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authorJörg Frings-Fürst <debian@jff-webhosting.net>2015-05-01 16:13:57 +0200
committerJörg Frings-Fürst <debian@jff-webhosting.net>2015-05-01 16:13:57 +0200
commit094535c010320967639e8e86f974d878e80baa72 (patch)
treeefc3094b20355dcbeebb2c4ece4fcfc69bffedb5 /link/collink.c
parentc07d0c2d2f6f7b0eb6e92cc6204bf05037957e82 (diff)
Imported Upstream version 1.7.0upstream/1.7.0
Diffstat (limited to 'link/collink.c')
-rw-r--r--link/collink.c1521
1 files changed, 1015 insertions, 506 deletions
diff --git a/link/collink.c b/link/collink.c
index 3bb93b7..655d4e4 100644
--- a/link/collink.c
+++ b/link/collink.c
@@ -1,6 +1,4 @@
-/* Version with Lab bt.1886 */
-
/*
* collink
*
@@ -25,10 +23,23 @@
* Abstract link support intent doesn't work properly for anything
* other than absolute. This should really be fixed.
*
+ * It would be good to add an option to allow a smaller destination
+ * gamut than the destination colorspace. This would allow applying
+ * a gamut mapping while staying in a wide gamut space. Do this
+ * in a similar way to the source + image gamut.
+ * ie. "-S src.gam,dst.gam"
+ *
+ * TV YCbCr clipping should preserve hue.
+ *
*/
/* NOTES:
+ Video :- current WTW TV encoding is clipped, not passed through with extrapolation.
+ If the display does a per component clipping, then passing through is probably
+ a bad thing, and cliping is the right behaviour, and just pass
+ the sync level though.
+
Normally the device side per channel curves are copied from
the source profiles to the link profile on the assumption that
the raw linearisation they do is good, and should be maintained
@@ -83,23 +94,72 @@
*/
+/*
+ Video encoding:
+
+ ArgyllCMS represents device values in a FP normalised form,
+ where 0.0 corresponds to the smallest valid device encoding,
+ and 1.0 corresponds to the largest valid device encoding.
+
+ For normal device values this means that 0.0 corresponds
+ with 0, and 1.0 corresponds with 2^bits-1.
+
+ For video this means that 0.0 corresponds with 0,
+ and 1.0 corresponds with (2^8-1) * 2^(bits-8),
+ with values above this regarded as aliases for
+ the maximum encoded values (ie. clipped/clamped).
+ Suitable care needs to be taken when converting
+ ArgyllCMS normalized numbers to/from video encoded
+ binary values. Because the full range and Video
+ encoding valid ranges coincide for 8 bits,
+ the 8 bit nomenclature and FP values are used
+ internally to defined the black and white points
+ for normalised video values.
+
+ There are additional complications with video encoding
+ when interacting with cLUTs that have a resolution
+ of less that 256. From an accuracy point of
+ view it is highly desirable that the black and possibly
+ white points coincide with a cLUT node.
+
+ Using cLUTs that are implemented using FP or high precision
+ math, the best way of achieving this is to use a piecewise
+ mapping of the FP values 0.0 bp wp 1.0 to
+ 0.0 cLUT_bp cLUT_wp 1.0, thereby preserving the
+ full encoding range in an encoding agnostic fashion.
+
+ External cLUTs that are implemented using integer logic
+ (ie, in HW, such as the eeColor) may choose to cope
+ with this probem in a different way, i.e. by
+ scaling against a value above the largest valid
+ device encoding. For instance, cLUTs of resolution
+ 65 would be normalised to 65 rather than the usual 64,
+ and a 16 bit encoding would be normalised to
+ 65536 rather than 65289, thereby lining the black
+ point encoded value up with a cLUT node as well
+ as making the normalised values independent
+ of the encoding bit depth. This implies that
+ the maximum valid encoding falls short of the
+ last cLUT entry.
+
+*/
+
#undef USE_MERGE_CLUT_OPT /* [Undef] When using inverse A2B table, merge the output luts */
/* with the clut for faster operation, and clipping in */
/* Jab space. Turned off because it affects the accuracy too much, */
/* and xicc handles Jab clip without this now. */
+#define USE_APXLS /* [Define] Use least squares approximation setting cLUT */
#define USE_CAM_CLIP_OPT /* [Define] Clip out of gamut in CAM space rather than XYZ or L*a*b* */
#define ENKHACK /* [Define] Enable K hack code */
#undef WARN_CLUT_CLIPPING /* [Undef] Print warning if setting clut clips */
-#undef DEBUG /* Report values of each sample transformed */
-#undef DEBUGC /* ie "if (tt)" */ /* Debug condition */
-#undef DEBUG_ONE /* test a single value out. Look for DBGNO to set value. */
-#undef NEUTKDEBUG /* print info about neutral L -> K mapping */
+#undef DEBUG /* [Und] Report values of each sample transformed */
+#undef DEBUGC /* [Und] ie "if (tt)" */ /* Debug condition */
+#undef DEBUG_ONE /* [Unf] test a single value out. Look for DBGNO to set value. */
+#undef NEUTKDEBUG /* [Unf] print info about neutral L -> K mapping */
-#undef LINTERP_OR /* Use simple extrapolation of Video encoded overrage values */
-
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
@@ -112,9 +172,11 @@
#include "numlib.h"
#include "icc.h"
#include "xicc.h"
+#include "bt1886.h"
#include "gamut.h"
#include "gammap.h"
#include "vrml.h"
+#include "ui.h"
void usage(char *diag, ...) {
int i;
@@ -138,7 +200,7 @@ void usage(char *diag, ...) {
fprintf(stderr," -q lmhu Quality - Low, Medium (def), High, Ultra\n");
// fprintf(stderr," -q fmsu Speed - Fast, Medium (def), Slow, Ultra Slow\n");
fprintf(stderr," -r res Override clut res. set by -q\n");
- fprintf(stderr," -n Don't preserve device linearization curves in result\n");
+ fprintf(stderr," -n [i|o] Don't preserve device linearization curves in result\n");
fprintf(stderr," -f Special :- Force neutral colors to be K only output\n");
fprintf(stderr," -fk Special :- Force K only neutral colors to be K only output\n");
fprintf(stderr," -F Special :- Force all colors to be K only output\n");
@@ -164,7 +226,7 @@ void usage(char *diag, ...) {
fprintf(stderr," %s\n",gmi.desc);
}
fprintf(stderr," -w [J,a,b] Use forced whitepoint hack [optional target point]\n");
-// fprintf(stderr," -W J,a,b Forced whitepoint adjustment by delta Jab\n");
+ fprintf(stderr," -b Use RGB->RGB forced black point hack\n");
fprintf(stderr," -c viewcond set source viewing conditions for %s,\n",icxcam_description(cam_default));
fprintf(stderr," either an enumerated choice, or a parameter\n");
fprintf(stderr," -d viewcond set destination viewing conditions for %s,\n",icxcam_description(cam_default));
@@ -203,14 +265,16 @@ void usage(char *diag, ...) {
fprintf(stderr," -3 flag Create \"3DLut\" output file as well as devlink\n");
fprintf(stderr," e eeColor .txt file\n");
fprintf(stderr," m MadVR .3dlut\t file\n");
- fprintf(stderr," -I b Apply BT.1886-like mapping with effective gamma 2.2 to input\n");
- fprintf(stderr," -I b:g.g Apply BT.1886-like mapping with effective gamma g.g to input\n");
- fprintf(stderr," -I B Apply BT.1886 mapping with technical gamma 2.4 to input\n");
- fprintf(stderr," -I B:g.g Apply BT.1886 mapping with technical gamma g.g to input\n");
+ fprintf(stderr," c IRIDAS .cube file\n");
+ fprintf(stderr," -I B Use BT.1886 source EOTF with technical gamma 2.4\n");
+ fprintf(stderr," -I b:g.g Use BT.1886-like source EOTF with effective gamma g.g\n");
+ fprintf(stderr," -I b:p.p:g.g Use effective gamma g.g source EOTF with p.p prop. output black point offset\n");
+ fprintf(stderr," -I g:g.g Use effective gamma g.g source EOTF with all output black point offset\n");
fprintf(stderr," -e flag Video encode input as:\n");
fprintf(stderr," -E flag Video encode output as:\n");
fprintf(stderr," n normal 0..1 full range RGB levels (default)\n");
fprintf(stderr," t (16-235)/255 \"TV\" RGB levels\n");
+ fprintf(stderr," T (16-235)/255 \"TV\" RGB levels, clip WTW [Input Only]\n");
fprintf(stderr," 6 Rec601 YCbCr SD (16-235,240)/255 \"TV\" levels\n");
fprintf(stderr," 7 Rec709 1125/60Hz YCbCr HD (16-235,240)/255 \"TV\" levels\n");
fprintf(stderr," 5 Rec709 1250/50Hz YCbCr HD (16-235,240)/255 \"TV\" levels\n");
@@ -218,38 +282,11 @@ void usage(char *diag, ...) {
fprintf(stderr," C Rec2020 Constant Luminance YCbCr UHD (16-235,240)/255 \"TV\" levels\n");
fprintf(stderr," x xvYCC Rec601 YCbCr Rec709 Prims. SD (16-235,240)/255 \"TV\" levels\n");
fprintf(stderr," X xvYCC Rec709 YCbCr Rec709 Prims. HD (16-235,240)/255 \"TV\" levels\n");
- fprintf(stderr," -P Create gamut gammap.wrl diagostic\n");
+ fprintf(stderr," -P Create gamut gammap%s diagostic\n",vrml_ext());
exit(1);
}
/* ------------------------------------------- */
-
-#ifdef NEVER
-/* If video encoding is being used, the edge of the video range */
-/* may not fall on a gid boundary, leading to innacuracies */
-/* in black, white, or the saturated colors. */
-/* To fix this, we notice which gid values just get clipped */
-/* by the video encoding, and after the grid is complete, */
-/* do a fixup pass to set the grid value to that needed */
-/* to make the edge value perferct. */
-
-/* For the eeColor wich has a fixed grod res. of 65, */
-/* the Luminance range 16-235 lands perfectly on a grid point, */
-/* and the CbCr maximum value of 240 missed by 1/256, */
-/* so we haven't yet implemented this fixup */
-
-/* Instead we are just tweaking the cLUT values of the black */
-/* point to avoid any error at this critical value. */
-
-typedef struct {
- int clip; /* Clip mask */
- int ix[MXDI]; /* Index of the grid point that was clipped */
- double in[MXDI]; /* grid value that was clipped */
- double out[MXDO]; /* clipped value */
-} edgepoints;
-#endif
-
-/* ------------------------------------------- */
/* structures to support icc calbacks */
/* Information needed from a profile */
@@ -276,20 +313,23 @@ struct _profinfo {
int lcurve; /* 1 to apply a Y like to L* curve for XYZ Matrix profiles */
/* 2 to apply a Y to L* curve for XYZ space */
int tvenc; /* 0 = full range RGB, 1 = RGB Video Level encoding, */
- /* 2 = Rec601 YCbCr encoding, 3 = Rec709 1150/60/2:1 YCbCr encoding */
- /* 4 = Rec709 1250/50/2:1 YCbCr encoding */
- /* 5 = Rec2020 Non-constant Luminance YCbCr encoding */
- /* 6 = Rec2020 Constant Luminance YCbCr encoding */
- /* 7 = xvYCC with Rec601 YCbCr encoding with Rec709 primaries */
- /* 8 = xvYCC with Rec709 YCbCr encoding with Rec709 primaries */
+ /* 1 = RGB Video Level encoding, */
+ /* 3 = Rec601 YCbCr encoding, */
+ /* 4 = Rec709 1150/60/2:1 YCbCr encoding */
+ /* 5 = Rec709 1250/50/2:1 YCbCr encoding */
+ /* 6 = Rec2020 Non-constant Luminance YCbCr encoding */
+ /* 7 = Rec2020 Constant Luminance YCbCr encoding */
+ /* 8 = xvYCC with Rec601 YCbCr encoding with Rec709 primaries */
+ /* 9 = xvYCC with Rec709 YCbCr encoding with Rec709 primaries */
/* (We save Video YCbCr as "RGB" space ICC profile) */
- int bt1886; /* 1 to apply BT.1886 black point & effective gamma to input */
- /* 2 to apply BT.1886 black point & technical gamma to input */
+ int tvclip; /* Clip rather than extrapolate */
+ int bt1886; /* 1 to apply input gamma curve using effective gamma */
+ /* 2 to apply input gamma curve using technical gamma */
+ double outoprop; /* Proportion of black output offset, 0.0 .. 1.0. 0.0 == BT.1886 */
