| /* |
| * Copyright (c) 2017, Alliance for Open Media. All rights reserved |
| * |
| * This source code is subject to the terms of the BSD 2 Clause License and |
| * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License |
| * was not distributed with this source code in the LICENSE file, you can |
| * obtain it at www.aomedia.org/license/software. If the Alliance for Open |
| * Media Patent License 1.0 was not distributed with this source code in the |
| * PATENTS file, you can obtain it at www.aomedia.org/license/patent. |
| */ |
| |
| #define _POSIX_C_SOURCE 200112L // rand_r() |
| #include <assert.h> |
| #include <float.h> |
| #include <limits.h> |
| #include <math.h> |
| #include <stdlib.h> |
| #include <time.h> |
| |
| #include "av1/encoder/bgsprite.h" |
| |
| #include "aom_mem/aom_mem.h" |
| #include "./aom_scale_rtcd.h" |
| #include "av1/common/mv.h" |
| #include "av1/common/warped_motion.h" |
| #include "av1/encoder/encoder.h" |
| #include "av1/encoder/global_motion.h" |
| #include "av1/encoder/mathutils.h" |
| #include "av1/encoder/temporal_filter.h" |
| |
| /* Blending Modes: |
| * 0 = Median |
| * 1 = Mean |
| */ |
| #define BGSPRITE_BLENDING_MODE 1 |
| |
| // Enable removal of outliers from mean blending mode. |
| #if BGSPRITE_BLENDING_MODE == 1 |
| #define BGSPRITE_MEAN_REMOVE_OUTLIERS 0 |
| #endif // BGSPRITE_BLENDING_MODE == 1 |
| |
| /* Interpolation for panorama alignment sampling: |
| * 0 = Nearest neighbor |
| * 1 = Bilinear |
| */ |
| #define BGSPRITE_INTERPOLATION 0 |
| |
| // Enable turning off bgsprite from firstpass metrics in define_gf_group. |
| #define BGSPRITE_ENABLE_METRICS 1 |
| |
| // Enable foreground/backgrond segmentation and combine with temporal filter. |
| #define BGSPRITE_ENABLE_SEGMENTATION 1 |
| |
| // Enable alignment using global motion. |
| #define BGSPRITE_ENABLE_GME 0 |
| |
| // Block size for foreground mask. |
| #define BGSPRITE_MASK_BLOCK_SIZE 4 |
| |
| typedef struct { |
| #if CONFIG_HIGHBITDEPTH |
| uint16_t y; |
| uint16_t u; |
| uint16_t v; |
| #else |
| uint8_t y; |
| uint8_t u; |
| uint8_t v; |
| #endif // CONFIG_HIGHBITDEPTH |
| uint8_t exists; |
| } YuvPixel; |
| |
| typedef struct { |
| int curr_model; |
| double mean[2]; |
| double var[2]; |
| int age[2]; |
| double u_mean[2]; |
| double v_mean[2]; |
| |
| #if CONFIG_HIGHBITDEPTH |
| uint16_t y; |
| uint16_t u; |
| uint16_t v; |
| #else |
| uint8_t y; |
| uint8_t u; |
| uint8_t v; |
| #endif // CONFIG_HIGHBITDEPTH |
| double final_var; |
| } YuvPixelGaussian; |
| |
| // Maps to convert from matrix form to param vector form. |
| static const int params_to_matrix_map[] = { 2, 3, 0, 4, 5, 1, 6, 7 }; |
| static const int matrix_to_params_map[] = { 2, 5, 0, 1, 3, 4, 6, 7 }; |
| |
| // Convert the parameter array to a 3x3 matrix form. |
| static void params_to_matrix(const double *const params, double *target) { |
| for (int i = 0; i < MAX_PARAMDIM - 1; i++) { |
| assert(params_to_matrix_map[i] < MAX_PARAMDIM - 1); |
| target[i] = params[params_to_matrix_map[i]]; |
| } |
| target[8] = 1; |
| } |
| |
| // Convert a 3x3 matrix to a parameter array form. |
| static void matrix_to_params(const double *const matrix, double *target) { |
| for (int i = 0; i < MAX_PARAMDIM - 1; i++) { |
| assert(matrix_to_params_map[i] < MAX_PARAMDIM - 1); |
| target[i] = matrix[matrix_to_params_map[i]]; |
| } |
| } |
| |
| #define TRANSFORM_MAT_DIM 3 |
| |
| // Do matrix multiplication on params. |
| static void multiply_params(double *const m1, double *const m2, |
| double *target) { |
| double m1_matrix[MAX_PARAMDIM]; |
| double m2_matrix[MAX_PARAMDIM]; |
| double result[MAX_PARAMDIM]; |
| |
| params_to_matrix(m1, m1_matrix); |
| params_to_matrix(m2, m2_matrix); |
| multiply_mat(m2_matrix, m1_matrix, result, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, TRANSFORM_MAT_DIM); |
| matrix_to_params(result, target); |
| } |
| |
| // Finds x and y limits of a single transformed image. |
| // Width and height are the size of the input video. |
| static void find_frame_limit(int width, int height, |
| const double *const transform, int *x_min, |
| int *x_max, int *y_min, int *y_max) { |
| double transform_matrix[MAX_PARAMDIM]; |
| double xy_matrix[3] = { 0, 0, 1 }; |
| double uv_matrix[3] = { 0 }; |
| // Macro used to update frame limits based on transformed coordinates. |
| #define UPDATELIMITS(u, v, x_min, x_max, y_min, y_max) \ |
| { \ |
| if ((int)ceil(u) > *x_max) { \ |
| *x_max = (int)ceil(u); \ |
| } \ |
| if ((int)floor(u) < *x_min) { \ |
| *x_min = (int)floor(u); \ |
| } \ |
| if ((int)ceil(v) > *y_max) { \ |
| *y_max = (int)ceil(v); \ |
| } \ |
| if ((int)floor(v) < *y_min) { \ |
| *y_min = (int)floor(v); \ |
| } \ |
| } |
| |
| params_to_matrix(transform, transform_matrix); |
| xy_matrix[0] = 0; |
| xy_matrix[1] = 0; |
| multiply_mat(transform_matrix, xy_matrix, uv_matrix, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, 1); |
| *x_max = (int)ceil(uv_matrix[0]); |
| *x_min = (int)floor(uv_matrix[0]); |
| *y_max = (int)ceil(uv_matrix[1]); |
| *y_min = (int)floor(uv_matrix[1]); |
| |
| xy_matrix[0] = width - 1; |
| xy_matrix[1] = 0; |
| multiply_mat(transform_matrix, xy_matrix, uv_matrix, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, 1); |
| UPDATELIMITS(uv_matrix[0], uv_matrix[1], x_min, x_max, y_min, y_max); |
| |
| xy_matrix[0] = width - 1; |
| xy_matrix[1] = height - 1; |
| multiply_mat(transform_matrix, xy_matrix, uv_matrix, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, 1); |
| UPDATELIMITS(uv_matrix[0], uv_matrix[1], x_min, x_max, y_min, y_max); |
| |
| xy_matrix[0] = 0; |
