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425 lines
13 KiB
425 lines
13 KiB
/* |
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* Copyright (C) 2007 Vitor Sessak <vitor1001@gmail.com> |
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* |
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* This file is part of FFmpeg. |
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* |
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* FFmpeg is free software; you can redistribute it and/or |
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* modify it under the terms of the GNU Lesser General Public |
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* License as published by the Free Software Foundation; either |
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* version 2.1 of the License, or (at your option) any later version. |
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* |
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* FFmpeg is distributed in the hope that it will be useful, |
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* but WITHOUT ANY WARRANTY; without even the implied warranty of |
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
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* Lesser General Public License for more details. |
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* |
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* You should have received a copy of the GNU Lesser General Public |
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* License along with FFmpeg; if not, write to the Free Software |
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA |
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*/ |
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/** |
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* @file elbg.c |
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* Codebook Generator using the ELBG algorithm |
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*/ |
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#include <string.h> |
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#include "libavutil/random.h" |
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#include "elbg.h" |
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#include "avcodec.h" |
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#define DELTA_ERR_MAX 0.1 ///< Precision of the ELBG algorithm (as percentual error) |
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/** |
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* In the ELBG jargon, a cell is the set of points that are closest to a |
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* codebook entry. Not to be confused with a RoQ Video cell. */ |
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typedef struct cell_s { |
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int index; |
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struct cell_s *next; |
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} cell; |
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/** |
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* ELBG internal data |
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*/ |
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typedef struct{ |
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int error; |
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int dim; |
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int numCB; |
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int *codebook; |
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cell **cells; |
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int *utility; |
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int *utility_inc; |
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int *nearest_cb; |
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int *points; |
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AVRandomState *rand_state; |
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} elbg_data; |
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static inline int distance_limited(int *a, int *b, int dim, int limit) |
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{ |
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int i, dist=0; |
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for (i=0; i<dim; i++) { |
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dist += (a[i] - b[i])*(a[i] - b[i]); |
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if (dist > limit) |
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return INT_MAX; |
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} |
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return dist; |
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} |
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static inline void vect_division(int *res, int *vect, int div, int dim) |
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{ |
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int i; |
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if (div > 1) |
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for (i=0; i<dim; i++) |
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res[i] = ROUNDED_DIV(vect[i],div); |
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else if (res != vect) |
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memcpy(res, vect, dim*sizeof(int)); |
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} |
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static int eval_error_cell(elbg_data *elbg, int *centroid, cell *cells) |
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{ |
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int error=0; |
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for (; cells; cells=cells->next) |
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error += distance_limited(centroid, elbg->points + cells->index*elbg->dim, elbg->dim, INT_MAX); |
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return error; |
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} |
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static int get_closest_codebook(elbg_data *elbg, int index) |
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{ |
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int i, pick=0, diff, diff_min = INT_MAX; |
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for (i=0; i<elbg->numCB; i++) |
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if (i != index) { |
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diff = distance_limited(elbg->codebook + i*elbg->dim, elbg->codebook + index*elbg->dim, elbg->dim, diff_min); |
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if (diff < diff_min) { |
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pick = i; |
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diff_min = diff; |
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} |
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} |
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return pick; |
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} |
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static int get_high_utility_cell(elbg_data *elbg) |
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{ |
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int i=0; |