double egamma; /* effective gamma to ain for */
double tgamma; /* technical gamma to ain for */
bt1886_info bt; /* BT.1886 adjustment info */
double rgb_bk[3]; /* Linear light input RGB black to bend to */
- double bt_bk[3]; /* Input profile bt.1886 modified black point in gamut map space */
double wp[3]; /* Lab/Jab white point for profile used by wphack & xyzscale */
icxLuBase *b2aluo; /* B2A lookup for inking == 7 */
}; typedef struct _profinfo profinfo;
@@ -298,7 +338,7 @@ struct _profinfo {
struct _clink {
/* Overall options */
int verb;
- int gamdiag; /* nz, create gammap.wrl diagnostic */
+ int gamdiag; /* nz, create gammap diagnostic */
int total, count, last; /* Progress count information */
int mode; /* 0 = simple mode, 1 = mapping mode, 2 = mapping mode with inverse A2B */
int quality; /* 0 = low, 1 = medium, 2 = high, 3 = ultra */
@@ -307,6 +347,7 @@ struct _clink {
int dst_kbp; /* nz = Use K only black point as dst gamut black point */
int dst_cmymap; /* masks C = 1, M = 2, Y = 4 to force 100% cusp map */
int tdlut; /* nz = 3DLut output, 1 = eeColor format, 2 = MadVR format */
+ /* 3 = .cube format */
icColorSpaceSignature pcsor; /* PCS to use between in & out profiles */
@@ -315,8 +356,10 @@ struct _clink {
int cmyhack; /* CMY 100% colorant map though hack, 1 = C, 2 = M, 4 = Y */
rspl *pcs2k; /* PCS L to K' lookup for nhack */
int wphack; /* 0 = off, 1 = hack to map input wp to output wp, 2 = to hwp[] */
+ int rgbbkhack; /* 0 = off, 1 = hack to map input bp to output bp (RGB -> RGB only) */
double hwp[3]; /* hack destination white point in PCS space */
int wphacked; /* Operation flag, set nz if white point was translated */
+ int bkhacked; /* Operation flag, set nz if black was translated */
int rel_oride; /* Relative override flag */
icmFile *abs_fp; /* Abstract profile transform */
@@ -336,9 +379,7 @@ struct _clink {
icxGMappingIntent gmi;
gammap *map; /* Gamut mapping */
gammap *Kmap; /* Gamut mapping K in to K out nhack == 2 and K in to K out */
-
-// edgepoints *epl; /* Edge point list for fixups when in.tvenc */
- /* we need 2 * di * gres ^ (di-1) entries max. */
+
/* Per profile setup information */
profinfo in;
@@ -410,6 +451,59 @@ static void l2y_curve(double *out, double *in, int isXYZ) {
/* ------------------------------------------- */
+#ifndef NEVER
+
+/* Clip a value to the RGB Video range 16..235 RGB. */
+/* Clip the incoming value clip[] in place. */
+/* Return the uncliped value in unclipped[] */
+/* Return a bit mask of the channels that have/would clip, */
+/* and the full value in the clip direction in full[]. */
+/* Scale all non-black values to avoid positive clipping and */
+/* Return the restoring scale factor (> 1.0) if this has occured. */
+static int clipVidRGB(double *pscale, double full[3], double unclipped[3], double clip[3]) {
+ int i, os = 0;
+ double mx = -1.0, scale = 1.0;
+
+ /* Locate the channel with the largest value */
+ for (i = 0; i < 3; i++) {
+ unclipped[i] = clip[i];
+ if (clip[i] > mx)
+ mx = clip[i];
+ }
+ /* One channel positively clipping */
+ if (mx > (235.0/255.0)) {
+ scale = ((235.0-16.0)/255.0)/(mx - (16.0/255.0));
+
+ /* Scale all non-black value down towards black, to avoid clipping */
+ for (i = 0; i < 3; i++) {
+ /* Note if channel would clip in itself */
+ if (clip[i] > (235.0/255.0)) {
+ full[i] = 1.0;
+ os |= (1 << i);
+ }
+ if (clip[i] > (16.0/255.0))
+ clip[i] = (clip[i] - 16.0/255.0) * scale + 16.0/255.0;
+ }
+ }
+
+ /* See if any values negatively clip */
+ for (i = 0; i < 3; i++) {
+ if (clip[i] < (16.0/255.0)) {
+ clip[i] = (16.0/255.0);
+ full[i] = 0.0;
+ os |= (1 << i);
+ }
+ }
+
+ scale = 1.0/scale;
+ if (pscale != NULL)
+ *pscale = scale;
+
+ return os;
+}
+
+#else
+
/* Clip a value to the RGB Video range 16..235 RGB */
/* Return a bit mask of the channels that have clipped */
/* Clip the incoming value clip[] in place */
@@ -431,6 +525,7 @@ static int clipVidRGB(double full[3], double unclipped[3], double clip[3]) {
}
return os;
}
+#endif
/* Clip a value to the YCbCr range range 16..235, 16..240 */
/* Return a bit mask of the channels that have clipped */
@@ -533,11 +628,98 @@ static void xvYCC_fwd_matrix(double *out, double *in) {
}
/* ======================================================= */
+/* cLUT Input value tweaks to make Video emcoded black land on */
+/* 65 res grid nodes. This should help 33 and 17 res cLUTs too*/
+
+/* This also makes the cLUT nodes line up with the eeColor cLUT nodes. */
+
+static void VidRGB_to_cLUT65(double out[3], double in[3]) {
+ int i;
+ for (i = 0; i < 3; i++) {
+ if (in[i] <= (236.0/255.0)) /* Scale up to near black point */
+ out[i] = in[i] * 255.0/256.0;
+ else
+ out[i] = 1.0 - (1.0 - in[i]) * (1.0 - 236.0/256.0) / (1.0 - 236.0/255.0);
+ }
+}
+
+static void cLUT65_to_VidRGB(double out[3], double in[3]) {
+ int i;
+ for (i = 0; i < 3; i++) {
+ if (in[i] <= (236.0/256.0)) /* Scale up to near black point */
+ out[i] = in[i] * 256.0/255.0;
+ else
+ out[i] = 1.0 - (1.0 - in[i]) * (1.0 - 236.0/255.0) / (1.0 - 236.0/256.0);
+ }
+}
+
+static void YCrCb_to_cLUT65(double out[3], double in[3]) {
+ if (in[0] <= (236.0/255.0)) /* Scale up to near black point */
+ out[0] = in[0] * 255.0/256.0;
+ else
+ out[0] = 1.0 - (1.0 - in[0]) * (1.0 - 236.0/256.0) / (1.0 - 236.0/255.0);
+
+ if (in[1] <= (240.0/255.0))
+ out[1] = in[1] * 255.0/256.0;
+ else
+ out[1] = 1.0 - (1.0 - in[1]) * (1.0 - 240.0/256.0) / (1.0 - 240.0/255.0);
+
+ if (in[2] <= (240.0/255.0))
+ out[2] = in[2] * 255.0/256.0;
+ else
+ out[2] = 1.0 - (1.0 - in[2]) * (1.0 - 240.0/256.0) / (1.0 - 240.0/255.0);
+}
+
+static void cLUT65_to_YCrCb(double out[3], double in[3]) {
+ if (in[0] <= (236.0/256.0)) /* Scale up to near black point */
+ out[0] = in[0] * 256.0/255.0;
+ else
+ out[0] = 1.0 - (1.0 - in[0]) * (1.0 - 236.0/255.0) / (1.0 - 236.0/256.0);
+
+ if (in[1] <= (240.0/256.0))
+ out[1] = in[1] * 256.0/255.0;
+ else
+ out[1] = 1.0 - (1.0 - in[1]) * (1.0 - 240.0/255.0) / (1.0 - 240.0/256.0);
+
+ if (in[2] <= (240.0/256.0))
+ out[2] = in[2] * 256.0/255.0;
+ else
+ out[2] = 1.0 - (1.0 - in[2]) * (1.0 - 240.0/255.0) / (1.0 - 240.0/256.0);
+}
+
+/* Hmm. I'm not so sure of the one... */
+static void xvYCC_to_cLUT65(double out[3], double in[3]) {
+ if (in[0] <= (236.0/255.0)) /* Scale up to near black point */
+ out[0] = in[0] * 255.0/256.0;
+ else
+ out[0] = 1.0 - (1.0 - in[0]) * (1.0 - 236.0/256.0) / (1.0 - 236.0/255.0);
+
+ out[1] = in[1];
+ out[2] = in[2];
+}
+
+static void cLUT65_to_xvYCC(double out[3], double in[3]) {
+ if (in[0] <= (236.0/256.0)) /* Scale up to near black point */
+ out[0] = in[0] * 256.0/255.0;
+ else
+ out[0] = 1.0 - (1.0 - in[0]) * (1.0 - 236.0/255.0) / (1.0 - 236.0/256.0);
+
+ out[1] = in[1];
+ out[2] = in[2];
+}
+
+/* ======================================================= */
/* Functions called back in setting up the transform table */
#ifdef DEBUGC
-static int tt = 0;
+int tt = 0;
+
+#define DEBUGCND DEBUGC
+
+#else
+
+# define DEBUGCND /* Define it as empty */
#endif /* DEBUGC */
@@ -545,21 +727,18 @@ static int tt = 0;
void devi_devip(void *cntx, double *out, double *in) {
int rv = 0;
clink *p = (clink *)cntx;
- int i, clip = 0;
+ int i, clip = 0; /* Not preserving video sync when doing video decode in input lut */
double uc[3]; /* Unclipped values (Video) */
double cin[3]; /* clipped input value (Video) */
double full[3]; /* Full value in clip direction (Video) */
#ifdef DEBUGC
- if (in[0] == 1.0 && in[1] == 1.0 && in[2] == 1.0 && in[3])
- tt = 1;
+// if (in[0] == 1.0 && in[1] == 1.0 && in[2] == 1.0 && in[3])
+// tt = 1;
#endif
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevIn->DevIn' got %s\n",icmPdv(p->in.chan, in));
+ DEBUGCND printf("DevIn->DevIn' got %s\n",icmPdv(p->in.chan, in));
#endif
for (i = 0; i < p->in.chan; i++)
@@ -567,22 +746,22 @@ void devi_devip(void *cntx, double *out, double *in) {
if (!p->in.nocurve) { /* Using profile per channel curves */
- /* Video encoding decode */
+ /* Video decode */
if (p->in.tvenc == 1) { /* Video 16-235 range */
- clip = clipVidRGB(full, uc, out);
+ clip = clipVidRGB(NULL, full, uc, out);
icmCpy3(cin, out);
icmVidRGB_2_RGB(out, out);
-#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("After TVdecode:\n",icmPdv(p->in.chan, out));
-#endif
- } else if (p->in.tvenc >= 2) { /* YCbCr */
+ } else if (p->in.tvenc >= 3) { /* YCbCr */
error("Can't use input curves with YCbCr input encoding");
}
+#ifdef DEBUG
+ if (p->in.tvenc) {
+ DEBUGCND printf("After TVdecode:\n",icmPdv(p->in.chan, out));
+ }
+#endif
+ /* Input curve */
switch(p->in.alg) {
case icmMonoFwdType: {
icxLuMono *lu = (icxLuMono *)p->in.luo; /* Safe to coerce */
@@ -591,7 +770,10 @@ void devi_devip(void *cntx, double *out, double *in) {
}
case icmMatrixFwdType: {
icxLuMatrix *lu = (icxLuMatrix *)p->in.luo; /* Safe to coerce */
- rv |= lu->fwd_curve(lu, out, out);
+ if (p->in.bt1886)
+ bt1886_fwd_curve(&p->in.bt, out, out);
+ else
+ rv |= lu->fwd_curve(lu, out, out);
break;
}
case icmLutType: {
@@ -606,19 +788,16 @@ void devi_devip(void *cntx, double *out, double *in) {
}
if (rv >= 2)
error("icc lookup failed: %d, %s",p->in.c->errc,p->in.c->err);
-
- /* Create linear interpolation from clip to full range */
- if (clip && p->in.tvenc) {
- for (i = 0; i < 3; i++) {
- if (clip & (1 << i)) {
- out[i] = out[i] + (uc[i] - cin[i])/(full[i] - cin[i]) * (full[i] - out[i]);
- }
- }
- }
+#ifdef DEBUG
+ DEBUGCND printf("After input curve:\n",icmPdv(p->in.chan, out));
+#endif
}
if (p->in.lcurve) { /* Apply Y to L* */
y2l_curve(out, out, p->in.lcurve == 2);
+#ifdef DEBUG
+ DEBUGCND printf("After Y -. L* curve:\n",icmPdv(p->in.chan, out));
+#endif
}
/* eeColor cLUT is fake 65^3 - only 64^3 is usable. This affects */
@@ -629,22 +808,41 @@ void devi_devip(void *cntx, double *out, double *in) {
out[i] = out[i] * (p->clutres-2.0)/(p->clutres-1.0);
/* This isn't actually usable, because the eeColor does its own YCbCr conversion */
- } else if (p->in.tvenc == 7 || p->in.tvenc == 8) { /* xvYCC */
+ } else if (p->in.tvenc == 8 || p->in.tvenc == 9) { /* xvYCC */
out[0] = out[0];
out[1] = (out[1] * (p->clutres-3.0) + 1.0)/(p->clutres-1.0); /* Keep symetrical */
out[2] = (out[2] * (p->clutres-3.0) + 1.0)/(p->clutres-1.0);
}
}
+ /* For video encoding, adjust index value vert slightly, */
+ /* to align black with grid node. (We assume that the 3DLut HW */
+ /* is doing this when there are no input & output curves for 2DLuts) */
+ if (p->in.tvenc != 0
+ && (p->clutres == 65
+ || p->clutres == 33
+ || p->clutres == 17)) {
+ if (p->in.tvenc == 1) { /* Video 16-235 range */
+ VidRGB_to_cLUT65(out, out);
+ } else if (p->in.tvenc == 3 /* Rec601 YCbCr */
+ || p->in.tvenc == 4 /* Rec709 1150/60/2:1 YCbCr */
+ || p->in.tvenc == 5 /* Rec709 1250/50/2:1 YCbCr */
+ || p->in.tvenc == 6 /* Rec2020 Non-constant Luminance YCbCr encoding */
+ || p->in.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
+ YCrCb_to_cLUT65(out, out);
+
+ } else if (p->in.tvenc == 8 /* SD xvYCC with Rec601 YCbCr encoding */
+ || p->in.tvenc == 9) { /* HD xvYCC with Rec709 YCbCr encoding */
+ // Hmm. Not sure what to do here, and how it interacts with above.
