207 lines
7.5 KiB
C
207 lines
7.5 KiB
C
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#include "libimagequant.h"
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#include "pam.h"
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#include "nearest.h"
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#include "mempool.h"
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#include <stdlib.h>
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struct sorttmp {
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float radius;
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unsigned int index;
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};
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struct head {
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// colors less than radius away from vantage_point color will have best match in candidates
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f_pixel vantage_point;
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float radius;
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unsigned int num_candidates;
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f_pixel *candidates_color;
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unsigned short *candidates_index;
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};
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struct nearest_map {
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const colormap *map;
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float nearest_other_color_dist[256];
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mempool mempool;
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struct head heads[];
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};
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static float distance_from_nearest_other_color(const colormap *map, const unsigned int i)
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{
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float second_best=MAX_DIFF;
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for(unsigned int j=0; j < map->colors; j++) {
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if (i == j) continue;
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float diff = colordifference(map->palette[i].acolor, map->palette[j].acolor);
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if (diff <= second_best) {
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second_best = diff;
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}
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}
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return second_best;
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}
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static int compareradius(const void *ap, const void *bp)
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{
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float a = ((const struct sorttmp*)ap)->radius;
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float b = ((const struct sorttmp*)bp)->radius;
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return a > b ? 1 : (a < b ? -1 : 0);
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}
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static struct head build_head(f_pixel px, const colormap *map, unsigned int num_candidates, mempool *m, float error_margin, bool skip_index[], unsigned int *skipped)
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{
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struct sorttmp colors[map->colors];
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unsigned int colorsused=0;
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for(unsigned int i=0; i < map->colors; i++) {
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if (skip_index[i]) continue; // colors in skip_index have been eliminated already in previous heads
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colors[colorsused].index = i;
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colors[colorsused].radius = colordifference(px, map->palette[i].acolor);
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colorsused++;
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}
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qsort(&colors, colorsused, sizeof(colors[0]), compareradius);
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assert(colorsused < 2 || colors[0].radius <= colors[1].radius); // closest first
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num_candidates = MIN(colorsused, num_candidates);
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struct head h = {
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.candidates_color = mempool_alloc(m, num_candidates * sizeof(h.candidates_color[0]), 0),
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.candidates_index = mempool_alloc(m, num_candidates * sizeof(h.candidates_index[0]), 0),
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.vantage_point = px,
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.num_candidates = num_candidates,
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};
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for(unsigned int i=0; i < num_candidates; i++) {
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h.candidates_color[i] = map->palette[colors[i].index].acolor;
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h.candidates_index[i] = colors[i].index;
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}
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// if all colors within this radius are included in candidates, then there cannot be any other better match
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// farther away from the vantage point than half of the radius. Due to alpha channel must assume pessimistic radius.
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h.radius = min_colordifference(px, h.candidates_color[num_candidates-1])/4.0f; // /4 = half of radius, but radius is squared
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for(unsigned int i=0; i < num_candidates; i++) {
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// divide again as that's matching certain subset within radius-limited subset
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// - 1/256 is a tolerance for miscalculation (seems like colordifference isn't exact)
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if (colors[i].radius < h.radius/4.f - error_margin) {
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skip_index[colors[i].index]=true;
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(*skipped)++;
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}
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}
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return h;
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}
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static colormap *get_subset_palette(const colormap *map)
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{
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if (map->subset_palette) {
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return map->subset_palette;
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}
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unsigned int subset_size = (map->colors+3)/4;
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colormap *subset_palette = pam_colormap(subset_size, map->malloc, map->free);
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for(unsigned int i=0; i < subset_size; i++) {
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subset_palette->palette[i] = map->palette[i];
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}
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return subset_palette;
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}
