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Diffstat (limited to 'tests/validation/reference/OpticalFlow.cpp')
-rw-r--r-- | tests/validation/reference/OpticalFlow.cpp | 404 |
1 files changed, 0 insertions, 404 deletions
diff --git a/tests/validation/reference/OpticalFlow.cpp b/tests/validation/reference/OpticalFlow.cpp deleted file mode 100644 index 0a04214045..0000000000 --- a/tests/validation/reference/OpticalFlow.cpp +++ /dev/null @@ -1,404 +0,0 @@ -/* - * Copyright (c) 2018 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 "OpticalFlow.h" - -#include "GaussianPyramidHalf.h" -#include "Scharr.h" -#include "Utils.h" - -namespace arm_compute -{ -namespace test -{ -namespace validation -{ -namespace reference -{ -namespace -{ -using KeyPointArray = std::vector<KeyPoint>; -using InternalKeyPointArray = std::vector<InternalKeyPoint>; - -// Constants used for Lucas-Kanade Algorithm -constexpr int W_BITS = 14; -constexpr float D0 = 1 << W_BITS; -constexpr float DETERMINANT_THRESHOLD = 1.0e-07f; -constexpr float EIGENVALUE_THRESHOLD = 1.0e-04f; -constexpr float FLT_SCALE = 1.0f / (1 << 20); - -// Creates an InternalKeyPointArray for tracking non-integral pixel coordinates -InternalKeyPointArray create_internal_keypoints(const KeyPointArray &keypoints) -{ - InternalKeyPointArray internal_keypoints; - - for(auto keypoint : keypoints) - { - InternalKeyPoint internal_keypoint; - - internal_keypoint.x = static_cast<float>(keypoint.x); - internal_keypoint.y = static_cast<float>(keypoint.y); - internal_keypoint.tracking_status = static_cast<bool>(keypoint.tracking_status); - - internal_keypoints.push_back(internal_keypoint); - } - - return internal_keypoints; -} - -// Scale tracked points based on Pyramid level -void scale_tracked_points(size_t level, size_t num_levels, bool use_initial_estimate, - InternalKeyPointArray &old_points_internal, InternalKeyPointArray &new_points_internal, - const KeyPointArray &old_points, const KeyPointArray &new_points_estimates) -{ - if(level == num_levels - 1) // lowest resolution - { - const float scale = std::pow(SCALE_PYRAMID_HALF, level); - - for(size_t i = 0; i < old_points.size(); ++i) - { - old_points_internal.at(i).x = old_points.at(i).x * scale; - old_points_internal.at(i).y = old_points.at(i).y * scale; - old_points_internal.at(i).tracking_status = true; - - InternalKeyPoint keypoint_to_track; - - if(use_initial_estimate) - { - keypoint_to_track.x = new_points_estimates.at(i).x * scale; - keypoint_to_track.y = new_points_estimates.at(i).y * scale; - keypoint_to_track.tracking_status = (new_points_estimates.at(i).tracking_status == 1); - } - else - { - keypoint_to_track.x = old_points_internal.at(i).x; - keypoint_to_track.y = old_points_internal.at(i).y; - keypoint_to_track.tracking_status = true; - } - - new_points_internal.at(i) = keypoint_to_track; - } - } - else - { - for(size_t i = 0; i < old_points.size(); ++i) - { - old_points_internal.at(i).x /= SCALE_PYRAMID_HALF; - old_points_internal.at(i).y /= SCALE_PYRAMID_HALF; - new_points_internal.at(i).x /= SCALE_PYRAMID_HALF; - new_points_internal.at(i).y /= SCALE_PYRAMID_HALF; - } - } -} - -bool is_invalid_keypoint(const InternalKeyPoint &keypoint, const ValidRegion &valid_region, size_t window_dimension) -{ - const int half_window = window_dimension / 2; - const int x = std::floor(keypoint.x); - const int y = std::floor(keypoint.y); - - return (x - half_window < valid_region.start(0)) || (x + half_window >= valid_region.end(0) - 1) || (y - half_window < valid_region.start(1)) || (y + half_window >= valid_region.end(1) - 1); -} - -template <typename T> -constexpr int INT_ROUND(T x, int n) -{ - return (x + (1 << (n - 1))) >> n; -} - -// Return the bilinear value at a specified coordinate with different border modes -template <typename T> -int bilinear_interpolate(const SimpleTensor<T> &in, Coordinates id, float wx, float wy, BorderMode border_mode, T constant_border_value, int scale) -{ - const int level = id.x(); - const int idy = id.y(); - - const float dx = wx; - const float dy = wy; - const float dx_1 = 1.0f - dx; - const float dy_1 = 1.0f - dy; - - const T border_value = constant_border_value; - - id.set(0, level); - id.set(1, idy); - const T tl = tensor_elem_at(in, id, border_mode, border_value); - id.set(0, level + 1); - id.set(1, idy); - const T tr = tensor_elem_at(in, id, border_mode, border_value); - id.set(0, level); - id.set(1, idy + 1); - const T bl = tensor_elem_at(in, id, border_mode, border_value); - id.set(0, level + 1); - id.set(1, idy + 1); - const T br = tensor_elem_at(in, id, border_mode, border_value); - - // weights - const int w00 = roundf(dx_1 * dy_1 * D0); - const int w01 = roundf(dx * dy_1 * D0); - const int w10 = roundf(dx_1 * dy * D0); - const int w11 = D0 - w00 - w01 - w10; - - return static_cast<int>(INT_ROUND(tl * w00 + tr * w01 + bl * w10 + br * w11, scale)); -} - -template <typename T> -std::vector<int> compute_derivative(const SimpleTensor<T> &input, const InternalKeyPoint &keypoint, - BorderMode border_mode, uint8_t constant_border_value, size_t window_dimension, int scale) -{ - std::vector<int> bilinear_values; - - const int half_window = window_dimension / 2; - - float keypoint_int_x = 0; - float keypoint_int_y = 0; - - const float wx = std::modf(keypoint.x, &keypoint_int_x); - const float wy = std::modf(keypoint.y, &keypoint_int_y); - - Coordinates tl_window(static_cast<int>(keypoint_int_x) - half_window, static_cast<int>(keypoint_int_y) - half_window); - Coordinates br_window(static_cast<int>(keypoint_int_x) + half_window, static_cast<int>(keypoint_int_y) + half_window); - - for(int y = tl_window.y(); y <= br_window.y(); ++y) - { - for(int x = tl_window.x(); x <= br_window.x(); ++x) - { - bilinear_values.push_back(bilinear_interpolate(input, Coordinates(x, y), wx, wy, border_mode, static_cast<T>(constant_border_value), scale)); - } - } - - return bilinear_values; -} - -std::tuple<float, float, float> compute_spatial_gradient_matrix(const std::vector<int> &bilinear_ix, const std::vector<int> &bilinear_iy) -{ - ARM_COMPUTE_ERROR_ON(bilinear_ix.size() != bilinear_iy.size()); - - int iA11 = 0; - int iA12 = 0; - int iA22 = 0; - - for(size_t i = 0; i < bilinear_ix.size(); ++i) - { - int ixval = bilinear_ix[i]; - int iyval = bilinear_iy[i]; - - iA11 += ixval * ixval; - iA12 += ixval * iyval; - iA22 += iyval * iyval; - } - - return std::make_tuple(iA11 * FLT_SCALE, iA12 * FLT_SCALE, iA22 * FLT_SCALE); -} - -std::tuple<double, double> compute_temporal_gradient_vector(const std::vector<int> &bilinear_it_old, - const std::vector<int> &bilinear_it_new, - const std::vector<int> &bilinear_ix, - const std::vector<int> &bilinear_iy) -{ - ARM_COMPUTE_ERROR_ON(bilinear_ix.size() != bilinear_iy.size()); - ARM_COMPUTE_ERROR_ON(bilinear_it_old.size() != bilinear_it_new.size()); - - int