+ // YCrCb_to_cLUT65(out, out);
+ }
+ }
+
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevIn->DevIn' ret %s\n",icmPdv(p->in.chan, out));
+ DEBUGCND printf("DevIn->DevIn' ret %s\n",icmPdv(p->in.chan, out));
#endif
}
-
/* - - - - - - - - - - - - */
/* clut, DevIn' -> DevOut' */
void devip_devop(void *cntx, double *out, double *in) {
@@ -657,18 +855,24 @@ void devip_devop(void *cntx, double *out, double *in) {
double konlyness = 0.0; /* Degree of K onlyness */
int ntrig = 0; /* K only output hack triggered */
int cmytrig = 0; /* CMY output hack triggered */
+ int rgbbktrig = 0; /* RGB black trigger */
int i, rv = 0;
clink *p = (clink *)cntx;
- int clip = 0; /* clip mask (Video) */
+ int clip = 0; /* clip mask (Video), to pass sync through 3DLut with Video dec/enc */
double cin[3]; /* clipped input value (Video) */
- double uc[3]; /* Unclipped values (Video) */
- double full[3]; /* Full value in clip direction (Video) */
+ double uci[3]; /* Unclipped input values (Video) */
+ double full[3]; /* Full (0.0/1.0) input value in clip direction (Video) */
+ double scale; /* RGB positive clipping scale factor (Video) */
-#ifdef DEBUG
#ifdef DEBUGC
- DEBUGC
+ tt = 0;
+// if (in[0] == 58.0/64.0 && in[1] == 58.0/64.0 && in[2] == 58.0/64.0)
+ if (in[0] == 4.0/64.0 && in[1] == 4.0/64.0 && in[2] == 4.0/64.0)
+ tt = 1;
#endif
- printf("DevIn'->DevOut' got %s\n",icmPdv(p->in.chan, in));
+
+#ifdef DEBUG
+ DEBUGCND printf("DevIn'->DevOut' got %s\n",icmPdv(p->in.chan, in));
#endif
/* Make a copy so we can modify it and are not affected when we write */
@@ -684,61 +888,84 @@ void devip_devop(void *cntx, double *out, double *in) {
win[i] = win[i] * (p->clutres-1.0)/(p->clutres-2.0);
/* This isn't actually usable, because the eeColor does its own YCbCr conversion */
- } else if (p->in.tvenc == 7 || p->in.tvenc == 8) { /* xvYCC */
+ } else if (p->in.tvenc == 8 || p->in.tvenc == 9) { /* xvYCC */
win[0] = win[0];
win[1] = (win[1] * (p->clutres-1.0) - 1.0)/(p->clutres-3.0);
win[2] = (win[2] * (p->clutres-1.0) - 1.0)/(p->clutres-3.0);
}
}
+ /* For video encoding, adjust index value to align black with */
+ /* grid node */
+ if (p->in.tvenc != 0
+ && (p->clutres == 65
+ || p->clutres == 33
+ || p->clutres == 17)) {
+ if (p->in.tvenc == 1) { /* Video 16-235 range */
+ cLUT65_to_VidRGB(win, win);
+ } else if (p->in.tvenc == 3 /* Rec601 YCbCr */
+ || p->in.tvenc == 4 /* Rec709 1150/60/2:1 YCbCr */
+ || p->in.tvenc == 5 /* Rec709 1250/50/2:1 YCbCr */
+ || p->in.tvenc == 6 /* Rec2020 Non-constant Luminance YCbCr encoding */
+ || p->in.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
+ cLUT65_to_YCrCb(win, win);
+
+ } else if (p->in.tvenc == 8 /* SD xvYCC with Rec601 YCbCr encoding */
+ || p->in.tvenc == 9) { /* HD xvYCC with Rec709 YCbCr encoding */
+ // Hmm. Not sure what to do here, and how it interacts with above.
+ // YCrCb_to_cLUT65(win, win);
+ }
+#ifdef DEBUG
+ DEBUGCND printf("After cLUT65 decode: %s\n",icmPdv(p->in.chan, win));
+#endif
+ }
+
if (p->in.nocurve) { /* Not using profile per channel curves */
- /* Video encoding decode */
+ /* Video encoding decode and input clipping */
+ scale = 1.0;
if (p->in.tvenc == 1) { /* Video 16-235 range */
- clip = clipVidRGB(full, uc, win);
+ clip = clipVidRGB(&scale, full, uci, win);
icmCpy3(cin, win);
icmVidRGB_2_RGB(win, win);
- } else if (p->in.tvenc == 2) { /* Rec601 YCbCr */
- clip = clipYCrCb(full, uc, win);
+ } else if (p->in.tvenc == 3) { /* Rec601 YCbCr */
+ clip = clipYCrCb(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec601_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 3) { /* Rec709 1150/60/2:1 YCbCr */
- clip = clipYCrCb(full, uc, win);
+ } else if (p->in.tvenc == 4) { /* Rec709 1150/60/2:1 YCbCr */
+ clip = clipYCrCb(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec709_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 4) { /* Rec709 1250/50/2:1 YCbCr */
- clip = clipYCrCb(full, uc, win);
+ } else if (p->in.tvenc == 5) { /* Rec709 1250/50/2:1 YCbCr */
+ clip = clipYCrCb(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec709_50_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 5) { /* Rec2020 Non-constant Luminance YCbCr encoding */
- clip = clipYCrCb(full, uc, win);
+ } else if (p->in.tvenc == 6) { /* Rec2020 Non-constant Luminance YCbCr encoding */
+ clip = clipYCrCb(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec2020_NCL_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 6) { /* Rec2020 Constant Luminance YCbCr encoding */
- clip = clipYCrCb(full, uc, win);
+ } else if (p->in.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
+ clip = clipYCrCb(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec2020_CL_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 7) { /* SD xvYCC with Rec601 YCbCr encoding */
- clip = clip_xvYCC(full, uc, win);
+ } else if (p->in.tvenc == 8) { /* SD xvYCC with Rec601 YCbCr encoding */
+ clip = clip_xvYCC(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec601_YPbPr_2_RGBd(win, win);
- } else if (p->in.tvenc == 8) { /* HD xvYCC with Rec709 YCbCr encoding */
- clip = clip_xvYCC(full, uc, win);
+ } else if (p->in.tvenc == 9) { /* HD xvYCC with Rec709 YCbCr encoding */
+ clip = clip_xvYCC(full, uci, win);
icmCpy3(cin, win);
icmRecXXX_YCbCr_2_YPbPr(win, win);
icmRec709_YPbPr_2_RGBd(win, win);
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("After TVdecode: %s\n",icmPdv(p->in.chan, win));
+ DEBUGCND printf("After TVdecode: %s\n",icmPdv(p->in.chan, win));
#endif
}
@@ -760,7 +987,7 @@ void devip_devop(void *cntx, double *out, double *in) {
ntrig = 1; /* K only output triggered flag */
} else if (p->nhack == 2) {
- double maxcmy; /* Comute a degree of source "K onlyness" */
+ double maxcmy; /* Compute a degree of source "K onlyness" */
double maxcmyk;
maxcmy = win[0]; /* Compute minimum of CMY */
@@ -790,10 +1017,7 @@ void devip_devop(void *cntx, double *out, double *in) {
&& win[2] < thr)
ntrig = 1; /* K only output triggered flag */
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("konlyness set to %f\n",konlyness);
+ DEBUGCND printf("konlyness set to %f\n",konlyness);
#endif
}
@@ -826,13 +1050,22 @@ void devip_devop(void *cntx, double *out, double *in) {
}
#endif /* ENKHACK */
+ /* Handle RGB black to RGB black hack */
+ if (p->rgbbkhack != 0) {
+ double thr = (0.5)/(p->clutres-1.0); /* Match threshold */
+
+ if (win[0] < thr
+ && win[1] < thr
+ && win[2] < thr) {
+ rgbbktrig = 1;
+ p->bkhacked++;
+ }
+ }
+
if (p->in.lcurve) { /* Apply L* to Y */
l2y_curve(win, win, p->in.lcurve == 2);
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("win[] set to L* value %s\n",icmPdv(p->in.chan, win));
+ DEBUGCND printf("win[] set to L* value %s\n",icmPdv(p->in.chan, win));
#endif
}
@@ -856,35 +1089,37 @@ void devip_devop(void *cntx, double *out, double *in) {
if (p->in.nocurve) { /* No explicit curve, so do implicit here */
- if (p->in.tvenc == 7 || p->in.tvenc == 8) { /* xvYCC */
- xvYCC_fwd_curve(pcsv, win); /* Allow for overrange values */
+ if (p->in.tvenc == 8 || p->in.tvenc == 9) { /* xvYCC */
+ if (p->in.bt1886)
+ bt1886_fwd_curve(&p->in.bt, pcsv, win);
+ else
+ xvYCC_fwd_curve(pcsv, win); /* Allow for overrange values */
xvYCC_fwd_matrix(pcsv, pcsv); /* Rec709 primaries */
} else {
- rv |= lu->fwd_curve(lu, pcsv, win);
+ if (p->in.bt1886)
+ bt1886_fwd_curve(&p->in.bt, pcsv, win);
+ else
+ rv |= lu->fwd_curve(lu, pcsv, win);
rv |= lu->fwd_matrix(lu, pcsv, pcsv);
}
} else {
- if (p->in.tvenc == 7 || p->in.tvenc == 8) /* xvYCC */
+ if (p->in.tvenc == 8 || p->in.tvenc == 9) /* xvYCC */
xvYCC_fwd_matrix(pcsv, pcsv); /* Rec709 primaries */
else
rv |= lu->fwd_matrix(lu, pcsv, win);
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("After matrix PCS' XYZ %s Lab %s\n",icmPdv(p->in.chan, pcsv), icmPLab(pcsv));
+ DEBUGCND printf("After matrix PCS' XYZ %s Lab %s\n",icmPdv(p->in.chan, pcsv), icmPLab(pcsv));
#endif
if (p->in.bt1886) {
- bt1886_apply(&p->in.bt, plu, pcsv, pcsv);
+ bt1886_wp_adjust(&p->in.bt, pcsv, pcsv);
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("After bt1886 PCS' XYZ %s Lab %s\n",icmPdv(p->in.chan, pcsv), icmPLab(pcsv));
+ DEBUGCND printf("After bt1886 PCS' XYZ %s Lab %s\n",icmPdv(p->in.chan, pcsv), icmPLab(pcsv));
#endif
- }
+ }
+
rv |= lu->fwd_abs(lu, pcsv, pcsv);
+
break;
}
case icmLutType: {
@@ -919,10 +1154,7 @@ void devip_devop(void *cntx, double *out, double *in) {
//printf("~1 copied win to locus\n");
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("Got possible K %s of %f %f %f %f\n",p->out.locus ? "locus" : "value", locus[0],locus[1],locus[2],locus[3]);
+ DEBUGCND printf("Got possible K %s of %f %f %f %f\n",p->out.locus ? "locus" : "value", locus[0],locus[1],locus[2],locus[3]);
#endif
}
rv |= lu->output(lu, pcsv, pcsv); /* PCS' -> */
@@ -951,14 +1183,11 @@ void devip_devop(void *cntx, double *out, double *in) {
* The order to do this intermediate processing is hard to figure out,
* as is the interaction between such elements. How should the
* abstract profile be properly handled ?
- * what should we do if the wphack is on and Y scaling is on ?
+ * what should we do if the wphack/rgbbkhack is on and Y scaling is on ?