| xy_matrix[1] = height - 1; |
| multiply_mat(transform_matrix, xy_matrix, uv_matrix, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, 1); |
| UPDATELIMITS(uv_matrix[0], uv_matrix[1], x_min, x_max, y_min, y_max); |
| |
| #undef UPDATELIMITS |
| } |
| |
| // Finds x and y limits for arrays. Also finds the overall max and minimums |
| static void find_limits(int width, int height, const double **const params, |
| int num_frames, int *x_min, int *x_max, int *y_min, |
| int *y_max, int *pano_x_min, int *pano_x_max, |
| int *pano_y_min, int *pano_y_max) { |
| *pano_x_max = INT_MIN; |
| *pano_x_min = INT_MAX; |
| *pano_y_max = INT_MIN; |
| *pano_y_min = INT_MAX; |
| for (int i = 0; i < num_frames; ++i) { |
| find_frame_limit(width, height, (const double *const)params[i], &x_min[i], |
| &x_max[i], &y_min[i], &y_max[i]); |
| if (x_max[i] > *pano_x_max) { |
| *pano_x_max = x_max[i]; |
| } |
| if (x_min[i] < *pano_x_min) { |
| *pano_x_min = x_min[i]; |
| } |
| if (y_max[i] > *pano_y_max) { |
| *pano_y_max = y_max[i]; |
| } |
| if (y_min[i] < *pano_y_min) { |
| *pano_y_min = y_min[i]; |
| } |
| } |
| } |
| |
| // Inverts a 3x3 matrix that is in the parameter form. |
| static void invert_params(const double *const params, double *target) { |
| double temp[MAX_PARAMDIM] = { 0 }; |
| params_to_matrix(params, temp); |
| |
| // Find determinant of matrix (expansion by minors). |
| const double det = temp[0] * ((temp[4] * temp[8]) - (temp[5] * temp[7])) - |
| temp[1] * ((temp[3] * temp[8]) - (temp[5] * temp[6])) + |
| temp[2] * ((temp[3] * temp[7]) - (temp[4] * temp[6])); |
| assert(det != 0); |
| |
| // inverse is transpose of cofactor * 1/det. |
| double inverse[MAX_PARAMDIM] = { 0 }; |
| inverse[0] = (temp[4] * temp[8] - temp[7] * temp[5]) / det; |
| inverse[1] = (temp[2] * temp[7] - temp[1] * temp[8]) / det; |
| inverse[2] = (temp[1] * temp[5] - temp[2] * temp[4]) / det; |
| inverse[3] = (temp[5] * temp[6] - temp[3] * temp[8]) / det; |
| inverse[4] = (temp[0] * temp[8] - temp[2] * temp[6]) / det; |
| inverse[5] = (temp[3] * temp[2] - temp[0] * temp[5]) / det; |
| inverse[6] = (temp[3] * temp[7] - temp[6] * temp[4]) / det; |
| inverse[7] = (temp[6] * temp[1] - temp[0] * temp[7]) / det; |
| inverse[8] = (temp[0] * temp[4] - temp[3] * temp[1]) / det; |
| |
| matrix_to_params(inverse, target); |
| } |
| |
| static void build_image_stack(YV12_BUFFER_CONFIG **const frames, |
| const int num_frames, const double **const params, |
| const int *const x_min, const int *const x_max, |
| const int *const y_min, const int *const y_max, |
| int pano_x_min, int pano_y_min, |
| YuvPixel ***img_stack) { |
| // Re-sample images onto panorama (pre-filtering). |
| const int x_offset = -pano_x_min; |
| const int y_offset = -pano_y_min; |
| const int frame_width = frames[0]->y_width; |
| const int frame_height = frames[0]->y_height; |
| for (int i = 0; i < num_frames; ++i) { |
| // Find transforms from panorama coordinate system back to single image |
| // coordinate system for sampling. |
| int transformed_width = x_max[i] - x_min[i] + 1; |
| int transformed_height = y_max[i] - y_min[i] + 1; |
| |
| double transform_matrix[MAX_PARAMDIM]; |
| double transform_params[MAX_PARAMDIM - 1]; |
| invert_params(params[i], transform_params); |
| params_to_matrix(transform_params, transform_matrix); |
| |
| #if CONFIG_HIGHBITDEPTH |
| const uint16_t *y_buffer16 = CONVERT_TO_SHORTPTR(frames[i]->y_buffer); |
| const uint16_t *u_buffer16 = CONVERT_TO_SHORTPTR(frames[i]->u_buffer); |
| const uint16_t *v_buffer16 = CONVERT_TO_SHORTPTR(frames[i]->v_buffer); |
| #endif // CONFIG_HIGHBITDEPTH |
| |
| for (int y = 0; y < transformed_height; ++y) { |
| for (int x = 0; x < transformed_width; ++x) { |
| // Do transform. |
| double xy_matrix[3] = { x + x_min[i], y + y_min[i], 1 }; |
| double uv_matrix[3] = { 0 }; |
| multiply_mat(transform_matrix, xy_matrix, uv_matrix, TRANSFORM_MAT_DIM, |
| TRANSFORM_MAT_DIM, 1); |
| |
| // Coordinates used for nearest neighbor interpolation. |
| int image_x = (int)round(uv_matrix[0]); |
| int image_y = (int)round(uv_matrix[1]); |
| |
| // Temporary values for bilinear interpolation |
| double interpolated_yvalue = 0.0; |
| double interpolated_uvalue = 0.0; |
| double interpolated_vvalue = 0.0; |
| double interpolated_fraction = 0.0; |
| int interpolation_count = 0; |
| |
| #if BGSPRITE_INTERPOLATION == 1 |
| // Coordintes used for bilinear interpolation. |
| double x_base; |
| double y_base; |
| double x_decimal = modf(uv_matrix[0], &x_base); |
| double y_decimal = modf(uv_matrix[1], &y_base); |
| |
| if ((x_decimal > 0.2 && x_decimal < 0.8) || |
| (y_decimal > 0.2 && y_decimal < 0.8)) { |
| for (int u = 0; u < 2; ++u) { |
| for (int v = 0; v < 2; ++v) { |
| int interp_x = (int)x_base + u; |
| int interp_y = (int)y_base + v; |
| if (interp_x >= 0 && interp_x < frame_width && interp_y >= 0 && |
| interp_y < frame_height) { |
| interpolation_count++; |
| |
| interpolated_fraction += |
| fabs(u - x_decimal) * fabs(v - y_decimal); |
| int ychannel_idx = interp_y * frames[i]->y_stride + interp_x; |
| int uvchannel_idx = (interp_y >> frames[i]->subsampling_y) * |
| frames[i]->uv_stride + |
| (interp_x >> frames[i]->subsampling_x); |
| #if CONFIG_HIGHBITDEPTH |
| if (frames[i]->flags & YV12_FLAG_HIGHBITDEPTH) { |
| interpolated_yvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| y_buffer16[ychannel_idx]; |
| interpolated_uvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| u_buffer16[uvchannel_idx]; |
