/* * Copyright (c) 2017-2022 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_MISC_SHAPE_CALCULATOR_H #define ARM_COMPUTE_MISC_SHAPE_CALCULATOR_H #include "arm_compute/core/Helpers.h" #include "arm_compute/core/ITensorInfo.h" #include "arm_compute/core/KernelDescriptors.h" #include "arm_compute/core/Utils.h" #include "arm_compute/runtime/FunctionDescriptors.h" #include "arm_compute/core/utils/helpers/tensor_transform.h" #include namespace arm_compute { namespace misc { namespace shape_calculator { /** Calculate the output tensor shape for the reduce mean operation * * @param[in] input Input tensor shape * @param[in] reduction_axis Reduction axis * @param[in] keep_dims Flag to indicate if dimensions are kept * * @return the calculated shape */ inline TensorShape calculate_reduce_mean_shape(ITensorInfo *input, const Coordinates &reduction_axis, bool keep_dims) { const int reduction_ops = reduction_axis.num_dimensions(); Coordinates axis_local = reduction_axis; const int input_dims = input->num_dimensions(); convert_negative_axis(axis_local, input_dims); TensorShape out_shape = input->tensor_shape(); // Configure reshape layer if we want to drop the dimensions if(!keep_dims) { // We have to sort the reduction axis vectors in order for remove_dimension // to work properly std::sort(axis_local.begin(), axis_local.begin() + reduction_ops); for(int i = 0; i < reduction_ops; ++i) { out_shape.remove_dimension(axis_local[i] - i); } return out_shape; } else { for(int i = 0; i < reduction_ops; ++i) { out_shape.set(axis_local[i], 1); } return out_shape; } } /** Calculate the output tensor shape of a vector input given the convolution dimensions * * @param[in] input Input tensor shape * @param[in] conv_w Convolution width * @param[in] conv_h Convolution height * @param[in] data_layout Data layout * * @return the calculated shape */ inline TensorShape compute_vector_to_tensor_output_shape(const TensorShape &input, size_t conv_w, size_t conv_h, const DataLayout &data_layout) { const size_t idx_w = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const size_t idx_h = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const size_t idx_c = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); TensorShape output_shape(input); output_shape.set(idx_w, conv_w); output_shape.set(idx_h, conv_h); output_shape.set(idx_c, input.x() / (conv_w * conv_h)); return output_shape; } /** Calculate the permuted shape of an input given a permutation vector * * @param[in] input Input tensor info * @param[in] perm Permutation vector * * @return the calculated shape */ inline TensorShape compute_permutation_output_shape(const ITensorInfo &input, const PermutationVector &perm) { TensorShape output_shape = input.tensor_shape(); permute(output_shape, perm); return output_shape; } /** Calculate the output shape of the reorg layer given a stride * * @param[in] input Input tensor info * @param[in] stride Stride * * @return the calculated shape */ inline TensorShape compute_reorg_output_shape(const ITensorInfo &input, int32_t stride) { const size_t idx_width = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH); const size_t idx_height = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::HEIGHT); const size_t idx_channel = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::CHANNEL); ARM_COMPUTE_ERROR_ON(stride <= 0); ARM_COMPUTE_ERROR_ON_MSG((input.tensor_shape()[idx_width] % stride != 0), "The width of the input tensor must be a multiple of stride"); ARM_COMPUTE_ERROR_ON_MSG((input.tensor_shape()[idx_height] % stride != 0), "The height of the input tensor must be a multiple of stride"); TensorShape output_shape{ input.tensor_shape() }; output_shape.set(idx_width, output_shape[idx_width] / stride); output_shape.set(idx_height, output_shape[idx_height] / stride); output_shape.set(idx_channel, output_shape[idx_channel] * stride * stride); return output_shape; } /** Calculate the reshaped shape of the weights * * @param[in] weights Weights tensor info * @param[in] has_bias (Optional) Set to true if there is bias * @param[in] num_groups (Optional) Number of groups * * @return the calculated shape of the reshaped weights */ inline TensorShape compute_weights_reshaped_shape(const ITensorInfo &weights, bool has_bias = false, unsigned int num_groups = 1) { // Number of groups greater than one are only supported for NCHW data layout, and the number of weights must be a multiple of it. ARM_COMPUTE_ERROR_ON(num_groups == 0); ARM_COMPUTE_ERROR_ON(weights.data_layout() == DataLayout::NHWC && num_groups > 1); ARM_COMPUTE_ERROR_ON((weights.dimension(3) % num_groups) != 0); // Calculate output shape TensorShape weights_reshaped{ weights.tensor_shape() }; weights_reshaped.set(3, weights_reshaped[3] / num_groups); weights_reshaped.collapse(3); const size_t tmp_dim = weights_reshaped[0]; weights_reshaped.set(0, weights_reshaped[1]); weights_reshaped.set(1, tmp_dim + (has_bias ? 1 : 0)); if(weights.num_dimensions() < 5) { weights_reshaped.set(2, num_groups); } return weights_reshaped; } /** Calculate the Left Hand Side matrix reshaped shape * * @param[in] a Input tensor info * @param[in] lhs_info Left Hand Side matrix information * @param[in] reinterpret_input_as_3d (Optional) Set to true if the input need to be interpreted as 3d * * @return the calculated shape */ inline TensorShape compute_lhs_reshaped_shape(const ITensorInfo &a, const GEMMLHSMatrixInfo &lhs_info, bool reinterpret_input_as_3d = false) { ARM_COMPUTE_ERROR_ON(lhs_info.m0 == 0); ARM_COMPUTE_ERROR_ON(lhs_info.k0 == 0); ARM_COMPUTE_ERROR_ON(lhs_info.v0 == 0); // Input width/height const unsigned int input_width = a.dimension(0); const unsigned int input_height = reinterpret_input_as_3d ? a.dimension(1) * a.dimension(2) : a.dimension(1); // Number of horizontal/vertical blocks in the input tensor const unsigned int num_horiz_blocks = std::ceil(input_width / static_cast(lhs_info.k0)); const unsigned int num_vert_blocks = std::ceil(input_height / static_cast(lhs_info.m0)); // Block size const unsigned int block_size = lhs_info.m0 * lhs_info.k0; // Output width/height const unsigned int output_width = block_size * num_horiz_blocks * lhs_info.v0; const unsigned int output_height = std::ceil(num_vert_blocks / static_cast(lhs_info.v0)); TensorShape lhs_shape{ a.tensor_shape() }; lhs_shape.set(0, output_width); lhs_shape.set(1, output_height); if((reinterpret_input_as_3d) && (lhs_shape.num_dimensions() > 2)) { // When the data format is NHWC and the shapes are Nx1x1 // the tensor shape num_dimensions is automatically set to 1 instead of 3. // To avoid failures by removing a dimension that doesn't exist // check if the number of dimensions is greater than 2. lhs_shape.remove_dimension(2); } return lhs_shape; } /** Calculate the Right Hand Side matrix reshaped shape * * @param[in] a Input tensor info * @param[in] rhs_info Right Hand Side matrix information * * @return the calculated shape */ inline TensorShape compute_rhs_reshaped_shape(const ITensorInfo &a, const GEMMRHSMatrixInfo &rhs_info) { ARM_COMPUTE_ERROR_ON(rhs_info.n0 == 0); ARM_COMPUTE_ERROR_ON(rhs_info.k0 == 0); ARM_COMPUTE_ERROR_ON(rhs_info.h0 == 0); // Input width/height const unsigned int input_width = a.dimension(0); const unsigned int input_height = a.dimension(1); // Number of horizontal/vertical blocks in the input tensor const unsigned int num_horiz_blocks = std::ceil(input_width / static_cast(rhs_info.n0)); const unsigned int num_vert_blocks = std::ceil(input_height / static_cast(rhs_info.k0)); // Block size const unsigned int block_size = rhs_info.n0 * rhs_info.k0; // Output width/height const unsigned int output_width = block_size * num_vert_blocks * rhs_info.h0; const unsigned int output_height = std::ceil(num_horiz_blocks / static_cast(rhs_info.h0)); TensorShape rhs_shape{ a.tensor_shape() }; rhs_shape.set(0, output_width); rhs_shape.set(1, output_height); return rhs_shape; } /** Calculate the interleaved shape of an input tensor * * @param[in] a Input tensor info * @param[in] mult_interleave4x4_height (Optional) Interleave4x4 height * @param[in] reinterpret_input_as_3d (Optional) Set to true if the input need to be interpreted as 3d * * @return the calculated shape */ inline TensorShape compute_interleaved_shape(const ITensorInfo &a, int mult_interleave4x4_height = 1, bool reinterpret_input_as_3d = false) { // The interleaved output matrix will have the following shape: [ a_height * W, ceil(a_width / W) ] where W = 4 * mult_interleave4x4_height ARM_COMPUTE_ERROR_ON(mult_interleave4x4_height < 1); const int interleave_width = 4 * mult_interleave4x4_height; TensorShape shape_interleaved_a{ a.tensor_shape() }; shape_interleaved_a.set(0, a.dimension(0) * interleave_width); if(reinterpret_input_as_3d) { const int M = a.dimension(1) * a.dimension(2); const int height = std::ceil(M / static_cast(interleave_width)); shape_interleaved_a.set(1, height); // When the data format is NHWC and the shapes are Nx1x1 // the tensor shape num_dimensions is automatically set to 1 instead of 3. // To avoid failures by removing a dimension that doesn't exist // check if the number of dimensions is greater than 2. if(shape_interleaved_a.num_dimensions() > 2) { shape_interleaved_a.remove_dimension(2); } } else { shape_interleaved_a.set(1, std::ceil(a.dimension(1) / static_cast(interleave_width))); } return shape_interleaved_a; } /** Calculate the transposed 1xW shape * * @param[in] b Input tensor info * * @return the calculated shape */ inline TensorShape compute_transpose1xW_shape(const ITensorInfo &b) { // The transpose1xW output matrix will have the following shape: [ b_height * 16, ceil(b_width / 16.0f) ] TensorShape shape_transposed1xW_b{ b.tensor_shape() }; shape_transposed1xW_b.set(0, b.dimension(1) * 16); shape_transposed1xW_b.set(1, std::ceil(b.dimension(0) / 16.f)); return shape_transposed1xW_b; } /** Calculate the transposed 1xW width element shape * * @param[in] b Input tensor info * @param[in] mult_transpose1xW_width (Optional) Transpose1xW width * * @return the calculated shape */ inline TensorShape compute_transpose1xW_with_element_size_shape(const ITensorInfo &b, int mult_transpose1xW_width = 1) { // Note: mult_transpose1xW_width expresses the number of chunks with size 1x(W) we want to store on the same row // The transpose1xW output matrix will have the following shape: // [ b_height * W, ceil(b_width / W) ] where W = (16 / element size of the tensor) * mult_transpose1xW_width ARM_COMPUTE_ERROR_ON(mult_transpose1xW_width < 1); TensorShape shape_transposed1xW_b{ b.tensor_shape() }; const size_t transpose_width = (16 / b.element_size()) * mult_transpose1xW_width; shape_transposed1xW_b.set(0, b.dimension(1) * transpose_width); shape_transposed1xW_b.set(1, static_cast(std::ceil(b.dimension(0) / static_cast(transpose_width)))); return shape_transposed1xW_b; } /** Calculate the reductionA shape used in GEMMLowp * * @param[in] b Input tensor info * * @return the calculated shape */ inline TensorShape compute_reductionA_shape(const ITensorInfo &b) { TensorShape shape_vector_sum_col{ b.tensor_shape() }; if(shape_vector_sum_col.num_dimensions() > 1) { shape_vector_sum_col.remove_dimension(1); } return shape_vector_sum_col; } /** Calculate the reductionB shape used in GEMMLowp * * @param[in] a Input tensor info * * @return the calculated shape */ inline TensorShape compute_reductionB_shape(const ITensorInfo &a) { TensorShape shape_vector_sum_row{ a.tensor_shape() }; shape_vector_sum_row.set(Window::DimX, a.dimension(1)); if(shape_vector_sum_row.num_dimensions() > 1) { shape_vector_sum_row.remove_dimension(1); } return shape_vector_sum_row; } /** Calculate the Col2Im shape * * @param[in] input Input tensor info * @param[in] convolved_dims Convolved dimensions * @param[in] batch_size_on_z True if batch size is on z axis * @param[in] num_groups (Optional) Number of groups when performing a grouped convolution * * @return the calculated shape */ inline TensorShape compute_col2im_shape(const ITensorInfo &input, const Size2D &convolved_dims, bool batch_size_on_z, unsigned int num_groups = 1) { ARM_COMPUTE_ERROR_ON(num_groups == 0); ARM_COMPUTE_ERROR_ON(input.tensor_shape()[1] != (convolved_dims.area())); ARM_COMPUTE_ERROR_ON((num_groups > 1) && input.tensor_shape()[2] != num_groups); const DataLayout data_layout = input.data_layout(); const int width_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int height_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); TensorShape col2im_shape{ input.tensor_shape() }; // If batches start on 3rd dimension shift dimensions right by 1 to retain upper tensor shape, // as first three will be override by H,W,C data if(batch_size_on_z && num_groups == 1) { col2im_shape.shift_right(1); } col2im_shape.set(width_idx, convolved_dims.width); col2im_shape.set(height_idx, convolved_dims.height); col2im_shape.set(channel_idx, input.tensor_shape()[0] * num_groups); return col2im_shape; } /** Calculate the transposed shape of a tensor * * @param[in] input Input tensor info * * @return the calculated shape */ inline TensorShape compute_transposed_shape(const ITensorInfo &input) { TensorShape shape_transposed{ input.tensor_shape() }; shape_transposed.set(0, input.dimension(1)); shape_transposed.set(1, input.dimension(0)); return shape_transposed; } /** Calculate the depthwise convolution output shape of a tensor * * @param[in] input Input tensor info * @param[in] weights Weights tensor info * @param[in] info Convolution info * * @return the calculated shape */ inline TensorShape compute_depthwise_convolution_shape(const ITensorInfo &input, const ITensorInfo &weights, const ConvolutionInfo &info) { const TensorShape input_shape{ input.tensor_shape() }; const TensorShape weights_shape{ weights.tensor_shape() }; const DataLayout data_layout = input.data_layout(); const int width_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int height_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); const DataLayout weights_data_layout = weights.data_layout(); const int weights_width_idx = get_data_layout_dimension_index(weights_data_layout, DataLayoutDimension::WIDTH); const int weights_height_idx = get_data_layout_dimension_index(weights_data_layout, DataLayoutDimension::HEIGHT); unsigned int output_width = 0; unsigned int output_height = 0; std::tie(output_width, output_height) = scaled_dimensions(input_shape[width_idx], input_shape[height_idx], weights_shape[weights_width_idx], weights_shape[weights_height_idx], info.pad_stride_info, info.dilation); TensorShape output_shape{ input_shape }; output_shape.set(width_idx, output_width); output_shape.set(height_idx, output_height); output_shape.set(channel_idx, input_shape[channel_idx] * info.depth_multiplier); return output_shape; } /** Calculate the upsampled output shape used for deconvolution * * @param[in] input Input tensor info * @param[in] weights Weights tensor shape * @param[in] sx Stride on x axis * @param[in] sy Stride on y axis * @param[in] out_dims Output shape dimensions * @param[in] padx Padding on x axis * @param[in] pady Padding on y axis * * @return the calculated shape */ inline TensorShape compute_deconvolution_upsampled_shape(const ITensorInfo &input, const ITensorInfo &weights, unsigned int sx, unsigned int sy, std::pair &out_dims, uint32_t &padx, uint32_t &pady) { const DataLayout data_layout = input.data_layout(); const size_t idx_w = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const size_t idx_h = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); // Find the upsampled dimensions unsigned int out_x = (input.dimension(idx_w) - 1) * sx + 1; unsigned int out_y = (input.dimension(idx_h) - 1) * sy + 1; // Find the padding needed for the convolution with stride 1 in order to match output shape padx = out_dims.first - (out_x - weights.dimension(idx_w) + 1); pady = out_dims.second - (out_y - weights.dimension(idx_h) + 1); out_x += padx; out_y += pady; TensorShape scale_out_shape(input.tensor_shape()); scale_out_shape.set(idx_w, out_x); scale_out_shape.set(idx_h, out_y); return scale_out_shape; } /** Calculate the output shape of the deconvolution layer * * @param[in] out_dims Output x and y shape dimensions * @param[in] input Input tensor info * @param[in] weights Weights tensor shape * * @return the calculated shape */ inline TensorShape compute_deconvolution_output_shape(const std::pair &out_dims, const ITensorInfo &input, const ITensorInfo &weights) { const TensorShape input_shape{ input.tensor_shape() }; const TensorShape weights_shape{ weights.tensor_shape() }; const DataLayout data_layout = input.data_layout(); const int width_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int height_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); const int batch_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::BATCHES); TensorShape out_shape{ input_shape }; out_shape.set(width_idx, out_dims.first); out_shape.set(height_idx, out_dims.second); out_shape.set(channel_idx, weights_shape[batch_idx]); return out_shape; } /** Calculate the im2col output shape of a tensor * * @param[in] input Input tensor info * @param[in] kernel_dims The kernel dimensions (width and height). * @param[in] conv_info Contains padding and stride information * @param[in] has_bias In case biases are provided expands the matrix with 1 * @param[in] dilation Dilation, in elements, across x and y * @param[in] batch_size_on_z True if batch size is on z axis * @param[in] num_groups (Optional) Number of groups when performing a grouped convolution * * @return the calculated shape */ inline TensorShape compute_im2col_conv_shape(const ITensorInfo *input, const Size2D &kernel_dims, const PadStrideInfo &conv_info, bool has_bias, const Size2D &dilation, bool batch_size_on_z, unsigned int num_groups = 1) { // The output shape will be the 3D shape [ out_channels * kernel_area, num_elems_per_out_channel, batches ] if batch_size_on_z == true // or the 4D shape [ out_channels * kernel_area / num_groups, num_elems_per_out_channel, num_groups, batches ] if batch_size_on_z == false ARM_COMPUTE_ERROR_ON(num_groups == 0); ARM_COMPUTE_ERROR_ON(num_groups > 1 && input->data_layout() != DataLayout::NCHW); ARM_COMPUTE_ERROR_ON(num_groups > 1 && batch_size_on_z); TensorShape output_shape{ input->tensor_shape() }; const DataLayout data_layout = input->data_layout(); const int width_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int height_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int channel_idx = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); std::pair out_dims = scaled_dimensions(output_shape[width_idx], output_shape[height_idx], kernel_dims.width, kernel_dims.height, conv_info, dilation); output_shape.set(0, (output_shape[channel_idx] / num_groups * kernel_dims.area() + (has_bias ? 1 : 0))); // NOLINT output_shape.set(1, (out_dims.first * out_dims.second)); if(batch_size_on_z && output_shape.num_dimensions() >= 3) { output_shape.remove_dimension(2); } else { output_shape.set(2, num_groups); } return output_shape; } /** Calculate the flattened output shape of a tensor * * @param[in] input Input tensor info * * @return the calculated shape */ inline TensorShape compute_flatten_shape(const ITensorInfo *input) { // The output shape will be the flatten version of the input (i.e. [ width * height * channels, num_batches, ... ] ). Used for FlattenLayer and FullyConnectedLayer. TensorShape output_shape{ input->tensor_shape() }; output_shape.collapse(3); return output_shape; } /** Calculate the softmax output shape of a tensor * * @param[in] input Input tensor info * @param[in] axis (Optional) Softmax axis * * @return the calculated shape */ inline TensorShape compute_softmax_shape(const ITensorInfo *input, size_t axis = 1) { // The output shape will be a 2D version of the input. For instance: // - [x,y,z] and axis 1 will return [x, y*z] // - [x,y,z,w] and axis 2 will return [x*y, w*z] // - [x,y,z,w] and axis 3 will return [x*y*z, w] TensorShape shape2D = input->tensor_shape(); if(axis < input->num_dimensions()) { // Collapse from axis onward (this changes the shape) shape2D.collapse_from(axis); // Collapse the rest (collapse is inclusive) shape2D.collapse(shape2D.num_dimensions() - 1); } else { // Collapse everything shape2D.collapse(shape2D.num_dimensions()); } if(axis == 0) { // If axis is zero the first dim should be one. Since // collapse is an inclusive operation we need to shift shape2D.shift_right(1); } return shape2D; } /** Calculate the winograd filter transform shape * * @param[in] input Input tensor info * @param[in] winograd_info Winograd information * * @return the calculated shape */ inline TensorShape compute_winograd_filter_transform_shape(const