*/
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("PCS before map %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]);
+ DEBUGCND printf("PCS before map %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]);
#endif
if (p->wphack) {
@@ -1023,10 +1252,7 @@ void devip_devop(void *cntx, double *out, double *in) {
//printf("scaled PCS %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]);
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("PCS after Y scale %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]);
+ DEBUGCND printf("PCS after Y scale %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]);
#endif
}
@@ -1052,10 +1278,7 @@ void devip_devop(void *cntx, double *out, double *in) {
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("PCS after map0 %f %f %f map1 %f %f %f\n", map0[0], map0[1], map0[2], map1[0], map1[1], map1[2]);
+ DEBUGCND printf("PCS after map0 %f %f %f map1 %f %f %f\n", map0[0], map0[1], map0[2], map1[0], map1[1], map1[2]);
#endif
/* Normal gamut mapping */
@@ -1067,10 +1290,7 @@ void devip_devop(void *cntx, double *out, double *in) {
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("PCS after map %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]);
+ DEBUGCND printf("PCS after map %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]);
#endif
} else {
pcsvm[0] = pcsv[0];
@@ -1096,10 +1316,7 @@ void devip_devop(void *cntx, double *out, double *in) {
/* mapping properly. */
p->abs_luo->lookup(p->abs_luo, pcsvm, pcsvm);
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("PCS after abstract %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]);
+ DEBUGCND printf("PCS after abstract %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]);
#endif
}
@@ -1131,17 +1348,15 @@ void devip_devop(void *cntx, double *out, double *in) {
locus[i] = tdevv[i];
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("Got possible K %s of %f %f %f %f\n",p->out.locus ? "locus" : "value", locus[0],locus[1],locus[2],locus[3]);
+ DEBUGCND printf("Got possible K %s of %f %f %f %f\n",p->out.locus ? "locus" : "value", locus[0],locus[1],locus[2],locus[3]);
#endif
}
/* Do PCS -> DevOut' */
if (p->nhack == 3 /* All to K only */
|| ntrig /* Neutral or K only to K only hack has triggered */
- || cmytrig) { /* 100% CMY rough hack has triggered */
+ || cmytrig /* 100% CMY rough hack has triggered */
+ || rgbbktrig) { /* RGB black inpu thas triggered */
if (p->nhack == 3 || ntrig) { /* Neutral to K only hack has triggered */
co pp;
@@ -1183,8 +1398,11 @@ void devip_devop(void *cntx, double *out, double *in) {
printf("CMY hack mapped %s to %s\n",icmPdv(p->in.chan, win), icmPdv(p->out.chan, out));
fflush(stdout);
}
+ } else if (rgbbktrig) {
+ out[0] = out[1] = out[2] = 0.0;
}
- } else { /* Neutral to K hack has NOT triggered */
+ } else { /* Various hacks haven't triggered */
+
switch(p->out.alg) {
case icmMonoBwdType: {
icxLuMono *lu = (icxLuMono *)p->out.luo; /* Safe to coerce */
@@ -1229,10 +1447,7 @@ void devip_devop(void *cntx, double *out, double *in) {
#endif
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("Calling inv_clut with K aux targets %f %f %f %f and pcsvm %f %f %f %f\n",
+ DEBUGCND printf("Calling inv_clut with K aux targets %f %f %f %f and pcsvm %f %f %f %f\n",
locus[0],locus[1],locus[2],locus[3],pcsvm[0],pcsvm[1],pcsvm[2],pcsvm[3]);
#endif
@@ -1243,10 +1458,7 @@ void devip_devop(void *cntx, double *out, double *in) {
rv |= lu->inv_clut(lu, out, pcsvm);
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("Got result %f %f %f %f\n", out[0],out[1],out[2],out[3]);
+ DEBUGCND printf("Got result %f %f %f %f\n", out[0],out[1],out[2],out[3]);
#endif
@@ -1266,31 +1478,22 @@ void devip_devop(void *cntx, double *out, double *in) {
if (p->cal != NULL && p->addcal == 1 && p->out.nocurve) {
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevOut' before cal curve %s\n\n",icmPdv(p->out.chan, out));
+ DEBUGCND printf("DevOut' before cal curve %s\n\n",icmPdv(p->out.chan, out));
#endif
p->cal->interp(p->cal, out, out);
}
if (p->out.lcurve) { /* Apply Y to L* */
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevOut' before y2l_curve %s\n\n",icmPdv(p->out.chan, out));
+ DEBUGCND printf("DevOut' before y2l_curve %s\n\n",icmPdv(p->out.chan, out));
#endif
y2l_curve(out, out, p->out.lcurve == 2);
}
- /* Video encoding encode */
- if (p->out.tvenc) {
+ /* Video encode */
+ if (p->out.nocurve && p->out.tvenc) {
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevOut' before TVenc %s\n\n",icmPdv(p->out.chan, out));
+ DEBUGCND printf("DevOut' before TVenc %s\n",icmPdv(p->out.chan, out));
#endif
for (i = 0; i < p->out.chan; i++) {
if (out[i] < 0.0)
@@ -1300,63 +1503,90 @@ void devip_devop(void *cntx, double *out, double *in) {
}
if (p->out.tvenc == 1) { /* Video 16-235 range */
icmRGB_2_VidRGB(out, out);
- } else if (p->out.tvenc == 2) { /* Rec601 YCbCr */
+ } else if (p->out.tvenc == 3) { /* Rec601 YCbCr */
icmRec601_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
- } else if (p->out.tvenc == 3) { /* Rec709 1150/60/2:1 YCbCr */
+ } else if (p->out.tvenc == 4) { /* Rec709 1150/60/2:1 YCbCr */
icmRec709_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
- } else if (p->out.tvenc == 4) { /* Rec709 1250/50/2:1 YCbCr */
+ } else if (p->out.tvenc == 5) { /* Rec709 1250/50/2:1 YCbCr */
icmRec709_50_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
- } else if (p->out.tvenc == 5) { /* Rec2020 Non-constant Luminance YCbCr encoding */
+ } else if (p->out.tvenc == 6) { /* Rec2020 Non-constant Luminance YCbCr encoding */
icmRec2020_NCL_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
- } else if (p->out.tvenc == 6) { /* Rec2020 Constant Luminance YCbCr encoding */
+ } else if (p->out.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
icmRec2020_CL_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
}
#ifdef NEVER
- else if (p->out.tvenc == 7) { /* SD xvYCC with Rec601 YCbCr encoding */
+ else if (p->out.tvenc == 8) { /* SD xvYCC with Rec601 YCbCr encoding */
icmRec601_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
- } else if (p->out.tvenc == 8) { /* HD xvYCC with Rec709 YCbCr encoding */
+ } else if (p->out.tvenc == 9) { /* HD xvYCC with Rec709 YCbCr encoding */
icmRec709_RGBd_2_YPbPr(out, out);
icmRecXXX_YPbPr_2_YCbCr(out, out);
}
#endif /* NEVER */
+
+#ifdef DEBUG
+ DEBUGCND printf("DevOut' after TVenc %s\n",icmPdv(p->out.chan, out));
+#endif
}
- /* Create linear interpolation from clip to full range */
- if (clip && p->out.tvenc) {
- for (i = 0; i < 3; i++) {
- if (clip & (1 << i)) {
-#ifdef LINTERP_OR
- /* Linear interpolate overrange to full */
-//printf("~1 clip[%d] = out %f + (uc %f - cin %f)/(full %f - cin %f) * (full %f - out %f) = ",
-//i, out[i], uc[i], cin[i], full[i], cin[i], full[i], out[i]);
- out[i] = out[i] + (uc[i] - cin[i])/(full[i] - cin[i]) * (full[i] - out[i]);
-//printf("%f\n",out[i]);
-#else
- double ifull = 1.0 - full[i]; /* Opposite limit to full */
+ if (clip && p->out.nocurve && p->out.tvenc) {
- /* Do simple extrapolation (Not perfect though) */
- out[i] = ifull + (out[i] - ifull) * (uc[i] - ifull)/(cin[i] - ifull);
+ /* For RGB encoding, unscale +ve clip to preserve hue */
+ if (p->out.tvenc == 1) { /* RGB Video 16-235 range */
- if (out[i] < 0.0 || out[i] > 1.0 /* clip */
- || fabs(uc[i] - full[i]) < 1e-6) /* or input is at sync level */
- out[i] = full[i];
-#endif
+ if (!p->in.tvclip && scale > 1.0) { /* We got +ve clipping */
+
+ /* Re-scale all non-black values */
+ for (i = 0; i < 3; i++) {
+ if (out[i] > (16.0/255.0))
+ out[i] = (out[i] - 16.0/255.0) * scale + 16.0/255.0;
+ }
+ }
+
+ /* Deal with -ve clipping and sync */
+ for (i = 0; i < 3; i++) {
+ if (clip & (1 << i)) {
+
+ if (full[i] == 0.0) { /* Only extrapolate in black direction */
+ double ifull = 1.0 - full[i]; /* Opposite limit to full */
+
+ /* Do simple extrapolation (Not perfect though) */
+ out[i] = ifull + (out[i] - ifull) * (uci[i] - ifull)/(cin[i] - ifull);
+ }
+
+ /* Clip or pass sync through */
+ if (out[i] < 0.0 || out[i] > 1.0 /* clip */
+ || fabs(uci[i] - full[i]) < 1e-6) /* or input is at sync level */
+ out[i] = full[i];
+ }
+ }
+
+ /* For YCrCb, do simple linear extrapolation of out of range input. */
+ /* (Note we should really change this to preserve hue instead !) */
+ } else {
+ for (i = 0; i < 3; i++) {
+ if (clip & (1 << i)) {
+ double ifull = 1.0 - full[i]; /* Opposite limit to full */
+
+ /* Do simple extrapolation (Not perfect though) */
+ out[i] = ifull + (out[i] - ifull) * (uci[i] - ifull)/(cin[i] - ifull);
+
+ if (out[i] < 0.0 || out[i] > 1.0 /* clip */
+ || fabs(uci[i] - full[i]) < 1e-6) /* or input is at sync level */
+ out[i] = full[i];
+ }
}
}
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevIn'->DevOut' ret %s\n\n",icmPdv(p->out.chan, out));
+ DEBUGCND printf("DevIn'->DevOut' ret %s\n\n",icmPdv(p->out.chan, out));
#endif
@@ -1376,35 +1606,28 @@ void devip_devop(void *cntx, double *out, double *in) {
void devop_devo(void *cntx, double *out, double *in) {
int rv = 0;
clink *p = (clink *)cntx;
- int i, clip = 0;
+ int i, clip = 0; /* Not preserving video sync when doing video decode in input lut */
double uc[3]; /* Unclipped values (Video) */
double cin[3]; /* clipped input value (Video) */
double full[3]; /* Full value in clip direction (Video) */
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevOut'->DevOut got %s\n",icmPdv(p->out.chan, in));
+ DEBUGCND printf("DevOut'->DevOut got %s\n",icmPdv(p->out.chan, in));
#endif
for (i = 0; i < p->out.chan; i++)
out[i] = in[i];
- if (p->out.lcurve) /* Apply L* to Y */
+ if (p->out.lcurve) { /* Apply L* to Y */
l2y_curve(out, out, p->out.lcurve == 2);
+#ifdef DEBUG
+ DEBUGCND printf("After L*->Y curve %s\n",icmPdv(p->out.chan, out));
+#endif
+ }
- if (p->out.nocurve == 0) { /* Using per channel curves */
-
- /* Video encoding decode */
- if (p->out.tvenc == 1) { /* Video 16-235 range */
- clip = clipVidRGB(full, uc, out);
- icmCpy3(cin, out);
- icmVidRGB_2_RGB(out, out);
- } else if (p->out.tvenc >= 2) { /* YCbCr */
- error("Can't use output curves with YCbCr output encoding");
- }
+ if (!p->out.nocurve) { /* Using per channel output curves */
+ /* Apply output curve */
switch(p->out.alg) {
case icmMonoBwdType: {
icxLuMono *lu = (icxLuMono *)p->out.luo; /* Safe to coerce */
@@ -1435,34 +1658,34 @@ void devop_devo(void *cntx, double *out, double *in) {
if (rv >= 2)
error("icc lookup failed: %d, %s",p->in.c->errc,p->in.c->err);
+#ifdef DEBUG
+ DEBUGCND printf("After output curve %s\n",icmPdv(p->out.chan, out));
+#endif
+ /* Apply calibration curve */
if (p->cal != NULL && p->addcal == 1) {
p->cal->interp(p->cal, out, out);
+#ifdef DEBUG
+ DEBUGCND printf("After calibration curve %s\n",icmPdv(p->out.chan, out));
+#endif
}
- /* Video encoding encode */
+ /* Apply Video encoding */
if (p->out.tvenc == 1) { /* Video 16-235 range */
icmRGB_2_VidRGB(out, out);
}
-
