src/cpu/kernels/CpuDirectConv3dKernel.cpp - ml/ComputeLibrary - Gitiles

 /*
  * Copyright (c) 2021 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.
  */
 #include "src/cpu/kernels/CpuDirectConv3dKernel.h"

 #include "src/core/NEON/kernels/detail/NEDirectConvolutionDetail.h"
 #include "src/core/NEON/wrapper/wrapper.h"

 #include "arm_compute/core/Error.h"
 #include "arm_compute/core/Helpers.h"
 #include "arm_compute/core/IAccessWindow.h"
 #include "arm_compute/core/ITensor.h"
 #include "arm_compute/core/Types.h"
 #include "arm_compute/core/Utils.h"
 #include "arm_compute/core/Validate.h"
 #include "arm_compute/core/utils/misc/ShapeCalculator.h"
 #include "src/core/CPP/Validate.h"
 #include "src/core/helpers/AutoConfiguration.h"
 #include "src/core/helpers/WindowHelpers.h"

 #include <algorithm>

 using namespace arm_compute::detail;

 namespace arm_compute
 {
 namespace cpu
 {
 namespace kernels
 {
 namespace
 {
 Status validate_arguments(const ITensorInfo *src, const ITensorInfo *weights, const ITensorInfo *biases, const ITensorInfo *dst, const Conv3dInfo &conv_info)
 {
     ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(src, weights, dst);
     ARM_COMPUTE_RETURN_ERROR_ON(src->data_layout() != DataLayout::NDHWC);
     ARM_COMPUTE_RETURN_ERROR_ON_CPU_F16_UNSUPPORTED(src);
     ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(src, 1, DataType::F16, DataType::F32);
     ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(src, weights);

     const DataLayout data_layout = src->data_layout();
     const int        channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL);

     // Weight layout is D, H, W, Cin, Cout
     ARM_COMPUTE_RETURN_ERROR_ON(weights->num_dimensions() > 5);
     ARM_COMPUTE_RETURN_ERROR_ON(weights->dimension(1) != src->dimension(channel_idx));

     if(biases != nullptr)
     {
         ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(weights, biases);
         ARM_COMPUTE_RETURN_ERROR_ON_MSG(biases->dimension(0) != weights->dimension(0),
                                         "biases size and number of output feature maps should match");
         ARM_COMPUTE_RETURN_ERROR_ON_MSG(biases->num_dimensions() > 1, "biases should be one dimensional");
     }

     // Checks performed when output is configured
     if(dst->total_size() != 0)
     {
         TensorShape output_shape = misc::shape_calculator::compute_conv3d_shape(src->tensor_shape(), weights->tensor_shape(), conv_info);

         DataType data_type = src->data_type();

         ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DIMENSIONS(dst->tensor_shape(), output_shape);
         ARM_COMPUTE_RETURN_ERROR_ON(dst->data_type() != data_type);
     }

     return Status{};
 }

 /** Reduce a vector to be a scalar by accumulating all lanes in the vector
  *
  * @param[in] v Vector to be reduced.
  *
  * @return the wrapped-around number.
  */
 auto vreduce(const float32x4_t &v)
 {
     auto v0    = wrapper::vgethigh(v);
     auto v1    = wrapper::vgetlow(v);
     auto v_out = wrapper::vadd(v0, v1);

     float a = wrapper::vgetlane(v_out, 0);
     float b = wrapper::vgetlane(v_out, 1);
     return a + b;
 }

 #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
 auto vreduce(const float16x8_t &v)
 {
     auto v0    = wrapper::vgethigh(v);
     auto v1    = wrapper::vgetlow(v);
     auto v_out = wrapper::vadd(v0, v1);

     float16_t a = wrapper::vgetlane(v_out, 0);
     float16_t b = wrapper::vgetlane(v_out, 1);
     float16_t c = wrapper::vgetlane(v_out, 2);
     float16_t d = wrapper::vgetlane(v_out, 3);
     return a + b + c + d;
 }
 #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
 }

 template <typename T>
 void CpuDirectConv3dKernel::convolve_ndhwc(const Window &window, const ITensor *src, const ITensor *weights, const ITensor *biases, ITensor *dst)
 {
     using vtype                                = wrapper::traits::neon_bitvector<T, wrapper::traits::BitWidth::W128>;
     using vector_type                          = typename vtype::type;
     using tag_type                             = typename vtype::tag_type;
     constexpr int num_elems_read_per_iteration = 16 / sizeof(T);