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LIQ_PRIVATE struct nearest_map *nearest_init(const colormap *map, bool fast)
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{
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colormap *subset_palette = get_subset_palette(map);
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const unsigned int num_vantage_points = map->colors > 16 ? MIN(map->colors/(fast ? 4 : 3), subset_palette->colors) : 0;
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const unsigned long heads_size = sizeof(struct head) * (num_vantage_points+1); // +1 is fallback head
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const unsigned long mempool_size = (sizeof(f_pixel) + sizeof(unsigned int)) * subset_palette->colors * map->colors/5 + (1<<14);
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mempool m = NULL;
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struct nearest_map *centroids = mempool_create(&m, sizeof(*centroids) + heads_size /* heads array is appended to it */, mempool_size, map->malloc, map->free);
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centroids->mempool = m;
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for(unsigned int i=0; i < map->colors; i++) {
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const float dist = distance_from_nearest_other_color(map,i);
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centroids->nearest_other_color_dist[i] = dist / 4.f; // half of squared distance
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}
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centroids->map = map;
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unsigned int skipped=0;
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assert(map->colors > 0);
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bool skip_index[map->colors]; for(unsigned int j=0; j < map->colors; j++) skip_index[j]=false;
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// floats and colordifference calculations are not perfect
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const float error_margin = fast ? 0 : 8.f/256.f/256.f;
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unsigned int h=0;
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for(; h < num_vantage_points; h++) {
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unsigned int num_candiadtes = 1+(map->colors - skipped)/((1+num_vantage_points-h)/2);
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centroids->heads[h] = build_head(subset_palette->palette[h].acolor, map, num_candiadtes, ¢roids->mempool, error_margin, skip_index, &skipped);
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if (centroids->heads[h].num_candidates == 0) {
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break;
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}
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}
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// assumption that there is no better color within radius of vantage point color
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// holds true only for colors within convex hull formed by palette colors.
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// The fallback must contain all colors, since there are too many edge cases to cover.
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if (!fast) for(unsigned int j=0; j < map->colors; j++) {
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skip_index[j] = false;
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}
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centroids->heads[h] = build_head((f_pixel){0,0,0,0}, map, map->colors, ¢roids->mempool, error_margin, skip_index, &skipped);
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centroids->heads[h].radius = MAX_DIFF;
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// get_subset_palette could have created a copy
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if (subset_palette != map->subset_palette) {
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pam_freecolormap(subset_palette);
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}
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return centroids;
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}
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LIQ_PRIVATE unsigned int nearest_search(const struct nearest_map *centroids, const f_pixel px, int likely_colormap_index, const float min_opaque_val, float *diff)
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{
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const bool iebug = px.a > min_opaque_val;
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const struct head *const heads = centroids->heads;
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assert(likely_colormap_index < centroids->map->colors);
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const float guess_diff = colordifference(centroids->map->palette[likely_colormap_index].acolor, px);
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if (guess_diff < centroids->nearest_other_color_dist[likely_colormap_index]) {
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if (diff) *diff = guess_diff;
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return likely_colormap_index;
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}
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for(unsigned int i=0; /* last head will always be selected */ ; i++) {
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float vantage_point_dist = colordifference(px, heads[i].vantage_point);
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if (vantage_point_dist <= heads[i].radius) {
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assert(heads[i].num_candidates);
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unsigned int ind=0;
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float dist = colordifference(px, heads[i].candidates_color[0]);
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/* penalty for making holes in IE */
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if (iebug && heads[i].candidates_color[0].a < 1) {
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dist += 1.f/1024.f;
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}
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for(unsigned int j=1; j < heads[i].num_candidates; j++) {
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float newdist = colordifference(px, heads[i].candidates_color[j]);
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/* penalty for making holes in IE */
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if (iebug && heads[i].candidates_color[j].a < 1) {
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newdist += 1.f/1024.f;
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}
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if (newdist < dist) {
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dist = newdist;
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ind = j;
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}
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}
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if (diff) *diff = dist;
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return heads[i].candidates_index[ind];
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}
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}
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}
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LIQ_PRIVATE void nearest_free(struct nearest_map *centroids)
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{
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mempool_destroy(centroids->mempool);
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}
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