Mercurial > hg > wm
view Meerwald/kim_common.c @ 22:d8551fb39a5e default tip
Added tag v0.6 for changeset 1c4ccd635a68
author | Peter Meerwald-Stadler <pmeerw@pmeerw.net> |
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date | Sat, 28 Jan 2023 23:57:51 +0100 |
parents | be303a3f5ea8 |
children |
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#include "wm.h" #include "kim_common.h" // find the largest absolute coefficient of a subband double find_subband_largest_coeff(Image_tree s, int subband, int verbose) { int i, j; double max; max = 0.0; for (i = 5; i < s->image->height-5; i++) for (j = 5; j < s->image->width-5; j++) { double coeff; coeff = fabs(get_pixel(s->image, i, j)); if (coeff > max) max = coeff; } if (verbose > 8) fprintf(stderr, " subband %f\n", max); return max; } // find largest absolute coefficient of the detail subbands (LH, HL, HH) of // a decomposition level double find_level_largest_coeff(Image_tree p, int verbose) { double h, v, d; h = find_subband_largest_coeff(p->horizontal, HORIZONTAL, verbose); v = find_subband_largest_coeff(p->vertical, VERTICAL, verbose); d = find_subband_largest_coeff(p->diagonal, DIAGONAL, verbose); return MAX(h, MAX(v, d)); } // calculate the significance threshold given the maximum absolute // coefficient at a decomposition level double calc_level_threshold(double max_coeff, int verbose) { double threshold; threshold = pow(2.0, floor(log(max_coeff) / log(2.0)) - 1.0); if (verbose > 7) fprintf(stderr, " max %f, threshold %f\n", max_coeff, threshold); return threshold; } // calculate an appropriate embedding strength for a given decomposition level // and a base alpha strength double calc_level_alpha_detail(double alpha, int maxlevels, int level, int verbose) { double level_alpha; level_alpha = alpha / pow(2.0, level - 1); return level_alpha; }