     // Scalar quantities (N D H W Cin)
     const int element_size   = src->info()->element_size();
     const int input_stride_w = src->info()->strides_in_bytes().y() / element_size;
     const int input_stride_h = src->info()->strides_in_bytes().z() / element_size;
     const int input_stride_d = src->info()->strides_in_bytes()[3] / element_size;
     const int input_stride_n = src->info()->strides_in_bytes()[4] / element_size;
     const int input_dim_w    = src->info()->dimension(1);
     const int input_dim_h    = src->info()->dimension(2);
     const int input_dim_d    = src->info()->dimension(3);

     // Kernel info (D H W Cin Cout)
     const unsigned int kernel_stride_w = weights->info()->strides_in_bytes()[2] / element_size;
     const unsigned int kernel_stride_h = weights->info()->strides_in_bytes()[3] / element_size;
     const unsigned int kernel_stride_d = weights->info()->strides_in_bytes()[4] / element_size;
     const int          kernel_dim_w    = weights->info()->dimension(2);
     const int          kernel_dim_h    = weights->info()->dimension(3);
     const int          kernel_dim_d    = weights->info()->dimension(4);

     // Convolution padding and stride
     const int conv_pad_top   = _conv_info.padding.top;
     const int conv_pad_left  = _conv_info.padding.left;
     const int conv_pad_front = _conv_info.padding.front;
     const int conv_stride_w  = _conv_info.stride.width;
     const int conv_stride_h  = _conv_info.stride.height;
     const int conv_stride_d  = _conv_info.stride.depth;

     // Setup input window for the output iterator
     Window window_out = window;
     window_out.set(Window::DimX, Window::Dimension(0, 1, 1));

     // Setup input window for the weights iterator
     Window window_w = calculate_max_window(*weights->info(), Steps());
     window_w.set(Window::DimY, Window::Dimension(0, 1, 1));
     window_w.set(Window::DimZ, Window::Dimension(0, 1, 1));
     window_w.set(Window::DimW, Window::Dimension(0, 1, 1));
     window_w.set(4, Window::Dimension(0, 1, 1));

     Iterator out(dst, window_out);
     Iterator wei(weights, window_w);

     const T *biases_ptr = nullptr;
     if(biases)
     {
         biases_ptr = reinterpret_cast<T *>(biases->buffer() + biases->info()->offset_first_element_in_bytes());
     }
     execute_window_loop(window_out, [&](const Coordinates & id)
     {
         // We are computing the theoretical input starting points
         const int in_w_start_t = static_cast<int>(id.y()) * conv_stride_w - conv_pad_left;
         const int in_h_start_t = static_cast<int>(id.z()) * conv_stride_h - conv_pad_top;
         const int in_d_start_t = static_cast<int>(id[3]) * conv_stride_d - conv_pad_front;
         const int in_w_end_t   = in_w_start_t + kernel_dim_w;
         const int in_h_end_t   = in_h_start_t + kernel_dim_h;
         const int in_d_end_t   = in_d_start_t + kernel_dim_d;

         // We are computing the valid initial and ending input points by checking the borders
         const int in_w_start = std::max(in_w_start_t, 0);
         const int in_h_start = std::max(in_h_start_t, 0);
         const int in_d_start = std::max(in_d_start_t, 0);
         const int in_w_end   = std::min(in_w_end_t, input_dim_w);
         const int in_h_end   = std::min(in_h_end_t, input_dim_h);
         const int in_d_end   = std::min(in_d_end_t, input_dim_d);