- /* Create linear interpolation from clip to full range */
- if (clip && p->out.tvenc) {
- for (i = 0; i < 3; i++) {
- if (clip & (1 << i)) {
- out[i] = out[i] + (uc[i] - cin[i])/(full[i] - cin[i]) * (full[i] - out[i]);
- }
- }
+#ifdef DEBUG
+ if (p->out.tvenc != 0) {
+ DEBUGCND printf("After Video encode %s\n",icmPdv(p->out.chan, out));
}
+#endif
+
}
#ifdef DEBUG
-#ifdef DEBUGC
- DEBUGC
-#endif
- printf("DevOut'->DevOut ret %s\n",icmPdv(p->out.chan, out));
+ DEBUGCND printf("DevOut'->DevOut ret %s\n",icmPdv(p->out.chan, out));
#endif
#ifdef DEBUGC
tt = 0;
#endif
-//printf("DevOut'->DevOut ret %s\n",icmPdv(p->out.chan, out));
}
/* ------------------------------------------- */
@@ -1499,7 +1722,9 @@ static double xyzoptfunc(void *cntx, double *v) {
clink *p = (clink *)cntx;
double swxyz[3], jab[3], dev[MAX_CHAN];
double rv;
- int rc = 0;
+ int j, rc = 0;
+
+//printf("~1 xyzoptfunc %f\n", v[0]);
rv = 2.0 - v[0]; /* Make Y as large as possible */
@@ -1531,18 +1756,21 @@ static double xyzoptfunc(void *cntx, double *v) {
switch(p->out.alg) {
case icmMonoBwdType: {
icxLuMono *lu = (icxLuMono *)p->out.luo; /* Safe to coerce */
+//printf("~1 Mono\n");
rc = lu->bwd_lookup(p->out.luo, dev, jab);
break;
}
case icmMatrixBwdType: {
icxLuMatrix *lu = (icxLuMatrix *)p->out.luo; /* Safe to coerce */
+//printf("~1 Matrix\n");
rc = lu->bwd_lookup(p->out.luo, dev, jab);
break;
}
case icmLutType: {
icxLuLut *lu = (icxLuLut *)p->out.luo; /* Safe to coerce */
+//printf("~1 Lut\n");
if (p->mode < 2) /* Using B2A table */
rc = lu->lookup(p->out.luo, dev, jab);
@@ -1553,9 +1781,16 @@ static double xyzoptfunc(void *cntx, double *v) {
default:
error("Unexpected algorithm type %d in devop of devip_devop()",p->out.alg);
}
-//printf("~1 device = %f %f %f, rc = %d\n", dev[0], dev[1], dev[2], rc);
+//printf("~1 in chan %d\n", p->out.luo->inputChan);
+//printf("~1 device = %s, rc = %d\n", icmPdv(p->out.luo->inputChan, dev), rc);
+ /* Matrix power curves don't clip on device space out of range, */
+ /* so check explicitly as well. */
+ for (j = 0; j < p->out.luo->inputChan; j++) {
+ if (dev[j] < 0.0 || dev[j] > 1.0)
+ rc |= 1;
+ }
if (rc != 0)
- rv += 500.0;
+ rv += 10.0;
//printf("~1 xyzoptfunc rv %f from xyzscale %f\n\n",rv,v[0]);
return rv;
@@ -1564,11 +1799,13 @@ static double xyzoptfunc(void *cntx, double *v) {
/* ------------------------------------------- */
int write_eeColor1DinputLuts(clink *li, char *tdlut_name);
-int write_eeColor3DLut(icc *icc, char *fname);
+int write_eeColor3DLut(icc *icc, clink *li, char *fname);
int write_eeColor1DoutputLuts(clink *li, char *tdlut_name);
int write_MadVR_3DLut(clink *li, icc *icc, char *fname);
+int write_cube_3DLut(clink *li, icc *icc, char *fname);
+
int
main(int argc, char *argv[]) {
int fa, nfa, mfa; /* argument we're looking at */
@@ -1626,8 +1863,9 @@ main(int argc, char *argv[]) {
li.in.nocurve = 0; /* Preserve device linearisation curve */
li.in.lcurve = 0; /* Don't apply a Y to L* curve after device curve */
li.in.tvenc = -1;
- li.in.egamma = 2.2; /* Default effective gamma */
- li.in.tgamma = 2.4; /* Default technical gamma */
+ li.in.outoprop = 0.0; /* Default BT.1886 syle input offset */
+ li.in.egamma = 2.2; /* Default effective gamma value */
+ li.in.tgamma = 2.4; /* Default technical gamma value */
li.out.intent = icmDefaultIntent; /* Default */
li.out.ink.tlimit = -1.0; /* Default no total limit */
li.out.ink.klimit = -1.0; /* Default no black limit */
@@ -1728,8 +1966,19 @@ main(int argc, char *argv[]) {
/* Disable profile per channel curve use in device link output */
else if (argv[fa][1] == 'n') {
- li.in.nocurve = 1;
- li.out.nocurve = 1;
+ if (na != NULL) { /* Found an optional individual disable */
+ fa = nfa;
+ if (na[0] == 'i')
+ li.in.nocurve = 1;
+ else if (na[0] == 'o')
+ li.out.nocurve = 1;
+ else
+ usage("Unexpected argument '%c' to -n flag",na[0]);
+
+ } else {
+ li.in.nocurve = 1;
+ li.out.nocurve = 1;
+ }
}
/* Hack to force input neutrals to K only output */
@@ -1853,6 +2102,12 @@ main(int argc, char *argv[]) {
usage("Couldn't parse hack white point (-w) value '%s'",na);
}
}
+
+ /* RGB->RGB black hack */
+ else if (argv[fa][1] == 'b') {
+ li.rgbbkhack = 1;
+ }
+
/* Input profile Intent or Mapping mode intent */
else if (argv[fa][1] == 'i') {
fa = nfa;
@@ -1959,7 +2214,7 @@ main(int argc, char *argv[]) {
if (sscanf(na+1,":%lf:%lf:%lf",&x,&y,&z) == 3) {
vc->Wxyz[0] = x; vc->Wxyz[1] = y; vc->Wxyz[2] = z;
} else if (sscanf(na+1,":%lf:%lf",&x,&y) == 2) {
- vc->Wxyz[0] = x; vc->Wxyz[1] = y;
+ vc->Wxyz[0] = x; vc->Wxyz[1] = y; vc->Wxyz[2] = -1;
} else
usage("Viewing condition (-%cw) unrecognised white point '%s'",argv[fa][1],na+1);
} else if (na[0] == 'a' || na[0] == 'A') {
@@ -1977,15 +2232,15 @@ main(int argc, char *argv[]) {
} else if (na[0] == 'f' || na[0] == 'F') {
if (na[1] != ':')
usage("Viewing conditions (-cf) missing ':'");
- vc->Yf = atof(na+2);
+ vc->Yf = atof(na+2)/100.0;
} else if (na[0] == 'g' || na[0] == 'G') {
double x, y, z;
if (sscanf(na+1,":%lf:%lf:%lf",&x,&y,&z) == 3) {
vc->Gxyz[0] = x; vc->Gxyz[1] = y; vc->Gxyz[2] = z;
} else if (sscanf(na+1,":%lf:%lf",&x,&y) == 2) {
- vc->Gxyz[0] = x; vc->Gxyz[1] = y;
+ vc->Gxyz[0] = x; vc->Gxyz[1] = y; vc->Gxyz[2] = -1;
} else if (sscanf(na+1,":%lf",&x) == 1) {
- vc->Yf = x/100.0;
+ vc->Yg = x/100.0;
} else
usage("Viewing condition (-%cf) unrecognised flare '%s'",argv[fa][1],na+1);
} else
@@ -2141,6 +2396,9 @@ main(int argc, char *argv[]) {
case 'm':
li.tdlut = 2;
break;
+ case 'c':
+ li.tdlut = 3;
+ break;
default:
usage("3DLut format (-3) argument '%s' not recognised",na);
}
@@ -2148,24 +2406,51 @@ main(int argc, char *argv[]) {
/* Intent modifier */
else if (argv[fa][1] == 'I') {
- double gamma = 0.0;
fa = nfa;
if (na == NULL) usage("Intent modifier flag (-I) needs an argument");
switch (na[0]) {
case 'b':
- li.in.bt1886 = 1;
- if (sscanf(na+1,":%lf",&gamma) == 1)
- li.in.egamma = gamma;
- break;
case 'B':
- li.in.bt1886 = 2;
- if (sscanf(na+1,":%lf",&gamma) == 1)
- li.in.tgamma = gamma;
+ case 'g':
+ case 'G': {
+ double outoprop = -1.0, gamma = -1.0;
+
+ if (na[0] == 'b' || na[0] == 'B')
+ li.in.outoprop = 0.0;
+ else if (na[0] == 'g' || na[0] == 'G')
+ li.in.outoprop = 1.0;
+
+ if (sscanf(na+1,":%lf:%lf",&outoprop, &gamma) != 2) {
+ outoprop = -1.0;
+ if (sscanf(na+1,":%lf",&gamma) != 1)
+ gamma = -1.0;
+ }
+
+ if (outoprop != -1.0) {
+ if (outoprop < 0.0 || outoprop > 1.0)
+ usage("Intent modifier -I%c expects output proportion in range 0.0 and 1.0",na[0]);
+ li.in.outoprop = outoprop;
+ }
+
+ if (gamma != -1.0 && (gamma <= 0.0 || gamma > 4.0))
+ usage("Intent modifier -I%c expects gamma value between 0.0 and 4.0",na[0]);
+ if (na[0] == 'b' || na[0] == 'g') {
+ li.in.bt1886 = 1;
+ if (gamma != -1.0) {
+ li.in.egamma = gamma;
+ }
+ } else if (na[0] == 'B' || na[0] == 'G') {
+ li.in.bt1886 = 2;
+ if (gamma != -1.0) {
+ li.in.tgamma = gamma;
+ }
+ }
+
break;
+ }
default:
- if (gamma == 0.0)
- usage("Intent modifier (-I) argument '%s' not recognised",na);
+ usage("Intent modifier (-I) argument '%s' not recognised",na);
}
}
@@ -2181,29 +2466,35 @@ main(int argc, char *argv[]) {
case 't': /* TV 16 .. 235 */
enc = 1;
break;
+ case 'T': /* TV 16 .. 235 Clip */
+ if (argv[fa][1] == 'E')
+ usage("Video encoding (-E) argument T not valid");
+ enc = 1;
+ li.in.tvclip = 1;
+ break;
case '6': /* Rec601 YCbCr */
- enc = 2;
+ enc = 3;
break;
case '7': /* Rec709 1150/60/2:1 YCbCr (HD) */
- enc = 3;
+ enc = 4;
break;
case '5': /* Rec709 1250/50/2:1 YCbCr (HD) */
- enc = 4;
+ enc = 5;
break;
case '2': /* Rec2020 Non-constant Luminance YCbCr (UHD) */
- enc = 5;
+ enc = 6;
break;
case 'C': /* Rec2020 Constant Luminance YCbCr (UHD) */
- enc = 6;
+ enc = 7;
break;
case 'x': /* xvYCC Rec601 YCbCr encoding (SD) */
- enc = 7;
+ enc = 8;
break;
case 'X': /* xvYCC Rec709 YCbCr encoding (HD) */
- enc = 8;
+ enc = 9;
break;
default:
- usage("Video encoding (-E) argument not recognised");
+ usage("Video encoding (-%c) argument '%c' not recognised",argv[fa][1],na[0]);
}
if (argv[fa][1] == 'e')
li.in.tvenc = enc;
@@ -2222,6 +2513,18 @@ main(int argc, char *argv[]) {
break;
}
+#ifdef NEVER
+ if (li.in.bt1886) {
+ printf("~1 bt1886 flag = %d\n",li.in.bt1886);
+
+ printf("~1 outoprop = %f\n",li.in.outoprop);
+ if (li.in.bt1886 == 2)
+ printf("~1 tgamma = %f\n",li.in.tgamma);
+ else
+ printf("~1 egamma = %f\n",li.in.egamma);
+ }
+#endif
+
if (fa >= argc || argv[fa][0] == '-') usage("Missing input profile");
strncpy(in_name,argv[fa++],MAXNAMEL); in_name[MAXNAMEL] = '\000';
@@ -2252,6 +2555,15 @@ main(int argc, char *argv[]) {
if (li.clutres == 0)
li.clutres = 65; /* This is good for video encoding levels */
+
+ } else if (li.tdlut == 3) { /* .cube */
+ strncpy(tdlut_name,link_name,MAXNAMEL-6); tdlut_name[MAXNAMEL-6] = '\000';
+ if ((xl = strrchr(tdlut_name, '.')) == NULL) /* Figure where extention is */
+ xl = tdlut_name + strlen(tdlut_name);
+ strcpy(xl,".cube");
+
+ if (li.clutres == 0)
+ li.clutres = 65; /* This is good for video encoding levels */
}
} else {
if (li.clutres > 255) usage("Resolution flag (-r) argument out of range (%d)",li.clutres);
@@ -2263,7 +2575,7 @@ main(int argc, char *argv[]) {
li.out.tvenc = 0;
/* Need to allow spec. of gamut/matrix for xvYCC & bt.1886 */
- if (li.out.tvenc == 7 || li.out.tvenc == 8) { /* xvYCC */
+ if (li.out.tvenc == 8 || li.out.tvenc == 9) { /* xvYCC */
usage("xvYCC output encoding is not supported");
}
@@ -2291,7 +2603,7 @@ main(int argc, char *argv[]) {
if (li.in.bt1886) {
if (li.mode == 0) { /* Simple mode */
if (li.in.intent == icmDefaultIntent) {
- warning("Setting BT.1886 input intent to Relative Colorimetric");
+ warning("Setting BT.1886/Abs power input intent to Relative Colorimetric");
li.in.intent = icRelativeColorimetric;
} else if (li.in.intent != icRelativeColorimetric
&& li.in.intent != icAbsoluteColorimetric) {
@@ -2299,7 +2611,7 @@ main(int argc, char *argv[]) {
}
if (li.out.intent == icmDefaultIntent) {
- warning("Setting BT.1886 output intent to Relative Colorimetric");
+ warning("Setting BT.1886/Abs power output intent to Relative Colorimetric");
li.out.intent = icRelativeColorimetric;
} else if (li.out.intent != icRelativeColorimetric
&& li.out.intent != icAbsoluteColorimetric) {
@@ -2307,7 +2619,7 @@ main(int argc, char *argv[]) {
}
} else {
if (!intentset) {
- warning("Setting BT.1886 intent to Relative Colorimetric");
+ warning("Setting BT.1886/Abs power intent to Relative Colorimetric");
if (xicc_enum_gmapintent(&li.gmi, icxNoGMIntent, "r") == -999)
error("Internal - intent 'r' isn't recognised");
}
@@ -2327,6 +2639,7 @@ main(int argc, char *argv[]) {
/* eeColor format. Currently we assume no input or output curves, */
/* even though it's technically possible to use them */
if (li.tdlut == 1) {
+ int inc;
if (li.in.nocurve == 0) {
warning("Disabling input curves for eeColor 3DLut creation");
@@ -2353,6 +2666,19 @@ main(int argc, char *argv[]) {
li.out.nocurve = 1;
}
}
+
