* @param[in] num_rows Number of rows in each feature map.
* @param[in] num_cols Number of columns in each feature map.
* @param[in] same_padding Use "SAME" padding, otherwise use "VALID".
*
* @return Storage size (in units of TIn) required.
*/
unsigned int get_input_storage_size(
int num_batches,
int num_channels,
int num_rows,
int num_cols,
bool same_padding) const override;
/** Get the working space required to perform the transformation.
*
* Note, the working space is only required when performing the
* transformation - hence it can be reused whenever the transformation is
* not running.
*
* @param[in] num_threads The greatest number of threads that will be used to execute the transform.
*
* @return Size of working space required in bytes.
*/
unsigned int get_working_space_size(unsigned int num_threads) const override;
/** Gets the stride between matrices in the input worspace
*
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_channels Number of feature maps in the input tensor.
* @param[in] num_rows Number of rows in each feature map.
* @param[in] num_cols Number of columns in each feature map.
* @param[in] same_padding Use "SAME" padding, otherwise use "VALID".
*
* @return Stride expressed in bytes.
*/
int get_matrix_stride(
int num_batches,
int num_channels,
int num_rows,
int num_cols,
bool same_padding) const override;
/** Default constructor */
NEWinogradLayerTransformInputKernel();
const char *name() const override
{
return "NEWinogradLayerTransformInputKernel";
}
/** Configure the output transform kernel.
*
* @param[in] input_nhwc Input tensor. Data types supported: F16/F32. Layout supported NHWC.
* @param[in] num_batches Number of batches in input tensor.
* @param[in] num_rows Number of rows in input tensor.
* @param[in] num_cols Number of columns in input tensor.
* @param[in] num_channels Number of channels in input tensor.
* @param[in] padding Padding type.
* @param[out] output Base of output matrices.
* @param[in] matrix_stride Stride between output matrices.
* @param[in] workspace Tensor to be used as the working space during the computation.
*/
void configure(
const ITensor *input_nhwc,
const int num_batches,
const int num_rows,
const int num_cols,
const int num_channels,
const PaddingType padding,
ITensor *output,
const int matrix_stride,
ITensor *workspace) override;
// Inherited methods overridden:
void run(const Window &window, const ThreadInfo &info) override;
/** Winograd base kernel */
using WinogradBase = winograd::WinogradGEMM<OutputTileRows, OutputTileCols, KernelRows, KernelCols, winograd::WinogradRoots::Integers>;
/** Winograd convolution kernel */
using WinogradConv = typename WinogradBase::template Convolution<T, T>;
/** Static function to check if given info will lead to a valid configuration of @ref NEWinogradLayerTransformInputKernel
*
* @param[in] input First tensor input info. Data types supported: F16/F32.
* @param[in] output Output tensor info. Data types supported: same as @p input.
* @param[in] winograd_info Contains Winograd's information described in @ref WinogradInfo
*
* @return a status
*/
static Status validate(const ITensorInfo *input, const ITensorInfo *output, const WinogradInfo &winograd_info);
private:
using InputTransform = typename WinogradBase::template InputTransform<T, T>;
std::unique_ptr<InputTransform> _transform{ nullptr };
const ITensor *_input_nhwc;
int _num_batches; /**< Number of batches in input tensor. */
int _num_rows; /**< Number of rows in input tensor. */
int _num_cols; /**< Number of columns in input tensor. */
int _num_channels; /**< Number of channels in input tensor. */
PaddingType _padding; /**< Padding type. */
ITensor *_output; /**< Base of output matrices. */
int _matrix_stride; /**< Stride between output matrices. */
int _padding_top; /**< Padding to apply to the top of the image. */
int _padding_left; /**< Padding to apply to the left of the image. */
int _padding_right; /**< Padding to apply to the right of the image. */
int _padding_bottom; /**< Padding to apply to the bottom of the image. */
ITensor *_workspace;
};
/** Interface for the NEON kernel to perform Winograd output transform. */
class INEWinogradLayerTransformOutputKernel : public INEKernel
{
public:
/** Get the working space required to perform the transformation.
*
* Note, the working space is only required when performing the
* transformation - hence it can be reused whenever the transformation is
* not running.
*
* @param[in] num_threads The greatest number of threads that will be used to execute the transform.
*
* @return Size of working space required in bytes.
*/
virtual unsigned int get_working_space_size(unsigned int num_threads) const = 0;
/** Determine how much memory (in units of TOut) to allocate for the
* (Winograd domain) output.
*
* @param[in] num_batches Number of batches in the output tensor.
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] num_output_channels Number of feature maps in the output tensor.
*
* @return Storage size (in units of TOut) required.
*/
virtual unsigned int get_output_storage_size(int num_batches, int num_rows, int num_cols, int num_output_channels) const = 0;
/** Gets the stride between matrices in the output worspace
*
* @param[in] num_batches Number of batches in the output tensor.