         // We use the input points to select the valid weight points to use
         const int wei_w_start = in_w_start - in_w_start_t;
         const int wei_h_start = in_h_start - in_h_start_t;
         const int wei_d_start = in_d_start - in_d_start_t;
         const int wei_w_end   = kernel_dim_w - (in_w_end_t - in_w_end);
         const int wei_h_end   = kernel_dim_h - (in_h_end_t - in_h_end);
         const int wei_d_end   = kernel_dim_d - (in_d_end_t - in_d_end);

         const int      index_c_out_end = weights->info()->dimension(0);
         const int      index_c_in_end  = weights->info()->dimension(1);
         const T *const in_ptr_start    = reinterpret_cast<const T *>(src->buffer() + src->info()->offset_first_element_in_bytes()) + id[4] * input_stride_n;

         execute_window_loop(window_w, [&](const Coordinates & id_w)
         {
             /*
             * This is the loop in the weights, and it goes along OFM (output feature map)
             */
             const auto weights_ptr_start = reinterpret_cast<const T *>(wei.ptr());
             T          out_temp          = static_cast<T>(0);
             T         *out_ptr           = reinterpret_cast<T *>(out.ptr());
             for(int index_wei_d = wei_d_start, index_in_d = in_d_start; index_wei_d < wei_d_end; ++index_wei_d, ++index_in_d)
             {
                 const auto in_ptr_d      = in_ptr_start + index_in_d * input_stride_d;
                 const auto weights_ptr_d = weights_ptr_start + index_wei_d * kernel_stride_d;
                 for(int index_wei_h = wei_h_start, index_in_h = in_h_start; index_wei_h < wei_h_end; ++index_wei_h, ++index_in_h)
                 {
                     const T *const in_ptr_row      = in_ptr_d + index_in_h * input_stride_h;
                     const T *const weights_ptr_row = weights_ptr_d + index_wei_h * kernel_stride_h;
                     for(int index_wei_w = wei_w_start, index_in_w = in_w_start; index_wei_w < wei_w_end; ++index_wei_w, ++index_in_w)
                     {
                         const T    *in_ptr_mover      = in_ptr_row + index_in_w * input_stride_w;
                         const T    *weights_ptr_mover = weights_ptr_row + index_wei_w * kernel_stride_w;
                         int         index_c_in        = 0;
                         vector_type out_temp_vec      = wrapper::vdup_n(static_cast<T>(0), tag_type());
                         vector_type w_vec             = wrapper::vdup_n(static_cast<T>(0), tag_type());
                         for(; index_c_in <= index_c_in_end - num_elems_read_per_iteration;
                             index_c_in += num_elems_read_per_iteration, in_ptr_mover += num_elems_read_per_iteration)
                         {
                             const auto src_vec = wrapper::vloadq(in_ptr_mover);
                             //Load Cin weights
                             for(unsigned int k = 0; k < num_elems_read_per_iteration; ++k, weights_ptr_mover += index_c_out_end)
                             {
                                 w_vec = wrapper::vsetlane(*weights_ptr_mover, w_vec, k);
                             }
                             out_temp_vec = wrapper::vmla(out_temp_vec, w_vec, src_vec);
                         }
                         out_temp += vreduce(out_temp_vec);
                         for(; index_c_in < index_c_in_end; ++index_c_in, ++in_ptr_mover, weights_ptr_mover += index_c_out_end)
                         {
                             const auto src_val = *(in_ptr_mover);
                             const auto w_val   = *(weights_ptr_mover);
                             out_temp += src_val * w_val;
                         }
                     }
                 }
             }
             *(reinterpret_cast<T *>(out_ptr + id_w[0])) = (biases) ? out_temp + biases_ptr[id_w[0]] : out_temp;
         },
         wei);
     },
     out);
 }

 void CpuDirectConv3dKernel::configure(const ITensorInfo *src, const ITensorInfo *weights, const ITensorInfo *biases, ITensorInfo *dst, const Conv3dInfo &conv_info)
 {
     ARM_COMPUTE_UNUSED(biases);
     ARM_COMPUTE_ERROR_ON_NULLPTR(src, weights, dst);

     _conv_info = conv_info;