ITensorInfo &input, const WinogradInfo &winograd_info) { TensorShape tensor_shape{ input.tensor_shape() }; const Size2D kernel_size = winograd_info.kernel_size; const Size2D output_tile_size = winograd_info.output_tile_size; const Size2D input_tile_size = Size2D(output_tile_size.width + kernel_size.width - 1, output_tile_size.height + kernel_size.height - 1); tensor_shape.remove_dimension(get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH)); tensor_shape.set(Window::DimX, input.dimension(3)); tensor_shape.set(Window::DimY, input.dimension(get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::CHANNEL))); tensor_shape.set(Window::DimZ, input_tile_size.area()); return tensor_shape; } /** Calculate the winograd input transform shape * * @param[in] input Input tensor info * @param[in] winograd_info Winograd information * * @return the calculated shape */ inline TensorShape compute_winograd_input_transform_shape(const ITensorInfo &input, const WinogradInfo &winograd_info) { const PadStrideInfo conv_info = winograd_info.convolution_info; const Size2D kernel_size = winograd_info.kernel_size; const Size2D output_tile_size = winograd_info.output_tile_size; const Size2D input_tile_size = Size2D(output_tile_size.width + kernel_size.width - 1, output_tile_size.height + kernel_size.height - 1); const size_t idx_w = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH); const size_t idx_h = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::HEIGHT); const size_t idx_c = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::CHANNEL); // Compute the number of output tiles along the x and y direction of size "output_tile_size" const Size2D num_tiles = compute_winograd_convolution_tiles(Size2D(input.tensor_shape()[idx_w], input.tensor_shape()[idx_h]), kernel_size, output_tile_size, conv_info); const unsigned int width = input.tensor_shape()[idx_c]; const unsigned int height = num_tiles.area(); const unsigned int depth = input_tile_size.area(); TensorShape output_shape{ input.tensor_shape() }; output_shape.set(0, width); output_shape.set(1, height); output_shape.set(2, depth); return output_shape; } /** Calculate the winograd output transform shape * * @param[in] input Input tensor info * @param[in] winograd_info Winograd information * * @return the calculated shape */ inline TensorShape compute_winograd_output_transform_shape(const ITensorInfo &input, const WinogradInfo &winograd_info) { const PadStrideInfo conv_info = winograd_info.convolution_info; const Size2D kernel_size = winograd_info.kernel_size; const Size2D input_dimensions = winograd_info.input_dimensions; const DataLayout data_layout = winograd_info.output_data_layout; // Compute output shape unsigned int output_width = 0; unsigned int output_height = 0; std::tie(output_width, output_height) = scaled_dimensions(input_dimensions.width, input_dimensions.height, kernel_size.width, kernel_size.height, conv_info); TensorShape tensor_shape{ input.tensor_shape() }; // Output dimension const unsigned int out_w = output_width; const unsigned int out_h = output_height; const unsigned int out_c = input.dimension(0); tensor_shape.set(get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH), out_w); tensor_shape.set(get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT), out_h); tensor_shape.set(get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL), out_c); return tensor_shape; } /** Calculate the deep convolution shape output shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] input_data_layout Input data layout * @param[in] weights_shape Weights tensor shape * @param[in] conv_info Contains padding and stride information * * @return the calculated shape */ inline TensorShape compute_deep_convolution_shape(const TensorShape &input_shape, DataLayout input_data_layout, const TensorShape &weights_shape, const PadStrideInfo &conv_info) { const size_t idx_width = get_data_layout_dimension_index(input_data_layout, DataLayoutDimension::WIDTH); const size_t idx_height = get_data_layout_dimension_index(input_data_layout, DataLayoutDimension::HEIGHT); const size_t idx_channel = get_data_layout_dimension_index(input_data_layout, DataLayoutDimension::CHANNEL); const unsigned int input_width = input_shape[idx_width]; const unsigned int input_height = input_shape[idx_height]; const unsigned int weights_width = weights_shape[idx_width]; const unsigned int weights_height = weights_shape[idx_height]; const unsigned int weights_out_channel = weights_shape[3]; unsigned int output_width = 0; unsigned int output_height = 0; std::tie(output_width, output_height) = scaled_dimensions(input_width, input_height, weights_width, weights_height, conv_info); TensorShape output_shape{ input_shape }; output_shape.set(idx_width, output_width); output_shape.set(idx_height, output_height); output_shape.set(idx_channel, weights_out_channel); return output_shape; } /** Calculate the deep convolution shape output shape of a tensor * * @param[in] input Input tensor info * @param[in] weights Weights tensor info * @param[in] conv_info Contains padding and stride information * * @return the calculated shape */ inline TensorShape compute_deep_convolution_shape(const ITensorInfo &input, const ITensorInfo &weights, const PadStrideInfo &conv_info) { return compute_deep_convolution_shape(input.tensor_shape(), input.data_layout(), weights.tensor_shape(), conv_info); } /** Calculate the indirect buffer output shape used by the indirect convolution function * * @param[in] input_shape Input tensor shape * @param[in] input_data_layout Input data layout * @param[in] weights_shape Weights tensor shape * @param[in] conv_info Contains padding and stride information * @param[in] desc Contains the direct/indirect convolution compute arguments, such as the tiling dimensions * * @return the calculated shape */ inline TensorShape compute_indirect_buffer_shape(const TensorShape &input_shape, DataLayout input_data_layout, const TensorShape &weights_shape, const PadStrideInfo &conv_info, const DirectConvComputeKernelInfo &desc) { ARM_COMPUTE_ERROR_ON_MSG(input_data_layout != DataLayout::NHWC, "The data layout can only be NHWC"); ARM_COMPUTE_ERROR_ON_MSG(desc.m0 <= 0 || desc.m0 > 8, "M0 can only be greater than 0 and less than or equal to 8"); const unsigned int m0 = desc.m0; const unsigned int kw = weights_shape[1]; const unsigned int kh = weights_shape[2]; TensorShape output_conv2d_shape = compute_deep_convolution_shape(input_shape, input_data_layout, weights_shape, conv_info); const unsigned int output_w = m0 * kw * kh; const unsigned int output_h = DIV_CEIL(output_conv2d_shape[1] * output_conv2d_shape[2], m0); const unsigned int output_b = output_conv2d_shape[3]; return TensorShape(output_w, output_h, output_b); } /** Calculate the min/max shape output shape of a tensor * * @param[in] input Input tensor info * * @return the calculated shape */ inline