/* pam.c - pam (portable alpha map) utility library ** ** © 2009-2017 by Kornel Lesiński. ** © 1989, 1991 by Jef Poskanzer. ** © 1997, 2000, 2002 by Greg Roelofs; based on an idea by Stefan Schneider. ** ** See COPYRIGHT file for license. */ #include #include #include "libimagequant.h" #include "pam.h" #include "mempool.h" LIQ_PRIVATE bool pam_computeacolorhash(struct acolorhash_table *acht, const rgba_pixel *const pixels[], unsigned int cols, unsigned int rows, const unsigned char *importance_map) { const unsigned int ignorebits = acht->ignorebits; const unsigned int channel_mask = 255U>>ignorebits<>ignorebits) ^ 0xFFU; const unsigned int posterize_mask = channel_mask << 24 | channel_mask << 16 | channel_mask << 8 | channel_mask; const unsigned int posterize_high_mask = channel_hmask << 24 | channel_hmask << 16 | channel_hmask << 8 | channel_hmask; const unsigned int hash_size = acht->hash_size; /* Go through the entire image, building a hash table of colors. */ for(unsigned int row = 0; row < rows; ++row) { for(unsigned int col = 0; col < cols; ++col) { unsigned int boost; // RGBA color is casted to long for easier hasing/comparisons union rgba_as_int px = {pixels[row][col]}; unsigned int hash; if (!px.rgba.a) { // "dirty alpha" has different RGBA values that end up being the same fully transparent color px.l=0; hash=0; boost = 2000; if (importance_map) { importance_map++; } } else { // mask posterizes all 4 channels in one go px.l = (px.l & posterize_mask) | ((px.l & posterize_high_mask) >> (8-ignorebits)); // fancier hashing algorithms didn't improve much hash = px.l % hash_size; if (importance_map) { boost = *importance_map++; } else { boost = 255; } } if (!pam_add_to_hash(acht, hash, boost, px, row, rows)) { return false; } } } acht->cols = cols; acht->rows += rows; return true; } LIQ_PRIVATE bool pam_add_to_hash(struct acolorhash_table *acht, unsigned int hash, unsigned int boost, union rgba_as_int px, unsigned int row, unsigned int rows) { /* head of the hash function stores first 2 colors inline (achl->used = 1..2), to reduce number of allocations of achl->other_items. */ struct acolorhist_arr_head *achl = &acht->buckets[hash]; if (achl->inline1.color.l == px.l && achl->used) { achl->inline1.perceptual_weight += boost; return true; } if (achl->used) { if (achl->used > 1) { if (achl->inline2.color.l == px.l) { achl->inline2.perceptual_weight += boost; return true; } // other items are stored as an array (which gets reallocated if needed) struct acolorhist_arr_item *other_items = achl->other_items; unsigned int i = 0; for (; i < achl->used-2; i++) { if (other_items[i].color.l == px.l) { other_items[i].perceptual_weight += boost; return true; } } // the array was allocated with spare items if (i < achl->capacity) { other_items[i] = (struct acolorhist_arr_item){ .color = px, .perceptual_weight = boost, }; achl->used++; ++acht->colors; return true; } if (++acht->colors > acht->maxcolors) { return false; } struct acolorhist_arr_item *new_items; unsigned int capacity; if (!other_items) { // there was no array previously, alloc "small" array capacity = 8; if (acht->freestackp <= 0) { // estimate how many colors are going to be + headroom const size_t mempool_size = ((acht->rows + rows-row) * 2 * acht->colors / (acht->rows + row + 1) + 1024) * sizeof(struct acolorhist_arr_item); new_items = mempool_alloc(&acht->mempool, sizeof(struct acolorhist_arr_item)*capacity, mempool_size); } else { // freestack stores previously freed (reallocated) arrays that can be reused // (all pesimistically assumed to be capacity = 8) new_items = acht->freestack[--acht->freestackp]; } } else { const unsigned int stacksize = sizeof(acht->freestack)/sizeof(acht->freestack[0]); // simply reallocs and copies array to larger capacity capacity = achl->capacity*2 + 16; if (acht->freestackp < stacksize-1) { acht->freestack[acht->freestackp++] = other_items; } const size_t mempool_size = ((acht->rows + rows-row) * 2 * acht->colors / (acht->rows + row + 1) + 32*capacity) * sizeof(struct acolorhist_arr_item); new_items = mempool_alloc(&acht->mempool, sizeof(struct acolorhist_arr_item)*capacity, mempool_size); if (!new_items) return false; memcpy(new_items, other_items, sizeof(other_items[0])*achl->capacity); } achl->other_items = new_items; achl->capacity = capacity; new_items[i] = (struct acolorhist_arr_item){ .color = px, .perceptual_weight = boost, }; achl->used++; } else { // these are elses for first checks whether first and second inline-stored colors are used achl->inline2.color.l = px.l; achl->inline2.perceptual_weight = boost; achl->used = 2; ++acht->colors; } } else { achl->inline1.color.l = px.l; achl->inline1.perceptual_weight = boost; achl->used = 1; ++acht->colors; } return true; } LIQ_PRIVATE struct acolorhash_table *pam_allocacolorhash(unsigned int maxcolors, unsigned int surface, unsigned int ignorebits, void* (*malloc)(size_t), void (*free)(void*)) { const size_t estimated_colors = MIN(maxcolors, surface/(ignorebits + (surface > 512*512 ? 6 : 5))); const size_t hash_size = estimated_colors < 66000 ? 6673 : (estimated_colors < 200000 ? 12011 : 24019); mempoolptr m = NULL; const size_t buckets_size = hash_size * sizeof(struct acolorhist_arr_head); const size_t mempool_size = sizeof(struct acolorhash_table) + buckets_size + estimated_colors * sizeof(struct acolorhist_arr_item); struct acolorhash_table *t = mempool_create(&m, sizeof(*t) + buckets_size, mempool_size, malloc, free); if (!t) return NULL; *t = (struct acolorhash_table){ .mempool = m, .hash_size = hash_size, .maxcolors = maxcolors, .ignorebits = ignorebits, }; memset(t->buckets, 0, buckets_size); return t; } ALWAYS_INLINE static float pam_add_to_hist(const float *gamma_lut, hist_item *achv, unsigned int *j, const struct acolorhist_arr_item *entry, const float max_perceptual_weight) { if (entry->perceptual_weight == 0) { return 0; } const float w = MIN(entry->perceptual_weight/128.f, max_perceptual_weight); achv[*j].adjusted_weight = achv[*j].perceptual_weight = w; achv[*j].acolor = rgba_to_f(gamma_lut, entry->color.rgba); *j += 1; return w; } LIQ_PRIVATE histogram *pam_acolorhashtoacolorhist(const struct acolorhash_table *acht, const double gamma, void* (*malloc)(size_t), void (*free)(void*)) { histogram *hist = malloc(sizeof(hist[0])); if (!hist || !acht) return NULL; *hist = (histogram){ .achv = malloc(MAX(1,acht->colors) * sizeof(hist->achv[0])), .size = acht->colors, .free = free, .ignorebits = acht->ignorebits, }; if (!hist->achv) return NULL; float gamma_lut[256]; to_f_set_gamma(gamma_lut, gamma); /* Limit perceptual weight to 1/10th of the image surface area to prevent a single color from dominating all others. */ float max_perceptual_weight = 0.1f * acht->cols * acht->rows; double total_weight = 0; unsigned int j=0; for(unsigned int i=0; i < acht->hash_size; ++i) { const struct acolorhist_arr_head *const achl = &acht->buckets[i]; if (achl->used) { total_weight += pam_add_to_hist(gamma_lut, hist->achv, &j, &achl->inline1, max_perceptual_weight); if (achl->used > 1) { total_weight += pam_add_to_hist(gamma_lut, hist->achv, &j, &achl->inline2, max_perceptual_weight); for(unsigned int k=0; k < achl->used-2; k++) { total_weight += pam_add_to_hist(gamma_lut, hist->achv, &j, &achl->other_items[k], max_perceptual_weight); } } } } hist->size = j; hist->total_perceptual_weight = total_weight; for(unsigned int k=0; k < hist->size; k++) { hist->achv[k].tmp.likely_colormap_index = 0; } if (!j) { pam_freeacolorhist(hist); return NULL; } return hist; } LIQ_PRIVATE void pam_freeacolorhash(struct acolorhash_table *acht) { if (acht) { mempool_destroy(acht->mempool); } } LIQ_PRIVATE void pam_freeacolorhist(histogram *hist) { hist->free(hist->achv); hist->free(hist); } LIQ_PRIVATE colormap *pam_colormap(unsigned int colors, void* (*malloc)(size_t), void (*free)(void*)) { assert(colors > 0 && colors < 65536); colormap *map; const size_t colors_size = colors * sizeof(map->palette[0]); map = malloc(sizeof(colormap) + colors_size); if (!map) return NULL; *map = (colormap){ .malloc = malloc, .free = free, .colors = colors, }; memset(map->palette, 0, colors_size); return map; } LIQ_PRIVATE colormap *pam_duplicate_colormap(colormap *map) { colormap *dupe = pam_colormap(map->colors, map->malloc, map->free); for(unsigned int i=0; i < map->colors; i++) { dupe->palette[i] = map->palette[i]; } return dupe; } LIQ_PRIVATE void pam_freecolormap(colormap *c) { c->free(c); } LIQ_PRIVATE void to_f_set_gamma(float gamma_lut[], const double gamma) { for(int i=0; i < 256; i++) { gamma_lut[i] = pow((double)i/255.0, internal_gamma/gamma); } }