/* * Copyright (c) 2016, 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. */ #include #include #include #include #include #include #include "config/aom_dsp_rtcd.h" #include "av1/encoder/global_motion.h" #include "av1/common/convolve.h" #include "av1/common/warped_motion.h" #include "av1/encoder/segmentation.h" #define MIN_TRANS_THRESH (1 * GM_TRANS_DECODE_FACTOR) // Border over which to compute the global motion #define ERRORADV_BORDER 0 int av1_is_enough_erroradvantage(double best_erroradvantage, int params_cost) { return best_erroradvantage < erroradv_tr && best_erroradvantage * params_cost < erroradv_prod_tr; } static void convert_to_params(const double *params, int32_t *model) { int i; int alpha_present = 0; model[0] = (int32_t)floor(params[0] * (1 << GM_TRANS_PREC_BITS) + 0.5); model[1] = (int32_t)floor(params[1] * (1 << GM_TRANS_PREC_BITS) + 0.5); model[0] = (int32_t)clamp(model[0], GM_TRANS_MIN, GM_TRANS_MAX) * GM_TRANS_DECODE_FACTOR; model[1] = (int32_t)clamp(model[1], GM_TRANS_MIN, GM_TRANS_MAX) * GM_TRANS_DECODE_FACTOR; for (i = 2; i < 6; ++i) { const int diag_value = ((i == 2 || i == 5) ? (1 << GM_ALPHA_PREC_BITS) : 0); model[i] = (int32_t)floor(params[i] * (1 << GM_ALPHA_PREC_BITS) + 0.5); model[i] = (int32_t)clamp(model[i] - diag_value, GM_ALPHA_MIN, GM_ALPHA_MAX); alpha_present |= (model[i] != 0); model[i] = (model[i] + diag_value) * GM_ALPHA_DECODE_FACTOR; } for (; i < 8; ++i) { model[i] = (int32_t)floor(params[i] * (1 << GM_ROW3HOMO_PREC_BITS) + 0.5); model[i] = (int32_t)clamp(model[i], GM_ROW3HOMO_MIN, GM_ROW3HOMO_MAX) * GM_ROW3HOMO_DECODE_FACTOR; alpha_present |= (model[i] != 0); } if (!alpha_present) { if (abs(model[0]) < MIN_TRANS_THRESH && abs(model[1]) < MIN_TRANS_THRESH) { model[0] = 0; model[1] = 0; } } } void av1_convert_model_to_params(const double *params, WarpedMotionParams *model) { convert_to_params(params, model->wmmat); model->wmtype = get_wmtype(model); model->invalid = 0; } // Adds some offset to a global motion parameter and handles // all of the necessary precision shifts, clamping, and // zero-centering. static int32_t add_param_offset(int param_index, int32_t param_value, int32_t offset) { const int scale_vals[3] = { GM_TRANS_PREC_DIFF, GM_ALPHA_PREC_DIFF, GM_ROW3HOMO_PREC_DIFF }; const int clamp_vals[3] = { GM_TRANS_MAX, GM_ALPHA_MAX, GM_ROW3HOMO_MAX }; // type of param: 0 - translation, 1 - affine, 2 - homography const int param_type = (param_index < 2 ? 0 : (param_index < 6 ? 1 : 2)); const int is_one_centered = (param_index == 2 || param_index == 5); // Make parameter zero-centered and offset the shift that was done to make // it compatible with the warped model param_value = (param_value - (is_one_centered << WARPEDMODEL_PREC_BITS)) >> scale_vals[param_type]; // Add desired offset to the rescaled/zero-centered parameter param_value += offset; // Clamp the parameter so it does not overflow the number of bits allotted // to it in the bitstream param_value = (int32_t)clamp(param_value, -clamp_vals[param_type], clamp_vals[param_type]); // Rescale the parameter to WARPEDMODEL_PRECISION_BITS so it is compatible // with the warped motion library param_value *= (1 << scale_vals[param_type]); // Undo the zero-centering step if necessary return param_value + (is_one_centered << WARPEDMODEL_PREC_BITS); } static void force_wmtype(WarpedMotionParams *wm, TransformationType wmtype) { switch (wmtype) { case IDENTITY: wm->wmmat[0] = 0; wm->wmmat[1] = 0; AOM_FALLTHROUGH_INTENDED; case TRANSLATION: wm->wmmat[2] = 1 << WARPEDMODEL_PREC_BITS; wm->wmmat[3] = 0; AOM_FALLTHROUGH_INTENDED; case ROTZOOM: wm->wmmat[4] = -wm->wmmat[3]; wm->wmmat[5] = wm->wmmat[2]; AOM_FALLTHROUGH_INTENDED; case AFFINE: break; default: assert(0); } wm->wmtype = wmtype; } #if CONFIG_AV1_HIGHBITDEPTH static int64_t highbd_warp_error( WarpedMotionParams *wm, const uint16_t *const ref, int width, int height, int stride, const uint16_t *const dst, int p_col, int p_row, int p_width, int p_height, int