     // Get convolved dimensions
     TensorShape output_shape = misc::shape_calculator::compute_conv3d_shape(src->tensor_shape(), weights->tensor_shape(), conv_info);

     DataType data_type = src->data_type();

     // Output auto inizialitation if not yet initialized
     auto_init_if_empty(*dst, output_shape, 1, data_type);

     // Perform validation step
     ARM_COMPUTE_ERROR_THROW_ON(validate_arguments(src, weights, biases, dst, conv_info));

     // Configure kernel window
     Window win = calculate_max_window(*dst, Steps());
     ICpuKernel::configure(win);
 }

 Status CpuDirectConv3dKernel::validate(const ITensorInfo *src, const ITensorInfo *weights, const ITensorInfo *biases, const ITensorInfo *dst, const Conv3dInfo &conv_info)
 {
     ARM_COMPUTE_RETURN_ON_ERROR(validate_arguments(src, weights, biases, dst, conv_info));

     return Status{};
 }

 void CpuDirectConv3dKernel::run_op(ITensorPack &tensors, const Window &window, const ThreadInfo &info)
 {
     ARM_COMPUTE_UNUSED(info);
     ARM_COMPUTE_ERROR_ON_UNCONFIGURED_KERNEL(this);
     ARM_COMPUTE_ERROR_ON_INVALID_SUBWINDOW(ICpuKernel::window(), window);

     auto src     = tensors.get_const_tensor(TensorType::ACL_SRC_0);
     auto weights = tensors.get_const_tensor(TensorType::ACL_SRC_1);
     auto biases  = tensors.get_const_tensor(TensorType::ACL_SRC_2);
     auto dst     = tensors.get_tensor(TensorType::ACL_DST);

     switch(src->info()->data_type())
     {
         case DataType::F32:
         {
             convolve_ndhwc<float>(window, src, weights, biases, dst);
             break;
         }
 #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
         case DataType::F16:
         {
             convolve_ndhwc<float16_t>(window, src, weights, biases, dst);
             break;
         }
 #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
         default:
             ARM_COMPUTE_ERROR("Data type not supported");
             break;
     }
 }

 const char *CpuDirectConv3dKernel::name() const
 {
     return "CpuDirectConv3dKernel";
 }
 } // namespace kernels
 } // namespace cpu
 } // namespace arm_compute
	/*
	* Copyright (c) 2021 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.
	*/
	#include "src/cpu/kernels/CpuDirectConv3dKernel.h"

	#include "src/core/NEON/kernels/detail/NEDirectConvolutionDetail.h"
	#include "src/core/NEON/wrapper/wrapper.h"

	#include "arm_compute/core/Error.h"
	#include "arm_compute/core/Helpers.h"
	#include "arm_compute/core/IAccessWindow.h"
	#include "arm_compute/core/ITensor.h"
	#include "arm_compute/core/Types.h"
	#include "arm_compute/core/Utils.h"
	#include "arm_compute/core/Validate.h"
	#include "arm_compute/core/utils/misc/ShapeCalculator.h"
	#include "src/core/CPP/Validate.h"
	#include "src/core/helpers/AutoConfiguration.h"
	#include "src/core/helpers/WindowHelpers.h"

	#include <algorithm>

	using namespace arm_compute::detail;

	namespace arm_compute
	{
	namespace cpu
	{
	namespace kernels
	{
	namespace
	{
	Status validate_arguments(const ITensorInfo src, const ITensorInfo weights, const ITensorInfo biases, const ITensorInfo dst, const Conv3dInfo &conv_info)
	{
	ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(src, weights, dst);
	ARM_COMPUTE_RETURN_ERROR_ON(src->data_layout() != DataLayout::NDHWC);
	ARM_COMPUTE_RETURN_ERROR_ON_CPU_F16_UNSUPPORTED(src);
	ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(src, 1, DataType::F16, DataType::F32);
	ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(src, weights);

	const DataLayout data_layout = src->data_layout();
	const int channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL);