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] num_output_channels Number of feature maps in the output tensor.
*
* @return Stride expressed in bytes.
*/
virtual int get_matrix_stride(int num_batches, int num_rows, int num_cols, int num_output_channels) const = 0;
/** Get the output shape of a convolution.
*
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] padding_same True if padding is SAME, false otherwise
*
* @return Shape of the output tensor
*/
virtual std::pair<unsigned int, unsigned int> get_output_shape(
int num_rows, /* Number of rows in each feature map of the input tensor. */
int num_cols, /* Number of columns in each feature map of the input tensor. */
bool padding_same /* True if padding is SAME, false otherwise */
) const = 0;
/** Configure the output transform kernel.
*
* @param[in] biases Pointer to the biases tensor.
* @param[in] transformed_output Pointer to working space for the output tensor in the Winograd domain.
* @param[in] matrix_stride Output matrix stride, can be computed with winograd::WinogradGEMM<2, 2, 3, 3>::Convolution<float, float>::get_output_matrix_stride()
* @param[out] output_nhwc Pointer to a tensor in NHWC data layout ordered output tensor, in the spatial domain.
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_rows Number of rows in output tensor.
* @param[in] num_cols Number of columns in output tensor.
* @param[in] num_channels Number of feature maps in the output tensor.
* @param[in] workspace Tensor to be used as the working space during the computation.
* @param[in] activation Activation to be used
*/
virtual void configure(
const ITensor *biases,
const ITensor *transformed_output,
const int matrix_stride,
ITensor *output_nhwc,
const int num_batches,
const int num_rows,
const int num_cols,
const int num_channels,
ITensor *workspace,
const arm_gemm::Activation &activation) = 0;
virtual ~INEWinogradLayerTransformOutputKernel()
{
}
};
/** NEON kernel to perform Winograd output transform. */
template <typename T, int OutputTileRows, int OutputTileCols, int KernelRows, int KernelCols>
class NEWinogradLayerTransformOutputKernel : public INEWinogradLayerTransformOutputKernel
{
public:
const char *name() const override
{
return "NEWinogradLayerTransformOutputKernel";
}
/** Constructor */
NEWinogradLayerTransformOutputKernel();
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformOutputKernel(const NEWinogradLayerTransformOutputKernel &) = delete;
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformOutputKernel &operator=(const NEWinogradLayerTransformOutputKernel &) = delete;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformOutputKernel(NEWinogradLayerTransformOutputKernel &&) = default;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformOutputKernel &operator=(NEWinogradLayerTransformOutputKernel &&) = default;
/** Default destructor */
~NEWinogradLayerTransformOutputKernel() = default;
// Inherited methods overridden:
/** Determine how much memory (in units of TOut) to allocate for the
* (Winograd domain) output.
*
* @param[in] num_batches Number of batches in the output tensor.
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] num_output_channels Number of feature maps in the output tensor.
*
* @return Storage size (in units of TOut) required.
*/
unsigned int get_output_storage_size(int num_batches, int num_rows, int num_cols, int num_output_channels) const override;
/** Gets the stride between matrices in the output worspace
*
* @param[in] num_batches Number of batches in the output tensor.
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] num_output_channels Number of feature maps in the output tensor.
*
* @return Stride expressed in bytes.
*/
int get_matrix_stride(int num_batches, int num_rows, int num_cols, int num_output_channels) const override;
/** Get the output shape of a convolution.
*
* @param[in] num_rows Number of rows in each feature map of the input tensor.
* @param[in] num_cols Number of columns in each feature map of the input tensor.
* @param[in] padding_same True if padding is SAME, false otherwise
*
* @return Shape of the output tensor
*/
std::pair<unsigned int, unsigned int> get_output_shape(
int num_rows, /* Number of rows in each feature map of the input tensor. */
int num_cols, /* Number of columns in each feature map of the input tensor. */
bool padding_same) const override;
/** Get the working space required to perform the transformation.
*
* Note, the working space is only required when performing the
* transformation - hence it can be reused whenever the transformation is
* not running.
*
* @param[in] num_threads The greatest number of threads that will be used to execute the transform.
*
* @return Size of working space required in bytes.
*/
unsigned int get_working_space_size(unsigned int num_threads) const override;
/** Configure the output transform kernel.
*
* @param[in] biases Pointer to the biases tensor.
* @param[in] transformed_output Pointer to working space for the output tensor in the Winograd domain.
* @param[in] matrix_stride Output matrix stride, can be computed with winograd::WinogradGEMM<2, 2, 3, 3>::Convolution<float, float>::get_output_matrix_stride()
* @param[out] output_nhwc Pointer to a tensor with NHWC data layout, in the spatial domain.