ib1 = 0; - int ib2 = 0; - - for(size_t i = 0; i < bilinear_ix.size(); ++i) - { - int ixval = bilinear_ix[i]; - int iyval = bilinear_iy[i]; - int ival = bilinear_it_old[i]; - int jval = bilinear_it_new[i]; - - const int diff = jval - ival; - - ib1 += diff * ixval; - ib2 += diff * iyval; - } - - const double b1 = ib1 * FLT_SCALE; - const double b2 = ib2 * FLT_SCALE; - - return std::make_tuple(b1, b2); -} -} // namespace - -template <typename T> -std::vector<KeyPoint> optical_flow(const SimpleTensor<T> &old_input, const SimpleTensor<T> &new_input, - const OpticalFlowParameters ¶ms, size_t num_levels, - const std::vector<KeyPoint> &old_points, const std::vector<KeyPoint> &new_points_estimates, - BorderMode border_mode, uint8_t constant_border_value) -{ - const int filter_size = 3; // scharr filter size - const size_t max_iterations = 1000; // fixed by kernel - const size_t window_dimension = params.window_dimension; - const size_t num_iterations = (params.termination == Termination::TERM_CRITERIA_EPSILON) ? max_iterations : params.num_iterations; - - KeyPointArray new_points(old_points.size()); - - InternalKeyPointArray old_points_internal = create_internal_keypoints(old_points); - InternalKeyPointArray new_points_internal = create_internal_keypoints(new_points_estimates); - - SimpleTensor<int16_t> scharr_gx; - SimpleTensor<int16_t> scharr_gy; - - // Create pyramids - std::vector<SimpleTensor<T>> old_pyramid = gaussian_pyramid_half(old_input, border_mode, constant_border_value, num_levels); - std::vector<SimpleTensor<T>> new_pyramid = gaussian_pyramid_half(new_input, border_mode, constant_border_value, num_levels); - - // Iterate over each level of the pyramid - for(size_t idx = num_levels; idx > 0; --idx) - { - const size_t level = idx - 1; - - // Calculate scharr gradients - std::tie(scharr_gx, scharr_gy) = scharr<int16_t, T>(old_pyramid[level], filter_size, border_mode, constant_border_value, GradientDimension::GRAD_XY); - - scale_tracked_points(level, num_levels, params.use_initial_estimate, old_points_internal, new_points_internal, old_points, new_points_estimates); - - // Calculate valid region based on image dimensions of current pyramid level - const ValidRegion valid_region = shape_to_valid_region(old_pyramid[level].shape(), (border_mode == BorderMode::UNDEFINED), BorderSize(filter_size / 2)); - - for(size_t i = 0; i < old_points.size(); ++i) - { - InternalKeyPoint &old_keypoint = old_points_internal.at(i); - InternalKeyPoint &new_keypoint = new_points_internal.at(i); - - // Helper function for untracking keypoints when on the lowest pyramid level (high resolution) - const auto untrack_keypoint = [&](bool predicate) - { - if(predicate && (level == 0)) - { - new_keypoint.tracking_status = false; - return true; - } - return predicate; - }; - - if(!old_keypoint.tracking_status) - { - continue; - } - - // Check if tracked coordinate is outside image coordinate - if(untrack_keypoint(is_invalid_keypoint(old_keypoint, valid_region, window_dimension))) - { - continue; - } - - // Compute spatial derivative - std::vector<int> bilinear_ix = compute_derivative(scharr_gx, old_keypoint, border_mode, constant_border_value, window_dimension, W_BITS); - std::vector<int> bilinear_iy = compute_derivative(scharr_gy, old_keypoint, border_mode, constant_border_value, window_dimension, W_BITS); - - float A11 = 0.f; - float A12 = 