| interpolated_vvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| v_buffer16[uvchannel_idx]; |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| interpolated_yvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| frames[i]->y_buffer[ychannel_idx]; |
| interpolated_uvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| frames[i]->u_buffer[uvchannel_idx]; |
| interpolated_vvalue += (1 - fabs(u - x_decimal)) * |
| (1 - fabs(v - y_decimal)) * |
| frames[i]->v_buffer[uvchannel_idx]; |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } |
| } |
| } |
| } |
| #endif // BGSPRITE_INTERPOLATION == 1 |
| |
| if (BGSPRITE_INTERPOLATION && interpolation_count > 2) { |
| if (interpolation_count != 4) { |
| interpolated_yvalue /= interpolated_fraction; |
| interpolated_uvalue /= interpolated_fraction; |
| interpolated_vvalue /= interpolated_fraction; |
| } |
| int pano_x = x + x_min[i] + x_offset; |
| int pano_y = y + y_min[i] + y_offset; |
| |
| #if CONFIG_HIGHBITDEPTH |
| if (frames[i]->flags & YV12_FLAG_HIGHBITDEPTH) { |
| img_stack[pano_y][pano_x][i].y = (uint16_t)interpolated_yvalue; |
| img_stack[pano_y][pano_x][i].u = (uint16_t)interpolated_uvalue; |
| img_stack[pano_y][pano_x][i].v = (uint16_t)interpolated_vvalue; |
| img_stack[pano_y][pano_x][i].exists = 1; |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| img_stack[pano_y][pano_x][i].y = (uint8_t)interpolated_yvalue; |
| img_stack[pano_y][pano_x][i].u = (uint8_t)interpolated_uvalue; |
| img_stack[pano_y][pano_x][i].v = (uint8_t)interpolated_vvalue; |
| img_stack[pano_y][pano_x][i].exists = 1; |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } else if (image_x >= 0 && image_x < frame_width && image_y >= 0 && |
| image_y < frame_height) { |
| // Place in panorama stack. |
| int pano_x = x + x_min[i] + x_offset; |
| int pano_y = y + y_min[i] + y_offset; |
| |
| int ychannel_idx = image_y * frames[i]->y_stride + image_x; |
| int uvchannel_idx = |
| (image_y >> frames[i]->subsampling_y) * frames[i]->uv_stride + |
| (image_x >> frames[i]->subsampling_x); |
| #if CONFIG_HIGHBITDEPTH |
| if (frames[i]->flags & YV12_FLAG_HIGHBITDEPTH) { |
| img_stack[pano_y][pano_x][i].y = y_buffer16[ychannel_idx]; |
| img_stack[pano_y][pano_x][i].u = u_buffer16[uvchannel_idx]; |
| img_stack[pano_y][pano_x][i].v = v_buffer16[uvchannel_idx]; |
| img_stack[pano_y][pano_x][i].exists = 1; |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| img_stack[pano_y][pano_x][i].y = frames[i]->y_buffer[ychannel_idx]; |
| img_stack[pano_y][pano_x][i].u = frames[i]->u_buffer[uvchannel_idx]; |
| img_stack[pano_y][pano_x][i].v = frames[i]->v_buffer[uvchannel_idx]; |
| img_stack[pano_y][pano_x][i].exists = 1; |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } |
| } |
| } |
| } |
| } |
| |
| #if BGSPRITE_BLENDING_MODE == 0 |
| // swaps two YuvPixels. |
| static void swap_yuv(YuvPixel *a, YuvPixel *b) { |
| const YuvPixel temp = *b; |
| *b = *a; |
| *a = temp; |
| } |
| |
| // Partitions array to find pivot index in qselect. |
| static int partition(YuvPixel arr[], int left, int right, int pivot_idx) { |
| YuvPixel pivot = arr[pivot_idx]; |
| |
| // Move pivot to the end. |
| swap_yuv(&arr[pivot_idx], &arr[right]); |
| |
| int p_idx = left; |
| for (int i = left; i < right; ++i) { |
| if (arr[i].y <= pivot.y) { |
| swap_yuv(&arr[i], &arr[p_idx]); |
| p_idx++; |
| } |
| } |
| |
| swap_yuv(&arr[p_idx], &arr[right]); |
| |
| return p_idx; |
| } |
| |
| // Returns the kth element in array, partially sorted in place (quickselect). |
| static YuvPixel qselect(YuvPixel arr[], int left, int right, int k) { |
| if (left >= right) { |
| return arr[left]; |
| } |
| unsigned int seed = (int)time(NULL); |
| int pivot_idx = left + rand_r(&seed) % (right - left + 1); |
| pivot_idx = partition(arr, left, right, pivot_idx); |
| |
| if (k == pivot_idx) { |
| return arr[k]; |
| } else if (k < pivot_idx) { |
| return qselect(arr, left, pivot_idx - 1, k); |
| } else { |
| return qselect(arr, pivot_idx + 1, right, k); |
| } |
| } |
| |
| // Blends image stack together using a temporal median. |
| static void blend_median(const int width, const int height, |
| const int num_frames, const YuvPixel ***image_stack, |
| YuvPixel **blended_img) { |
| // Allocate stack of pixels |
| YuvPixel *pixel_stack = aom_calloc(num_frames, sizeof(*pixel_stack)); |
| |
| // Apply median filtering using quickselect. |
| for (int y = 0; y < height; ++y) { |
| for (int x = 0; x < width; ++x) { |
| int count = 0; |
| for (int i = 0; i < num_frames; ++i) { |
| if (image_stack[y][x][i].exists) { |
| pixel_stack[count] = image_stack[y][x][i]; |
| ++count; |
| } |
| } |
| if (count == 0) { |
| // Just make the pixel black. |
| // TODO(toddnguyen): Color the pixel with nearest neighbor |
| blended_img[y][x].exists = 0; |
| } else { |
| const int median_idx = (int)floor(count / 2); |
| YuvPixel median = qselect(pixel_stack, 0, count - 1, median_idx); |
| |
| // Make the median value the 0th index for UV subsampling later |
| blended_img[y][x] = median; |
| blended_img[y][x].exists = 1; |
| } |
| } |
| } |
| |
| aom_free(pixel_stack); |
| } |
| #endif // BGSPRITE_BLENDING_MODE == 0 |
| |
| #if BGSPRITE_BLENDING_MODE == 1 |
| // Blends image stack together using a temporal mean. |
| static void blend_mean(const int width, const int height, const int num_frames, |
| const YuvPixel ***image_stack, YuvPixel **blended_img, |
| int highbitdepth) { |
| for (int y = 0; y < height; ++y) { |
| for (int x = 0; x < width; ++x) { |
| // Find |
| uint32_t y_sum = 0; |
| uint32_t u_sum = 0; |
| uint32_t v_sum = 0; |
| uint32_t count = 0; |
| for (int i = 0; i < num_frames; ++i) { |
| if (image_stack[y][x][i].exists) { |