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/* Using linear search, do binary if it ever turns to be speed critical */ |
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int r = av_random(elbg->rand_state)%(elbg->utility_inc[elbg->numCB-1]-1) + 1; |
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while (elbg->utility_inc[i] < r) |
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i++; |
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assert(!elbg->cells[i]); |
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return i; |
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} |
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/** |
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* Implementation of the simple LBG algorithm for just two codebooks |
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*/ |
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static int simple_lbg(int dim, |
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int *centroid[3], |
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int newutility[3], |
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int *points, |
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cell *cells) |
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{ |
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int i, idx; |
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int numpoints[2] = {0,0}; |
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int newcentroid[2][dim]; |
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cell *tempcell; |
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memset(newcentroid, 0, sizeof(newcentroid)); |
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newutility[0] = |
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newutility[1] = 0; |
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for (tempcell = cells; tempcell; tempcell=tempcell->next) { |
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idx = distance_limited(centroid[0], points + tempcell->index*dim, dim, INT_MAX)>= |
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distance_limited(centroid[1], points + tempcell->index*dim, dim, INT_MAX); |
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numpoints[idx]++; |
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for (i=0; i<dim; i++) |
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newcentroid[idx][i] += points[tempcell->index*dim + i]; |
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} |
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vect_division(centroid[0], newcentroid[0], numpoints[0], dim); |
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vect_division(centroid[1], newcentroid[1], numpoints[1], dim); |
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for (tempcell = cells; tempcell; tempcell=tempcell->next) { |
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int dist[2] = {distance_limited(centroid[0], points + tempcell->index*dim, dim, INT_MAX), |
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distance_limited(centroid[1], points + tempcell->index*dim, dim, INT_MAX)}; |
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int idx = dist[0] > dist[1]; |
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newutility[idx] += dist[idx]; |
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} |
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return newutility[0] + newutility[1]; |
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} |
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static void get_new_centroids(elbg_data *elbg, int huc, int *newcentroid_i, |
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int *newcentroid_p) |
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{ |
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cell *tempcell; |
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int min[elbg->dim]; |
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int max[elbg->dim]; |
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int i; |
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for (i=0; i< elbg->dim; i++) { |
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min[i]=INT_MAX; |
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max[i]=0; |
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} |
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for (tempcell = elbg->cells[huc]; tempcell; tempcell = tempcell->next) |
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for(i=0; i<elbg->dim; i++) { |
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min[i]=FFMIN(min[i], elbg->points[tempcell->index*elbg->dim + i]); |
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max[i]=FFMAX(max[i], elbg->points[tempcell->index*elbg->dim + i]); |
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} |
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for (i=0; i<elbg->dim; i++) { |
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newcentroid_i[i] = min[i] + (max[i] - min[i])/3; |
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newcentroid_p[i] = min[i] + (2*(max[i] - min[i]))/3; |
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} |
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} |
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/** |
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* Add the points in the low utility cell to its closest cell. Split the high |
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* utility cell, putting the separed points in the (now empty) low utility |
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* cell. |
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* |
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* @param elbg Internal elbg data |
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* @param indexes {luc, huc, cluc} |
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* @param newcentroid A vector with the position of the new centroids |
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*/ |
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static void shift_codebook(elbg_data *elbg, int *indexes, |
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int *newcentroid[3]) |
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{ |
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cell *tempdata; |
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cell **pp = &elbg->cells[indexes[2]]; |
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while(*pp) |
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pp= &(*pp)->next; |
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*pp = elbg->cells[indexes[0]]; |
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elbg->cells[indexes[0]] = NULL; |
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tempdata = elbg->cells[indexes[1]]; |
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elbg->cells[indexes[1]] = NULL; |
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while(tempdata) { |
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cell *tempcell2 = tempdata->next; |
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int idx = distance_limited(elbg->points + tempdata->index*elbg->dim, |
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newcentroid[0], elbg->dim, INT_MAX) > |
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distance_limited(elbg->points + tempdata->index*elbg->dim, |