0.f; - float A22 = 0.f; - std::tie(A11, A12, A22) = compute_spatial_gradient_matrix(bilinear_ix, bilinear_iy); - - // Calculate criteria for lost tracking : Matrix A is invertible - // 1. The determinant of the matrix is less than DETERMINANT_THRESHOLD - // 2. The minimum eigenvalue of the matrix is less than EIGENVALUE_THRESHOLD - const float trace_A = A11 + A22; - const float determinant = A11 * A22 - A12 * A12; - const float discriminant = (trace_A * trace_A) - 4.0f * (determinant); - const float eigenvalue_A = (trace_A - std::sqrt(discriminant)) / 2.0f; - - // Divide by window_dimension squared to reduce the floating point accummulation error - const float eigenvalue = eigenvalue_A / (window_dimension * window_dimension); - - // Check if it is a good point to track - if(untrack_keypoint(eigenvalue < EIGENVALUE_THRESHOLD || determinant < DETERMINANT_THRESHOLD)) - { - continue; - } - - float prev_delta_x = 0.f; - float prev_delta_y = 0.f; - - for(size_t j = 0; j < num_iterations; ++j) - { - // Check if tracked coordinate is outside image coordinate - if(untrack_keypoint(is_invalid_keypoint(new_keypoint, valid_region, window_dimension))) - { - break; - } - - // Compute temporal derivative - std::vector<int> bilinear_it_old = compute_derivative(old_pyramid[level], old_keypoint, border_mode, constant_border_value, window_dimension, W_BITS - 5); - std::vector<int> bilinear_it_new = compute_derivative(new_pyramid[level], new_keypoint, border_mode, constant_border_value, window_dimension, W_BITS - 5); - - double b1 = 0.f; - double b2 = 0.f; - std::tie(b1, b2) = compute_temporal_gradient_vector(bilinear_it_old, bilinear_it_new, bilinear_ix, bilinear_iy); - - // Compute motion vector -> A^-1 * -b - const float delta_x = (A12 * b2 - A22 * b1) / determinant; - const float delta_y = (A12 * b1 - A11 * b2) / determinant; - - // Update the new position - new_keypoint.x += delta_x; - new_keypoint.y += delta_y; - - const float magnitude_squared = delta_x * delta_x + delta_y * delta_y; - - // Check if termination criteria is EPSILON and if it is satisfied - if(magnitude_squared <= params.epsilon && (params.termination == Termination::TERM_CRITERIA_EPSILON || params.termination == Termination::TERM_CRITERIA_BOTH)) - { - break; - } - - // Check convergence analyzing the previous delta - if(j > 0 && (std::fabs(delta_x + prev_delta_x) < 0.01f && std::fabs(delta_y + prev_delta_y) < 0.01f)) - { - new_keypoint.x -= delta_x * SCALE_PYRAMID_HALF; - new_keypoint.y -= delta_y * SCALE_PYRAMID_HALF; - - break; - } - - prev_delta_x = delta_x; - prev_delta_y = delta_y; - } - } - } - - // Copy optical flow coordinates to output vector - for(size_t i = 0; i < old_points.size(); ++i) - { - const InternalKeyPoint &new_keypoint = new_points_internal.at(i); - - new_points.at(i).x = roundf(new_keypoint.x); - new_points.at(i).y = roundf(new_keypoint.y); - new_points.at(i).tracking_status = new_keypoint.tracking_status ? 1 : 0; - } - - return new_points; -} - -template std::vector<KeyPoint> optical_flow(const SimpleTensor<uint8_t> &old_input, const SimpleTensor<uint8_t> &new_input, - const OpticalFlowParameters ¶ms, size_t num_levels, - const std::vector<KeyPoint> &old_points, const std::vector<KeyPoint> &new_points_estimates, - BorderMode border_mode, uint8_t constant_border_value); -} // namespace reference -} // namespace validation -} // namespace test -} // namespace arm_compute |