| y_sum += image_stack[y][x][i].y; |
| u_sum += image_stack[y][x][i].u; |
| v_sum += image_stack[y][x][i].v; |
| ++count; |
| } |
| } |
| |
| #if BGSPRITE_MEAN_REMOVE_OUTLIERS |
| if (count > 1) { |
| double stdev = 0; |
| double y_mean = (double)y_sum / count; |
| for (int i = 0; i < num_frames; ++i) { |
| if (image_stack[y][x][i].exists) { |
| stdev += pow(y_mean - image_stack[y][x][i].y, 2); |
| } |
| } |
| stdev = sqrt(stdev / count); |
| |
| uint32_t inlier_y_sum = 0; |
| uint32_t inlier_u_sum = 0; |
| uint32_t inlier_v_sum = 0; |
| uint32_t inlier_count = 0; |
| for (int i = 0; i < num_frames; ++i) { |
| if (image_stack[y][x][i].exists && |
| fabs(image_stack[y][x][i].y - y_mean) <= 1.5 * stdev) { |
| inlier_y_sum += image_stack[y][x][i].y; |
| inlier_u_sum += image_stack[y][x][i].u; |
| inlier_v_sum += image_stack[y][x][i].v; |
| ++inlier_count; |
| } |
| } |
| count = inlier_count; |
| y_sum = inlier_y_sum; |
| u_sum = inlier_u_sum; |
| v_sum = inlier_v_sum; |
| } |
| #endif // BGSPRITE_MEAN_REMOVE_OUTLIERS |
| |
| if (count != 0) { |
| blended_img[y][x].exists = 1; |
| #if CONFIG_HIGHBITDEPTH |
| if (highbitdepth) { |
| blended_img[y][x].y = (uint16_t)OD_DIVU(y_sum, count); |
| blended_img[y][x].u = (uint16_t)OD_DIVU(u_sum, count); |
| blended_img[y][x].v = (uint16_t)OD_DIVU(v_sum, count); |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| (void)highbitdepth; |
| blended_img[y][x].y = (uint8_t)OD_DIVU(y_sum, count); |
| blended_img[y][x].u = (uint8_t)OD_DIVU(u_sum, count); |
| blended_img[y][x].v = (uint8_t)OD_DIVU(v_sum, count); |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } else { |
| blended_img[y][x].exists = 0; |
| } |
| } |
| } |
| } |
| #endif // BGSPRITE_BLENDING_MODE == 1 |
| |
| #if BGSPRITE_ENABLE_SEGMENTATION |
| // Builds dual-mode single gaussian model from image stack. |
| static void build_gaussian(const YuvPixel ***image_stack, const int num_frames, |
| const int width, const int height, |
| const int x_block_width, const int y_block_height, |
| const int block_size, YuvPixelGaussian **gauss) { |
| const double initial_variance = 10.0; |
| const double s_theta = 2.0; |
| |
| // Add images to dual-mode single gaussian model |
| for (int y_block = 0; y_block < y_block_height; ++y_block) { |
| for (int x_block = 0; x_block < x_block_width; ++x_block) { |
| // Process all blocks. |
| YuvPixelGaussian *model = &gauss[y_block][x_block]; |
| |
| // Process all frames. |
| for (int i = 0; i < num_frames; ++i) { |
| // Add block to the Gaussian model. |
| double max_variance[2] = { 0.0, 0.0 }; |
| double temp_y_mean = 0.0; |
| double temp_u_mean = 0.0; |
| double temp_v_mean = 0.0; |
| |
| // Find mean/variance of a block of pixels. |
| int temp_count = 0; |
| for (int sub_y = 0; sub_y < block_size; ++sub_y) { |
| for (int sub_x = 0; sub_x < block_size; ++sub_x) { |
| const int y = y_block * block_size + sub_y; |
| const int x = x_block * block_size + sub_x; |
| if (y < height && x < width && image_stack[y][x][i].exists) { |
| ++temp_count; |
| temp_y_mean += (double)image_stack[y][x][i].y; |
| temp_u_mean += (double)image_stack[y][x][i].u; |
| temp_v_mean += (double)image_stack[y][x][i].v; |
| |
| const double variance_0 = |
| pow((double)image_stack[y][x][i].y - model->mean[0], 2); |
| const double variance_1 = |
| pow((double)image_stack[y][x][i].y - model->mean[1], 2); |
| |
| if (variance_0 > max_variance[0]) { |
| max_variance[0] = variance_0; |
| } |
| if (variance_1 > max_variance[1]) { |
| max_variance[1] = variance_1; |
| } |
| } |
| } |
| } |
| |
| // If pixels exist in the block, add to the model. |
| if (temp_count > 0) { |
| assert(temp_count <= block_size * block_size); |
| temp_y_mean /= temp_count; |
| temp_u_mean /= temp_count; |
| temp_v_mean /= temp_count; |
| |
| // Switch the background model to the oldest model. |
| if (model->age[0] > model->age[1]) { |
| model->curr_model = 0; |
| } else if (model->age[1] > model->age[0]) { |
| model->curr_model = 1; |
| } |
| |
| // If model is empty, initialize model. |
| if (model->age[model->curr_model] == 0) { |
| model->mean[model->curr_model] = temp_y_mean; |
| model->u_mean[model->curr_model] = temp_u_mean; |
| model->v_mean[model->curr_model] = temp_v_mean; |
| model->var[model->curr_model] = initial_variance; |
| model->age[model->curr_model] = 1; |
| } else { |
| // Constants for current model and foreground model (0 or 1). |
| const int opposite = 1 - model->curr_model; |
| const int current = model->curr_model; |
| const double j = i; |
| |
| // Put block into the appropriate model. |
| if (pow(temp_y_mean - model->mean[current], 2) < |
| s_theta * model->var[current]) { |
| // Add block to the current background model |
| model->age[current] += 1; |
| const double prev_weight = 1 / j; |
| const double curr_weight = (j - 1) / j; |
| model->mean[current] = prev_weight * model->mean[current] + |
| curr_weight * temp_y_mean; |
| model->u_mean[current] = prev_weight * model->u_mean[current] + |
| curr_weight * temp_u_mean; |
| model->v_mean[current] = prev_weight * model->v_mean[current] + |
| curr_weight * temp_v_mean; |
| model->var[current] = prev_weight * model->var[current] + |
| curr_weight * max_variance[current]; |
| } else { |
| // Block does not fit into current background candidate. Add to |
| // foreground candidate and reinitialize if necessary. |
| const double var_fg = pow(temp_y_mean - model->mean[opposite], 2); |
| |
| if (var_fg <= s_theta * model->var[opposite]) { |
| model->age[opposite] += 1; |
| const double prev_weight = 1 / j; |
| const double curr_weight = (j - 1) / j; |
