/* See LICENSE file for copyright and license details. */ #ifndef NARROW_FLOAT_TYPE # define NARROW_FLOAT_TYPE double # define NARROW_FLOAT_TYPE_AUTO #endif #ifndef WIDE_FLOAT_TYPE # define WIDE_FLOAT_TYPE NARROW_FLOAT_TYPE # define WIDE_FLOAT_TYPE_AUTO #endif #ifndef TYPE # define TYPE NARROW_FLOAT_TYPE # define TYPE_AUTO # define TYPEMAX 1 #else # define TYPEMAX ((TYPE)~(TYPE)0) #endif #ifndef RMAP # define RMAP(Y) ((NARROW_FLOAT_TYPE)((WIDE_FLOAT_TYPE)(Y) / TYPEMAX)) # define RMAP_AUTO #endif #define MAP(Y) (TYPE)((WIDE_FLOAT_TYPE)(Y) * TYPEMAX + (WIDE_FLOAT_TYPE)0.5f) #define R (&((TYPE *)&img[i])[settings.rpos]) #define G (&((TYPE *)&img[i])[settings.gpos]) #define B (&((TYPE *)&img[i])[settings.bpos]) #define A (&((TYPE *)&img[i])[settings.apos]) do { NARROW_FLOAT_TYPE opacity = (NARROW_FLOAT_TYPE)colour->opacity / 255; NARROW_FLOAT_TYPE al, alpha = (NARROW_FLOAT_TYPE)colour->alpha / 255; NARROW_FLOAT_TYPE re, red = (NARROW_FLOAT_TYPE)colour->red / 255; NARROW_FLOAT_TYPE gr, green = (NARROW_FLOAT_TYPE)colour->green / 255; NARROW_FLOAT_TYPE bl, blue = (NARROW_FLOAT_TYPE)colour->blue / 255; NARROW_FLOAT_TYPE transparency; if (settings.apos < 0) { if (gly_psize > 1) { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { *R = MAP(RMAP(*R) * (1 - opacity * gly[c + ri]) + gly[c + ri] * red); *G = MAP(RMAP(*G) * (1 - opacity * gly[c + gi]) + gly[c + gi] * green); *B = MAP(RMAP(*B) * (1 - opacity * gly[c + bi]) + gly[c + bi] * blue); } } } else { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { transparency = 1 - opacity * gly[c + ri]; *R = MAP(RMAP(*R) * transparency + gly[c + ri] * red); *G = MAP(RMAP(*G) * transparency + gly[c + gi] * green); *B = MAP(RMAP(*B) * transparency + gly[c + bi] * blue); } } } } else if (image->premultiplied) { if (gly_psize > 1) { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { high = gly[c + ri] > gly[c + gi] ? gly[c + ri] : gly[c + gi]; high = high > gly[c + bi] ? high : gly[c + bi]; *R = MAP(RMAP(*R) * (1 - opacity * gly[c + ri]) + gly[c + ri] * red); *G = MAP(RMAP(*G) * (1 - opacity * gly[c + gi]) + gly[c + gi] * green); *B = MAP(RMAP(*B) * (1 - opacity * gly[c + bi]) + gly[c + bi] * blue); *A = MAP(RMAP(*A) * (1 - opacity * high) + high * alpha); } } } else { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { transparency = 1 - opacity * gly[c + ri]; *R = MAP(RMAP(*R) * transparency + gly[c + ri] * red); *G = MAP(RMAP(*G) * transparency + gly[c + ri] * green); *B = MAP(RMAP(*B) * transparency + gly[c + ri] * blue); *A = MAP(RMAP(*A) * transparency + gly[c + ri] * alpha); } } } } else { if (gly_psize > 1) { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { high = gly[c + ri] > gly[c + gi] ? gly[c + ri] : gly[c + gi]; high = high > gly[c + bi] ? high : gly[c + bi]; re = RMAP(*R) * RMAP(*A) * (1 - opacity * gly[c + ri]) + gly[c + ri] * red; gr = RMAP(*G) * RMAP(*A) * (1 - opacity * gly[c + gi]) + gly[c + gi] * green; bl = RMAP(*B) * RMAP(*A) * (1 - opacity * gly[c + bi]) + gly[c + bi] * blue; al = RMAP(*A) * (1 - opacity * high) + high * alpha; if (fpclassify(al) != FP_ZERO) { *R = MAP(re); *G = MAP(gr); *B = MAP(bl); *A = MAP(al); } else { *R = *G = *B = *A = 0; } } } } else { for (img = img_start, r = startr; r < endr; r++, img += img_linesize, gly += gly_linesize) { for (c = startc, i = 0; c < endc; c += gly_psize, i += psize) { transparency = 1 - opacity * gly[c + ri]; re = RMAP(*R) * RMAP(*A) * transparency + gly[c + ri] * red; gr = RMAP(*G) * RMAP(*A) * transparency + gly[c + ri] * green; bl = RMAP(*B) * RMAP(*A) * transparency + gly[c + ri] * blue; al = RMAP(*A) * transparency + gly[c + ri] * alpha; if (fpclassify(al) != FP_ZERO) { *R = MAP(re); *G = MAP(gr); *B = MAP(bl); *A = MAP(al); } else { *R = *G = *B = *A = 0; } } } } } } while (0); #ifdef NARROW_FLOAT_TYPE_AUTO # undef NARROW_FLOAT_TYPE_AUTO # undef NARROW_FLOAT_TYPE #endif #ifdef WIDE_FLOAT_TYPE_AUTO # undef WIDE_FLOAT_TYPE_AUTO # undef WIDE_FLOAT_TYPE #endif #ifdef TYPE_AUTO # undef TYPE_AUTO # undef TYPE #endif #undef TYPEMAX #ifdef RMAP_AUTO # undef RMAP_AUTO # undef RMAP #endif #undef MAP #undef R #undef G #undef B #undef A