+ /* .cube format. It doesn't support in and out per channel curves */
+ else if (li.tdlut == 3) {
+
+ if (li.in.nocurve == 0) {
+ warning("Disabling input curves for .cube 3DLut creation");
+ li.in.nocurve = 1;
+ }
+ if (li.out.nocurve == 0) {
+ warning("Disabling output curves for .cube 3DLut creation");
+ li.out.nocurve = 1;
+ }
+ }
}
/* - - - - - - - - - - - - - - - - - - - */
@@ -3172,6 +3498,17 @@ main(int argc, char *argv[]) {
error("Output profile must be RGB to output MadVR 3DLut");
}
+ /* .cube format. */
+ else if (li.tdlut == 3) {
+
+ if (li.in.csp != icSigRgbData)
+ error("Input profile must be RGB to output .cube 3DLut");
+
+ if (li.out.csp != icSigRgbData)
+ error("Output profile must be RGB to output .cube 3DLut");
+ }
+
+
if (li.in.tvenc) {
if (li.in.csp != icSigRgbData)
error("Input profile must be RGB to use video encoding option");
@@ -3182,95 +3519,6 @@ main(int argc, char *argv[]) {
}
}
- /* Do sanity check and setup for BT.1886 gamma mapping */
- if (li.in.bt1886) {
- bt1886_setnop(&li.in.bt);
- }
- if (li.in.bt1886 == 1 || li.in.bt1886 == 2) { /* If doing BT.1886 black point mapping */
- icxLuBase *oluo; /* Output fwd lookup */
- icxLuMatrix *lu; /* Input profile lookup */
- icmLuMatrix *plu; /* Input profile lookup */
- double bp[3], rgb[3];
-
- /* Check input profile is an RGB matrix profile */
- if (li.in.alg != icmMatrixFwdType
- || li.in.csp != icSigRgbData)
- error("BT.1886 mode only works with an RGB matrix input profile");
-
- lu = (icxLuMatrix *)li.in.luo; /* Safe to coerce - we have checked it's matrix. */
- plu = (icmLuMatrix *)lu->plu;
-
- if ((oluo = li.out.x->get_luobj(li.out.x, ICX_CLIP_NEAREST, icmFwd, icRelativeColorimetric,
- icSigXYZData, icmLuOrdNorm, &li.out.vc, &li.out.ink)) == NULL) {
- error("get xlookup object failed: %d, %s",li.out.x->errc,li.out.x->err);
- }
- /* We're assuming that the input space has a perfect black point... */
-
- /* Lookup the ouput black point in XYZ PCS.*/
- bp[0] = bp[1] = bp[2] = 0.0;
- oluo->lookup(oluo, bp, bp);
-
- if (li.in.bt1886 == 1) { /* Using effective gamma */
- li.in.tgamma = xicc_tech_gamma(li.in.egamma, bp[1]);
- if (li.verb)
- printf("Technical gamma %f used to achieve effective gamma %f\n",li.in.tgamma, li.in.egamma);
- } else {
- if (li.verb)
- printf("Using technical gamma %f\n",li.in.tgamma);
- }
-
- bt1886_setup(&li.in.bt, bp, li.in.tgamma);
-
- if (li.verb) {
- printf("bt1886 target out black rel XYZ = %f %f %f, Lab %f %f %f\n",
- bp[0],bp[1],bp[2], li.in.bt.outL, li.in.bt.tab[0], li.in.bt.tab[1]);
- printf("bt1886 Y input offset = %f\n", li.in.bt.ingo);
- printf("bt1886 Y output scale = %f\n", li.in.bt.outsc);
- }
-
- /* Check black point now produced by input profile with bt.1886 adjustment */
- rgb[0] = rgb[1] = rgb[2] = 0.0;
- lu->fwd_curve(lu, rgb, rgb);
- lu->fwd_matrix(lu, rgb, rgb);
- bt1886_apply(&li.in.bt, plu, rgb, rgb);
- if (li.verb) printf("bt1886 check input black point rel. XYZ %f %f %f\n", rgb[0],rgb[1],rgb[2]);
- /* Convert XYZ black point to gamut mapping space */
- lu->fwd_abs(lu, li.in.bt_bk, bp);
- if (li.verb) printf("bt1886 check input black point PCS %f %f %f\n", li.in.bt_bk[0],li.in.bt_bk[1],li.in.bt_bk[2]);
-
- oluo->del(oluo);
-
- if (li.verb) {
- int no = 21;
-
- /* Overral rendering curve from video in to output target */
- printf("BT.1886 overall rendering\n");
- for (i = 0; i < no; i++) {
- double v = i/(no-1.0), vv;
- double vi[3], vo[3], Lab[3];
- double loglog = 0.0;
-
- if (v <= 0.081)
- vv = v/4.5;
- else
- vv = pow((0.099 + v)/1.099, 1.0/0.45);
-
- vi[0] = vv * 0.9642; /* To D50 XYZ */
- vi[1] = vv * 1.0000;
- vi[2] = vv * 0.8249;
-
- bt1886_apply(&li.in.bt, plu, vo, vi); /* BT.1886 mapping */
-
- icmXYZ2Lab(&icmD50, Lab, vo);
-
- if (v > 1e-9 && vo[1] > 1e-9 && fabs(v - 1.0) > 1e-9)
- loglog = log(vo[1])/log(v);
-
- printf(" In %5.1f%% -> XYZ in %f -> bt.1886 %f, log/log %.3f, Lab %f %f %f \n",v * 100.0,vi[1],vo[1], loglog, Lab[0], Lab[1], Lab[2]);
- }
- }
- }
-
/* - - - - - - - - - - - - - - - - - - - */
/* Setup the gamut mapping */
// ~~~~ need to account for possible abstract profile after source !!!!
@@ -3323,14 +3571,6 @@ main(int argc, char *argv[]) {
if ((csgam = li.in.luo->get_gamut(li.in.luo, sgres)) == NULL)
error ("%d, %s",li.in.x->errc, li.in.x->err);
- /* If BT.1886 has modified the effective input space black point, */
- /* change the black point in the source gamut to match. (Note that */
- /* this doesn't fix the source gamut surface itself, but should */
- /* make sure that the gamut mapping black point mapping works properly.) */
- if (li.in.bt1886 == 1) {
- csgam->set_cs_bp_kp_ovrd(csgam, li.in.bt_bk, li.in.bt_bk);
- }
-
/* Grab a given source image gamut. */
if (sgam_name[0] != '\000') { /* Optional source gamut - ie. from an images */
@@ -3367,7 +3607,7 @@ main(int argc, char *argv[]) {
li.map = new_gammap(li.verb, csgam, igam, ogam, &li.gmi,
li.src_kbp, li.dst_kbp, li.cmyhack, li.rel_oride,
- mapres, NULL, NULL, li.gamdiag ? "gammap.wrl" : NULL
+ mapres, NULL, NULL, li.gamdiag ? "gammap" : NULL
);
if (li.map == NULL)
error ("Failed to make gamut map transform");
@@ -3378,7 +3618,7 @@ main(int argc, char *argv[]) {
li.Kmap = new_gammap(li.verb, csgam, igam, ogam, &li.gmi,
1, 1, li.cmyhack, li.rel_oride,
- mapres, NULL, NULL, li.gamdiag ? "gammap.wrl" : NULL
+ mapres, NULL, NULL, li.gamdiag ? "gammap" : NULL
);
if (li.Kmap == NULL)
error ("Failed to make K only gamut map transform");
@@ -3421,6 +3661,148 @@ main(int argc, char *argv[]) {
}
}
+ /* Check rgbbkhack is being used in correct circumstances */
+ if (li.rgbbkhack) {
+ if (li.in.csp != icSigRgbData
+ || li.out.csp != icSigRgbData)
+ error("Black hack (-b) only valid for RGB input & output");
+ }
+
+ /* Do sanity check and setup for BT.1886 gamma mapping */
+ if (li.in.bt1886) {
+ bt1886_setnop(&li.in.bt);
+ }
+ if (li.in.bt1886) { /* If doing BT.1886/output offset power black point mapping */
+ int fl = 0; /* Flags */
+ icxLuMatrix *lu; /* Input profile lookup */
+ icmLuMatrix *plu; /* Input profile lookup */
+ icxLuBase *oluo; /* Output fwd lookup */
+ double bp[3], rgb[3];
+
+ /* Check input profile is an RGB matrix profile */
+ if (li.in.alg != icmMatrixFwdType
+ || li.in.csp != icSigRgbData)
+ error("BT.1886/Abs power mode only works with an RGB matrix input profile");
+
+ /* Get ready to do fwd lookup on input profile */
+ lu = (icxLuMatrix *)li.in.luo; /* Safe to coerce - we have checked it's matrix. */
+ plu = (icmLuMatrix *)lu->plu;
+
+ /* Get ready to do fwd lookup on output profile */
+ /* (li.out.lu may or may not be what we want, so temporarily make another one */
+
+ fl = ICX_CLIP_NEAREST;
+
+#ifdef USE_MERGE_CLUT_OPT
+ fl |= ICX_MERGE_CLUT;
+#endif
+#ifdef USE_CAM_CLIP_OPT
+ fl |= ICX_CAM_CLIP;
+#endif
+ if ((oluo = li.out.x->get_luobj(li.out.x, fl, icmFwd,
+ li.out.intent, li.pcsor, icmLuOrdNorm, &li.out.vc,
+ &li.out.ink)) == NULL) {
+ error("get xlookup object failed: %d, %s",li.out.x->errc,li.out.x->err);
+ }
+
+ /* We're assuming that the input space has a perfect black point... */
+ /* and we're assuming that RGB=0 gives us outpu black. Hmm... */
+
+ /* Lookup the ouput black point in our gamut mapping PCS.*/
+ bp[0] = bp[1] = bp[2] = 0.0;
+ oluo->lookup(oluo, bp, bp);
+
+ if (li.verb)
+ printf("Output black PCS = %f %f %f\n",bp[0],bp[1],bp[2]);
+
+ /* Compute pre-gamut mapping black point value */
+ if (li.mode > 0 && li.gmi.usemap) {
+ li.map->invdomap1(li.map, bp, bp);
+ if (li.verb)
+ printf("Output black PCS pre GMAP = %f %f %f\n",bp[0],bp[1],bp[2]);
+ }
+
+ /* Undo luminence scaling */
+ if (li.xyzscale < 1.0) {
+ double xyz[3];
+
+ /* Convert our PCS to XYZ */
+ if (li.pcsor == icxSigJabData) {
+ /* We're being bad in delving inside the xluo, but we'll fix it latter */
+ oluo->cam->cam_to_XYZ(oluo->cam, xyz, bp);
+ } else
+ error("Internal :- not setup to handle Y scaling and non-Jab PCS");
+
+ /* Unscale it */
+ xyz[0] /= li.xyzscale;
+ xyz[1] /= li.xyzscale;
+ xyz[2] /= li.xyzscale;
+
+ /* Convert back to PCS */
+ if (li.pcsor == icxSigJabData) {
+ /* We're being bad in delving inside the xluo, but we'll fix it latter */
+ oluo->cam->XYZ_to_cam(oluo->cam, bp, xyz);
+ } else
+ error("Internal :- not setup to handle Y scaling and non-Jab PCS");
+
+ if (li.verb)
+ printf("Output black PCS pre lumscale = %f %f %f\n",bp[0],bp[1],bp[2]);
+ }
+
+ /* PCS to matrix relative colorimetric XYZ value */
+ lu->bwd_abs(lu, bp, bp);
+
+ bt1886_setup(&li.in.bt, &plu->pcswht, bp, li.in.outoprop,
+ li.in.bt1886 == 1 ? li.in.egamma : li.in.tgamma, li.in.bt1886 == 1 ? 1 : 0);
+
+ if (li.verb) {
+ printf("Gamma curve target out black rel XYZ = %f %f %f, Lab %f %f %f\n",
+ bp[0],bp[1],bp[2], li.in.bt.outL, li.in.bt.tab[1], li.in.bt.tab[2]);
+ printf("Proportion of black output offset = %f%s\n", li.in.outoprop,
+ li.in.outoprop == 0.0 ? " (BT.1886)" : "");
+ printf("Gamma Y input offset = %f\n", li.in.bt.ingo);
+ if (li.in.bt1886 == 1) /* Using effective gamma */
+ printf("Gamma Y power = %f (effective = %f)\n", li.in.bt.gamma,li.in.egamma);
+ else
+ printf("Gamma Y power = %f\n", li.in.bt.gamma);
+ printf("Gamma Y output scale = %f\n", li.in.bt.outsc);
+ printf("Gamma Y output offset = %f\n", li.in.bt.outo);
+ }
+
+ /* Check black point now produced by input profile with bt.1886/Abs power adjustment */
+ rgb[0] = rgb[1] = rgb[2] = 0.0;
+ bt1886_fwd_curve(&li.in.bt, rgb, rgb);
+ lu->fwd_matrix(lu, rgb, rgb);
+ bt1886_wp_adjust(&li.in.bt, rgb, rgb);
+ if (li.verb) printf("bt1886 check input black point rel. XYZ %f %f %f\n", rgb[0],rgb[1],rgb[2]);
+ /* We're done with our output profile lookup */
+ oluo->del(oluo);
+
+ if (li.verb) {
+ int no = 21;
+
+ /* Overral rendering curve from video in to output target */
+ printf("BT.1886 overall rendering\n");
+ for (i = 0; i < no; i++) {
+ double v = i/(no-1.0), vv;
+ double vi[3], vo[3], Lab[3];
+ double loglog = 0.0;
+
+ vi[0] = vi[1] = vi[2] = v;
+
+ bt1886_fwd_curve(&li.in.bt, vo, vi);
+ lu->fwd_matrix(lu, vo, vo);
+ bt1886_wp_adjust(&li.in.bt, vo, vo);
+ icmXYZ2Lab(&plu->pcswht, Lab, vo);
+
+ if (v > 1e-9 && vo[1] > 1e-9 && fabs(v - 1.0) > 1e-9)
+ loglog = log(vo[1])/log(v);
+
+ printf(" In %5.1f%% -> XYZ in %f -> bt.1886 %f, log/log %.3f, Lab %f %f %f \n",v * 100.0,vi[1],vo[1], loglog, Lab[0], Lab[1], Lab[2]);
+ }
+ }
+ }
+
/* Create the link profile */
if (verify == 0) {
icmFile *wr_fp;
@@ -3444,12 +3826,12 @@ main(int argc, char *argv[]) {
/* Values that must be set before writing */
wh->deviceClass = icSigLinkClass; /* We are creating a link ! */
- if (li.in.tvenc >= 2) {
+ if (li.in.tvenc >= 3) {
wh->colorSpace = icSigYCbCrData; /* Use YCbCr encoding */
} else {
wh->colorSpace = li.in.h->colorSpace; /* Input profile device space */
}
- if (li.out.tvenc >= 2) {
+ if (li.out.tvenc >= 3) {
wh->pcs = icSigYCbCrData; /* Use YCbCr encoding */
} else {
wh->pcs = li.out.h->colorSpace; /* Output profile device space */
@@ -3880,7 +4262,7 @@ main(int argc, char *argv[]) {