| model->mean[opposite] = prev_weight * model->mean[opposite] + |
| curr_weight * temp_y_mean; |
| model->u_mean[opposite] = |
| prev_weight * model->u_mean[opposite] + |
| curr_weight * temp_u_mean; |
| model->v_mean[opposite] = |
| prev_weight * model->v_mean[opposite] + |
| curr_weight * temp_v_mean; |
| model->var[opposite] = prev_weight * model->var[opposite] + |
| curr_weight * max_variance[opposite]; |
| } else if (model->age[opposite] == 0 || |
| var_fg > s_theta * model->var[opposite]) { |
| model->mean[opposite] = temp_y_mean; |
| model->u_mean[opposite] = temp_u_mean; |
| model->v_mean[opposite] = temp_v_mean; |
| model->var[opposite] = initial_variance; |
| model->age[opposite] = 1; |
| } else { |
| // This case should never happen. |
| assert(0); |
| } |
| } |
| } |
| } |
| } |
| |
| // Select the oldest candidate as the background model. |
| if (model->age[0] == 0 && model->age[1] == 0) { |
| model->y = 0; |
| model->u = 0; |
| model->v = 0; |
| model->final_var = 0; |
| } else if (model->age[0] > model->age[1]) { |
| model->y = (uint8_t)model->mean[0]; |
| model->u = (uint8_t)model->u_mean[0]; |
| model->v = (uint8_t)model->v_mean[0]; |
| model->final_var = model->var[0]; |
| } else { |
| model->y = (uint8_t)model->mean[1]; |
| model->u = (uint8_t)model->u_mean[1]; |
| model->v = (uint8_t)model->v_mean[1]; |
| model->final_var = model->var[1]; |
| } |
| } |
| } |
| } |
| |
| // Builds foreground mask based on reference image and gaussian model. |
| // In mask[][], 1 is foreground and 0 is background. |
| static void build_mask(const int x_min, const int y_min, const int x_offset, |
| const int y_offset, const int x_block_width, |
| const int y_block_height, const int block_size, |
| const YuvPixelGaussian **gauss, |
| YV12_BUFFER_CONFIG *const reference, |
| YV12_BUFFER_CONFIG *const panorama, uint8_t **mask) { |
| const int crop_x_offset = x_min + x_offset; |
| const int crop_y_offset = y_min + y_offset; |
| const double d_theta = 4.0; |
| |
| for (int y_block = 0; y_block < y_block_height; ++y_block) { |
| for (int x_block = 0; x_block < x_block_width; ++x_block) { |
| // Create mask to determine if ARF is background for foreground. |
| const YuvPixelGaussian *model = &gauss[y_block][x_block]; |
| double temp_y_mean = 0.0; |
| int temp_count = 0; |
| |
| for (int sub_y = 0; sub_y < block_size; ++sub_y) { |
| for (int sub_x = 0; sub_x < block_size; ++sub_x) { |
| // x and y are panorama coordinates. |
| const int y = y_block * block_size + sub_y; |
| const int x = x_block * block_size + sub_x; |
| |
| const int arf_y = y - crop_y_offset; |
| const int arf_x = x - crop_x_offset; |
| |
| if (arf_y >= 0 && arf_y < panorama->y_height && arf_x >= 0 && |
| arf_x < panorama->y_width) { |
| ++temp_count; |
| const int ychannel_idx = arf_y * panorama->y_stride + arf_x; |
| temp_y_mean += (double)reference->y_buffer[ychannel_idx]; |
| } |
| } |
| } |
| if (temp_count > 0) { |
| assert(temp_count <= block_size * block_size); |
| temp_y_mean /= temp_count; |
| |
| if (pow(temp_y_mean - model->y, 2) > model->final_var * d_theta) { |
| // Mark block as foreground. |
| mask[y_block][x_block] = 1; |
| } |
| } |
| } |
| } |
| } |
| #endif // BGSPRITE_ENABLE_SEGMENTATION |
| |
| // Resamples blended_img into panorama, including UV subsampling. |
| static void resample_panorama(YuvPixel **blended_img, const int center_idx, |
| const int *const x_min, const int *const y_min, |
| int pano_x_min, int pano_x_max, int pano_y_min, |
| int pano_y_max, YV12_BUFFER_CONFIG *panorama) { |
| const int width = pano_x_max - pano_x_min + 1; |
| const int height = pano_y_max - pano_y_min + 1; |
| const int x_offset = -pano_x_min; |
| const int y_offset = -pano_y_min; |
| const int crop_x_offset = x_min[center_idx] + x_offset; |
| const int crop_y_offset = y_min[center_idx] + y_offset; |
| #if CONFIG_HIGHBITDEPTH |
| if (panorama->flags & YV12_FLAG_HIGHBITDEPTH) { |
| // Use median Y value. |
| uint16_t *pano_y_buffer16 = CONVERT_TO_SHORTPTR(panorama->y_buffer); |
| uint16_t *pano_u_buffer16 = CONVERT_TO_SHORTPTR(panorama->u_buffer); |
| uint16_t *pano_v_buffer16 = CONVERT_TO_SHORTPTR(panorama->v_buffer); |
| |
| for (int y = 0; y < panorama->y_height; ++y) { |
| for (int x = 0; x < panorama->y_width; ++x) { |
| const int ychannel_idx = y * panorama->y_stride + x; |
| if (blended_img[y + crop_y_offset][x + crop_x_offset].exists) { |
| pano_y_buffer16[ychannel_idx] = |
| blended_img[y + crop_y_offset][x + crop_x_offset].y; |
| } else { |
| pano_y_buffer16[ychannel_idx] = 0; |
| } |
| } |
| } |
| |
| // UV subsampling with median UV values |
| for (int y = 0; y < panorama->uv_height; ++y) { |
| for (int x = 0; x < panorama->uv_width; ++x) { |
| uint32_t avg_count = 0; |
| uint32_t u_sum = 0; |
| uint32_t v_sum = 0; |
| |
| // Look at surrounding pixels for subsampling |
| for (int s_x = 0; s_x < panorama->subsampling_x + 1; ++s_x) { |
| for (int s_y = 0; s_y < panorama->subsampling_y + 1; ++s_y) { |
| int y_sample = crop_y_offset + (y << panorama->subsampling_y) + s_y; |
| int x_sample = crop_x_offset + (x << panorama->subsampling_x) + s_x; |
| if (y_sample > 0 && y_sample < height && x_sample > 0 && |
| x_sample < width && blended_img[y_sample][x_sample].exists) { |
| u_sum += blended_img[y_sample][x_sample].u; |
| v_sum += blended_img[y_sample][x_sample].v; |
| avg_count++; |
| } |
| } |
| } |
| |
| const int uvchannel_idx = y * panorama->uv_stride + x; |
| if (avg_count != 0) { |
| pano_u_buffer16[uvchannel_idx] = (uint16_t)OD_DIVU(u_sum, avg_count); |
| pano_v_buffer16[uvchannel_idx] = (uint16_t)OD_DIVU(v_sum, avg_count); |
