Mercurial > hg > wm
view Meerwald-dir/dwt.c @ 24:9f20bce6184e v0.7
move directories, support netpbm 11
author | Peter Meerwald-Stadler <pmeerw@pmeerw.net> |
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date | Fri, 20 Dec 2024 13:08:59 +0100 |
parents | Meerwald/dwt.c@1906e659edd0 |
children |
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#include "wm.h" #include "dwt.h" char filter_file[MAXPATHLEN] = ""; AllFilters dwt_allfilters; FilterGH *dwt_filters = NULL; int dwt_method; int dwt_cols; int dwt_rows; int dwt_levels; int dwt_filter; void init_dwt(int cols, int rows, const char *filter_name, int filter, int level, int method) { int i; if (strcmp(filter_file, filter_name)) { if (filter_name) strcpy(filter_file, filter_name); else strcpy(filter_file, "filter.dat"); /* memory leak here - there is no function unload_filters() */ dwt_allfilters = load_filters(filter_file); if (!dwt_allfilters) { fprintf(stderr, "init_dwt(): unable to open filter definition file %s\n", filter_file); return; } } #ifdef DEBUG if (level <= 0 || level > rint(log(MIN(cols, rows))/log(2.0)) - 2) { fprintf(stderr, "init_dwt(): level parameter does not match image width/height\n"); return; } #endif if (dwt_filters && level != dwt_levels) { free(dwt_filters); dwt_filters = NULL; } dwt_levels = level; if (!dwt_filters) dwt_filters = calloc(level + 1, sizeof(FilterGH)); for (i = 0; i < level + 1; i++) dwt_filters[i] = (dwt_allfilters->filter)[filter]; dwt_filter = filter; dwt_method = method; dwt_cols = cols; dwt_rows = rows; } Image_tree fdwt(gray **pixels) { Image image; Image_tree tree; int i, j; image = new_image(dwt_cols, dwt_rows); for (i = 0; i < dwt_rows; i++) for (j = 0; j < dwt_cols; j++) set_pixel(image, j, i, pixels[i][j]); tree = wavelettransform(image, dwt_levels, dwt_filters, dwt_method); free_image(image); return tree; } Image_tree fdwt_wp(gray **pixels) { Image image; Image_tree tree; int i, j; image = new_image(dwt_cols, dwt_rows); for (i = 0; i < dwt_rows; i++) for (j = 0; j < dwt_cols; j++) set_pixel(image, j, i, pixels[i][j]); tree = wavelettransform_wp(image, dwt_levels, dwt_filters, dwt_method); free_image(image); return tree; } void idwt(Image_tree dwts, gray **pixels) { Image image; int i, j; image = inv_transform(dwts, dwt_filters, dwt_method + 1); for (i = 0; i < dwt_rows; i++) for (j = 0; j < dwt_cols; j++) pixels[i][j] = PIXELRANGE((int) (get_pixel(image, j, i) + 0.5)); free_image(image); } void idwt_wp(Image_tree dwts, gray **pixels) { Image image; int i, j; image = inv_transform(dwts, dwt_filters, dwt_method + 1); for (i = 0; i < dwt_rows; i++) for (j = 0; j < dwt_cols; j++) pixels[i][j] = PIXELRANGE((int) (get_pixel(image, j, i) + 0.5)); free_image(image); } int gen_pollen_filter(double *filter, double alpha, double beta, int which) { int i, j, k, filterlength; double tf[6]; /* parameter alpha, beta have to be in range -Pi .. Pi */ if (alpha < -M_PI || alpha >= M_PI) { fprintf(stderr, "alpha %f out of range\n", alpha); return -1; } if (beta < -M_PI || beta >= M_PI) { fprintf(stderr, "beta %f out of range\n", beta); return -1; } /* generate Pollen filter coefficients, see http://www.dfw.net/~cody for details */ tf[0] = ((1.0 + cos(alpha) + sin(alpha)) * (1.0 - cos(beta) - sin(beta)) + 2.0 * sin(beta) * cos(alpha)) / 4.0; tf[1] = ((1.0 - cos(alpha) + sin(alpha)) * (1.0 + cos(beta) - sin(beta)) - 2.0 * sin(beta) * cos(alpha)) / 4.0; tf[2] = (1.0 + cos(alpha - beta) + sin(alpha - beta)) / 2.0; tf[3] = (1.0 + cos(alpha - beta) - sin(alpha - beta)) / 2.0; tf[4] = 1.0 - tf[0] - tf[2]; tf[5] = 1.0 - tf[1] - tf[3]; /* set close-to-zero filter coefficients to zero */ for (i = 0; i < 6; i++) if (fabs(tf[i]) < 1.0e-15) tf[i] = 0.0; /* find the first non-zero wavelet coefficient */ i = 0; while (tf[i] == 0.0) i++; /* find the last non-zero wavelet coefficient */ j = 5; while (tf[j] == 0.0) j--; filterlength = j - i + 1; for (k = 0; k < filterlength; k++) switch (which) { case FILTERH: filter[k] = tf[j--] / 2.0; break; case FILTERG: filter[k] = (double) (((i & 0x01) * 2) - 1) * tf[i] / 2.0; i++; break; case FILTERHi: filter[k] = tf[j--]; break; case FILTERGi: filter[k] = (double) (((i & 0x01) * 2) - 1) * tf[i]; i++; break; default: return -1; } while (k < 6) filter[k++] = 0.0; return filterlength; } void dwt_pollen_filter(double alpha, double beta) { FilterGH filter; int i; filter = malloc(sizeof(struct FilterGHStruct)); #ifdef DEBUG if (!filter) { fprintf(stderr, "dwt_pollen_filter(): malloc failed()\n"); return; } #endif filter->type = FTOther; filter->name = "pollen"; filter->g = new_filter(6); filter->g->type = FTSymm; filter->g->hipass = 1; filter->g->len = gen_pollen_filter(filter->g->data, alpha, beta, FILTERG); filter->g->start = -filter->g->len / 2; filter->g->end = filter->g->len / 2 - 1; filter->h = new_filter(6); filter->h->type = FTSymm; filter->h->hipass = 0; filter->h->len = gen_pollen_filter(filter->h->data, alpha, beta, FILTERH); filter->h->start = -filter->h->len / 2; filter->h->end = filter->h->len / 2 - 1; filter->gi = new_filter(6); filter->gi->type = FTSymm; filter->gi->hipass = 1; filter->gi->len = gen_pollen_filter(filter->gi->data, alpha, beta, FILTERGi); filter->gi->start = -filter->gi->len / 2; filter->gi->end = filter->gi->len / 2 - 1; filter->hi = new_filter(6); filter->hi->type = FTSymm; filter->hi->hipass = 0; filter->hi->len = gen_pollen_filter(filter->hi->data, alpha, beta, FILTERHi); filter->hi->start = -filter->hi->len / 2; filter->hi->end = filter->hi->len / 2 - 1; #ifdef DEBUG if (dwt_levels <= 0) { fprintf(stderr, "dwt_pollen_filter(): level invalid - set to zero\n"); return; } #endif #ifdef DEBUG if (!dwt_filters) { fprintf(stderr, "dwt_pollen_filter(): wm_dwt not initialized, call init_dwt() first\n"); return; } #endif for (i = 0; i < dwt_levels + 1; i++) dwt_filters[i] = filter; } int gen_param_filter(double *filter, int n, double alpha[], int which) { int i, j, k, filterlength; double *tf, *t; tf = malloc(2 * (n + 1) * sizeof(double)); t = malloc(2 * (n + 1) * sizeof(double)); if (!tf) { fprintf(stderr, "gen_param_filter(): malloc() failed\n"); return -1; } tf[0] = 1.0 / sqrt(2.0); tf[1] = 1.0 / sqrt(2.0); for (k = 0; k < n; k++) { for (i = 0; i < 2 * (k + 2); i++) { #define H(X) (((X) < 0 || (X) >= 2 * (k + 1)) ? 0.0 : tf[X]) t[i] = 0.5 * (H(i - 2) + H(i) + cos(alpha[k]) * (H(i - 2) - H(i)) + (i & 1 ? -1.0 : 1.0) * sin(alpha[k]) * (H(2 * (k + 2) - i - 1) - H(2 * (k + 2) - i - 3))); } for (i = 0; i < 2 * (k + 2); i++) tf[i] = t[i]; } /* set close-to-zero filter coefficients to zero */ for (i = 0; i < 2 * (n + 1) ; i++) if (fabs(tf[i]) < 1.0e-15) tf[i] = 0.0; /* find the first non-zero wavelet coefficient */ i = 0; while (tf[i] == 0.0) i++; /* find the last non-zero wavelet coefficient */ j = 2 * (n + 1) - 1; while (tf[j] == 0.0) j--; filterlength = j - i + 1; for (k = 0; k < filterlength; k++) switch (which) { case FILTERG: case FILTERGi: filter[k] = (double) ((((i+1) & 0x01) * 2) - 1) * tf[i]; i++; break; case FILTERH: case FILTERHi: filter[k] = tf[j--]; break; default: return -1; } while (k < 2 * (n + 1)) filter[k++] = 0.0; return filterlength; } void dwt_param_filter(double alpha[], int param_len[]) { FilterGH filter; int i; int param_len_sum = 0; #ifdef DEBUG if (dwt_levels <= 0) { fprintf(stderr, "dwt_param_filter(): level invalid - set to zero\n"); return; } #endif #ifdef DEBUG if (!dwt_filters) { fprintf(stderr, "dwt_param_filter(): wm_dwt not initialized, call init_dwt() first\n"); return; } #endif for (i = 0; i < dwt_levels + 1; i++) { filter = malloc(sizeof(struct FilterGHStruct)); #ifdef DEBUG if (!filter) { fprintf(stderr, "dwt_param_filter(): malloc failed()\n"); return; } #endif filter->type = FTOrtho; filter->name = "param"; filter->g = new_filter(2 * (param_len[i] + 1)); filter->g->type = FTSymm; filter->g->hipass = 1; filter->g->len = gen_param_filter(filter->g->data, param_len[i], &alpha[param_len_sum], FILTERG); filter->g->start = -filter->g->len / 2; filter->g->end = filter->g->len / 2 - 1; filter->h = new_filter(2 * (param_len[i] + 1)); filter->h->type = FTSymm; filter->h->hipass = 0; filter->h->len = gen_param_filter(filter->h->data, param_len[i], &alpha[param_len_sum], FILTERH); filter->h->start = -filter->h->len / 2; filter->h->end = filter->h->len / 2 - 1; filter->gi = 0; filter->hi = 0; dwt_filters[i] = filter; param_len_sum += param_len[i]; } } void done_dwt() { }