* @param[in] num_batches Number of batches in the input tensor.
* @param[in] num_rows Number of rows in output tensor.
* @param[in] num_cols Number of columns in output tensor.
* @param[in] num_channels Number of feature maps in the output tensor.
* @param[in] workspace Tensor to be used as the working space during the computation.
* @param[in] activation Activation to be used
*/
void configure(
const ITensor *biases,
const ITensor *transformed_output,
const int matrix_stride,
ITensor *output_nhwc,
const int num_batches,
const int num_rows,
const int num_cols,
const int num_channels,
ITensor *workspace,
const arm_gemm::Activation &activation) override;
void run(const Window &window, const ThreadInfo &info) override;
/** Static function to check if given info will lead to a valid configuration of @ref NEWinogradLayerTransformOutputKernel
*
* @param[in] input Source tensor info with shape [C, N, 16, batches] or [C, N, 36, batches]. Data types supported: F16/F32.
* @param[in] bias Biases tensor info. Shared biases supported. Biases are 1D tensor with dimensions [OFM]. It can be a nullptr. Data type supported: as @p input
* @param[in] output Destination tensor info with shape [output_convolved_dims.width, output_convolved_dims.height, C, batches]. Data type supported: same as @p input
* @param[in] winograd_info Contains Winograd's information described in @ref WinogradInfo
*
* @return a status
*/
static Status validate(const ITensorInfo *input, const ITensorInfo *bias, const ITensorInfo *output, const WinogradInfo &winograd_info);
private:
using WinogradBase = winograd::WinogradGEMM<OutputTileRows, OutputTileCols, KernelRows, KernelCols, winograd::WinogradRoots::Integers>;
using WinogradConv = typename WinogradBase::template Convolution<T, T>;
using OutputTransform = typename WinogradBase::template OutputTransform<T, T>;
std::unique_ptr<OutputTransform> _transform{ nullptr };
const ITensor *_biases;
const ITensor *_transformed_output;
ITensor *_workspace;
int _matrix_stride;
int _matrix_row_stride;
ITensor *_output_nhwc;
int _num_batches;
int _num_rows;
int _num_cols;
int _num_channels;
};
/** Interface for the NEON kernel to perform Winograd weights transform. */
class INEWinogradLayerTransformWeightsKernel : public INEKernel
{
public:
/** Prevent instances of this class from being copied (As this class contains pointers) */
INEWinogradLayerTransformWeightsKernel(const INEWinogradLayerTransformWeightsKernel &) = default;
/** Prevent instances of this class from being copied (As this class contains pointers) */
INEWinogradLayerTransformWeightsKernel &operator=(const INEWinogradLayerTransformWeightsKernel &) = default;
/** Allow instances of this class to be moved */
INEWinogradLayerTransformWeightsKernel(INEWinogradLayerTransformWeightsKernel &&) = default;
/** Allow instances of this class to be moved */
INEWinogradLayerTransformWeightsKernel &operator=(INEWinogradLayerTransformWeightsKernel &&) = default;
INEWinogradLayerTransformWeightsKernel()
{
}
virtual ~INEWinogradLayerTransformWeightsKernel()
{
}
/** Determine how much memory (in units of T) to allocate for the
* transformed weights.
*
* @param[in] num_output_channels Number of output feature maps.
* @param[in] num_input_channels Number of input feature maps.
*
* @return Storage size (in units of T) required.
*/
virtual unsigned int get_weight_storage_size(int num_output_channels, int num_input_channels) const = 0;
/** Gets the stride between matrices in the kernel worspace
*
* @param[in] num_output_channels Number of output feature maps.
* @param[in] num_input_channels Number of input feature maps.
*
* @return Stride expressed in bytes.
*/
virtual int get_matrix_stride(int num_output_channels, int num_input_channels) const = 0;
/** Configure the weights transform kernel.
*
* @param[in] weights_hwio Pointer to the weights tensor
* @param[out] output Pointer to working space for the output tensor in the Winograd domain.
* @param[in] matrix_stride Stride across matrices in the output workspace.
* @param[in] num_output_channels Number of filters.
* @param[in] num_input_channels Number of channels in each filter.
*/
virtual void configure(const ITensor *weights_hwio, ITensor *output, const int matrix_stride, const int num_output_channels, const int num_input_channels) = 0;
/** Static function to check if given info will lead to a valid configuration of @ref NEWinogradLayerTransformWeightsKernel
*
* @param[in] input First tensor input info. Data types supported: F16/F32.
* @param[in] weights Weights tensor info. Data types supported: same as @p input.