| } else { |
| pano_u_buffer16[uvchannel_idx] = 0; |
| pano_v_buffer16[uvchannel_idx] = 0; |
| } |
| } |
| } |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| // Use blended Y value. |
| for (int y = 0; y < panorama->y_height; ++y) { |
| for (int x = 0; x < panorama->y_width; ++x) { |
| const int ychannel_idx = y * panorama->y_stride + x; |
| // Use filtered background. |
| if (blended_img[y + crop_y_offset][x + crop_x_offset].exists) { |
| panorama->y_buffer[ychannel_idx] = |
| blended_img[y + crop_y_offset][x + crop_x_offset].y; |
| } else { |
| panorama->y_buffer[ychannel_idx] = 0; |
| } |
| } |
| } |
| |
| // UV subsampling with blended UV values. |
| for (int y = 0; y < panorama->uv_height; ++y) { |
| for (int x = 0; x < panorama->uv_width; ++x) { |
| uint16_t avg_count = 0; |
| uint16_t u_sum = 0; |
| uint16_t v_sum = 0; |
| |
| // Look at surrounding pixels for subsampling. |
| for (int s_x = 0; s_x < panorama->subsampling_x + 1; ++s_x) { |
| for (int s_y = 0; s_y < panorama->subsampling_y + 1; ++s_y) { |
| int y_sample = crop_y_offset + (y << panorama->subsampling_y) + s_y; |
| int x_sample = crop_x_offset + (x << panorama->subsampling_x) + s_x; |
| if (y_sample > 0 && y_sample < height && x_sample > 0 && |
| x_sample < width && blended_img[y_sample][x_sample].exists) { |
| u_sum += blended_img[y_sample][x_sample].u; |
| v_sum += blended_img[y_sample][x_sample].v; |
| avg_count++; |
| } |
| } |
| } |
| |
| const int uvchannel_idx = y * panorama->uv_stride + x; |
| if (avg_count != 0) { |
| panorama->u_buffer[uvchannel_idx] = |
| (uint8_t)OD_DIVU(u_sum, avg_count); |
| panorama->v_buffer[uvchannel_idx] = |
| (uint8_t)OD_DIVU(v_sum, avg_count); |
| } else { |
| panorama->u_buffer[uvchannel_idx] = 0; |
| panorama->v_buffer[uvchannel_idx] = 0; |
| } |
| } |
| } |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } |
| |
| #if BGSPRITE_ENABLE_SEGMENTATION |
| // Combines temporal filter output and bgsprite output to make final ARF output |
| static void combine_arf(YV12_BUFFER_CONFIG *const temporal_arf, |
| YV12_BUFFER_CONFIG *const bgsprite, |
| uint8_t **const mask, const int block_size, |
| const int x_offset, const int y_offset, |
| YV12_BUFFER_CONFIG *target) { |
| const int height = temporal_arf->y_height; |
| const int width = temporal_arf->y_width; |
| |
| YuvPixel **blended_img = aom_malloc(height * sizeof(*blended_img)); |
| for (int i = 0; i < height; ++i) { |
| blended_img[i] = aom_malloc(width * sizeof(**blended_img)); |
| } |
| |
| const int block_2_height = (height / BGSPRITE_MASK_BLOCK_SIZE) + |
| (height % BGSPRITE_MASK_BLOCK_SIZE != 0 ? 1 : 0); |
| const int block_2_width = (width / BGSPRITE_MASK_BLOCK_SIZE) + |
| (width % BGSPRITE_MASK_BLOCK_SIZE != 0 ? 1 : 0); |
| |
| for (int block_y = 0; block_y < block_2_height; ++block_y) { |
| for (int block_x = 0; block_x < block_2_width; ++block_x) { |
| int count = 0; |
| int total = 0; |
| for (int sub_y = 0; sub_y < BGSPRITE_MASK_BLOCK_SIZE; ++sub_y) { |
| for (int sub_x = 0; sub_x < BGSPRITE_MASK_BLOCK_SIZE; ++sub_x) { |
| const int img_y = block_y * BGSPRITE_MASK_BLOCK_SIZE + sub_y; |
| const int img_x = block_x * BGSPRITE_MASK_BLOCK_SIZE + sub_x; |
| const int mask_y = (y_offset + img_y) / block_size; |
| const int mask_x = (x_offset + img_x) / block_size; |
| |
| if (img_y < height && img_x < width) { |
| if (mask[mask_y][mask_x]) { |
| ++count; |
| } |
| ++total; |
| } |
| } |
| } |
| |
| const double threshold = 0.30; |
| const int amount = (int)(threshold * total); |
| for (int sub_y = 0; sub_y < BGSPRITE_MASK_BLOCK_SIZE; ++sub_y) { |
| for (int sub_x = 0; sub_x < BGSPRITE_MASK_BLOCK_SIZE; ++sub_x) { |
| const int y = block_y * BGSPRITE_MASK_BLOCK_SIZE + sub_y; |
| const int x = block_x * BGSPRITE_MASK_BLOCK_SIZE + sub_x; |
| if (y < height && x < width) { |
| blended_img[y][x].exists = 1; |
| const int ychannel_idx = y * temporal_arf->y_stride + x; |
| const int uvchannel_idx = |
| (y >> temporal_arf->subsampling_y) * temporal_arf->uv_stride + |
| (x >> temporal_arf->subsampling_x); |
| |
| if (count > amount) { |
| // Foreground; use temporal arf. |
| #if CONFIG_HIGHBITDEPTH |
| if (temporal_arf->flags & YV12_FLAG_HIGHBITDEPTH) { |
| uint16_t *pano_y_buffer16 = |
| CONVERT_TO_SHORTPTR(temporal_arf->y_buffer); |
| uint16_t *pano_u_buffer16 = |
| CONVERT_TO_SHORTPTR(temporal_arf->u_buffer); |
| uint16_t *pano_v_buffer16 = |
| CONVERT_TO_SHORTPTR(temporal_arf->v_buffer); |
| blended_img[y][x].y = pano_y_buffer16[ychannel_idx]; |
| blended_img[y][x].u = pano_u_buffer16[uvchannel_idx]; |
| blended_img[y][x].v = pano_v_buffer16[uvchannel_idx]; |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| blended_img[y][x].y = temporal_arf->y_buffer[ychannel_idx]; |
| blended_img[y][x].u = temporal_arf->u_buffer[uvchannel_idx]; |
| blended_img[y][x].v = temporal_arf->v_buffer[uvchannel_idx]; |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } else { |
| // Background; use bgsprite arf. |
| #if CONFIG_HIGHBITDEPTH |
| if (bgsprite->flags & YV12_FLAG_HIGHBITDEPTH) { |
| uint16_t *pano_y_buffer16 = |
| CONVERT_TO_SHORTPTR(bgsprite->y_buffer); |
| uint16_t *pano_u_buffer16 = |
| CONVERT_TO_SHORTPTR(bgsprite->u_buffer); |
| uint16_t *pano_v_buffer16 = |
| CONVERT_TO_SHORTPTR(bgsprite->v_buffer); |
| blended_img[y][x].y = pano_y_buffer16[ychannel_idx]; |
| blended_img[y][x].u = pano_u_buffer16[uvchannel_idx]; |
| blended_img[y][x].v = pano_v_buffer16[uvchannel_idx]; |
| } else { |
| #endif // CONFIG_HIGHBITDEPTH |
| blended_img[y][x].y = bgsprite->y_buffer[ychannel_idx]; |
| blended_img[y][x].u = bgsprite->u_buffer[uvchannel_idx]; |