outputEnt = out_curve_res;
/* Sanity checking */
- if (li.in.tvenc >= 2) { /* YCbCr encoded input */
+ if (li.in.tvenc >= 3) { /* YCbCr encoded input */
if ((clutPoints & 1) == 0)
warning("Making grid resolution is even - this is not ideal for YCbCr input");
}
@@ -3897,6 +4279,12 @@ main(int argc, char *argv[]) {
warning("MadVR 3DLut will work best with grid resolution of 65 (got %d)",clutPoints);
inputEnt = 1024; /* Not used */
outputEnt = 1024; /* Not used */
+
+ } else if (li.tdlut == 3) {
+ if (clutPoints != 65 && clutPoints != 129 && clutPoints != 256)
+ warning(".cube 3DLut will work best with grid resolution of 65 (got %d)",clutPoints);
+ inputEnt = 1024; /* Not used */
+ outputEnt = 1024; /* Not used */
}
/* Limits are grid indexes that should not be adjusted by SET_APXLS */
@@ -3905,18 +4293,31 @@ main(int argc, char *argv[]) {
apxls_min = tapxls_min;
apxls_max = tapxls_max;
for (i = 0; i < li.in.chan; i++) {
- apxls_min[i] = (int)(16.0/255.0 * (clutPoints-1.0) + 0.9);
- apxls_max[i] = (int)(235.0/255.0 * (clutPoints-1.0) + 0.1);
+ if (clutPoints <= 65) {
+ apxls_min[i] = (int)(4.0/64.0 * (clutPoints-1.0) + 0.9);
+ apxls_max[i] = (int)(58.0/64.0 * (clutPoints-1.0) + 0.1);
+ } else {
+ apxls_min[i] = (int)(16.0/255.0 * (clutPoints-1.0) + 0.9);
+ apxls_max[i] = (int)(235.0/255.0 * (clutPoints-1.0) + 0.1);
+ }
}
- } else if (li.in.tvenc >= 2) { /* YCbCr encoded */
+ } else if (li.in.tvenc >= 3) { /* YCbCr encoded */
apxls_min = tapxls_min;
apxls_max = tapxls_max;
for (i = 0; i < li.in.chan; i++) {
- apxls_min[i] = (int)(16.0/255.0 * (clutPoints-1.0) + 0.9);
- if (i == 0)
- apxls_max[i] = (int)(235.0/255.0 * (clutPoints-1.0) + 0.1);
- else
- apxls_max[i] = (int)(240.0/255.0 * (clutPoints-1.0) + 0.1);
+ if (clutPoints <= 65) {
+ apxls_min[i] = (int)(4.0/64.0 * (clutPoints-1.0) + 0.9);
+ if (i == 0)
+ apxls_max[i] = (int)(58.0/64.0 * (clutPoints-1.0) + 0.1);
+ else
+ apxls_max[i] = (int)(60.0/64.0 * (clutPoints-1.0) + 0.1);
+ } else {
+ apxls_min[i] = (int)(16.0/255.0 * (clutPoints-1.0) + 0.9);
+ if (i == 0)
+ apxls_max[i] = (int)(235.0/255.0 * (clutPoints-1.0) + 0.1);
+ else
+ apxls_max[i] = (int)(240.0/255.0 * (clutPoints-1.0) + 0.1);
+ }
}
}
@@ -3954,13 +4355,19 @@ main(int argc, char *argv[]) {
if (li.verb)
printf("Filling in Lut table\n");
#ifdef DEBUG_ONE
-#define DBGNO 3 /* Up to 10 */
+#define DBGNO 1 /* Up to 10 */
#ifndef NEVER
/* Test a single given rgb/cmyk -> cmyk value */
{
double in[10][MAX_CHAN];
double out[MAX_CHAN];
+
+ in[0][0] = 125.0/255.0;
+ in[0][1] = 61.4/255.0;
+ in[0][2] = 28.42/255.0;
+ in[0][0] = 0.5;
+
// in[0][0] = 0.2;
// in[0][1] = 0.2;
// in[0][2] = 0.8;
@@ -3980,20 +4387,23 @@ main(int argc, char *argv[]) {
// in[0][2] = 16.0/255.0;
// in[0][3] = 0.0;
- in[0][0] = 3.0/64.0;
- in[0][1] = 3.0/64.0;
- in[0][2] = 3.0/64.0;
- in[0][3] = 0.0;
+// in[0][0] = 3.0/64.0;
+// in[0][1] = 3.0/64.0;
+// in[0][2] = 3.0/64.0;
+// in[0][3] = 0.0;
+
+// in[1][0] = 4.0/64.0;
+// in[1][1] = 4.0/64.0;
+// in[1][2] = 4.0/64.0;
+// in[1][3] = 0.0;
- in[1][0] = 4.0/64.0;
- in[1][1] = 4.0/64.0;
- in[1][2] = 4.0/64.0;
- in[1][3] = 0.0;
+// in[2][0] = 5.0/64.0;
+// in[2][1] = 5.0/64.0;
+// in[2][2] = 5.0/64.0;
+// in[2][3] = 0.0;
- in[2][0] = 5.0/64.0;
- in[2][1] = 5.0/64.0;
- in[2][2] = 5.0/64.0;
- in[2][3] = 0.0;
+ if (li.map != NULL)
+ li.map->dbg = 1;
for (i = 0; i < DBGNO; i++) {
printf("Input %f %f %f %*\n",in[i][0], in[i][1], in[i][2], in[i][3]);
@@ -4002,8 +4412,12 @@ main(int argc, char *argv[]) {
devip_devop((void *)&li, out, out);
printf("Out'' %f %f %f %*\n",out[0], out[1], out[2], out[3]);
devop_devo((void *)&li, out, out);
- printf("Out %f %f %f %*\n\n",out[0], out[1], out[2], out[3]);
+ printf("Out %f %f %f %f\n\n",out[0], out[1], out[2], out[3]);
}
+
+ if (li.map != NULL)
+ li.map->dbg = 0;
+
}
#endif /* NEVER */
@@ -4016,6 +4430,7 @@ main(int argc, char *argv[]) {
;
li.total = itotal;
/* Allow for extra lookups due to ICM_CLUT_SET_APXLS */
+#ifdef USE_APXLS
if (apxls_min != NULL && apxls_max != NULL) {
for (itotal = 1, ui = 0; ui < li.in.chan; ui++)
itotal *= (apxls_max[ui] - apxls_min[ui]);
@@ -4024,13 +4439,17 @@ main(int argc, char *argv[]) {
itotal *= (clutPoints-1);
}
li.total += itotal;
+#endif /* USE_APXLS */
li.count = 0;
printf(" 0%%"); fflush(stdout);
}
if (icmSetMultiLutTables(
1,
&wo,
- ICM_CLUT_SET_APXLS, /* Use aproximate least squares */
+#ifdef USE_APXLS
+ ICM_CLUT_SET_APXLS | /* Use aproximate least squares */
+#endif /* USE_APXLS */
+ 0,
&li, /* Context */
li.in.h->colorSpace, /* Input color space */
li.out.h->colorSpace, /* Output color space */
@@ -4060,7 +4479,13 @@ main(int argc, char *argv[]) {
if (li.verb && li.wphack && li.wphacked > 1)
printf("Warning :- white point hack trigger more than once! (%d)\n",li.wphacked);
- /* Special case black point correction when we are usng TV encoding */
+ if (li.verb && li.rgbbkhack && li.bkhacked == 0)
+ printf("Warning :- RGB black point hack didn't trigger!\n");
+ if (li.verb && li.rgbbkhack && li.bkhacked > 1)
+ printf("Warning :- RGB black hack trigger more than once! (%d)\n",li.bkhacked);
+
+#ifdef NEVER /* Don't need this now that we've made the black line up on the grid ? */
+ /* Special case black point correction when we are using TV encoding */
/* and the black probably doesn't lie on a grid point. */
/* This probably only works if we can have "-ve" output values */
/* by virtue of the output being tv encoded too. */
@@ -4077,26 +4502,24 @@ main(int argc, char *argv[]) {
/* Encode input value */
if (li.out.tvenc == 1) { /* Video 16-235 range */
icmRGB_2_VidRGB(ival, ival);
- } else if (li.out.tvenc == 2) { /* Rec601 YCbCr */
+ } else if (li.out.tvenc == 3) { /* Rec601 YCbCr */
icmRec601_RGBd_2_YPbPr(ival, ival);
icmRecXXX_YPbPr_2_YCbCr(ival, ival);
- } else if (li.out.tvenc == 3) { /* Rec709 1150/60/2:1 YCbCr */
+ } else if (li.out.tvenc == 4) { /* Rec709 1150/60/2:1 YCbCr */
icmRec709_RGBd_2_YPbPr(ival, ival);
icmRecXXX_YPbPr_2_YCbCr(ival, ival);
- } else if (li.out.tvenc == 4) { /* Rec709 1250/50/2:1 YCbCr */
+ } else if (li.out.tvenc == 5) { /* Rec709 1250/50/2:1 YCbCr */
icmRec709_50_RGBd_2_YPbPr(ival, ival);
icmRecXXX_YPbPr_2_YCbCr(ival, ival);
- } else if (li.out.tvenc == 5) { /* Rec2020 Non-constant Luminance YCbCr encoding */
+ } else if (li.out.tvenc == 6) { /* Rec2020 Non-constant Luminance YCbCr encoding */
icmRec2020_NCL_RGBd_2_YPbPr(ival, ival);
icmRecXXX_YPbPr_2_YCbCr(ival, ival);
- } else if (li.out.tvenc == 6) { /* Rec2020 Constant Luminance YCbCr encoding */
+ } else if (li.out.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
icmRec2020_CL_RGBd_2_YPbPr(ival, ival);
icmRecXXX_YPbPr_2_YCbCr(ival, ival);
}
-//printf("input value %f %f %f\n",ival[0], ival[1], ival[2]);
lut->lookup_clut_sx(lut, oval, ival);
-//printf("before tune out %f %f %f\n",oval[0], oval[1], oval[2]);
/* Lookup the cLUT input value */
devi_devip((void *)&li, ival, ival);
@@ -4104,25 +4527,19 @@ main(int argc, char *argv[]) {
/* Look up black output value we want */
devip_devop((void *)&li, oval, ival);
-//printf("bp tune target %f %f %f\n",oval[0], oval[1], oval[2]);
- // ~~~~9999 should do a lookup to set sx/nl type corrctly
+ // ~9 should do a lookup to set sx/nl type corrctly
rv = lut->tune_value(lut, oval, ival);
// rv = icmLut_tune_value_sx(lut, oval, ival);
// rv = icmLut_tune_value_nl(lut, oval, ival);
if (rv != 0)
warning("Fine tuning video black failed - clipping");
-
-// lut->lookup_clut_sx(lut, oval, ival);
-//printf("after sx out %f %f %f\n",oval[0], oval[1], oval[2]);
-
-// lut->lookup_clut_nl(lut, oval, ival);
-//printf("after nl out %f %f %f\n",oval[0], oval[1], oval[2]);
}
+#endif /* NEVER */
if (li.verb)
- printf("Writing out file\n");
+ printf("Writing ICC file '%s'\n",link_name);
/* Write the file out */
if ((rv = wr_icc->write(wr_icc,wr_fp,0)) != 0)
@@ -4131,7 +4548,7 @@ main(int argc, char *argv[]) {
/* eeColor format */
if (li.tdlut == 1) {
write_eeColor1DinputLuts(&li, tdlut_name);
- if (write_eeColor3DLut(wr_icc, tdlut_name))
+ if (write_eeColor3DLut(wr_icc, &li, tdlut_name))
error ("Write file '%s' failed",tdlut_name);
write_eeColor1DoutputLuts(&li, tdlut_name);
}
@@ -4142,6 +4559,12 @@ main(int argc, char *argv[]) {
error ("Write file '%s' failed",tdlut_name);
}
+ /* .cube format */
+ else if (li.tdlut == 3) {
+ if (write_cube_3DLut(&li, wr_icc, tdlut_name))
+ error ("Write file '%s' failed",tdlut_name);
+ }
+
wr_icc->del(wr_icc);
wr_fp->del(wr_fp);
@@ -4323,6 +4746,21 @@ main(int argc, char *argv[]) {
/* ===================================================================== */
+/* Tweak for eeColor input and output value encodings */
+
+static void VidRGB_to_eeColor(double out[3], double in[3]) {
+ int i;
+ for (i = 0; i < 3; i++)
+ out[i] = in[i] * 255.0/256.0;
+}
+
+static void eeColor_to_VidRGB(double out[3], double in[3]) {
+ int i;
+ for (i = 0; i < 3; i++)
+ out[i] = in[i] * 256.0/255.0;
+}
+
+
/* Write a eeColor 1DLut input LUT files */
/* Return nz on error */
int write_eeColor1DinputLuts(clink *li, char *tdlut_name) {
@@ -4350,89 +4788,42 @@ int write_eeColor1DinputLuts(clink *li, char *tdlut_name) {
for (i = 0; i < 1024; i++) {
for (k = 0; k < 3; k++)
in[k] = i/(1024-1.0);
- devi_devip((void *)li, out, in);
- fp->gprintf(fp,"%.6f\n",out[j]);
- }
-
- if (fp->del(fp))
- error ("write_eeColor1DinputLuts to '%s' failed",fname);
- }
- return 0;
-}
-
-#ifdef NEVER
-/* Write a eeColor 3DLut file */
-/* Return nz on error */
-/* (We delve inside the icc structure, so don't use this code) */
-int write_eeColor3DLut(icc *icc, char *fname) {
- icmLut *lut;
- icmFile *fp;
-
- if ((lut = (icmLut *)icc->read_tag(icc, icSigAToB0Tag)) == NULL)
- error("write_eeColor3DLut: unableto locate A2B tag: %d, %s",icc->errc,icc->err);
-
- /* Open up the 3dlut file for writing */
- if ((fp = new_icmFileStd_name(fname,"w")) == NULL)
- error ("write_eeColor3DLut: Can't open file '%s'",fname);
-
- {
- int i, j, k;
- DCOUNT(gc, MAX_CHAN, lut->inputChan, 0, 0, lut->clutPoints);
- int ord[3] = { 1, 0, 2 }; /* Channel order, fastest to slowest, G, R, B */
-
- DC_INIT(gc);
-
- while (!DC_DONE(gc)) {
- int ix;
-
- ix = 0;
- for (i = 0; i < lut->inputChan; i++) {
- ix += lut->dinc[ord[i]] * gc[i];
- }
-
- /* Hmm. We're assuming that the eeColor is smart enough */
- /* to map the floating point values to the maximum */
- /* video encoded range, ie 255 * (bits - 8). */
- /* It's not clear if "bits" is 8, 10 or 12, or if */
- /* it actually works this way though. */
+ /* Full range -> 64/65 scaled */
+ /* or Video -> cLUT65 index */
+ devi_devip((void *)li, out, in);
- /* It's also not clear what it does for full range input, */
- /* if anything. Ie. it may just map that to 255 * (bits - 8) too. */
+ if (li->in.tvenc == 1) { /* Video 16-235 range */
+ cLUT65_to_VidRGB(out, out);
- /* There are two sets of RGB values. One is (suposedly)
- the "calibrated white point" and one "the native white point".