*
* @return a status
*/
static Status validate(const ITensorInfo *input, const ITensorInfo *weights);
};
/** NEON kernel to perform Winograd weights transform. */
template <typename T, int OutputTileRows, int OutputTileCols, int KernelRows, int KernelCols>
class NEWinogradLayerTransformWeightsKernel final : public INEWinogradLayerTransformWeightsKernel
{
public:
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformWeightsKernel(const NEWinogradLayerTransformWeightsKernel &) = delete;
/** Prevent instances of this class from being copied (As this class contains pointers) */
NEWinogradLayerTransformWeightsKernel &operator=(const NEWinogradLayerTransformWeightsKernel &) = delete;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformWeightsKernel(NEWinogradLayerTransformWeightsKernel &&) = default;
/** Allow instances of this class to be moved */
NEWinogradLayerTransformWeightsKernel &operator=(NEWinogradLayerTransformWeightsKernel &&) = default;
/** Default destructor */
~NEWinogradLayerTransformWeightsKernel() = default;
/** Default constructor. */
NEWinogradLayerTransformWeightsKernel();
const char *name() const override
{
return "NEWinogradLayerTransformWeightsKernel";
}
/** Static function to check if given info will lead to a valid configuration of @ref NEWinogradLayerTransformWeightsKernel
*
* @param[in] input Source tensor info. The input is a 4D tensor with dimensions [kernel_x, kernel_y, IFM, OFM] (NCHW data layout).
* kernel_x must be 3 and equal to kernel_y. Data types supported: F16/F32.
* @param[in] output Destination tensor info. The output is a 3D tensor with dimensions [OFM, IFM, 16] or [OFM, IFM, 36]. Data type supported: same as @p input
* @param[in] winograd_info Contains Winograd's information described in @ref WinogradInfo
*
* @return a status
*/
static Status validate(const ITensorInfo *input, const ITensorInfo *output, const WinogradInfo &winograd_info);
// Inherited methods overridden:
#ifndef DOXYGEN_SKIP_THIS
/** Configure the weights transform kernel.
*
* @param[in] weights_hwio Pointer to the weights tensor
* @param[out] output Pointer to working space for the output tensor in the Winograd domain.
* @param[in] matrix_stride Stride across matrices in the output workspace.
* @param[in] num_output_channels Number of filters.
* @param[in] num_input_channels Number of channels in each filter.
*/
void configure(const ITensor *weights_hwio, ITensor *output, const int matrix_stride, const int num_output_channels, const int num_input_channels) override;
#endif /* DOXYGEN_SKIP_THIS */
/** Determine how much memory (in units of T) to allocate for the
* transformed weights.
*
* @param[in] num_output_channels Number of output feature maps.
* @param[in] num_input_channels Number of input feature maps.
*
* @return Storage size (in units of T) required.
*/
unsigned int get_weight_storage_size(int num_output_channels, int num_input_channels) const override;
/** Gets the stride between matrices in the input worspace
*
* @param[in] num_output_channels Number of output feature maps.
* @param[in] num_input_channels Number of input feature maps.
*
* @return Stride expressed in bytes.
*/
int get_matrix_stride(int num_output_channels, int num_input_channels) const override;
void run(const Window &window, const ThreadInfo &info) override;
bool is_parallelisable() const override;
private:
using WinogradBase = winograd::WinogradGEMM<OutputTileRows, OutputTileCols, KernelRows, KernelCols, winograd::WinogradRoots::Integers>;
using WinogradConv = typename WinogradBase::template Convolution<T, T>;
using WeightsTransform = typename WinogradBase::template WeightsTransform<T, T>;
std::unique_ptr<WeightsTransform> _transform{ nullptr };
const ITensor *_weights_hwio;
ITensor *_output;
int _matrix_stride;
int _num_output_channels;
int _num_input_channels;
};
/** NEON kernel to perform Winograd. */
template <typename TIn, typename TOut, int OutputTileRows, int OutputTileCols, int KernelRows, int KernelCols>
class NEWinogradLayerConfiguration
{
public:
/** Winograd base kernel */
using WinogradBase = winograd::WinogradGEMM<OutputTileRows, OutputTileCols, KernelRows, KernelCols, winograd::WinogradRoots::Integers>;
/** Winograd convolution kernel */
using WinogradConv = typename WinogradBase::template Convolution<TIn, TOut>;
using TransformInputKernel = NEWinogradLayerTransformInputKernel<TIn, OutputTileRows, OutputTileCols, KernelRows, KernelCols>;
using TransformWeightsKernel = NEWinogradLayerTransformWeightsKernel<TIn, OutputTileRows, OutputTileCols, KernelRows, KernelCols>;
using TransformOutputKernel = NEWinogradLayerTransformOutputKernel<TOut, OutputTileRows, OutputTileCols, KernelRows, KernelCols>;
};
} // namespace arm_compute
#endif /*ARM_COMPUTE_NEGEMMWINOGRADCONVOLUTIONLAYERKERNEL_H*/