| blended_img[y][x].v = bgsprite->v_buffer[uvchannel_idx]; |
| #if CONFIG_HIGHBITDEPTH |
| } |
| #endif // CONFIG_HIGHBITDEPTH |
| } |
| } |
| } |
| } |
| } |
| } |
| |
| const int x_min = 0; |
| const int y_min = 0; |
| resample_panorama(blended_img, 0, &x_min, &y_min, 0, width - 1, 0, height - 1, |
| target); |
| |
| for (int i = 0; i < height; ++i) { |
| aom_free(blended_img[i]); |
| } |
| aom_free(blended_img); |
| } |
| #endif // BGSPRITE_ENABLE_SEGMENTATION |
| |
| // Stitches images together to create ARF and stores it in 'panorama'. |
| static void stitch_images(AV1_COMP *cpi, YV12_BUFFER_CONFIG **const frames, |
| const int num_frames, const int distance, |
| const int center_idx, const double **const params, |
| const int *const x_min, const int *const x_max, |
| const int *const y_min, const int *const y_max, |
| int pano_x_min, int pano_x_max, int pano_y_min, |
| int pano_y_max, YV12_BUFFER_CONFIG *panorama) { |
| const int width = pano_x_max - pano_x_min + 1; |
| const int height = pano_y_max - pano_y_min + 1; |
| |
| // Create pano_stack[y][x][num_frames] stack of pixel values |
| YuvPixel ***pano_stack = aom_malloc(height * sizeof(*pano_stack)); |
| for (int i = 0; i < height; ++i) { |
| pano_stack[i] = aom_malloc(width * sizeof(**pano_stack)); |
| for (int j = 0; j < width; ++j) { |
| pano_stack[i][j] = aom_calloc(num_frames, sizeof(***pano_stack)); |
| } |
| } |
| |
| build_image_stack(frames, num_frames, params, x_min, x_max, y_min, y_max, |
| pano_x_min, pano_y_min, pano_stack); |
| |
| // Create blended_img[y][x] of combined panorama pixel values. |
| YuvPixel **blended_img = aom_malloc(height * sizeof(*blended_img)); |
| for (int i = 0; i < height; ++i) { |
| blended_img[i] = aom_malloc(width * sizeof(**blended_img)); |
| } |
| |
| // Blending and saving result in blended_img. |
| #if BGSPRITE_BLENDING_MODE == 1 |
| blend_mean(width, height, num_frames, (const YuvPixel ***)pano_stack, |
| blended_img, panorama->flags & YV12_FLAG_HIGHBITDEPTH); |
| #else // BGSPRITE_BLENDING_MODE != 1 |
| blend_median(width, height, num_frames, (const YuvPixel ***)pano_stack, |
| blended_img); |
| #endif // BGSPRITE_BLENDING_MODE == 1 |
| |
| // NOTE(toddnguyen): Right now the ARF in the cpi struct is fixed size at |
| // the same size as the frames. For now, we crop the generated panorama. |
| assert(panorama->y_width <= width && panorama->y_height <= height); |
| |
| // Resamples the blended_img into the panorama buffer. |
| YV12_BUFFER_CONFIG bgsprite; |
| memset(&bgsprite, 0, sizeof(bgsprite)); |
| aom_alloc_frame_buffer(&bgsprite, frames[0]->y_width, frames[0]->y_height, |
| frames[0]->subsampling_x, frames[0]->subsampling_y, |
| #if CONFIG_HIGHBITDEPTH |
| frames[0]->flags & YV12_FLAG_HIGHBITDEPTH, |
| #endif |
| frames[0]->border, 0); |
| aom_yv12_copy_frame(frames[0], &bgsprite); |
| bgsprite.bit_depth = frames[0]->bit_depth; |
| resample_panorama(blended_img, center_idx, x_min, y_min, pano_x_min, |
| pano_x_max, pano_y_min, pano_y_max, &bgsprite); |
| |
| #if BGSPRITE_ENABLE_SEGMENTATION |
| YV12_BUFFER_CONFIG temporal_bgsprite; |
| memset(&temporal_bgsprite, 0, sizeof(temporal_bgsprite)); |
| aom_alloc_frame_buffer(&temporal_bgsprite, frames[0]->y_width, |
| frames[0]->y_height, frames[0]->subsampling_x, |
| frames[0]->subsampling_y, |
| #if CONFIG_HIGHBITDEPTH |
| frames[0]->flags & YV12_FLAG_HIGHBITDEPTH, |
| #endif |
| frames[0]->border, 0); |
| aom_yv12_copy_frame(frames[0], &temporal_bgsprite); |
| temporal_bgsprite.bit_depth = frames[0]->bit_depth; |
| |
| av1_temporal_filter(cpi, &bgsprite, &temporal_bgsprite, distance); |
| |
| // Block size constants for gaussian model. |
| const int N_1 = 2; |
| const int y_block_height = (height / N_1) + (height % N_1 != 0 ? 1 : 0); |
| const int x_block_width = (width / N_1) + (height % N_1 != 0 ? 1 : 0); |
| YuvPixelGaussian **gauss = aom_malloc(y_block_height * sizeof(*gauss)); |
| for (int i = 0; i < y_block_height; ++i) { |
| gauss[i] = aom_calloc(x_block_width, sizeof(**gauss)); |
| } |
| |
| // Build Gaussian model. |
| build_gaussian((const YuvPixel ***)pano_stack, num_frames, width, height, |
| x_block_width, y_block_height, N_1, gauss); |
| |
| // Select background model and build foreground mask. |
| uint8_t **mask = aom_malloc(y_block_height * sizeof(*mask)); |
| for (int i = 0; i < y_block_height; ++i) { |
| mask[i] = aom_calloc(x_block_width, sizeof(**mask)); |
| } |
| |
| const int x_offset = -pano_x_min; |
| const int y_offset = -pano_y_min; |
| build_mask(x_min[center_idx], y_min[center_idx], x_offset, y_offset, |
| x_block_width, y_block_height, N_1, |
| (const YuvPixelGaussian **)gauss, |
| (YV12_BUFFER_CONFIG * const) frames[center_idx], panorama, mask); |
| |
| YV12_BUFFER_CONFIG temporal_arf; |
| memset(&temporal_arf, 0, sizeof(temporal_arf)); |
| aom_alloc_frame_buffer(&temporal_arf, frames[0]->y_width, frames[0]->y_height, |
| frames[0]->subsampling_x, frames[0]->subsampling_y, |
| #if CONFIG_HIGHBITDEPTH |
| frames[0]->flags & YV12_FLAG_HIGHBITDEPTH, |
| #endif |
| frames[0]->border, 0); |
| aom_yv12_copy_frame(frames[0], &temporal_arf); |
| temporal_arf.bit_depth = frames[0]->bit_depth; |
| av1_temporal_filter(cpi, NULL, &temporal_arf, distance); |
| |
| combine_arf(&temporal_arf, &temporal_bgsprite, mask, N_1, x_offset, y_offset, |
| panorama); |
| |
| aom_free_frame_buffer(&temporal_arf); |
| aom_free_frame_buffer(&temporal_bgsprite); |
| for (int i = 0; i < y_block_height; ++i) { |
| aom_free(gauss[i]); |
| aom_free(mask[i]); |
| } |
| aom_free(gauss); |
| aom_free(mask); |
| #else // !BGSPRITE_ENABLE_SEGMENTATION |