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newcentroid[1], elbg->dim, INT_MAX); |
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tempdata->next = elbg->cells[indexes[idx]]; |
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elbg->cells[indexes[idx]] = tempdata; |
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tempdata = tempcell2; |
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} |
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} |
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static void evaluate_utility_inc(elbg_data *elbg) |
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{ |
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int i, inc=0; |
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for (i=0; i < elbg->numCB; i++) { |
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if (elbg->numCB*elbg->utility[i] > elbg->error) |
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inc += elbg->utility[i]; |
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elbg->utility_inc[i] = inc; |
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} |
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} |
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static void update_utility_and_n_cb(elbg_data *elbg, int idx, int newutility) |
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{ |
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cell *tempcell; |
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elbg->utility[idx] = newutility; |
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for (tempcell=elbg->cells[idx]; tempcell; tempcell=tempcell->next) |
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elbg->nearest_cb[tempcell->index] = idx; |
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} |
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/** |
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* Evaluate if a shift lower the error. If it does, call shift_codebooks |
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* and update elbg->error, elbg->utility and elbg->nearest_cb. |
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* |
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* @param elbg Internal elbg data |
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* @param indexes {luc (low utility cell, huc (high utility cell), cluc (closest cell to low utility cell)} |
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*/ |
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static void try_shift_candidate(elbg_data *elbg, int idx[3]) |
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{ |
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int j, k, olderror=0, newerror, cont=0; |
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int newutility[3]; |
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int newcentroid[3][elbg->dim]; |
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int *newcentroid_ptrs[3]; |
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cell *tempcell; |
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newcentroid_ptrs[0] = newcentroid[0]; |
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newcentroid_ptrs[1] = newcentroid[1]; |
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newcentroid_ptrs[2] = newcentroid[2]; |
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for (j=0; j<3; j++) |
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olderror += elbg->utility[idx[j]]; |
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memset(newcentroid[2], 0, elbg->dim*sizeof(int)); |
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for (k=0; k<2; k++) |
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for (tempcell=elbg->cells[idx[2*k]]; tempcell; tempcell=tempcell->next) { |
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cont++; |
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for (j=0; j<elbg->dim; j++) |
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newcentroid[2][j] += elbg->points[tempcell->index*elbg->dim + j]; |
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} |
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vect_division(newcentroid[2], newcentroid[2], cont, elbg->dim); |
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get_new_centroids(elbg, idx[1], newcentroid[0], newcentroid[1]); |
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newutility[2] = eval_error_cell(elbg, newcentroid[2], elbg->cells[idx[0]]); |
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newutility[2] += eval_error_cell(elbg, newcentroid[2], elbg->cells[idx[2]]); |
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newerror = newutility[2]; |
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newerror += simple_lbg(elbg->dim, newcentroid_ptrs, newutility, elbg->points, |
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elbg->cells[idx[1]]); |
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if (olderror > newerror) { |
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shift_codebook(elbg, idx, newcentroid_ptrs); |
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elbg->error += newerror - olderror; |
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for (j=0; j<3; j++) |
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update_utility_and_n_cb(elbg, idx[j], newutility[j]); |
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evaluate_utility_inc(elbg); |
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} |
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} |
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/** |
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* Implementation of the ELBG block |
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*/ |
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static void do_shiftings(elbg_data *elbg) |
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{ |
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int idx[3]; |
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evaluate_utility_inc(elbg); |
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for (idx[0]=0; idx[0] < elbg->numCB; idx[0]++) |
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if (elbg->numCB*elbg->utility[idx[0]] < elbg->error) { |
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if (elbg->utility_inc[elbg->numCB-1] == 0) |
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return; |
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idx[1] = get_high_utility_cell(elbg); |
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idx[2] = get_closest_codebook(elbg, idx[0]); |
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if (idx[1] != idx[0] && idx[1] != idx[2]) |
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try_shift_candidate(elbg, idx); |
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} |
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} |
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#define BIG_PRIME 433494437LL |
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void ff_init_elbg(int *points, int dim, int numpoints, int *codebook, |
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int numCB, int max_steps, int *closest_cb, |
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AVRandomState *rand_state) |
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{ |
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int i, k; |
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if (numpoints > 24*numCB) { |