p_stride, int subsampling_x, int subsampling_y, int bd, int64_t best_error, uint8_t *segment_map, int segment_map_stride) { int64_t gm_sumerr = 0; const int error_bsize_w = AOMMIN(p_width, WARP_ERROR_BLOCK); const int error_bsize_h = AOMMIN(p_height, WARP_ERROR_BLOCK); uint16_t tmp[WARP_ERROR_BLOCK * WARP_ERROR_BLOCK]; ConvolveParams conv_params = get_conv_params(0, 0, bd); conv_params.use_dist_wtd_comp_avg = 0; for (int i = p_row; i < p_row + p_height; i += WARP_ERROR_BLOCK) { for (int j = p_col; j < p_col + p_width; j += WARP_ERROR_BLOCK) { int seg_x = j >> WARP_ERROR_BLOCK_LOG; int seg_y = i >> WARP_ERROR_BLOCK_LOG; // Only compute the error if this block contains inliers from the motion // model if (!segment_map[seg_y * segment_map_stride + seg_x]) continue; // avoid warping extra 8x8 blocks in the padded region of the frame // when p_width and p_height are not multiples of WARP_ERROR_BLOCK const int warp_w = AOMMIN(error_bsize_w, p_col + p_width - j); const int warp_h = AOMMIN(error_bsize_h, p_row + p_height - i); highbd_warp_plane(wm, ref, width, height, stride, tmp, j, i, warp_w, warp_h, WARP_ERROR_BLOCK, subsampling_x, subsampling_y, bd, &conv_params); gm_sumerr += av1_calc_highbd_frame_error(tmp, WARP_ERROR_BLOCK, dst + j + i * p_stride, warp_w, warp_h, p_stride, bd); if (gm_sumerr > best_error) return INT64_MAX; } } return gm_sumerr; } #endif static int64_t warp_error(WarpedMotionParams *wm, const uint8_t *const ref, int width, int height, int stride, const uint8_t *const dst, int p_col, int p_row, int p_width, int p_height, int p_stride, int subsampling_x, int subsampling_y, int64_t best_error, uint8_t *segment_map, int segment_map_stride) { int64_t gm_sumerr = 0; int warp_w, warp_h; const int error_bsize_w = AOMMIN(p_width, WARP_ERROR_BLOCK); const int error_bsize_h = AOMMIN(p_height, WARP_ERROR_BLOCK); DECLARE_ALIGNED(16, uint8_t, tmp[WARP_ERROR_BLOCK * WARP_ERROR_BLOCK]); ConvolveParams conv_params = get_conv_params(0, 0, 8); conv_params.use_dist_wtd_comp_avg = 0; for (int i = p_row; i < p_row + p_height; i += WARP_ERROR_BLOCK) { for (int j = p_col; j < p_col + p_width; j += WARP_ERROR_BLOCK) { int seg_x = j >> WARP_ERROR_BLOCK_LOG; int seg_y = i >> WARP_ERROR_BLOCK_LOG; // Only compute the error if this block contains inliers from the motion // model if (!segment_map[seg_y * segment_map_stride + seg_x]) continue; // avoid warping extra 8x8 blocks in the padded region of the frame // when p_width and p_height are not multiples of WARP_ERROR_BLOCK warp_w = AOMMIN(error_bsize_w, p_col + p_width - j); warp_h = AOMMIN(error_bsize_h, p_row + p_height - i); warp_plane(wm, ref, width, height, stride, tmp, j, i, warp_w, warp_h, WARP_ERROR_BLOCK, subsampling_x, subsampling_y, &conv_params); gm_sumerr += av1_calc_frame_error(tmp, WARP_ERROR_BLOCK, dst + j + i * p_stride, warp_w, warp_h, p_stride); if (gm_sumerr > best_error) return INT64_MAX; } } return gm_sumerr; } int64_t av1_warp_error(WarpedMotionParams *wm, int use_hbd, int bd, const uint8_t *ref, int width, int height, int stride, uint8_t *dst, int p_col, int p_row, int p_width, int p_height, int p_stride, int subsampling_x, int subsampling_y, int64_t best_error, uint8_t *segment_map, int segment_map_stride) { if (wm->wmtype <= AFFINE) if (!av1_get_shear_params(wm)) return INT64_MAX; #if CONFIG_AV1_HIGHBITDEPTH if (use_hbd) return highbd_warp_error(wm, CONVERT_TO_SHORTPTR(ref), width, height, stride, CONVERT_TO_SHORTPTR(dst), p_col, p_row, p_width, p_height, p_stride, subsampling_x, subsampling_y, bd, best_error, segment_map, segment_map_stride); #endif (void)use_hbd; (void)bd; return warp_error(wm, ref, width, height, stride, dst, p_col, p_row, p_width, p_height, p_stride, subsampling_x, subsampling_y, best_error, segment_map, segment_map_stride); } // Factors used to calculate the thresholds for av1_warp_error static double thresh_factors[GM_REFINEMENT_COUNT] = { 1.25, 1.20, 1.15, 1.10, 1.05 }; static INLINE int64_t calc_approx_erroradv_threshold( double