| av1_temporal_filter(cpi, &bgsprite, panorama, distance); |
| #endif // BGSPRITE_ENABLE_SEGMENTATION |
| |
| aom_free_frame_buffer(&bgsprite); |
| for (int i = 0; i < height; ++i) { |
| for (int j = 0; j < width; ++j) { |
| aom_free(pano_stack[i][j]); |
| } |
| aom_free(pano_stack[i]); |
| aom_free(blended_img[i]); |
| } |
| aom_free(pano_stack); |
| aom_free(blended_img); |
| } |
| |
| int av1_background_sprite(AV1_COMP *cpi, int distance) { |
| #if BGSPRITE_ENABLE_METRICS |
| // Do temporal filter if firstpass stats disable bgsprite. |
| if (!cpi->bgsprite_allowed) { |
| return 1; |
| } |
| #endif // BGSPRITE_ENABLE_METRICS |
| |
| YV12_BUFFER_CONFIG *frames[MAX_LAG_BUFFERS] = { NULL }; |
| static const double identity_params[MAX_PARAMDIM - 1] = { |
| 0.0, 0.0, 1.0, 0.0, 0.0, 1.0, 0.0, 0.0 |
| }; |
| |
| const int frames_after_arf = |
| av1_lookahead_depth(cpi->lookahead) - distance - 1; |
| int frames_fwd = (cpi->oxcf.arnr_max_frames - 1) >> 1; |
| int frames_bwd; |
| |
| // Define the forward and backwards filter limits for this arnr group. |
| if (frames_fwd > frames_after_arf) frames_fwd = frames_after_arf; |
| if (frames_fwd > distance) frames_fwd = distance; |
| frames_bwd = frames_fwd; |
| |
| #if CONFIG_EXT_REFS |
| const GF_GROUP *const gf_group = &cpi->twopass.gf_group; |
| if (gf_group->rf_level[gf_group->index] == GF_ARF_LOW) { |
| cpi->is_arf_filter_off[gf_group->arf_update_idx[gf_group->index]] = 1; |
| frames_fwd = 0; |
| frames_bwd = 0; |
| } else { |
| cpi->is_arf_filter_off[gf_group->arf_update_idx[gf_group->index]] = 0; |
| } |
| #endif // CONFIG_EXT_REFS |
| |
| const int start_frame = distance + frames_fwd; |
| const int frames_to_stitch = frames_bwd + 1 + frames_fwd; |
| |
| // Get frames to be included in background sprite. |
| for (int frame = 0; frame < frames_to_stitch; ++frame) { |
| const int which_buffer = start_frame - frame; |
| struct lookahead_entry *buf = |
| av1_lookahead_peek(cpi->lookahead, which_buffer); |
| frames[frames_to_stitch - 1 - frame] = &buf->img; |
| } |
| |
| // Allocate empty arrays for parameters between frames. |
| double **params = aom_malloc(frames_to_stitch * sizeof(*params)); |
| for (int i = 0; i < frames_to_stitch; ++i) { |
| params[i] = aom_malloc(sizeof(identity_params)); |
| memcpy(params[i], identity_params, sizeof(identity_params)); |
| } |
| |
| // Use global motion to find affine transformations between frames. |
| // params[i] will have the transform from frame[i] to frame[i-1]. |
| // params[0] will have the identity matrix (has no previous frame). |
| #if BGSPRITE_ENABLE_GME |
| TransformationType model = AFFINE; |
| int inliers_by_motion[RANSAC_NUM_MOTIONS]; |
| for (int frame = 0; frame < frames_to_stitch - 1; ++frame) { |
| const int global_motion_ret = compute_global_motion_feature_based( |
| model, frames[frame + 1], frames[frame], |
| #if CONFIG_HIGHBITDEPTH |
| cpi->common.bit_depth, |
| #endif // CONFIG_HIGHBITDEPTH |
| inliers_by_motion, params[frame + 1], RANSAC_NUM_MOTIONS); |
| |
| // Quit if global motion had an error. |
| if (global_motion_ret == 0) { |
| for (int i = 0; i < frames_to_stitch; ++i) { |
| aom_free(params[i]); |
| } |
| aom_free(params); |
| return 1; |
| } |
| } |
| #endif // BGSPRITE_ENABLE_GME |
| |
| // Compound the transformation parameters. |
| for (int i = 1; i < frames_to_stitch; ++i) { |
| multiply_params(params[i - 1], params[i], params[i]); |
| } |
| |
| // Compute frame limits for final stitched images. |
| int pano_x_max = INT_MIN; |
| int pano_x_min = INT_MAX; |
| int pano_y_max = INT_MIN; |
| int pano_y_min = INT_MAX; |
| int *x_max = aom_malloc(frames_to_stitch * sizeof(*x_max)); |
| int *x_min = aom_malloc(frames_to_stitch * sizeof(*x_min)); |
| int *y_max = aom_malloc(frames_to_stitch * sizeof(*y_max)); |
| int *y_min = aom_malloc(frames_to_stitch * sizeof(*y_min)); |
| |
| find_limits(frames[0]->y_width, frames[0]->y_height, |
| (const double **const)params, frames_to_stitch, x_min, x_max, |
| y_min, y_max, &pano_x_min, &pano_x_max, &pano_y_min, &pano_y_max); |
| |
| // Center panorama on the ARF. |
| const int center_idx = frames_bwd; |
| assert(center_idx >= 0 && center_idx < frames_to_stitch); |
| |
| // Recompute transformations to adjust to center image. |
| // Invert center image's transform. |
| double inverse[MAX_PARAMDIM - 1] = { 0 }; |
| invert_params(params[center_idx], inverse); |
| |
| // Multiply the inverse to all transformation parameters. |
| for (int i = 0; i < frames_to_stitch; ++i) { |
| multiply_params(inverse, params[i], params[i]); |
| } |
| |
| // Recompute frame limits for new adjusted center. |
| find_limits(frames[0]->y_width, frames[0]->y_height, |
| (const double **const)params, frames_to_stitch, x_min, x_max, |
| y_min, y_max, &pano_x_min, &pano_x_max, &pano_y_min, &pano_y_max); |
| |
| // Stitch Images and apply bgsprite filter. |
| stitch_images(cpi, frames, frames_to_stitch, distance, center_idx, |
| (const double **const)params, x_min, x_max, y_min, y_max, |
| pano_x_min, pano_x_max, pano_y_min, pano_y_max, |
| &cpi->alt_ref_buffer); |
| |
| // Free memory. |
| for (int i = 0; i < frames_to_stitch; ++i) { |
| aom_free(params[i]); |
| } |
| aom_free(params); |
| aom_free(x_max); |
| aom_free(x_min); |
| aom_free(y_max); |
| aom_free(y_min); |
| |
| return 0; |
| } |
| |
| #undef _POSIX_C_SOURCE |
| #undef BGSPRITE_BLENDING_MODE |
| #undef BGSPRITE_INTERPOLATION |
| #undef BGSPRITE_ENABLE_METRICS |
| #undef BGSPRITE_ENABLE_SEGMENTATION |
| #undef BGSPRITE_ENABLE_GME |
| #undef BGSPRITE_MASK_BLOCK_SIZE |
| #undef TRANSFORM_MAT_DIM |