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author | Robin Watts <robin.watts@artifex.com> | 2017-07-20 15:04:55 +0100 |
---|---|---|
committer | Robin Watts <robin.watts@artifex.com> | 2017-09-12 14:32:33 +0100 |
commit | 674acf4579af2e129ec52d4a176ff359f39e9ca9 (patch) | |
tree | 015d423dfd1799ef4764d61558b70e7b5a9abe15 /source | |
parent | d9e5ef7fb43ac6415ee947f373df77138c78b177 (diff) | |
download | mupdf-674acf4579af2e129ec52d4a176ff359f39e9ca9.tar.xz |
Fix separation pixmap conversion functions for DeviceN.
Diffstat (limited to 'source')
-rw-r--r-- | source/fitz/separation.c | 360 |
1 files changed, 329 insertions, 31 deletions
diff --git a/source/fitz/separation.c b/source/fitz/separation.c index f202d1aa..dfec38ff 100644 --- a/source/fitz/separation.c +++ b/source/fitz/separation.c @@ -290,6 +290,7 @@ fz_copy_pixmap_area_converting_seps(fz_context *ctx, fz_pixmap *dst, fz_pixmap * int x, y, i, j, k; unsigned char mapped[FZ_MAX_COLORS]; int unmapped = sseps_n; + int device_n = 0; assert(da == sa); assert(ss == fz_count_active_separations(ctx, sseps)); @@ -319,30 +320,45 @@ fz_copy_pixmap_area_converting_seps(fz_context *ctx, fz_pixmap *dst, fz_pixmap * } else { - fz_pixmap_converter *pc = fz_lookup_pixmap_converter(ctx, dst->colorspace, src->colorspace); + device_n = fz_colorspace_is_device_n(ctx, src->colorspace); + if (device_n) + fz_clear_pixmap(ctx, dst); + else + { + fz_pixmap_converter *pc = fz_lookup_pixmap_converter(ctx, dst->colorspace, src->colorspace); - pc(ctx, dst, src, prf, default_cs, NULL, 0); + pc(ctx, dst, src, prf, default_cs, NULL, 0); + } } /* Make a map of what spots go where */ + for (i = 0; i < sseps_n; i++) + mapped[i] = 0; + for (i = 0, k = 0; i < dseps_n; i++) { const char *name; + int state = sep_state(dseps, i); - if (sep_state(dseps, i) >= FZ_SEPARATION_DISABLED) + if (state != FZ_SEPARATION_SPOT) continue; name = dseps->name[i]; + if (name == NULL) + continue; map[k] = -1; - mapped[k] = 0; for (j = 0; j < sseps_n; j++) { - if (sep_state(sseps, j) >= FZ_SEPARATION_DISABLED) + const char *sname; + if (mapped[j]) continue; - if (!strcmp(name, sseps->name[j])) + if (sep_state(sseps, j) != FZ_SEPARATION_SPOT) + continue; + sname = sseps->name[j]; + if (sname && !strcmp(name, sname)) { map[k] = j; unmapped--; - mapped[k] = 1; + mapped[j] = 1; break; } } @@ -351,8 +367,10 @@ fz_copy_pixmap_area_converting_seps(fz_context *ctx, fz_pixmap *dst, fz_pixmap * if (sa) map[k] = sseps_n; - /* Now we need to make d[i] = map[i] < 0 : 255 ? s[map[i]] */ + /* Now we need to make d[i] = map[i] < 0 : 0 ? s[map[i]] */ + ds += da; + if (ds) { unsigned char *dd = ddata + dc; const unsigned char *sd = sdata + sc; @@ -361,7 +379,7 @@ fz_copy_pixmap_area_converting_seps(fz_context *ctx, fz_pixmap *dst, fz_pixmap * for (x = dw; x > 0; x--) { for (i = 0; i < ds; i++) - dd[i] = map[i] < 0 ? 255 : sd[map[i]]; + dd[i] = map[i] < 0 ? 0 : sd[map[i]]; dd += dn; sd += sn; } @@ -370,39 +388,319 @@ fz_copy_pixmap_area_converting_seps(fz_context *ctx, fz_pixmap *dst, fz_pixmap * } } - /* If we've handled all the spots, we're done. */ - if (unmapped == 0) - return dst; + if (unmapped) + { + /* Still need to handle mapping 'lost' spots down to process colors */ + for (i = 0; i < sseps_n; i++) + { + float convert[FZ_MAX_COLORS]; + + if (mapped[i]) + continue; + /* Src spot i is not mapped. We need to convert that down. */ + fz_separation_equivalent(ctx, sseps, i, color_params, dst->colorspace, prf, convert); - /* Still need to handle mapping 'lost' spots down to process colors */ - for (i = 0; i < sseps_n; i++) + if (fz_colorspace_is_subtractive(ctx, dst->colorspace)) + { + if (fz_colorspace_is_subtractive(ctx, src->colorspace)) + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata + sc; + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = sd[i]; + if (v != 0) + for (k = 0; k < dc; k++) + dd[k] = fz_clampi(dd[k] + v * convert[k], 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + else + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata + sc; + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = 0xff - sd[i]; + if (v != 0) + for (k = 0; k < dc; k++) + dd[k] = fz_clampi(dd[k] + v * convert[k], 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + } + else + { + if (fz_colorspace_is_subtractive(ctx, src->colorspace)) + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata + sc; + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = sd[i]; + if (v != 0) + for (k = 0; k < dc; k++) + dd[k] = fz_clampi(dd[k] - v * (1-convert[k]), 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + else + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata + sc; + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = 0xff - sd[i]; + if (v != 0) + for (k = 0; k < dc; k++) + dd[k] = fz_clampi(dd[k] - v * (1-convert[k]), 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + } + } + } + + if (device_n) { - float convert[FZ_MAX_COLORS]; + /* Map the colorants down */ + int n = fz_colorspace_n(ctx, src->colorspace); - if (mapped[i]) - continue; - /* Src spot i is not mapped. We need to convert that down. */ - fz_separation_equivalent(ctx, sseps, i, color_params, dst->colorspace, prf, convert); + fz_color_converter cc; + fz_find_color_converter(ctx, &cc, prf, dst->colorspace, src->colorspace, color_params); + fz_try(ctx) { - unsigned char *dd = ddata; - const unsigned char *sd = sdata + sc; - for (y = dh; y > 0; y--) + unmapped = 0; + for (i = 0; i < n; i++) { - for (x = dw; x > 0; x--) + const char *name = fz_colorspace_colorant(ctx, src->colorspace, i); + + map[i] = 0; + + if (name) { - unsigned char v = sd[i]; - if (v == 0) + if (!strcmp(name, "None")) + continue; + if (!strcmp(name, "All")) + { + int k, n1 = dn - da; + unsigned char *dd = ddata; + const unsigned char *sd = sdata + i; + + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = *sd; + sd += sn; + for (k = 0; k < n1; k++) + dd[k] = v; + dd += dn; + } + dd += dstride; + sd += sstride; + } continue; - for (i = 0; i < dc; i++) - dd[i] = fz_clampi(dd[i] + v * convert[i], 0, 255); - dd += dn; - sd += sn; + } + for (j = 0; j < dc; j++) + { + const char *dname = fz_colorspace_colorant(ctx, dst->colorspace, j); + if (dname && !strcmp(name, dname)) + goto map_device_n_spot; + } + for (j = 0; j < dseps_n; j++) + { + const char *dname = dseps->name[j]; + if (dname && !strcmp(name, dname)) + { + j += dc; + goto map_device_n_spot; + } + } + } + if (0) + { + unsigned char *dd; + const unsigned char *sd; + map_device_n_spot: + /* Directly map a devicen colorant to a + * component (either process or spot) + * in the destination. */ + dd = ddata + j; + sd = sdata + i; + + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + *dd = *sd; + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + else + { + unmapped = 1; + map[i] = 1; + } + } + if (unmapped) + { +/* The standard spot mapping algorithm assumes that it's reasonable + * to treat the components of deviceN spaces as being orthogonal, + * and to add them together at the end. This avoids a color lookup + * per pixel. The alternative mapping algorithm looks up each + * pixel at a time, and is hence slower. */ +#define ALTERNATIVE_SPOT_MAP +#ifndef ALTERNATIVE_SPOT_MAP + for (i = 0; i < n; i++) + { + /* Src component i is not mapped. We need to convert that down. */ + unsigned char *dd = ddata; + const unsigned char *sd = sdata; + float convert[FZ_MAX_COLORS]; + float colors[FZ_MAX_COLORS]; + + if (map[i] == 0) + continue; + + memset(colors, 0, sizeof(float) * n); + colors[i] = 1; + cc.convert(ctx, &cc, convert, colors); + + if (fz_colorspace_is_subtractive(ctx, dst->colorspace)) + { + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = sd[i]; + if (v != 0) + { + for (j = 0; j < dc; j++) + dd[j] = fz_clampi(dd[j] + v * convert[j], 0, 255); + } + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + else + { + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = sd[i]; + if (v != 0) + { + for (j = 0; j < dc; j++) + dd[j] = fz_clampi(dd[j] - v * (1-convert[j]), 0, 255); + } + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + } +#else +/* If space is subtractive then treat spots like Adobe does in Photoshop. + * Which is to just use an equivalent CMYK value. If we are in an additive + * color space we will need to convert on a pixel-by-pixel basis. + */ + float convert[FZ_MAX_COLORS]; + float colors[FZ_MAX_COLORS]; + + if (fz_colorspace_is_subtractive(ctx, dst->colorspace)) + { + for (i = 0; i < n; i++) + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata; + + if (map[i] == 0) + continue; + + memset(colors, 0, sizeof(float) * n); + colors[i] = 1; + cc.convert(ctx, &cc, convert, colors); + + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + unsigned char v = sd[i]; + if (v != 0) + for (j = 0; j < dc; j++) + dd[j] = fz_clampi(dd[j] + v * convert[j], 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } + } + } + else + { + unsigned char *dd = ddata; + const unsigned char *sd = sdata; + for (y = dh; y > 0; y--) + { + for (x = dw; x > 0; x--) + { + for (j = 0; j < n; j++) + colors[j] = map[j] ? sd[j] / 255.0f : 0; + cc.convert(ctx, &cc, convert, colors); + + for (j = 0; j < dc; j++) + dd[j] = fz_clampi(255 * convert[j], 0, 255); + dd += dn; + sd += sn; + } + dd += dstride; + sd += sstride; + } } - dd += dstride; - sd += sstride; +#endif } } + fz_always(ctx) + fz_drop_color_converter(ctx, &cc); + fz_catch(ctx) + fz_rethrow(ctx); } return dst; |