	// Weight layout is D, H, W, Cin, Cout
	ARM_COMPUTE_RETURN_ERROR_ON(weights->num_dimensions() > 5);
	ARM_COMPUTE_RETURN_ERROR_ON(weights->dimension(1) != src->dimension(channel_idx));

	if(biases != nullptr)
	{
	ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(weights, biases);
	ARM_COMPUTE_RETURN_ERROR_ON_MSG(biases->dimension(0) != weights->dimension(0),
	"biases size and number of output feature maps should match");
	ARM_COMPUTE_RETURN_ERROR_ON_MSG(biases->num_dimensions() > 1, "biases should be one dimensional");
	}

	// Checks performed when output is configured
	if(dst->total_size() != 0)
	{
	TensorShape output_shape = misc::shape_calculator::compute_conv3d_shape(src->tensor_shape(), weights->tensor_shape(), conv_info);

	DataType data_type = src->data_type();

	ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DIMENSIONS(dst->tensor_shape(), output_shape);
	ARM_COMPUTE_RETURN_ERROR_ON(dst->data_type() != data_type);
	}

	return Status{};
	}

	/** Reduce a vector to be a scalar by accumulating all lanes in the vector
	*
	* @param[in] v Vector to be reduced.
	*
	* @return the wrapped-around number.
	*/
	auto vreduce(const float32x4_t &v)
	{
	auto v0 = wrapper::vgethigh(v);
	auto v1 = wrapper::vgetlow(v);
	auto v_out = wrapper::vadd(v0, v1);

	float a = wrapper::vgetlane(v_out, 0);
	float b = wrapper::vgetlane(v_out, 1);
	return a + b;
	}

	#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
	auto vreduce(const float16x8_t &v)
	{
	auto v0 = wrapper::vgethigh(v);
	auto v1 = wrapper::vgetlow(v);
	auto v_out = wrapper::vadd(v0, v1);

	float16_t a = wrapper::vgetlane(v_out, 0);
	float16_t b = wrapper::vgetlane(v_out, 1);
	float16_t c = wrapper::vgetlane(v_out, 2);
	float16_t d = wrapper::vgetlane(v_out, 3);
	return a + b + c + d;
	}
	#endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
	}

	template <typename T>
	void CpuDirectConv3dKernel::convolve_ndhwc(const Window &window, const ITensor src, const ITensor weights, const ITensor biases, ITensor dst)
	{
	using vtype = wrapper::traits::neon_bitvector<T, wrapper::traits::BitWidth::W128>;
	using vector_type = typename vtype::type;
	using tag_type = typename vtype::tag_type;
	constexpr int num_elems_read_per_iteration = 16 / sizeof(T);

	// Scalar quantities (N D H W Cin)
	const int element_size = src->info()->element_size();
	const int input_stride_w = src->info()->strides_in_bytes().y() / element_size;
	const int input_stride_h = src->info()->strides_in_bytes().z() / element_size;
	const int input_stride_d = src->info()->strides_in_bytes()[3] / element_size;
	const int input_stride_n = src->info()->strides_in_bytes()[4] / element_size;
	const int input_dim_w = src->info()->dimension(1);
	const int input_dim_h = src->info()->dimension(2);
	const int input_dim_d = src->info()->dimension(3);

	// Kernel info (D H W Cin Cout)
	const unsigned int kernel_stride_w = weights->info()->strides_in_bytes()[2] / element_size;
	const unsigned int kernel_stride_h = weights->info()->strides_in_bytes()[3] / element_size;
	const unsigned int kernel_stride_d = weights->info()->strides_in_bytes()[4] / element_size;
	const int kernel_dim_w = weights->info()->dimension(2);
	const int kernel_dim_h = weights->info()->dimension(3);
	const int kernel_dim_d = weights->info()->dimension(4);

	// Convolution padding and stride
	const int conv_pad_top = _conv_info.padding.top;
	const int conv_pad_left = _conv_info.padding.left;
	const int conv_pad_front = _conv_info.padding.front;
	const int conv_stride_w = _conv_info.stride.width;
	const int conv_stride_h = _conv_info.stride.height;
	const int conv_stride_d = _conv_info.stride.depth;

	// Setup input window for the output iterator
	Window window_out = window;
	window_out.set(Window::DimX, Window::Dimension(0, 1, 1));