TensorShape compute_min_max_shape(const ITensorInfo *input) { TensorShape output_shape{ input->tensor_shape() }; output_shape.set(Window::DimX, 2); output_shape.remove_dimension(1); output_shape.remove_dimension(1); return output_shape; } /** Calculate the output pool shape of a tensor * * @param[in] input Input tensor info * @param[in] pool_info Pooling layer info * * @return the calculated shape */ inline TensorShape compute_pool_shape(const ITensorInfo &input, PoolingLayerInfo pool_info) { int pooled_w = 0; int pooled_h = 0; TensorShape output_shape{ input.tensor_shape() }; const bool is_global_pooling = pool_info.is_global_pooling; const int idx_width = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::HEIGHT); const int input_width = input.tensor_shape()[idx_width]; const int input_height = input.tensor_shape()[idx_height]; const int pool_size_x = is_global_pooling ? output_shape[idx_width] : pool_info.pool_size.width; const int pool_size_y = is_global_pooling ? output_shape[idx_height] : pool_info.pool_size.height; std::tie(pooled_w, pooled_h) = scaled_dimensions_signed(input_width, input_height, pool_size_x, pool_size_y, pool_info.pad_stride_info); ARM_COMPUTE_ERROR_ON_MSG((pooled_w < 1 || pooled_h < 1), "Calculated output dimension size is invalid"); output_shape.set(idx_width, static_cast(pooled_w)); output_shape.set(idx_height, static_cast(pooled_h)); return output_shape; } /** Calculate the output unpool shape of a tensor * * @param[in] input Input tensor info * @param[in] pool_info Pooling layer info * * @return the calculated shape */ inline TensorShape compute_unpool_shape(const ITensorInfo &input, PoolingLayerInfo pool_info) { const unsigned int idx_width = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH); const unsigned int idx_height = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::HEIGHT); const TensorShape input_shape = input.tensor_shape(); ARM_COMPUTE_ERROR_ON(input_shape[idx_height] <= 1 || input_shape[idx_width] <= 1); const PadStrideInfo pad_stride_info = pool_info.pad_stride_info; const unsigned int stride_x = pad_stride_info.stride().first; const unsigned int stride_y = pad_stride_info.stride().second; const int pad_left = pad_stride_info.pad_left(); const int pad_top = pad_stride_info.pad_top(); const int pad_right = pad_stride_info.pad_right(); const int pad_bottom = pad_stride_info.pad_bottom(); TensorShape output_shape = input_shape; const unsigned int out_width = (input_shape[idx_width] - 1) * stride_x - pad_left - pad_right + pool_info.pool_size.width; const unsigned int out_height = (input_shape[idx_height] - 1) * stride_y - pad_top - pad_bottom + pool_info.pool_size.height; output_shape.set(idx_width, out_width); output_shape.set(idx_height, out_height); return output_shape; } /** Calculate the output roi align shape of a tensor * * @param[in] input Input tensor info * @param[in] rois Rois tensor info * @param[in] pool_info Pooling layer info * * @return the calculated shape */ inline TensorShape compute_roi_align_shape(const ITensorInfo &input, const ITensorInfo &rois, ROIPoolingLayerInfo pool_info) { TensorShape output_shape{ input.tensor_shape() }; const unsigned int idx_width = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::WIDTH); const unsigned int idx_height = get_data_layout_dimension_index(input.data_layout(), DataLayoutDimension::HEIGHT); output_shape.set(idx_width, pool_info.pooled_width()); output_shape.set(idx_height, pool_info.pooled_height()); output_shape.set(3, rois.dimension(1)); return output_shape; } /** Calculate the RNN shape of a tensor * * @param[in] input Input tensor info * @param[in] batch_size Batch size * * @return the calculated shape */ inline TensorShape compute_rnn_shape(const ITensorInfo *input, const unsigned int batch_size) { TensorShape output_shape{ input->tensor_shape() }; output_shape.set(1, batch_size); return output_shape; } /** Calculate the matrix multiplication output shape of two tensors * * @param[in] input0 First input tensor info * @param[in] input1 Second input tensor info * @param[in] is_interleaved_transposed True if the input is interleaved transposed * @param[in] reshape_info GEMM reshape info * * @return the calculated shape */ inline TensorShape compute_mm_shape(const ITensorInfo &input0, const ITensorInfo &input1, bool is_interleaved_transposed, const GEMMReshapeInfo &reshape_info) { ARM_COMPUTE_ERROR_ON_MSG(input0.num_dimensions() > 4, "The number of dimensions for the matrix A must be <= 4"); ARM_COMPUTE_ERROR_ON_MSG(is_interleaved_transposed && reshape_info.reinterpret_input_as_3d(), "The first input tensor cannot be reinterpreted as 3D if is_interleaved_transposed is true"); const bool reinterpret_input_as_3d = reshape_info.reinterpret_input_as_3d(); const bool reinterpret_output_as_3d = reshape_info.depth_output_gemm3d() != 0; const int depth_output_gemm3d = reinterpret_output_as_3d ? reshape_info.depth_output_gemm3d() : 1; const int m = reshape_info.reinterpret_input_as_3d() ? input0.dimension(1) * input0.dimension(2) : input0.dimension(1); // If the output of GEMM has to be reinterpreted as 3D, the number of input0 rows (M) is obtained collapsing the second and third // dimension of the output tensor const int dim0 = is_interleaved_transposed ? reshape_info.n() : input1.dimension(0); const int dim1 = is_interleaved_transposed ? reshape_info.m() / depth_output_gemm3d : m / depth_output_gemm3d; const int dim2 = reinterpret_input_as_3d ? input0.tensor_shape()[3] : input0.tensor_shape()[2]; const int dim3 = reinterpret_input_as_3d ? 1 : input0.tensor_shape()[3]; TensorShape output_shape{ input0.tensor_shape() }; output_shape.set(0, dim0); output_shape.set(1, dim1); output_shape.set(2, reinterpret_output_as_3d ? depth_output_gemm3d : dim2); output_shape.set(3, reinterpret_output_as_3d ? dim2 : dim3); output_shape.set(4, reinterpret_output_as_3d ? dim3 : 1); return output_shape; } /** Calculate the matrix multiplication output shape of two tensors * * @param[in] input0 First input tensor info * @param[in] input1 Second input tensor info * @param[in] gemm_info GEMM reshape info * * @return the calculated shape */ inline TensorShape compute_mm_shape(const ITensorInfo &input0, const ITensorInfo &input1, const GEMMReshapeInfo &gemm_info) { ARM_COMPUTE_UNUSED(input1); ARM_COMPUTE_ERROR_ON_MSG(input0.num_dimensions() > 4, "The number of dimensions for the matrix A must be <= 4"); const bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d(); const bool reinterpret_output_as_3d = gemm_info.depth_output_gemm3d() != 0; const int depth_output_gemm3d = reinterpret_output_as_3d ? gemm_info.depth_output_gemm3d() : 1; TensorShape output_shape{ input0.tensor_shape() }; if(!reinterpret_input_as_3d && !reinterpret_output_as_3d) { output_shape.set(0, gemm_info.n()); output_shape.set(1, gemm_info.m()); } else { // If the output of GEMM has to be reinterpreted as 