scaling_factor, int64_t erroradv_threshold) { return erroradv_threshold < (int64_t)(((double)INT64_MAX / scaling_factor) + 0.5) ? (int64_t)(scaling_factor * erroradv_threshold + 0.5) : INT64_MAX; } int64_t av1_refine_integerized_param( WarpedMotionParams *wm, TransformationType wmtype, int use_hbd, int bd, uint8_t *ref, int r_width, int r_height, int r_stride, uint8_t *dst, int d_width, int d_height, int d_stride, int n_refinements, int64_t best_frame_error, uint8_t *segment_map, int segment_map_stride, int64_t erroradv_threshold) { static const int max_trans_model_params[TRANS_TYPES] = { 0, 2, 4, 6 }; const int border = ERRORADV_BORDER; int i = 0, p; int n_params = max_trans_model_params[wmtype]; int32_t *param_mat = wm->wmmat; int64_t step_error, best_error; int32_t step; int32_t *param; int32_t curr_param; int32_t best_param; force_wmtype(wm, wmtype); best_error = av1_warp_error(wm, use_hbd, bd, ref, r_width, r_height, r_stride, dst + border * d_stride + border, border, border, d_width - 2 * border, d_height - 2 * border, d_stride, 0, 0, best_frame_error, segment_map, segment_map_stride); best_error = AOMMIN(best_error, best_frame_error); step = 1 << (n_refinements - 1); for (i = 0; i < n_refinements; i++, step >>= 1) { int64_t error_adv_thresh = calc_approx_erroradv_threshold(thresh_factors[i], erroradv_threshold); for (p = 0; p < n_params; ++p) { int step_dir = 0; // Skip searches for parameters that are forced to be 0 param = param_mat + p; curr_param = *param; best_param = curr_param; // look to the left *param = add_param_offset(p, curr_param, -step); step_error = av1_warp_error(wm, use_hbd, bd, ref, r_width, r_height, r_stride, dst + border * d_stride + border, border, border, d_width - 2 * border, d_height - 2 * border, d_stride, 0, 0, AOMMIN(best_error, error_adv_thresh), segment_map, segment_map_stride); if (step_error < best_error) { best_error = step_error; best_param = *param; step_dir = -1; } // look to the right *param = add_param_offset(p, curr_param, step); step_error = av1_warp_error(wm, use_hbd, bd, ref, r_width, r_height, r_stride, dst + border * d_stride + border, border, border, d_width - 2 * border, d_height - 2 * border, d_stride, 0, 0, AOMMIN(best_error, error_adv_thresh), segment_map, segment_map_stride); if (step_error < best_error) { best_error = step_error; best_param = *param; step_dir = 1; } *param = best_param; // look to the direction chosen above repeatedly until error increases // for the biggest step size while (step_dir) { *param = add_param_offset(p, best_param, step * step_dir); step_error = av1_warp_error(wm, use_hbd, bd, ref, r_width, r_height, r_stride, dst + border * d_stride + border, border, border, d_width - 2 * border, d_height - 2 * border, d_stride, 0, 0, AOMMIN(best_error, error_adv_thresh), segment_map, segment_map_stride); if (step_error < best_error) { best_error = step_error; best_param = *param; } else { *param = best_param; step_dir = 0; } } } } force_wmtype(wm, wmtype); wm->wmtype = get_wmtype(wm); return best_error; } #define FEAT_COUNT_TR 3 #define SEG_COUNT_TR 0.40 void av1_compute_feature_segmentation_map(uint8_t *segment_map, int width, int height, int *inliers, int num_inliers) { int seg_count = 0; memset(segment_map, 0, sizeof(*segment_map) * width * height); for (int i = 0; i < num_inliers; i++) { int x = inliers[i * 2]; int y = inliers[i * 2 + 1]; int seg_x = x >> WARP_ERROR_BLOCK_LOG; int seg_y = y >> WARP_ERROR_BLOCK_LOG; segment_map[seg_y * width + seg_x] += 1; } for (int i = 0; i < height; i++) { for (int j = 0; j < width; j++) { uint8_t feat_count = segment_map[i * width + j]; segment_map[i * width + j] = (feat_count >= FEAT_COUNT_TR); seg_count += (segment_map[i * width + j]); } } // If this motion does not make up a large enough portion of the frame, // use the unsegmented version of the error metric if (seg_count < (width * height * SEG_COUNT_TR)) memset(segment_map, 1, width * height * sizeof(*segment_map)); }