	// Setup input window for the weights iterator
	Window window_w = calculate_max_window(*weights->info(), Steps());
	window_w.set(Window::DimY, Window::Dimension(0, 1, 1));
	window_w.set(Window::DimZ, Window::Dimension(0, 1, 1));
	window_w.set(Window::DimW, Window::Dimension(0, 1, 1));
	window_w.set(4, Window::Dimension(0, 1, 1));

	Iterator out(dst, window_out);
	Iterator wei(weights, window_w);

	const T *biases_ptr = nullptr;
	if(biases)
	{
	biases_ptr = reinterpret_cast<T *>(biases->buffer() + biases->info()->offset_first_element_in_bytes());
	}
	execute_window_loop(window_out, [&](const Coordinates & id)
	{
	// We are computing the theoretical input starting points
	const int in_w_start_t = static_cast<int>(id.y()) * conv_stride_w - conv_pad_left;
	const int in_h_start_t = static_cast<int>(id.z()) * conv_stride_h - conv_pad_top;
	const int in_d_start_t = static_cast<int>(id[3]) * conv_stride_d - conv_pad_front;
	const int in_w_end_t = in_w_start_t + kernel_dim_w;
	const int in_h_end_t = in_h_start_t + kernel_dim_h;
	const int in_d_end_t = in_d_start_t + kernel_dim_d;

	// We are computing the valid initial and ending input points by checking the borders
	const int in_w_start = std::max(in_w_start_t, 0);
	const int in_h_start = std::max(in_h_start_t, 0);
	const int in_d_start = std::max(in_d_start_t, 0);
	const int in_w_end = std::min(in_w_end_t, input_dim_w);
	const int in_h_end = std::min(in_h_end_t, input_dim_h);
	const int in_d_end = std::min(in_d_end_t, input_dim_d);

	// We use the input points to select the valid weight points to use
	const int wei_w_start = in_w_start - in_w_start_t;
	const int wei_h_start = in_h_start - in_h_start_t;
	const int wei_d_start = in_d_start - in_d_start_t;
	const int wei_w_end = kernel_dim_w - (in_w_end_t - in_w_end);
	const int wei_h_end = kernel_dim_h - (in_h_end_t - in_h_end);
	const int wei_d_end = kernel_dim_d - (in_d_end_t - in_d_end);

	const int index_c_out_end = weights->info()->dimension(0);
	const int index_c_in_end = weights->info()->dimension(1);
	const T const in_ptr_start = reinterpret_cast<const T >(src->buffer() + src->info()->offset_first_element_in_bytes()) + id[4] * input_stride_n;

	execute_window_loop(window_w, [&](const Coordinates & id_w)
	{
	/*
	* This is the loop in the weights, and it goes along OFM (output feature map)
	*/
	const auto weights_ptr_start = reinterpret_cast<const T *>(wei.ptr());
	T out_temp = static_cast<T>(0);
	T out_ptr = reinterpret_cast<T >(out.ptr());
	for(int index_wei_d = wei_d_start, index_in_d = in_d_start; index_wei_d < wei_d_end; ++index_wei_d, ++index_in_d)
	{
	const auto in_ptr_d = in_ptr_start + index_in_d * input_stride_d;
	const auto weights_ptr_d = weights_ptr_start + index_wei_d * kernel_stride_d;
	for(int index_wei_h = wei_h_start, index_in_h = in_h_start; index_wei_h < wei_h_end; ++index_wei_h, ++index_in_h)
	{
	const T const in_ptr_row = in_ptr_d + index_in_h input_stride_h;
	const T const weights_ptr_row = weights_ptr_d + index_wei_h kernel_stride_h;
	for(int index_wei_w = wei_w_start, index_in_w = in_w_start; index_wei_w < wei_w_end; ++index_wei_w, ++index_in_w)
	{
	const T in_ptr_mover = in_ptr_row + index_in_w input_stride_w;
	const T weights_ptr_mover = weights_ptr_row + index_wei_w kernel_stride_w;
	int index_c_in = 0;
	vector_type out_temp_vec = wrapper::vdup_n(static_cast<T>(0), tag_type());
	vector_type w_vec = wrapper::vdup_n(static_cast<T>(0), tag_type());
	for(; index_c_in <= index_c_in_end - num_elems_read_per_iteration;
	index_c_in += num_elems_read_per_iteration, in_ptr_mover += num_elems_read_per_iteration)
	{
	const auto src_vec = wrapper::vloadq(in_ptr_mover);
	//Load Cin weights
	for(unsigned int k = 0; k < num_elems_read_per_iteration; ++k, weights_ptr_mover += index_c_out_end)
	{
	w_vec = wrapper::vsetlane(*weights_ptr_mover, w_vec, k);
	}
	out_temp_vec = wrapper::vmla(out_temp_vec, w_vec, src_vec);
	}
	out_temp += vreduce(out_temp_vec);
	for(; index_c_in < index_c_in_end; ++index_c_in, ++in_ptr_mover, weights_ptr_mover += index_c_out_end)
	{
	const auto src_val = *(in_ptr_mover);
	const auto w_val = *(weights_ptr_mover);
	out_temp += src_val * w_val;
	}
	}
	}
	}
	(reinterpret_cast<T >(out_ptr + id_w[0])) = (biases) ? out_temp + biases_ptr[id_w[0]] : out_temp;
	},
	wei);
	},
	out);
	}