3D, the number of input0 rows (M) is obtained collapsing the second and third // dimension of the output tensor const int batch_size = reinterpret_input_as_3d ? input0.tensor_shape()[3] : input0.tensor_shape()[2]; output_shape.set(0, gemm_info.n()); output_shape.set(1, gemm_info.m() / depth_output_gemm3d); output_shape.set(2, reinterpret_output_as_3d ? depth_output_gemm3d : batch_size); output_shape.set(3, reinterpret_output_as_3d ? batch_size : 1); } return output_shape; } /** Calculate the matrix multiplication output shape of two tensors * * @param[in] input0 First input tensor info * @param[in] input1 Second input tensor info * @param[in] gemm_info GEMM kernel info used to retrieve the original dimensions of the input matrices * * @return the calculated shape */ inline TensorShape compute_mm_shape(const ITensorInfo &input0, const ITensorInfo &input1, const GEMMKernelInfo &gemm_info) { ARM_COMPUTE_UNUSED(input1); ARM_COMPUTE_ERROR_ON_MSG(input0.num_dimensions() > 4, "The number of dimensions for the matrix A must be <= 4"); const bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d; const bool reinterpret_output_as_3d = gemm_info.depth_output_gemm3d != 0; const unsigned int depth_output_gemm3d = reinterpret_output_as_3d ? gemm_info.depth_output_gemm3d : 1; TensorShape output_shape{ input0.tensor_shape() }; if(!reinterpret_input_as_3d && !reinterpret_output_as_3d) { output_shape.set(0, gemm_info.n); output_shape.set(1, gemm_info.m); } else { // If the output of GEMM has to be reinterpreted as 3D, the number of input0 rows (M) is obtained collapsing the second and third // dimension of the output tensor const unsigned int batch_size = reinterpret_input_as_3d ? input0.tensor_shape()[3] : input0.tensor_shape()[2]; output_shape.set(0, gemm_info.n); output_shape.set(1, gemm_info.m / depth_output_gemm3d); output_shape.set(2, reinterpret_output_as_3d ? depth_output_gemm3d : batch_size); output_shape.set(3, reinterpret_output_as_3d ? batch_size : 1); } return output_shape; } /** Calculate the matrix multiplication output shape of two tensors * * @param[in] input Input tensor info * @param[in] gemm_3d_depth (Optional) GEMM 3d depth * @param[in] batch_size_on_z (Optional) True if batch size is on z axis * * @return the calculated shape */ inline TensorShape compute_output_stage_shape(const ITensorInfo &input, unsigned int gemm_3d_depth = 1, bool batch_size_on_z = false) { ARM_COMPUTE_ERROR_ON(input.data_layout() != DataLayout::NHWC && gemm_3d_depth > 1); TensorShape output_shape = input.tensor_shape(); if(gemm_3d_depth > 1) { if(batch_size_on_z) { output_shape.shift_right(1); } output_shape.set(0, input.tensor_shape().x()); output_shape.set(1, input.tensor_shape().y() / gemm_3d_depth); output_shape.set(2, gemm_3d_depth); } return output_shape; } /** Calculate the strided slice output shape of a tensor * * @param[in] input Input tensor info * @param[in] starts The starts of the dimensions of the input tensor to be sliced * @param[in] ends The ends of the dimensions of the input tensor to be sliced * @param[in] strides The strides of the dimensions of the input tensor to be sliced * @param[in] begin_mask If the ith bit of begin_mask is set, starts[i] is ignored and the fullest possible range in that dimension is used instead. * @param[in] end_mask If the ith bit of end_mask is set, ends[i] is ignored and the fullest possible range in that dimension is used instead. * @param[in] shrink_axis_mask If the ith bit of shrink_axis_mask is set, it implies that the ith specification shrinks the dimensionality by 1 * * @return the calculated shape */ inline TensorShape compute_strided_slice_shape(const ITensorInfo &input, const Coordinates &starts, const Coordinates &ends, const Coordinates &strides, int32_t begin_mask, int32_t end_mask, int32_t shrink_axis_mask) { using namespace arm_compute::helpers::tensor_transform; return compute_strided_slice_output_shape(input.tensor_shape(), starts, ends, strides, begin_mask, end_mask, shrink_axis_mask); } /** Calculate the slice output shape of a tensor * * @param[in] input_shape Input tensor info * @param[in] starts The starts of the dimensions of the input tensor to be sliced * @param[in] ends The ends of the dimensions of the input tensor to be sliced * * @return the calculated shape */ inline TensorShape compute_slice_shape(const TensorShape &input_shape, const Coordinates &starts, const Coordinates &ends) { using namespace arm_compute::helpers::tensor_transform; return compute_strided_slice_output_shape(input_shape, starts, ends, BiStrides(), 0, construct_slice_end_mask(ends), 0); } /** Calculate the batch to space output shape of a tensor * * @param[in] input Input tensor info * @param[in] block_x Block shape x value * @param[in] block_y Block shape y value * * @return the calculated shape */ inline TensorShape compute_batch_to_space_shape(const ITensorInfo *input, const int block_x, const int block_y) { ARM_COMPUTE_ERROR_ON(block_x <= 0 || block_y <= 0); const DataLayout data_layout = input->data_layout(); const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int idx_batch = get_data_layout_dimension_index(data_layout, DataLayoutDimension::BATCHES); TensorShape output_shape{ input->tensor_shape() }; output_shape.set(idx_width, input->tensor_shape()[idx_width] * block_x); output_shape.set(idx_height, input->tensor_shape()[idx_height] * block_y); output_shape.set(idx_batch, input->tensor_shape()[idx_batch] / (block_x * block_y)); return output_shape; } /** Calculate the depth to space output shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] data_layout Operation data layout * @param[in] block Block shape value * * @return the calculated shape */ inline TensorShape compute_depth_to_space_shape(const TensorShape &input_shape, DataLayout data_layout, int block) { ARM_COMPUTE_ERROR_ON(block < 2); const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int idx_channel = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); TensorShape output_shape{ input_shape }; output_shape.set(idx_width, input_shape[idx_width] * block); output_shape.set(idx_height, input_shape[idx_height] * block); output_shape.set(idx_channel, input_shape[idx_channel] / (block * block)); return output_shape; } /** Calculate the split output shape of a tensor * * @param[in] input Input tensor info * @param[in] axis Axis on which to split the input * @param[in] num_splits Number of splits * * @return the calculated shape */ inline TensorShape compute_split_shape(const ITensorInfo *input, unsigned int axis, unsigned int num_splits) { TensorShape empty_shape; empty_shape.set(0, 0); TensorShape out_shape{ input->tensor_shape() }; // Return empty shape if axis is invalid if(axis > input->tensor_shape().num_dimensions()) { return empty_shape; } size_t axis_size = out_shape[axis]; // Return empty shape if num_split is not valid if(axis_size % num_splits) { return