- It's hard to guess what this is.
- */
-
- for (i = 0; i < lut->inputChan; i++) {
- fp->gprintf(fp," %.6f",lut->clutTable[ix + i]);
+ /* eeColor doesn't actually do YCrCb explicitly, but put this here for completeness */
+ } else if (li->in.tvenc == 3 /* Rec601 YCbCr */
+ || li->in.tvenc == 4 /* Rec709 1150/60/2:1 YCbCr */
+ || li->in.tvenc == 5 /* Rec709 1250/50/2:1 YCbCr */
+ || li->in.tvenc == 6 /* Rec2020 Non-constant Luminance YCbCr encoding */
+ || li->in.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
+ cLUT65_to_YCrCb(out, out);
}
- for (i = 0; i < lut->outputChan; i++) {
- fp->gprintf(fp," %.6f",lut->clutTable[ix + i]);
- }
-
- fp->gprintf(fp,"\n");
- DC_INC(gc);
+ fp->gprintf(fp,"%.6f\n",out[j]);
}
+
+ if (fp->del(fp))
+ error ("write_eeColor1DinputLuts to '%s' failed",fname);
}
- if (fp->del(fp))
- error ("write_eeColor3DLut: write to '%s' failed",fname);
return 0;
}
-#else
-
/* Write a eeColor 3DLut file by doing a lookup for each node. */
/* Return nz on error */
-int write_eeColor3DLut(icc *icc, char *fname) {
+int write_eeColor3DLut(icc *icc, clink *li, char *fname) {
icmLuBase *luo;
icmLuLut *lut;
int i, j, k;
DCOUNT(gc, MAX_CHAN, 3, 0, 0, 65);
int ord[3]; /* Input channel order, fastest to slowest */
icmFile *fp;
+// int trace = 0;
/* Get a conversion object. We assume it is of the right type, being a link */
if ((luo = icc->get_luobj(icc, icmFwd, icmDefaultIntent, icmSigDefaultData, icmLuOrdNorm))
@@ -4451,33 +4842,81 @@ int write_eeColor3DLut(icc *icc, char *fname) {
ord[0] = 1; ord[1] = 0; ord[2] = 2; /* Fastest to slowest G R B */
while (!DC_DONE(gc)) {
- double in[3], out[3];
+ double oin[3], in[3], out[3];
+
+ /* Our assumption is that the eeColor maps the FP range 1.0
+ to 64 * 2^(bits -6). This is sligghtly too much for
+ full range (PC), but exactly lines the black point
+ up on the 4th grid node for any video encodig bit depth,
+ and results in input values being the same as output
+ values for the null transform
+ */
+ /* There are two sets of RGB values. One is (suposedly)
+ the "calibrated white point" and one "the native white point",
+ but experiments don't give any indications that the first
+ three entries are capable of affecting the result in any way
+ in any mode..
+ */
+
+ /* The eeColor wires the 65'th node to 1.0, and we can skip */
+ /* creating it */
+ if (gc[0] == 64 || gc[1] == 64 || gc[2] == 64)
+ goto next;
- /* Hmm. If we knew how the eeColor quantized the incoming video values, */
- /* we could do the same quantization here for better accuracy. */
- /* It's hard to guess given the unknown 8/10/12 bit nature of it. */
for (i = 0; i < 3; i++)
- in[ord[i]] = gc[i]/64.0;
+ oin[ord[i]] = gc[i]/64.0;
+
+// trace = 0;
+// if (gc[0] == 4 && gc[1] == 4 && gc[2] == 4) trace = 1;
+// if (gc[0] == 58 && gc[1] == 58 && gc[2] == 58) trace = 1;
+// if (gc[0] == 59 && gc[1] == 59 && gc[2] == 59) trace = 1;
+
+// if (trace) printf("eeColor ix oin = %f %f %f\n", oin[0], oin[1], oin[2]);
+
+ eeColor_to_VidRGB(in, oin);
+
+// if (trace) printf("Video in = %f %f %f\n", in[0], in[1], in[2]);
+
+ if (li->clutres == 65
+ || li->clutres == 33
+ || li->clutres == 17) {
+
+ if (li->in.tvenc == 1) { /* Video 16-235 range */
+ VidRGB_to_cLUT65(in, in);
+
+ /* eeColor doesn't actually do YCrCb explicitly, but put this here for completeness */
+ } else if (li->in.tvenc == 3 /* Rec601 YCbCr */
+ || li->in.tvenc == 4 /* Rec709 1150/60/2:1 YCbCr */
+ || li->in.tvenc == 5 /* Rec709 1250/50/2:1 YCbCr */
+ || li->in.tvenc == 6 /* Rec2020 Non-constant Luminance YCbCr encoding */
+ || li->in.tvenc == 7) { /* Rec2020 Constant Luminance YCbCr encoding */
+ YCrCb_to_cLUT65(in, in);
+ }
+ }
+// if (trace) printf("cLut in = %f %f %f\n", in[0], in[1], in[2]);
if (lut->clut(lut, out, in) > 1)
error ("write_eeColor3DLut: %d, %s",icc->errc,icc->err);
-//printf("~1 %f %f %f -> %f %f %f\n", in[0], in[1], in[2], out[0], out[1], out[2]);
+// if (trace) printf("cLut/video out = %f %f %f\n", out[0], out[1], out[2]);
+
+ VidRGB_to_eeColor(out, out);
+// if (trace) printf("eeColor out = %f %f %f\n", out[0], out[1], out[2]);
for (i = 0; i < 3; i++)
- fp->gprintf(fp," %.6f",out[i]);
+ fp->gprintf(fp," %.6f",oin[i]);
for (i = 0; i < 3; i++)
fp->gprintf(fp," %.6f",out[i]);
fp->gprintf(fp,"\n");
+ next:;
DC_INC(gc);
}
if (fp->del(fp))
error ("write_eeColor3DLut: write to '%s' failed",fname);
return 0;
}
-#endif
/* Write a eeColor 1DLut output LUT files */
/* Return nz on error */
@@ -4574,11 +5013,11 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
write_ORD32_le(8, h + of); of += 4; /* input bit depth */
write_ORD32_le(8, h + of); of += 4;
write_ORD32_le(8, h + of); of += 4;
- write_ORD32_le(li->in.tvenc >= 2 ? 1 : 0, h + of); of += 4; /* Input BGR or cCbCr enc */
+ write_ORD32_le(li->in.tvenc >= 3 ? 1 : 0, h + of); of += 4; /* Input BGR or cCbCr enc */
if (dov2)
write_ORD32_le(li->in.tvenc != 0 ? 1 : 0, h + of), of += 4; /* Range */
write_ORD32_le(16, h + of); of += 4; /* Output bit depth */
- write_ORD32_le(li->out.tvenc >= 2 ? 1 : 0, h + of); of += 4; /* Output BGR or YCbCr encoding */
+ write_ORD32_le(li->out.tvenc >= 3 ? 1 : 0, h + of); of += 4; /* Output BGR or YCbCr encoding */
if (dov2)
write_ORD32_le(li->out.tvenc != 0 ? 1 : 0, h + of), of += 4; /* Range */
write_ORD32_le(0x200, h + of); of += 4; /* Bytes to parameters */
@@ -4604,7 +5043,7 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
write_ORD32_le(clutsize, h + of); of += 4; /* Uncompressed clut size */
if (li->verb)
- printf("Writing 3dLut\n");
+ printf("Writing MadVR 3dLut '%s'\n",fname);
/* Write the 3dlutheader */
if (fp->write(fp, h, 1, 0x4000) != 0x4000)
@@ -4619,7 +5058,7 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
DC_INIT(gc);
- if (li->in.tvenc >= 2) { /* YCbCr fastest to slowest is Y Cb Cr */
+ if (li->in.tvenc >= 3) { /* YCbCr fastest to slowest is Y Cb Cr */
ord[0] = 0; ord[1] = 1; ord[2] = 2; /* Y Cb Cr */
} else { /* RGB fastest to slowest is B G R */
@@ -4638,7 +5077,7 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
//printf("~1 %f %f %f -> %f %f %f\n", in[0], in[1], in[2], out[0], out[1], out[2]);
- if (li->in.tvenc == 7 || li->in.tvenc == 8) { /* xvYCC */
+ if (li->in.tvenc == 8 || li->in.tvenc == 9) { /* xvYCC */
for (i = 1; i < 3; i++) { /* Force 'sync' entry values on CbCr*/
if (gc[i] == 0) {
out[i] = 0.0;
@@ -4660,7 +5099,7 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
}
- if (li->out.tvenc >= 2) { /* YCbCr order is YCbCr */
+ if (li->out.tvenc >= 3) { /* YCbCr order is YCbCr */
write_ORD16_le(iout[0], buf + 0);
write_ORD16_le(iout[1], buf + 2);
write_ORD16_le(iout[2], buf + 4);
@@ -4736,5 +5175,75 @@ int write_MadVR_3DLut(clink *li, icc *icc, char *fname) {
return 0;
}
+/* ===================================================================== */
+/* Write .cube 3dlut file */
+
+/* Return nz on error */
+int write_cube_3DLut(clink *li, icc *icc, char *fname) {
+ icmFile *fp;
+ ORD8 *h;
+ int clutsize;
+ int i;
+
+ icmLuBase *luo;
+ icmLut *lu;
+
+ /* Get a conversion object. We assume it is of the right type */
+ if ((luo = icc->get_luobj(icc, icmFwd, icmDefaultIntent,
+ icmSigDefaultData, icmLuOrdNorm)) == NULL)
+ error ("write_cube_3DLut: %d, %s",icc->errc, icc->err);
+
+ /* Open up the 3dlut file for writing */
+ if ((fp = new_icmFileStd_name(fname,"w")) == NULL)
+ error("write_cube_3DLut: Can't open file '%s'",fname);
+
+ lu = ((icmLuLut *)luo)->lut;
+ clutsize = lu->clutPoints;
+
+ fp->gprintf(fp, "# Created by ArgyllCMS\n");
+ fp->gprintf(fp, "LUT_3D_SIZE %d\n",clutsize);
+// fp->gprintf(fp, "DOMAIN_MIN %f %f %f\n",0.0, 0.0, 0.0);
+// fp->gprintf(fp, "DOMAIN_MAX %f %f %f\n",1.0, 1.0, 1.0);
+
+ if (li->verb)
+ printf("Writing .cube 3dLut '%s'\n",fname);
+
+ /* Write the clut data */
+ {
+ int i, j, k;
+ DCOUNT(gc, MAX_CHAN, 3, 0, 0, clutsize);
+ int ord[3]; /* Input channel order, fastest to slowest */
+
+ DC_INIT(gc);
+
+ /* RGB fastest to slowest is R G B */
+ ord[0] = 0; ord[1] = 1; ord[2] = 2; /* R G B */
+
+ while (!DC_DONE(gc)) {
+ double in[3], out[3];
+ int iout[3];
+
+ for (i = 0; i < 3; i++)
+ in[ord[i]] = gc[i]/(clutsize-1.0);
+
+ if (luo->lookup(luo, out, in) > 1)
+ error ("write_cube_3DLut: %d, %s",icc->errc,icc->err);
+
+//printf("~1 %f %f %f -> %f %f %f\n", in[0], in[1], in[2], out[0], out[1], out[2]);
+ fp->gprintf(fp, " %f %f %f\n",out[0], out[1], out[2]);
+
+ DC_INC(gc);
+ }
+ }
+
+ if (fp->del(fp))
+ error ("write_cube_3DLut: write to '%s' failed",fname);
+
+ luo->del(luo);
+
+ return 0;
+}
+
+