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/* ELBG is very costly for a big number of points. So if we have a lot |
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of them, get a good initial codebook to save on iterations */ |
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int *temp_points = av_malloc(dim*(numpoints/8)*sizeof(int)); |
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for (i=0; i<numpoints/8; i++) { |
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k = (i*BIG_PRIME) % numpoints; |
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memcpy(temp_points + i*dim, points + k*dim, dim*sizeof(int)); |
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} |
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ff_init_elbg(temp_points, dim, numpoints/8, codebook, numCB, 2*max_steps, closest_cb, rand_state); |
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ff_do_elbg(temp_points, dim, numpoints/8, codebook, numCB, 2*max_steps, closest_cb, rand_state); |
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av_free(temp_points); |
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} else // If not, initialize the codebook with random positions |
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for (i=0; i < numCB; i++) |
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memcpy(codebook + i*dim, points + ((i*BIG_PRIME)%numpoints)*dim, |
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dim*sizeof(int)); |
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} |
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void ff_do_elbg(int *points, int dim, int numpoints, int *codebook, |
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int numCB, int max_steps, int *closest_cb, |
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AVRandomState *rand_state) |
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{ |
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int dist; |
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elbg_data elbg_d; |
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elbg_data *elbg = &elbg_d; |
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int i, j, k, last_error, steps=0; |
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int *dist_cb = av_malloc(numpoints*sizeof(int)); |
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int *size_part = av_malloc(numCB*sizeof(int)); |
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cell *list_buffer = av_malloc(numpoints*sizeof(cell)); |
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cell *free_cells; |
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elbg->error = INT_MAX; |
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elbg->dim = dim; |
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elbg->numCB = numCB; |
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elbg->codebook = codebook; |
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elbg->cells = av_malloc(numCB*sizeof(cell *)); |
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elbg->utility = av_malloc(numCB*sizeof(int)); |
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elbg->nearest_cb = closest_cb; |
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elbg->points = points; |
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elbg->utility_inc = av_malloc(numCB*sizeof(int)); |
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elbg->rand_state = rand_state; |
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do { |
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free_cells = list_buffer; |
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last_error = elbg->error; |
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steps++; |
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memset(elbg->utility, 0, numCB*sizeof(int)); |
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memset(elbg->cells, 0, numCB*sizeof(cell *)); |
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elbg->error = 0; |
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/* This loop evaluate the actual Voronoi partition. It is the most |
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costly part of the algorithm. */ |
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for (i=0; i < numpoints; i++) { |
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dist_cb[i] = INT_MAX; |
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for (k=0; k < elbg->numCB; k++) { |
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dist = distance_limited(elbg->points + i*elbg->dim, elbg->codebook + k*elbg->dim, dim, dist_cb[i]); |
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if (dist < dist_cb[i]) { |
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dist_cb[i] = dist; |
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elbg->nearest_cb[i] = k; |
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} |
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} |
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elbg->error += dist_cb[i]; |
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elbg->utility[elbg->nearest_cb[i]] += dist_cb[i]; |
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free_cells->index = i; |
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free_cells->next = elbg->cells[elbg->nearest_cb[i]]; |
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elbg->cells[elbg->nearest_cb[i]] = free_cells; |
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free_cells++; |
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} |
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do_shiftings(elbg); |
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memset(size_part, 0, numCB*sizeof(int)); |
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memset(elbg->codebook, 0, elbg->numCB*dim*sizeof(int)); |
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for (i=0; i < numpoints; i++) { |
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size_part[elbg->nearest_cb[i]]++; |
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for (j=0; j < elbg->dim; j++) |
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elbg->codebook[elbg->nearest_cb[i]*elbg->dim + j] += |
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elbg->points[i*elbg->dim + j]; |
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} |
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for (i=0; i < elbg->numCB; i++) |
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vect_division(elbg->codebook + i*elbg->dim, |
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elbg->codebook + i*elbg->dim, size_part[i], elbg->dim); |
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} while(((last_error - elbg->error) > DELTA_ERR_MAX*elbg->error) && |
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(steps < max_steps)); |
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av_free(dist_cb); |
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av_free(size_part); |
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av_free(elbg->utility); |
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av_free(list_buffer); |
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av_free(elbg->cells); |
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av_free(elbg->utility_inc); |
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}
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