empty_shape; } out_shape[axis] = axis_size / num_splits; return out_shape; } /** Calculate the space to batch output shape of a tensor * * @param[in] input Input tensor info * @param[in] block_x Block shape x value * @param[in] block_y Block shape y value * @param[in] padding_left Left padding values * @param[in] padding_right Right padding values * * @return the calculated shape */ inline TensorShape compute_space_to_batch_shape(const ITensorInfo *input, const int block_x, const int block_y, const Size2D &padding_left, const Size2D &padding_right) { TensorShape output_shape{ input->tensor_shape() }; const DataLayout data_layout = input->data_layout(); const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int idx_batch = get_data_layout_dimension_index(data_layout, DataLayoutDimension::BATCHES); ARM_COMPUTE_ERROR_ON((input->tensor_shape()[idx_width] + padding_left.x() + padding_right.x()) % block_x != 0); ARM_COMPUTE_ERROR_ON((input->tensor_shape()[idx_height] + padding_left.y() + padding_right.y()) % block_y != 0); output_shape.set(idx_width, (input->tensor_shape()[idx_width] + padding_left.x() + padding_right.x()) / block_x); output_shape.set(idx_height, (input->tensor_shape()[idx_height] + padding_left.y() + padding_right.y()) / block_y); output_shape.set(idx_batch, input->tensor_shape()[idx_batch] * block_x * block_y); return output_shape; } /** Calculate the space to batch output shape of a tensor * * @param[in] input Input tensor info * @param[in] block_shape Block shape value * * @return the calculated shape */ inline TensorShape compute_space_to_depth_shape(const ITensorInfo *input, int32_t block_shape) { TensorShape output_shape{ input->tensor_shape() }; const DataLayout data_layout = input->data_layout(); const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int idx_depth = get_data_layout_dimension_index(data_layout, DataLayoutDimension::CHANNEL); output_shape.set(idx_width, input->tensor_shape()[idx_width] / block_shape); output_shape.set(idx_height, input->tensor_shape()[idx_height] / block_shape); output_shape.set(idx_depth, input->tensor_shape()[idx_depth] * (block_shape * block_shape)); return output_shape; } /** Calculate the prior box output shape of a tensor * * @param[in] input Input tensor info * @param[in] info PriorBoxLayer info * * @return the calculated shape */ inline TensorShape compute_prior_box_shape(const ITensorInfo &input, const PriorBoxLayerInfo &info) { DataLayout data_layout = input.data_layout(); const size_t idx_w = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const size_t idx_h = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int num_priors = info.aspect_ratios().size() * info.min_sizes().size() + info.max_sizes().size(); TensorShape output_shape{}; output_shape.set(0, input.dimension(idx_w) * input.dimension(idx_h) * num_priors * 4); output_shape.set(1, 2); return output_shape; } /** Calculate the padded shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] padding Paddings list * * @return the calculated shape */ inline TensorShape compute_padded_shape(const TensorShape &input_shape, const PaddingList &padding) { TensorShape padded_shape = input_shape; for(size_t dim = 0; dim < padding.size(); ++dim) { const auto &padding_pair = padding[dim]; const uint32_t shape_on_index = (padded_shape.num_dimensions() <= dim) ? 1 : input_shape[dim]; padded_shape.set(dim, padding_pair.first + shape_on_index + padding_pair.second); } return padded_shape; } /** Calculate the tiled shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] multiples Paddings list * * @return the calculated shape */ inline TensorShape compute_tiled_shape(const TensorShape &input_shape, const Multiples &multiples) { TensorShape tiled_shape = input_shape; for(size_t dim = 0; dim < multiples.size(); ++dim) { tiled_shape.set(dim, input_shape[dim] * multiples[dim]); } return tiled_shape; } /** Calculate the reduced shape of a tensor given an axis * * @param[in] input Input tensor info * @param[in] axis Axis on which to perform reduction * @param[in] keep_dims (Optional) Whether to keep the dimension after reduction operation. Defaults to true. * * @return the calculated shape */ inline TensorShape compute_reduced_shape(const TensorShape &input, unsigned int axis, bool keep_dims = true) { TensorShape output_shape{ input }; if(!keep_dims) { output_shape.remove_dimension(axis); } else { output_shape.set(axis, 1); } return output_shape; } /** Calculate the upsampled shape of a tensor * * @param[in] input Input tensor info * @param[in] info Contains stride information (x and y) * * @return the calculated shape */ inline TensorShape compute_upsample_shape(const ITensorInfo &input, const Size2D &info) { const DataLayout data_layout = input.data_layout(); const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); TensorShape scale_out_shape(input.tensor_shape()); const unsigned int out_x = input.dimension(idx_width) * info.x(); const unsigned int out_y = input.dimension(idx_height) * info.y(); scale_out_shape.set(idx_width, out_x); scale_out_shape.set(idx_height, out_y); return scale_out_shape; } /** Get the tensor shape * * @param[in] data Input data * * @return the extracted tensor shape */ template inline TensorShape extract_shape(T *data) { return data->info()->tensor_shape(); } inline TensorShape extract_shape(ITensorInfo *data) { return data->tensor_shape(); } inline TensorShape extract_shape(const ITensorInfo *data) { return data->tensor_shape(); } inline TensorShape extract_shape(const TensorShape *data) { return *data; } inline TensorShape extract_shape(TensorShape *data) { return *data; } /** Calculate the unstack shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] axis Axis on which to perform the unstack operation * * @return the calculated shape */ inline TensorShape calculate_unstack_shape(TensorShape input_shape, unsigned int axis) { ARM_COMPUTE_ERROR_ON(axis > input_shape.num_dimensions()); input_shape.remove_dimension(axis); return input_shape; } /** Calculate the concatenate output shape of the concatenate operation along a single axis * * @param[in] input Vector containing the shapes of the inputs * @param[in] axis Axis along which to concatenate the input tensors * * @return the calculated shape */ template inline TensorShape calculate_concatenate_shape(const std::vector &input, size_t axis) { TensorShape out_shape = extract_shape(input[0]); #if defined(ARM_COMPUTE_ASSERTS_ENABLED) // All dimensions must match except the axis one for(unsigned int i = 0; i < MAX_DIMS; ++i) { if(i == axis) { continue; } for(const auto &tensor : input) { ARM_COMPUTE_ERROR_ON(tensor == nullptr); const TensorShape shape = extract_shape(tensor); ARM_COMPUTE_ERROR_ON(out_shape[i] != shape[i]); } } #endif // defined(ARM_COMPUTE_ASSERTS_ENABLED) // Calculate output shape size_t new_size = 0; for(const auto &tensor : input) { const TensorShape shape = extract_shape(tensor); new_size += shape[axis]; } out_shape.set(axis, new_size); return out_shape; } /** Calculate the stack output shape of a tensor * * @param[in] a Input tensor info * @param[in] axis Axis on which to perform the stack operation * @param[in] num_tensors Number of tensors to stack * * @return the calculated shape */ inline TensorShape compute_stack_shape(const ITensorInfo &a, unsigned int axis, unsigned int num_tensors) { ARM_COMPUTE_ERROR_ON(axis > a.num_dimensions()); ARM_COMPUTE_ERROR_ON(a.num_dimensions() > 4); TensorShape shape_out{ a.tensor_shape() }; shape_out.set(axis, num_tensors); unsigned int i_shift = 0; for(unsigned int i = 0; i < a.num_dimensions(); ++i) { if(i == axis) { i_shift++; } shape_out.set(i + i_shift, a.tensor_shape()[i]); } return shape_out; } /** Calculate the output shape of 3d Convolution * * @param[in] src Input tensor shape * @param[in] weights Weights tensor shape * @param[in] conv3d_info 3d Convolution Parameters object * * @return the calculated shape */ inline TensorShape compute_conv3d_shape(const TensorShape &src, const TensorShape &weights, const Conv3dInfo &conv3d_info) { // Weight tensor shape indices (D H W Cin Cout) constexpr unsigned int weights_depth_dim = 4u; constexpr unsigned int weights_height_dim = 3u; constexpr unsigned int weights_width_dim = 2u; constexpr unsigned int weights_CHout_dim = 0u; // Source/Destination Tensor shape indices (N D H W C) constexpr unsigned int batch_dim = 4u; constexpr unsigned int depth_dim = 3u; constexpr unsigned int height_dim = 2u; constexpr unsigned int width_dim = 1u; constexpr unsigned int channel_dim = 0u; TensorShape output_shape{ src }; const size_t pad_left = conv3d_info.padding.left; const size_t pad_right = conv3d_info.padding.right; const size_t pad_top = conv3d_info.padding.top; const size_t pad_bottom = conv3d_info.padding.bottom; const size_t pad_front = conv3d_info.padding.front; const size_t pad_back = conv3d_info.padding.back; const size_t dilation_x = conv3d_info.dilation.width; const size_t dilation_y = conv3d_info.dilation.height; const size_t dilation_z = conv3d_info.dilation.depth; const size_t stride_x = conv3d_info.stride.x(); const size_t stride_y = conv3d_info.stride.y(); const size_t stride_z = conv3d_info.stride.z(); int output_width_size = 0; int output_height_size = 0; int output_depth_size = 0; switch(conv3d_info.round_type) { case DimensionRoundingType::FLOOR: output_width_size = static_cast(std::floor((static_cast(src[width_dim] + pad_left + pad_right - (dilation_x * (weights[weights_width_dim] - 1) + 1)) / stride_x) + 1)); output_height_size = static_cast(std::floor((static_cast(src[height_dim] + pad_top + pad_bottom - (dilation_y * (weights[weights_height_dim] - 1) + 1)) / stride_y) + 1)); output_depth_size = static_cast(std::floor((static_cast(src[depth_dim] + pad_front + pad_back - (dilation_z * (weights[weights_depth_dim] - 1) + 1)) / stride_z) + 1)); break; case DimensionRoundingType::CEIL: output_width_size = static_cast(std::ceil((static_cast(src[width_dim] + pad_left + pad_right - (dilation_x * (weights[weights_width_dim] - 1) + 1)) / stride_x) + 1)); output_height_size = static_cast(std::ceil((static_cast(src[height_dim] + pad_top + pad_bottom - (dilation_y * (weights[weights_height_dim] - 1) + 1)) / stride_y) + 1)); output_depth_size = static_cast(std::ceil((static_cast(src[depth_dim] + pad_front + pad_back - (dilation_z * (weights[weights_depth_dim] - 1) + 1)) / stride_z) + 1)); break; default: ARM_COMPUTE_ERROR("Unsupported rounding type"); } output_shape.set(batch_dim, src[batch_dim]); output_shape.set(width_dim, output_width_size); output_shape.set(height_dim, output_height_size); output_shape.set(depth_dim, output_depth_size); output_shape.set(channel_dim, weights[weights_CHout_dim]); return output_shape; } /** Calculate the output pool3d shape of a tensor * * @param[in] src Input tensor info * @param[in] pool3d_info Pooling layer info * * @return the calculated shape */ inline TensorShape compute_pool3d_shape(const TensorShape &src, Pooling3dLayerInfo pool3d_info) { TensorShape output_shape{ src }; const auto data_layout = DataLayout::NDHWC; const int idx_width = get_data_layout_dimension_index(data_layout, DataLayoutDimension::WIDTH); const int idx_height = get_data_layout_dimension_index(data_layout, DataLayoutDimension::HEIGHT); const int idx_depth = get_data_layout_dimension_index(data_layout, DataLayoutDimension::DEPTH); const int pool_size_width = pool3d_info.is_global_pooling ? src[idx_width] : pool3d_info.pool_size.width; const int pool_size_height = pool3d_info.is_global_pooling ? src[idx_height] : pool3d_info.pool_size.height; const int pool_size_depth = pool3d_info.is_global_pooling ? src[idx_depth] : pool3d_info.pool_size.depth; int output_width = 0; int output_height = 0; int output_depth = 0; std::tie(output_width, output_height, output_depth) = scaled_3d_dimensions_signed(src[idx_width], src[idx_height], src[idx_depth], pool_size_width, pool_size_height, pool_size_depth, pool3d_info); ARM_COMPUTE_ERROR_ON_MSG((output_width < 1 || output_height < 1 || output_depth < 1), "Calculated output dimension size is invalid"); output_shape.set(idx_width, static_cast(output_width)); output_shape.set(idx_height, static_cast(output_height)); output_shape.set(idx_depth, static_cast(output_depth)); return output_shape; } /** Calculate the gather output shape of a tensor * * @param[in] input_shape Input tensor shape * @param[in] indices_shape Indices tensor shape. Only supports for 2d and 3d indices * @param[in] actual_axis Axis to be used in the computation * * @note Let input_shape be (X,Y,Z) and indices shape (W,O,P) and axis 1 * the new shape is computed by replacing the axis in the input shape with * the indice shape so the output shape will be (X,W,O,P,Z) * * @return the calculated shape */ inline TensorShape compute_gather_shape(const TensorShape &input_shape, const TensorShape &indices_shape, uint32_t actual_axis) { ARM_COMPUTE_ERROR_ON(input_shape.num_dimensions() > 4); ARM_COMPUTE_ERROR_ON(actual_axis >= input_shape.num_dimensions()); ARM_COMPUTE_ERROR_ON(indices_shape.num_dimensions() > 3); TensorShape output_shape = input_shape; if(indices_shape.num_dimensions() == 1u) { output_shape[actual_axis] = indices_shape[0]; } else { const auto ind_num_dims { indices_shape.num_dimensions() }; output_shape.shift_right(ind_num_dims - 1); switch(actual_axis) { case 1: { output_shape[0] = input_shape[0]; for(size_t idx = 0; idx < ind_num_dims; ++idx) { output_shape.set(actual_axis + idx, indices_shape[idx], false); } break; } default: { // 2d and 3d indices are only supported for axis == 1 ARM_COMPUTE_ERROR_ON(actual_axis != 1 && indices_shape.num_dimensions() > 1); } } } return output_shape; } } // namespace shape_calculator } // namespace misc } // namespace arm_compute #endif /* ARM_COMPUTE_MISC_SHAPE_CALCULATOR_H */