	void CpuDirectConv3dKernel::configure(const ITensorInfo src, const ITensorInfo weights, const ITensorInfo biases, ITensorInfo dst, const Conv3dInfo &conv_info)
	{
	ARM_COMPUTE_UNUSED(biases);
	ARM_COMPUTE_ERROR_ON_NULLPTR(src, weights, dst);

	_conv_info = conv_info;

	// Get convolved dimensions
	TensorShape output_shape = misc::shape_calculator::compute_conv3d_shape(src->tensor_shape(), weights->tensor_shape(), conv_info);

	DataType data_type = src->data_type();

	// Output auto inizialitation if not yet initialized
	auto_init_if_empty(*dst, output_shape, 1, data_type);

	// Perform validation step
	ARM_COMPUTE_ERROR_THROW_ON(validate_arguments(src, weights, biases, dst, conv_info));

	// Configure kernel window
	Window win = calculate_max_window(*dst, Steps());
	ICpuKernel::configure(win);
	}

	Status CpuDirectConv3dKernel::validate(const ITensorInfo src, const ITensorInfo weights, const ITensorInfo biases, const ITensorInfo dst, const Conv3dInfo &conv_info)
	{
	ARM_COMPUTE_RETURN_ON_ERROR(validate_arguments(src, weights, biases, dst, conv_info));

	return Status{};
	}

	void CpuDirectConv3dKernel::run_op(ITensorPack &tensors, const Window &window, const ThreadInfo &info)
	{
	ARM_COMPUTE_UNUSED(info);
	ARM_COMPUTE_ERROR_ON_UNCONFIGURED_KERNEL(this);
	ARM_COMPUTE_ERROR_ON_INVALID_SUBWINDOW(ICpuKernel::window(), window);

	auto src = tensors.get_const_tensor(TensorType::ACL_SRC_0);
	auto weights = tensors.get_const_tensor(TensorType::ACL_SRC_1);
	auto biases = tensors.get_const_tensor(TensorType::ACL_SRC_2);
	auto dst = tensors.get_tensor(TensorType::ACL_DST);

	switch(src->info()->data_type())
	{
	case DataType::F32:
	{
	convolve_ndhwc<float>(window, src, weights, biases, dst);
	break;
	}
	#ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
	case DataType::F16:
	{
	convolve_ndhwc<float16_t>(window, src, weights, biases, dst);
	break;
	}
	#endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC
	default:
	ARM_COMPUTE_ERROR("Data type not supported");
	break;
	}
	}

	const char *CpuDirectConv3dKernel::name() const
	{
	return "CpuDirectConv3dKernel";
	}
	} // namespace kernels
	} // namespace cpu
	} // namespace arm_compute