ptrdiff_t wa_linesize; // linesize for wa in struct size unit
float weight_lut[WEIGHT_LUT_SIZE]; // lookup table mapping (scaled) patch differences to their associated weights
float pdiff_lut_scale; // scale factor for patch differences before looking into the LUT
- int max_meaningful_diff; // maximum difference considered (if the patch difference is too high we ignore the pixel)
+ uint32_t max_meaningful_diff; // maximum difference considered (if the patch difference is too high we ignore the pixel)
NLMeansDSPContext dsp;
} NLMeansContext;
return ff_set_common_formats(ctx, fmts_list);
}
-/*
- * M is a discrete map where every entry contains the sum of all the entries
- * in the rectangle from the top-left origin of M to its coordinate. In the
- * following schema, "i" contains the sum of the whole map:
- *
- * M = +----------+-----------------+----+
- * | | | |
- * | | | |
- * | a| b| c|
- * +----------+-----------------+----+
- * | | | |
- * | | | |
- * | | X | |
- * | | | |
- * | d| e| f|
- * +----------+-----------------+----+
- * | | | |
- * | g| h| i|
- * +----------+-----------------+----+
- *
- * The sum of the X box can be calculated with:
- * X = e-d-b+a
- *
- * See https://en.wikipedia.org/wiki/Summed_area_table
- *
- * The compute*_ssd functions compute the integral image M where every entry
- * contains the sum of the squared difference of every corresponding pixels of
- * two input planes of the same size as M.
- */
-static inline int get_integral_patch_value(const uint32_t *ii, int ii_lz_32, int x, int y, int p)
-{
- const int a = ii[(y - p - 1) * ii_lz_32 + (x - p - 1)];
- const int b = ii[(y - p - 1) * ii_lz_32 + (x + p )];
- const int d = ii[(y + p ) * ii_lz_32 + (x - p - 1)];
- const int e = ii[(y + p ) * ii_lz_32 + (x + p )];
- return e - d - b + a;
-}
-
/**
* Compute squared difference of the safe area (the zone where s1 and s2
* overlap). It is likely the largest integral zone, so it is interesting to do
const int e = FFMAX(s->research_hsize, s->research_hsize_uv)
+ FFMAX(s->patch_hsize, s->patch_hsize_uv);
- s->chroma_w = FF_CEIL_RSHIFT(inlink->w, desc->log2_chroma_w);
- s->chroma_h = FF_CEIL_RSHIFT(inlink->h, desc->log2_chroma_h);
+ s->chroma_w = AV_CEIL_RSHIFT(inlink->w, desc->log2_chroma_w);
+ s->chroma_h = AV_CEIL_RSHIFT(inlink->h, desc->log2_chroma_h);
s->nb_planes = av_pix_fmt_count_planes(inlink->format);
/* Allocate the integral image with extra edges of thickness "e"
const int slice_end = (process_h * (jobnr+1)) / nb_jobs;
const int starty = td->starty + slice_start;
const int endy = td->starty + slice_end;
+ const int p = td->p;
+ const uint32_t *ii = td->ii_start + (starty - p - 1) * s->ii_lz_32 - p - 1;
+ const int dist_b = 2*p + 1;
+ const int dist_d = dist_b * s->ii_lz_32;
+ const int dist_e = dist_d + dist_b;
for (y = starty; y < endy; y++) {
const uint8_t *src = td->src + y*src_linesize;
struct weighted_avg *wa = s->wa + y*s->wa_linesize;
for (x = td->startx; x < td->endx; x++) {
- const int patch_diff_sq = get_integral_patch_value(td->ii_start, s->ii_lz_32, x, y, td->p);
+ /*
+ * M is a discrete map where every entry contains the sum of all the entries
+ * in the rectangle from the top-left origin of M to its coordinate. In the
+ * following schema, "i" contains the sum of the whole map:
+ *
+ * M = +----------+-----------------+----+
+ * | | | |
+ * | | | |
+ * | a| b| c|
+ * +----------+-----------------+----+
+ * | | | |
+ * | | | |
+ * | | X | |
+ * | | | |
+ * | d| e| f|
+ * +----------+-----------------+----+
+ * | | | |
+ * | g| h| i|
+ * +----------+-----------------+----+
+ *
+ * The sum of the X box can be calculated with:
+ * X = e-d-b+a
+ *
+ * See https://en.wikipedia.org/wiki/Summed_area_table
+ *
+ * The compute*_ssd functions compute the integral image M where every entry
+ * contains the sum of the squared difference of every corresponding pixels of
+ * two input planes of the same size as M.
+ */
+ const uint32_t a = ii[x];
+ const uint32_t b = ii[x + dist_b];
+ const uint32_t d = ii[x + dist_d];
+ const uint32_t e = ii[x + dist_e];
+ const uint32_t patch_diff_sq = e - d - b + a;
+
if (patch_diff_sq < s->max_meaningful_diff) {
- const int weight_lut_idx = patch_diff_sq * s->pdiff_lut_scale;
+ const unsigned weight_lut_idx = patch_diff_sq * s->pdiff_lut_scale;
const float weight = s->weight_lut[weight_lut_idx]; // exp(-patch_diff_sq * s->pdiff_scale)
wa[x].total_weight += weight;
wa[x].sum += weight * src[x];
}
}
+ ii += s->ii_lz_32;
}
return 0;
}