From c07d0c2d2f6f7b0eb6e92cc6204bf05037957e82 Mon Sep 17 00:00:00 2001 From: =?UTF-8?q?J=C3=B6rg=20Frings-F=C3=BCrst?= Date: Mon, 1 Sep 2014 15:43:52 +0200 Subject: Imported Upstream version 1.6.3 --- link/collink.c | 1752 +++++++++++++++++++++++++++++++++++++++++++++++++++----- 1 file changed, 1597 insertions(+), 155 deletions(-) (limited to 'link') diff --git a/link/collink.c b/link/collink.c index 6c40efd..3bb93b7 100644 --- a/link/collink.c +++ b/link/collink.c @@ -1,4 +1,6 @@ +/* Version with Lab bt.1886 */ + /* * collink * @@ -22,6 +24,7 @@ * * Abstract link support intent doesn't work properly for anything * other than absolute. This should really be fixed. + * */ /* NOTES: @@ -51,7 +54,6 @@ The source profile per channel curve plus a Y to L* curve it's a Matrix profile. - Colorspace representations are a bit of a mess. It's hard to know what space color is in at any point, and difficult to transform to match some other element. Putting the different colorspace support within @@ -96,6 +98,8 @@ #undef NEUTKDEBUG /* print info about neutral L -> K mapping */ +#undef LINTERP_OR /* Use simple extrapolation of Video encoded overrage values */ + #include #include #include @@ -104,12 +108,12 @@ #include #include "copyright.h" #include "aconfig.h" +#include "counters.h" #include "numlib.h" #include "icc.h" #include "xicc.h" #include "gamut.h" #include "gammap.h" -// ~~~99 #include "vrml.h" void usage(char *diag, ...) { @@ -140,6 +144,8 @@ void usage(char *diag, ...) { fprintf(stderr," -F Special :- Force all colors to be K only output\n"); fprintf(stderr," -fcmy Special :- Force 100%% C,M or Y only to stay pure \n"); fprintf(stderr," -p absprof Include abstract profile in link\n"); + fprintf(stderr," -a file.cal Apply calibration curves to link output and append linear\n"); + fprintf(stderr," -H file.cal Append calibration curves to 3dlut\n"); fprintf(stderr," -s Simple Mode (default)\n"); fprintf(stderr," -g [src.gam] Gamut Mapping Mode [optional source image gamut]\n"); fprintf(stderr," -G [src.gam] Gamut Mapping Mode using inverse outprofile A2B\n"); @@ -176,10 +182,11 @@ void usage(char *diag, ...) { fprintf(stderr," w:x:y Adapted white point as x, y\n"); fprintf(stderr," a:adaptation Adaptation luminance in cd.m^2 (default 50.0)\n"); fprintf(stderr," b:background Background %% of image luminance (default 20)\n"); - fprintf(stderr," l:scenewhite Scene white in cd.m^2 if surround = auto (default 250)\n"); - fprintf(stderr," f:flare Flare light %% of image luminance (default 1)\n"); - fprintf(stderr," f:X:Y:Z Flare color as XYZ (default media white)\n"); - fprintf(stderr," f:x:y Flare color as x, y\n"); + fprintf(stderr," l:imagewhite Image white in cd.m^2 if surround = auto (default 250)\n"); + fprintf(stderr," f:flare Flare light %% of image luminance (default 0)\n"); + fprintf(stderr," g:glare Flare light %% of ambient (default 1)\n"); + fprintf(stderr," g:X:Y:Z Flare color as XYZ (default media white, Abs: D50)\n"); + fprintf(stderr," g:x:y Flare color as x, y\n"); fprintf(stderr," -t tlimit set source total ink limit, 0 - 400%% (estimate by default)\n"); fprintf(stderr," -T klimit set source black ink limit, 0 - 100%% (estimate by default)\n"); fprintf(stderr," Inverse outprofile A2B Options:\n"); @@ -193,10 +200,55 @@ void usage(char *diag, ...) { fprintf(stderr," -K parameters Same as -k, but target is K locus rather than K value itself\n"); fprintf(stderr," -l tlimit set destination total ink limit, 0 - 400%% (estimate by default)\n"); fprintf(stderr," -L klimit set destination black ink limit, 0 - 100%% (estimate by default)\n"); + 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," -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," 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"); + fprintf(stderr," 2 Rec2020 YCbCr UHD (16-235,240)/255 \"TV\" levels\n"); + 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"); 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 */ @@ -205,6 +257,7 @@ struct _profinfo { /* Setup parameters */ icRenderingIntent intent; /* Selected ICC rendering intent */ icxViewCond vc; /* Viewing Condition for CAM */ + int vc_set; /* vc may not be default (for verb) */ int inking; /* k inking algorithm, 0 = input, 1 = min, */ /* 2 = 0.5, 3 = max, 4 = ramp, 5 = curve, 6 = dual curve */ /* 7 = outpupt profile K value */ @@ -222,6 +275,21 @@ struct _profinfo { int nocurve; /* NZ to not use device curve in per channel curve */ 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 */ + /* (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 */ + 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; @@ -238,6 +306,7 @@ struct _clink { int src_kbp; /* nz = Use K only black point as src gamut black point */ 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 */ icColorSpaceSignature pcsor; /* PCS to use between in & out profiles */ @@ -256,6 +325,10 @@ struct _clink { xicc *abs_xicc; icxLuBase *abs_luo; /* NULL if none */ + int addcal; /* 1 = apply cal to 3dLut and set linear cal1 */ + /* 2 = set cal1 to cal */ + xcal *cal; /* Calibration to apply, NULL if none */ + /* (We current assume that xyzscale can't be used with gmi) */ double xyzscale; /* < 1.0 if Y is to be scaled in destination XYZ space */ double swxyz[3]; /* Source white point in XYZ */ @@ -264,6 +337,8 @@ struct _clink { 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; @@ -334,6 +409,130 @@ static void l2y_curve(double *out, double *in, int isXYZ) { } /* ------------------------------------------- */ + +/* 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 */ +/* Return the uncliped value in unclipped[] */ +/* Return the full value in the clip direction in full[] */ +static int clipVidRGB(double full[3], double unclipped[3], double clip[3]) { + int i, os = 0; + for (i = 0; i < 3; i++) { + unclipped[i] = clip[i]; + if (clip[i] < (16.0/255.0)) { + clip[i] = (16.0/255.0); + full[i] = 0.0; + os |= (1 << i); + } else if (clip[i] > (235.0/255.0)) { + clip[i] = (235.0/255.0); + full[i] = 1.0; + os |= (1 << i); + } + } + return os; +} + +/* Clip a value to the YCbCr range range 16..235, 16..240 */ +/* Return a bit mask of the channels that have clipped */ +/* Clip the incoming value clip[] in place */ +/* Return the uncliped value in unclipped[] */ +/* Return the full value in the clip direction in full[] */ +static int clipYCrCb(double full[3], double unclipped[3], double clip[3]) { + int os = 0; + + unclipped[0] = clip[0]; + if (clip[0] < (16.0/255.0)) { + clip[0] = (16.0/255.0); + full[0] = 0.0; + os |= 1; + } else if (clip[0] > (235.0/255.0)) { + clip[0] = (235.0/255.0); + full[0] = 1.0; + os |= 1; + } + + unclipped[1] = clip[1]; + if (clip[1] < (16.0/255.0)) { + clip[1] = (16.0/255.0); + full[1] = 0.0; + os |= 2; + } else if (clip[1] > (240.0/255.0)) { + clip[1] = (240.0/255.0); + full[1] = 1.0; + os |= 2; + } + + unclipped[2] = clip[2]; + if (clip[2] < (16.0/255.0)) { + clip[2] = (16.0/255.0); + full[2] = 0.0; + os |= 4; + } else if (clip[2] > (240.0/255.0)) { + clip[2] = (240.0/255.0); + full[2] = 1.0; + os |= 4; + } + + return os; +} + +/* Clip a value to the xvYCC range range 16..235, 0..255 */ +/* (We should clip CbCr to 1..254 range, but unless we are using */ +/* a 256 res cLUT, this would mess up the mapping at the edges.) */ +/* Return a bit mask of the channels that have clipped */ +/* Clip the incoming value clip[] in place */ +/* Return the uncliped value in unclipped[] */ +/* Return the full value in the clip direction in full[] */ +static int clip_xvYCC(double full[3], double unclipped[3], double clip[3]) { + int os = 0; + + unclipped[0] = clip[0]; + if (clip[0] < (16.0/255.0)) { + clip[0] = (16.0/255.0); + full[0] = 0.0; + os |= 1; + } else if (clip[0] > (235.0/255.0)) { + clip[0] = (235.0/255.0); + full[0] = 1.0; + os |= 1; + } + + unclipped[1] = clip[1]; + unclipped[2] = clip[2]; + + return os; +} + +/* Apply the Rec709 power curve to extended values using symetry */ +static void xvYCC_fwd_curve(double *out, double *in) { + int i; + + for (i = 0; i < 3; i++) { + if (fabs(in[i]) <= 0.081) + out[i] = in[i]/4.5; + else { + if (in[i] < 0.0) + out[i] = -pow((0.099 + -in[i])/1.099, 1.0/0.45); + else + out[i] = pow((0.099 + in[i])/1.099, 1.0/0.45); + } + } +} + +/* Apparently xvYCC601 uses the Rec709 primaries */ + +/* Convert RGB to D50 Rec709 RGB */ +static void xvYCC_fwd_matrix(double *out, double *in) { + double mat[3][3] = { + { 0.436029, 0.385099, 0.143072 }, + { 0.222438, 0.716942, 0.060621 }, + { 0.013897, 0.097076, 0.713926 } + }; + + icmMulBy3x3(out, mat, in); +} + +/* ======================================================= */ /* Functions called back in setting up the transform table */ #ifdef DEBUGC @@ -346,6 +545,10 @@ static int tt = 0; void devi_devip(void *cntx, double *out, double *in) { int rv = 0; clink *p = (clink *)cntx; + int i, clip = 0; + 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]) @@ -356,30 +559,46 @@ void devi_devip(void *cntx, double *out, double *in) { #ifdef DEBUGC DEBUGC #endif - printf("DevIn->DevIn' got %f %f %f %f\n",in[0], in[1], in[2], in[3]); fflush(stdout); + printf("DevIn->DevIn' got %s\n",icmPdv(p->in.chan, in)); #endif - if (p->in.nocurve) { /* Don't use profile per channel curves */ - int i; - for (i = 0; i < p->in.chan; i++) - out[i] = in[i]; - } else { /* Use input profile per channel curves */ + for (i = 0; i < p->in.chan; i++) + out[i] = in[i]; + + if (!p->in.nocurve) { /* Using profile per channel curves */ + + /* Video encoding decode */ + if (p->in.tvenc == 1) { /* Video 16-235 range */ + clip = clipVidRGB(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 */ + error("Can't use input curves with YCbCr input encoding"); + } + switch(p->in.alg) { case icmMonoFwdType: { icxLuMono *lu = (icxLuMono *)p->in.luo; /* Safe to coerce */ - rv |= lu->fwd_curve(lu, out, in); + rv |= lu->fwd_curve(lu, out, out); break; } case icmMatrixFwdType: { icxLuMatrix *lu = (icxLuMatrix *)p->in.luo; /* Safe to coerce */ - rv |= lu->fwd_curve(lu, out, in); + rv |= lu->fwd_curve(lu, out, out); break; } case icmLutType: { icxLuLut *lu = (icxLuLut *)p->in.luo; /* Safe to coerce */ /* Since not PCS, in_abs and matrix cannot be valid, */ /* so input curve on own is ok to use. */ - rv |= lu->input(lu, out, in); + rv |= lu->input(lu, out, out); break; } default: @@ -387,18 +606,41 @@ 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]); + } + } + } } if (p->in.lcurve) { /* Apply Y to L* */ -//printf("~1 y2l_curve got %f %f %f, isXYZ %d\n",in[0],in[1],in[2],p->in.lcurve == 2); y2l_curve(out, out, p->in.lcurve == 2); } + /* eeColor cLUT is fake 65^3 - only 64^3 is usable. This affects */ + /* full range and xvYCC RGB, so map inputs to cLUT to only use 64^3 */ + if (p->tdlut == 1) { + if (p->in.tvenc == 0) { /* Full range */ + for (i = 0; i < p->in.chan; i++) + 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 */ + 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); + } + } + #ifdef DEBUG #ifdef DEBUGC DEBUGC #endif - printf("DevIn->DevIn' ret %f %f %f %f\n",out[0], out[1], out[2], in[3]); fflush(stdout); + printf("DevIn->DevIn' ret %s\n",icmPdv(p->in.chan, out)); #endif } @@ -406,6 +648,7 @@ void devi_devip(void *cntx, double *out, double *in) { /* - - - - - - - - - - - - */ /* clut, DevIn' -> DevOut' */ void devip_devop(void *cntx, double *out, double *in) { + double oin[MAX_CHAN]; /* original input values */ double win[MAX_CHAN]; /* working input values */ double pcsv[MAX_CHAN]; /* PCS intermediate value, pre-gamut map */ double pcsvm[MAX_CHAN]; /* PCS intermediate value, post-gamut map */ @@ -416,14 +659,89 @@ void devip_devop(void *cntx, double *out, double *in) { int cmytrig = 0; /* CMY output hack triggered */ int i, rv = 0; clink *p = (clink *)cntx; + int clip = 0; /* clip mask (Video) */ + double cin[3]; /* clipped input value (Video) */ + double uc[3]; /* Unclipped values (Video) */ + double full[3]; /* Full value in clip direction (Video) */ #ifdef DEBUG #ifdef DEBUGC DEBUGC #endif - printf("DevIn'->DevOut' got %f %f %f %f\n",in[0], in[1], in[2], in[3]); fflush(stdout); + 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 */ + /* to out when out == in */ + for (i = 0; i < p->in.chan; i++) + win[i] = oin[i] = in[i]; + + /* eeColor cLUT is fake 65^3 - only 64^3 is usable. This affects */ + /* full range and xvYCC RGB, so un-map inputs to cLUT to only use 64^3 */ + if (p->tdlut == 1) { + if (p->in.tvenc == 0) { + for (i = 0; i < p->in.chan; i++) + 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 */ + 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); + } + } + + if (p->in.nocurve) { /* Not using profile per channel curves */ + /* Video encoding decode */ + if (p->in.tvenc == 1) { /* Video 16-235 range */ + clip = clipVidRGB(full, uc, win); + icmCpy3(cin, win); + icmVidRGB_2_RGB(win, win); + } else if (p->in.tvenc == 2) { /* Rec601 YCbCr */ + clip = clipYCrCb(full, uc, 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); + 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); + 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); + 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); + 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); + 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); + 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)); +#endif + } + #ifdef ENKHACK /* Handle neutral recognition/output K only hack */ /* (see discussion at top of file for generalization of this idea) */ @@ -436,30 +754,30 @@ void devip_devop(void *cntx, double *out, double *in) { /* input space device values here. It also made sure that there are at */ /* least 3 input channels. */ - if (fabs(in[0] - in[1]) < thr - && fabs(in[1] - in[2]) < thr - && fabs(in[2] - in[0]) < thr) + if (fabs(win[0] - win[1]) < thr + && fabs(win[1] - win[2]) < thr + && fabs(win[2] - win[0]) < thr) ntrig = 1; /* K only output triggered flag */ } else if (p->nhack == 2) { double maxcmy; /* Comute a degree of source "K onlyness" */ double maxcmyk; - maxcmy = in[0]; /* Compute minimum of CMY */ - if (in[1] > maxcmy) - maxcmy = in[1]; - if (in[2] > maxcmy) - maxcmy = in[2]; + maxcmy = win[0]; /* Compute minimum of CMY */ + if (win[1] > maxcmy) + maxcmy = win[1]; + if (win[2] > maxcmy) + maxcmy = win[2]; maxcmyk = maxcmy; /* Compute minimum of all inks */ - if (in[3] > maxcmyk) - maxcmyk = in[3]; + if (win[3] > maxcmyk) + maxcmyk = win[3]; -//printf("~1 maxcmy = %f, maxcmyk = %f, in[3] = %f\n",maxcmy,maxcmyk,in[3]); - if (in[3] <= 0.0 || maxcmy > in[3]) { +//printf("~1 maxcmy = %f, maxcmyk = %f, win[3] = %f\n",maxcmy,maxcmyk,win[3]); + if (win[3] <= 0.0 || maxcmy > win[3]) { konlyness = 0.0; } else { - konlyness = (in[3] - maxcmy)/in[3]; + konlyness = (win[3] - maxcmy)/win[3]; } /* As we approach no colorant, blend towards no Konlyness */ @@ -467,9 +785,9 @@ void devip_devop(void *cntx, double *out, double *in) { konlyness *= maxcmyk/0.2; /* We want to see if the input colors are exactly K only. */ - if (in[0] < thr - && in[1] < thr - && in[2] < thr) + if (win[0] < thr + && win[1] < thr + && win[2] < thr) ntrig = 1; /* K only output triggered flag */ #ifdef DEBUG #ifdef DEBUGC @@ -485,46 +803,36 @@ void devip_devop(void *cntx, double *out, double *in) { double thr = (0.5)/(p->clutres-1.0); /* Match threshold */ if (p->cmyhack & 1) { - if (in[0] > (1.0 - thr) - && in[1] < thr - && in[2] < thr - && (p->in.chan < 4 || in[3] < thr)) + if (win[0] > (1.0 - thr) + && win[1] < thr + && win[2] < thr + && (p->in.chan < 4 || win[3] < thr)) cmytrig |= 1; } if (p->cmyhack & 2) { - if (in[0] < thr - && in[1] > (1.0 - thr) - && in[2] < thr - && (p->in.chan < 4 || in[3] < thr)) + if (win[0] < thr + && win[1] > (1.0 - thr) + && win[2] < thr + && (p->in.chan < 4 || win[3] < thr)) cmytrig |= 2; } if (p->cmyhack & 4) { - if (in[0] < thr - && in[1] < thr - && in[2] > (1.0 - thr) - && (p->in.chan < 4 || in[3] < thr)) + if (win[0] < thr + && win[1] < thr + && win[2] > (1.0 - thr) + && (p->in.chan < 4 || win[3] < thr)) cmytrig |= 4; } } #endif /* ENKHACK */ if (p->in.lcurve) { /* Apply L* to Y */ - l2y_curve(win, in, p->in.lcurve == 2); -#ifdef DEBUG -#ifdef DEBUGC - DEBUGC -#endif - printf("win[] set to L* value %f %f %f %f\n",win[0], win[1], win[2], win[3]); fflush(stdout); -#endif - - } else { - for (i = 0; i < p->in.chan; i++) - win[i] = in[i]; + l2y_curve(win, win, p->in.lcurve == 2); #ifdef DEBUG #ifdef DEBUGC - DEBUGC + DEBUGC #endif - printf("win[] set to in[] value %f %f %f %f\n",win[0], win[1], win[2], win[3]); fflush(stdout); + printf("win[] set to L* value %s\n",icmPdv(p->in.chan, win)); #endif } @@ -544,13 +852,38 @@ void devip_devop(void *cntx, double *out, double *in) { } case icmMatrixFwdType: { icxLuMatrix *lu = (icxLuMatrix *)p->in.luo; /* Safe to coerce */ + icmLuMatrix *plu = (icmLuMatrix *)lu->plu; /* Safe to coerce */ if (p->in.nocurve) { /* No explicit curve, so do implicit here */ - rv |= lu->fwd_curve(lu, pcsv, win); - rv |= lu->fwd_matrix(lu, pcsv, pcsv); + + if (p->in.tvenc == 7 || p->in.tvenc == 8) { /* xvYCC */ + xvYCC_fwd_curve(pcsv, win); /* Allow for overrange values */ + xvYCC_fwd_matrix(pcsv, pcsv); /* Rec709 primaries */ + } else { + rv |= lu->fwd_curve(lu, pcsv, win); + rv |= lu->fwd_matrix(lu, pcsv, pcsv); + } } else { - rv |= lu->fwd_matrix(lu, pcsv, win); + if (p->in.tvenc == 7 || p->in.tvenc == 8) /* 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)); +#endif + if (p->in.bt1886) { + bt1886_apply(&p->in.bt, plu, pcsv, pcsv); +#ifdef DEBUG +#ifdef DEBUGC + DEBUGC +#endif + 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; } @@ -625,7 +958,7 @@ void devip_devop(void *cntx, double *out, double *in) { #ifdef DEBUGC DEBUGC #endif - printf("PCS before map %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]); fflush(stdout); + printf("PCS before map %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]); #endif if (p->wphack) { @@ -693,7 +1026,7 @@ void devip_devop(void *cntx, double *out, double *in) { #ifdef DEBUGC DEBUGC #endif - printf("PCS after Y scale %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]); fflush(stdout); + printf("PCS after Y scale %f %f %f\n",pcsv[0], pcsv[1], pcsv[2]); #endif } @@ -737,7 +1070,7 @@ void devip_devop(void *cntx, double *out, double *in) { #ifdef DEBUGC DEBUGC #endif - printf("PCS after map %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]); fflush(stdout); + printf("PCS after map %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]); #endif } else { pcsvm[0] = pcsv[0]; @@ -766,7 +1099,7 @@ void devip_devop(void *cntx, double *out, double *in) { #ifdef DEBUGC DEBUGC #endif - printf("PCS after abstract %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]); fflush(stdout); + printf("PCS after abstract %f %f %f\n",pcsvm[0], pcsvm[1], pcsvm[2]); #endif } @@ -931,14 +1264,99 @@ void devip_devop(void *cntx, double *out, double *in) { error("icc lookup failed: %d, %s",p->in.c->errc,p->in.c->err); } - if (p->out.lcurve) /* Apply Y to L* */ + 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)); +#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)); +#endif y2l_curve(out, out, p->out.lcurve == 2); + } + /* Video encoding encode */ + if (p->out.tvenc) { #ifdef DEBUG #ifdef DEBUGC DEBUGC #endif - printf("DevIn'->DevOut' ret %f %f %f %f\n\n",out[0], out[1], out[2], out[3]); fflush(stdout); + printf("DevOut' before TVenc %s\n\n",icmPdv(p->out.chan, out)); +#endif + for (i = 0; i < p->out.chan; i++) { + if (out[i] < 0.0) + out[i] = 0.0; + else if (out[i] > 1.0) + out[i] = 1.0; + } + if (p->out.tvenc == 1) { /* Video 16-235 range */ + icmRGB_2_VidRGB(out, out); + } else if (p->out.tvenc == 2) { /* 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 */ + icmRec709_RGBd_2_YPbPr(out, out); + icmRecXXX_YPbPr_2_YCbCr(out, out); + } else if (p->out.tvenc == 4) { /* 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 */ + icmRec2020_NCL_RGBd_2_YPbPr(out, out); + icmRecXXX_YPbPr_2_YCbCr(out, out); + } else if (p->out.tvenc == 6) { /* 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 */ + icmRec601_RGBd_2_YPbPr(out, out); + icmRecXXX_YPbPr_2_YCbCr(out, out); + } else if (p->out.tvenc == 8) { /* HD xvYCC with Rec709 YCbCr encoding */ + icmRec709_RGBd_2_YPbPr(out, out); + icmRecXXX_YPbPr_2_YCbCr(out, out); + } +#endif /* NEVER */ + } + + /* 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 */ + + /* Do simple extrapolation (Not perfect though) */ + out[i] = ifull + (out[i] - ifull) * (uc[i] - ifull)/(cin[i] - ifull); + + 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 + } + } + } + +#ifdef DEBUG +#ifdef DEBUGC + DEBUGC +#endif + printf("DevIn'->DevOut' ret %s\n\n",icmPdv(p->out.chan, out)); #endif @@ -958,23 +1376,35 @@ 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; + int i, clip = 0; + 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 %f %f %f %f\n",in[0], in[1], in[2], in[4]); fflush(stdout); + 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); 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"); + } + switch(p->out.alg) { case icmMonoBwdType: { icxLuMono *lu = (icxLuMono *)p->out.luo; /* Safe to coerce */ @@ -1004,16 +1434,35 @@ 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); + + if (p->cal != NULL && p->addcal == 1) { + p->cal->interp(p->cal, out, out); + } + + /* Video encoding encode */ + 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 #ifdef DEBUGC DEBUGC #endif - printf("DevOut'->DevOut ret %f %f %f %f\n",out[0], out[1], out[2], out[3]); fflush(stdout); + 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)); } /* ------------------------------------------- */ @@ -1114,19 +1563,29 @@ static double xyzoptfunc(void *cntx, double *v) { /* ------------------------------------------- */ +int write_eeColor1DinputLuts(clink *li, char *tdlut_name); +int write_eeColor3DLut(icc *icc, char *fname); +int write_eeColor1DoutputLuts(clink *li, char *tdlut_name); + +int write_MadVR_3DLut(clink *li, icc *icc, char *fname); + int main(int argc, char *argv[]) { int fa, nfa, mfa; /* argument we're looking at */ char in_name[MAXNAMEL+1]; char sgam_name[MAXNAMEL+1] = "\000"; /* Source gamut name */ char abs_name[MAXNAMEL+1] = "\000"; /* Abstract profile name */ + char cal_name[MAXNAMEL+1] = "\000"; /* Calibration filename */ char out_name[MAXNAMEL+1]; char link_name[MAXNAMEL+1]; + char tdlut_name[MAXNAMEL+1]; int verify = 0; /* Do verify pass */ int outinkset = 0; /* The user specfied an output inking */ int intentset = 0; /* The user specified an intent */ int vcset = 0; /* Viewing conditions were set by user */ int modeset = 0; /* The gamut mapping mode was set by the user */ + int addcal = 0; /* 1 = Incorporate cal. curves in 3dLUT and set linear cal1 */ + /* 2 = Set 3dLut cal1 to calibration curves */ int rv = 0; icxViewCond ivc, ovc; /* Viewing Condition Overrides for in and out profiles */ int ivc_e = -1, ovc_e = -1; /* Enumerated viewing condition */ @@ -1147,7 +1606,7 @@ main(int argc, char *argv[]) { li.count = 0; li.last = -1; li.mode = 0; /* Default simple link mode */ - li.quality = 1; /* Medium quality */ + li.quality = -1; /* Not set */ li.clutres = 0; /* No resolution override */ li.nhack = 0; li.cmyhack = 0; /* Mask for 100% purity through mapping of CMY */ @@ -1166,6 +1625,9 @@ main(int argc, char *argv[]) { li.in.locus = 0; /* Default K value target */ 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.out.intent = icmDefaultIntent; /* Default */ li.out.ink.tlimit = -1.0; /* Default no total limit */ li.out.ink.klimit = -1.0; /* Default no black limit */ @@ -1178,6 +1640,7 @@ main(int argc, char *argv[]) { li.out.locus = 0; /* Default K value target */ li.out.nocurve = 0; /* Preserve device linearisation curve */ li.out.lcurve = 0; /* Don't apply an L* to Y curve before device curve */ + li.out.tvenc = -1; li.out.b2aluo = NULL; /* B2A lookup for inking == 7 */ xicc_enum_gmapintent(&li.gmi, icxDefaultGMIntent, NULL); /* Set default overall intent */ @@ -1189,7 +1652,8 @@ main(int argc, char *argv[]) { ivc.Yb = -1.0; ivc.Lv = -1.0; ivc.Yf = -1.0; - ivc.Fxyz[0] = -1.0; ivc.Fxyz[1] = -1.0; ivc.Fxyz[2] = -1.0; + ivc.Yg = -1.0; + ivc.Gxyz[0] = -1.0; ivc.Gxyz[1] = -1.0; ivc.Gxyz[2] = -1.0; ovc.Ev = -1; ovc.Wxyz[0] = -1.0; ovc.Wxyz[1] = -1.0; ovc.Wxyz[2] = -1.0; @@ -1197,7 +1661,8 @@ main(int argc, char *argv[]) { ovc.Yb = -1.0; ovc.Lv = -1.0; ovc.Yf = -1.0; - ovc.Fxyz[0] = -1.0; ovc.Fxyz[1] = -1.0; ovc.Fxyz[2] = -1.0; + ovc.Yg = -1.0; + ovc.Gxyz[0] = -1.0; ovc.Gxyz[1] = -1.0; ovc.Gxyz[2] = -1.0; if (argc < 4) usage("Too few arguments, got %d expect at least 3",argc-1); @@ -1262,13 +1727,14 @@ main(int argc, char *argv[]) { verify = 1; /* Disable profile per channel curve use in device link output */ - else if (argv[fa][1] == 'n' || argv[fa][1] == 'N') { + else if (argv[fa][1] == 'n') { li.in.nocurve = 1; li.out.nocurve = 1; } /* Hack to force input neutrals to K only output */ - else if (argv[fa][1] == 'f' || argv[fa][1] == 'F') { + else if (argv[fa][1] == 'f' + || argv[fa][1] == 'F') { if (argv[fa][1] == 'f') { if (na != NULL) { /* XXXK -> XXXK hack */ @@ -1299,7 +1765,7 @@ main(int argc, char *argv[]) { } /* Quality */ - else if (argv[fa][1] == 'q' || argv[fa][1] == 'Q') { + else if (argv[fa][1] == 'q') { fa = nfa; if (na == NULL) usage("Quality flag (-q) needs an argument"); switch (na[0]) { @@ -1328,22 +1794,33 @@ main(int argc, char *argv[]) { } /* CLUT resolution override */ - else if (argv[fa][1] == 'r' || argv[fa][1] == 'R') { + else if (argv[fa][1] == 'r') { int rr; fa = nfa; if (na == NULL) usage("Resolution flag (-r) needs an argument"); rr = atoi(na); - if (rr < 1 || rr > 255) usage("Resolution flag (-r) argument out of range (%d)",rr); + if (rr < 1 || rr > 256) usage("Resolution flag (-r) argument out of range (%d)",rr); li.clutres = rr; } /* Abstract profile */ else if (argv[fa][1] == 'p') { - if (na == NULL) usage("Expected abstract profile filename after -a"); + if (na == NULL) usage("Expected abstract profile filename after -p"); fa = nfa; strncpy(abs_name,na,MAXNAMEL); abs_name[MAXNAMEL] = '\000'; } + /* Calibration curves */ + else if (argv[fa][1] == 'a' + || argv[fa][1] == 'H') { + if (na == NULL) usage("Expected calibration filename after -%c",argv[fa][1]); + strncpy(cal_name,na,MAXNAMEL); cal_name[MAXNAMEL] = '\000'; + addcal = 1; + if (argv[fa][1] == 'H') + addcal = 2; + fa = nfa; + } + /* Simple mode */ else if (argv[fa][1] == 's') { li.mode = 0; @@ -1351,7 +1828,8 @@ main(int argc, char *argv[]) { } /* Maping mode */ - else if (argv[fa][1] == 'g' || argv[fa][1] == 'G') { + else if (argv[fa][1] == 'g' + || argv[fa][1] == 'G') { li.mode = 1; if (argv[fa][1] == 'G') { li.mode = 2; @@ -1365,7 +1843,7 @@ main(int argc, char *argv[]) { } /* White point hack */ - else if (argv[fa][1] == 'w' || argv[fa][1] == 'W') { + else if (argv[fa][1] == 'w') { li.wphack = 1; if (na != NULL) { // To a particular white point fa = nfa; @@ -1376,7 +1854,7 @@ main(int argc, char *argv[]) { } } /* Input profile Intent or Mapping mode intent */ - else if (argv[fa][1] == 'i' || argv[fa][1] == 'I') { + else if (argv[fa][1] == 'i') { fa = nfa; if (na == NULL) usage("Input intent flag (-i) needs an argument"); /* Record it for simple mode */ @@ -1407,7 +1885,7 @@ main(int argc, char *argv[]) { } /* Output profile Intent */ - else if (argv[fa][1] == 'o' || argv[fa][1] == 'O') { + else if (argv[fa][1] == 'o') { fa = nfa; if (na == NULL) usage("Output intent flag (-o) needs an argument"); switch (na[0]) { @@ -1433,18 +1911,17 @@ main(int argc, char *argv[]) { } /* Viewing conditions */ - else if (argv[fa][1] == 'c' || argv[fa][1] == 'C' - || argv[fa][1] == 'd' || argv[fa][1] == 'D') { + else if (argv[fa][1] == 'c' || argv[fa][1] == 'd') { icxViewCond *vc; - if (argv[fa][1] == 'c' || argv[fa][1] == 'C') { + if (argv[fa][1] == 'c') { vc = &ivc; } else { vc = &ovc; } fa = nfa; - if (na == NULL) usage("Viewing conditions flag (-[cd]) needs an argument"); + if (na == NULL) usage("Viewing conditions flag (-%c) needs an argument",argv[fa][1]); #ifdef NEVER if (na[0] >= '0' && na[0] <= '9') { if (vc == &ivc) @@ -1464,7 +1941,7 @@ main(int argc, char *argv[]) { } } else if (na[0] == 's' || na[0] == 'S') { if (na[1] != ':') - usage("Viewing conditions (-[cd]s) missing ':'"); + usage("Viewing conditions (-%cs) missing ':'",argv[fa][1]); if (na[2] == 'n' || na[2] == 'N') { vc->Ev = vc_none; /* Automatic */ } else if (na[2] == 'a' || na[2] == 'A') { @@ -1476,7 +1953,7 @@ main(int argc, char *argv[]) { } else if (na[2] == 'c' || na[2] == 'C') { vc->Ev = vc_cut_sheet; } else - usage("Viewing condition (-[cd]) unrecognised surround '%c'",na[2]); + usage("Viewing condition (-%c) unrecognised surround '%c'",argv[fa][1],na[2]); } else if (na[0] == 'w' || na[0] == 'W') { double x, y, z; if (sscanf(na+1,":%lf:%lf:%lf",&x,&y,&z) == 3) { @@ -1484,36 +1961,41 @@ main(int argc, char *argv[]) { } else if (sscanf(na+1,":%lf:%lf",&x,&y) == 2) { vc->Wxyz[0] = x; vc->Wxyz[1] = y; } else - usage("Viewing condition (-[cd]w) unrecognised white point '%s'",na+1); + usage("Viewing condition (-%cw) unrecognised white point '%s'",argv[fa][1],na+1); } else if (na[0] == 'a' || na[0] == 'A') { if (na[1] != ':') - usage("Viewing conditions (-[cd]a) missing ':'"); + usage("Viewing conditions (-ca) missing ':'"); vc->La = atof(na+2); } else if (na[0] == 'b' || na[0] == 'B') { if (na[1] != ':') - usage("Viewing conditions (-[cd]b) missing ':'"); + usage("Viewing conditions (-cb) missing ':'"); vc->Yb = atof(na+2)/100.0; } else if (na[0] == 'l' || na[0] == 'L') { if (na[1] != ':') - usage("Viewing conditions (-[cd]l) missing ':'"); + usage("Viewing conditions (-l) missing ':'"); vc->Lv = atof(na+2); } else if (na[0] == 'f' || na[0] == 'F') { + if (na[1] != ':') + usage("Viewing conditions (-cf) missing ':'"); + vc->Yf = atof(na+2); + } else if (na[0] == 'g' || na[0] == 'G') { double x, y, z; if (sscanf(na+1,":%lf:%lf:%lf",&x,&y,&z) == 3) { - vc->Fxyz[0] = x; vc->Fxyz[1] = y; vc->Fxyz[2] = z; + vc->Gxyz[0] = x; vc->Gxyz[1] = y; vc->Gxyz[2] = z; } else if (sscanf(na+1,":%lf:%lf",&x,&y) == 2) { - vc->Fxyz[0] = x; vc->Fxyz[1] = y; + vc->Gxyz[0] = x; vc->Gxyz[1] = y; } else if (sscanf(na+1,":%lf",&x) == 1) { vc->Yf = x/100.0; } else - usage("Viewing condition (-[cd]f) unrecognised flare '%s'",na+1); + usage("Viewing condition (-%cf) unrecognised flare '%s'",argv[fa][1],na+1); } else - usage("Viewing condition (-[cd]) unrecognised sub flag '%c'",na[0]); + usage("Viewing condition (-%c) unrecognised sub flag '%c'",argv[fa][1],na[0]); vcset = 1; /* Viewing conditions were set by user */ } /* Inking rule */ - else if (argv[fa][1] == 'k' || argv[fa][1] == 'K') { + else if (argv[fa][1] == 'k' + || argv[fa][1] == 'K') { fa = nfa; if (na == NULL) usage("Inking rule flag (-k) needs an argument"); if (argv[fa][1] == 'k') @@ -1648,6 +2130,88 @@ main(int argc, char *argv[]) { li.mode = 2; } + /* 3DLut output */ + else if (argv[fa][1] == '3') { + fa = nfa; + if (na == NULL) usage("3dLut format flag (-3) needs an argument"); + switch (na[0]) { + case 'e': + li.tdlut = 1; + break; + case 'm': + li.tdlut = 2; + break; + default: + usage("3DLut format (-3) argument '%s' not recognised",na); + } + } + + /* 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; + break; + default: + if (gamma == 0.0) + usage("Intent modifier (-I) argument '%s' not recognised",na); + } + } + + /* Video RGB in and out encoding */ + else if (argv[fa][1] == 'e' + || argv[fa][1] == 'E') { + int enc; + if (na == NULL) usage("Video encoding flag (-%c) needs an argument",argv[fa][1]); + switch (na[0]) { + case 'n': /* Normal */ + enc = 0; + break; + case 't': /* TV 16 .. 235 */ + enc = 1; + break; + case '6': /* Rec601 YCbCr */ + enc = 2; + break; + case '7': /* Rec709 1150/60/2:1 YCbCr (HD) */ + enc = 3; + break; + case '5': /* Rec709 1250/50/2:1 YCbCr (HD) */ + enc = 4; + break; + case '2': /* Rec2020 Non-constant Luminance YCbCr (UHD) */ + enc = 5; + break; + case 'C': /* Rec2020 Constant Luminance YCbCr (UHD) */ + enc = 6; + break; + case 'x': /* xvYCC Rec601 YCbCr encoding (SD) */ + enc = 7; + break; + case 'X': /* xvYCC Rec709 YCbCr encoding (HD) */ + enc = 8; + break; + default: + usage("Video encoding (-E) argument not recognised"); + } + if (argv[fa][1] == 'e') + li.in.tvenc = enc; + else + li.out.tvenc = enc; + fa = nfa; + } + /* Gammut mapping diagnostic plots */ else if (argv[fa][1] == 'P') li.gamdiag = 1; @@ -1667,9 +2231,52 @@ main(int argc, char *argv[]) { if (fa >= argc || argv[fa][0] == '-') usage("Missing result profile"); strncpy(link_name,argv[fa++],MAXNAMEL); link_name[MAXNAMEL] = '\000'; + if (li.tdlut) { + char *xl; + if (li.tdlut == 1) { /* eeColor */ + strncpy(tdlut_name,link_name,MAXNAMEL-4); tdlut_name[MAXNAMEL-4] = '\000'; + if ((xl = strrchr(tdlut_name, '.')) == NULL) /* Figure where extention is */ + xl = tdlut_name + strlen(tdlut_name); + strcpy(xl,".txt"); + + if (li.clutres > 255) usage("Resolution flag (-r) argument out of range (%d)",li.clutres); + + if (li.clutres == 0) + li.clutres = 65; + + } else if (li.tdlut == 2) { /* MadVR */ + 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,".3dlut"); + + 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); + } + + if (li.in.tvenc < 0) + li.in.tvenc = 0; + if (li.out.tvenc < 0) + 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 */ + usage("xvYCC output encoding is not supported"); + } + if (xpi.profDesc == NULL) xpi.profDesc = link_name; /* Default description */ + if (li.quality < 0) { /* Not set by user */ + if (li.tdlut) + li.quality = 2; /* Use high quality gamut mapping */ + else + li.quality = 1; /* Default to medium quality */ + } + if (li.verb) printf("Got options\n"); @@ -1677,13 +2284,84 @@ main(int argc, char *argv[]) { #ifndef ENKHACK /* Enable K hack code */ warning("!!!!!! linkl/collink.c ENKHACK not enabled !!!!!!"); #endif + + /* - - - - - - - - - - - - - - - - - - - */ + /* Set some implied flags for bt1886 */ + + if (li.in.bt1886) { + if (li.mode == 0) { /* Simple mode */ + if (li.in.intent == icmDefaultIntent) { + warning("Setting BT.1886 input intent to Relative Colorimetric"); + li.in.intent = icRelativeColorimetric; + } else if (li.in.intent != icRelativeColorimetric + && li.in.intent != icAbsoluteColorimetric) { + warning("BT.1886 in simple link mode is intended to work with a colorimetric in intent"); + } + + if (li.out.intent == icmDefaultIntent) { + warning("Setting BT.1886 output intent to Relative Colorimetric"); + li.out.intent = icRelativeColorimetric; + } else if (li.out.intent != icRelativeColorimetric + && li.out.intent != icAbsoluteColorimetric) { + warning("BT.1886 in simple link mode is intended to work with a colorimetric in intent"); + } + } else { + if (!intentset) { + warning("Setting BT.1886 intent to Relative Colorimetric"); + if (xicc_enum_gmapintent(&li.gmi, icxNoGMIntent, "r") == -999) + error("Internal - intent 'r' isn't recognised"); + } + +#ifdef NEVER + if (li.gmi.glumbcpf != 0.0 || li.gmi.glumbexf != 0.0) { + warning("Gamut mapping will do black point mapping, so BT.1886 black point mapping will be disabled"); + li.in.bt1886 = 2; /* Disable black point adjustment */ + } +#endif + } + } + + /* Set some implied flags for 3dLuts */ + if (li.tdlut) { + + /* eeColor format. Currently we assume no input or output curves, */ + /* even though it's technically possible to use them */ + if (li.tdlut == 1) { + + if (li.in.nocurve == 0) { + warning("Disabling input curves for eeColor 3DLut creation"); + li.in.nocurve = 1; + } + if (li.out.nocurve == 0) { + warning("Disabling output curves for eeColor 3DLut creation"); + li.out.nocurve = 1; + } + + if (li.in.tvenc != li.out.tvenc) + warning("eeColor usually needs same input & output encoding"); + } + + /* MadVR format. It doesn't support in and out per channel curves */ + else if (li.tdlut == 2) { + + if (li.in.nocurve == 0) { + warning("Disabling input curves for MadVR 3DLut creation"); + li.in.nocurve = 1; + } + if (li.out.nocurve == 0) { + warning("Disabling output curves for MadVR 3DLut creation"); + li.out.nocurve = 1; + } + } + } + /* - - - - - - - - - - - - - - - - - - - */ /* Sanity checking/defaulting of options */ /* Deal with options that need link mode -g */ if (li.mode < 1 && (li.in.intent == icMaxEnumIntent /* User set a smart linking intent */ - || vcset /* Viewing conditions were set by user */ + || vcset /* Viewing conditions were set by user */ || li.wphack)) { if (modeset) { if (li.in.intent == icMaxEnumIntent) @@ -1916,6 +2594,20 @@ main(int argc, char *argv[]) { && li.out.h->deviceClass != icSigColorSpaceClass) /* For sRGB etc. */ error("Output profile isn't a device profile"); + /* Grab the calibration if requested */ + if (addcal) { + if ((li.cal = new_xcal()) == NULL) + error("new_xcal failed"); + + if ((li.cal->read(li.cal, cal_name)) != 0) + error("%s",li.cal->err); + + li.addcal = addcal; + + /* (Don't use vcgt in output profile, because it may include tv encoding, */ + /* and we don't currently have a way of detecting this */ + } + /* Wrap with an expanded icc */ if ((li.out.x = new_xicc(li.out.c)) == NULL) error ("Creation of output profile xicc failed"); @@ -1990,15 +2682,18 @@ main(int argc, char *argv[]) { xicc *x; icxViewCond *v, *vc; int es; + int *set; if (i == 0) { v = &ivc; /* Override parameters */ vc = &li.in.vc; /* Target parameters */ + set = &li.in.vc_set; es = ivc_e; x = li.in.x; /* xicc */ } else { v = &ovc; /* Override parameters */ vc = &li.out.vc; /* Target parameters */ + set = &li.out.vc_set; es = ovc_e; x = li.out.x; /* xicc */ } @@ -2012,14 +2707,18 @@ main(int argc, char *argv[]) { if (es != -1) { if (xicc_enum_viewcond(x, vc, es, NULL, 0, NULL) == -999) error ("%d, %s",x->errc, x->err); + *set = 1; } /* Then any individual paramaters */ - if (v->Ev >= 0) + if (v->Ev >= 0) { vc->Ev = v->Ev; + *set = 1; + } if (v->Wxyz[0] >= 0.0 && v->Wxyz[1] > 0.0 && v->Wxyz[2] >= 0.0) { /* Normalise XYZ to current media white */ vc->Wxyz[0] = v->Wxyz[0]/v->Wxyz[1] * vc->Wxyz[1]; vc->Wxyz[2] = v->Wxyz[2]/v->Wxyz[1] * vc->Wxyz[1]; + *set = 1; } if (v->Wxyz[0] >= 0.0 && v->Wxyz[1] >= 0.0 && v->Wxyz[2] < 0.0) { /* Convert Yxy to XYZ */ @@ -2028,27 +2727,42 @@ main(int argc, char *argv[]) { double z = 1.0 - x - y; vc->Wxyz[0] = x/y * vc->Wxyz[1]; vc->Wxyz[2] = z/y * vc->Wxyz[1]; + *set = 1; } - if (v->La >= 0.0) + if (v->La >= 0.0) { vc->La = v->La; - if (v->Yb >= 0.0) + *set = 1; + } + if (v->Yb >= 0.0) { vc->Yb = v->Yb; - if (v->Lv >= 0.0) + *set = 1; + } + if (v->Lv >= 0.0) { vc->Lv = v->Lv; - if (v->Yf >= 0.0) + *set = 1; + } + if (v->Yf >= 0.0) { vc->Yf = v->Yf; - if (v->Fxyz[0] >= 0.0 && v->Fxyz[1] > 0.0 && v->Fxyz[2] >= 0.0) { + *set = 1; + } + if (v->Yg >= 0.0) { + vc->Yg = v->Yg; + *set = 1; + } + if (v->Gxyz[0] >= 0.0 && v->Gxyz[1] > 0.0 && v->Gxyz[2] >= 0.0) { /* Normalise XYZ to current media white */ - vc->Fxyz[0] = v->Fxyz[0]/v->Fxyz[1] * vc->Fxyz[1]; - vc->Fxyz[2] = v->Fxyz[2]/v->Fxyz[1] * vc->Fxyz[1]; + vc->Gxyz[0] = v->Gxyz[0]/v->Gxyz[1] * vc->Gxyz[1]; + vc->Gxyz[2] = v->Gxyz[2]/v->Gxyz[1] * vc->Gxyz[1]; + *set = 1; } - if (v->Fxyz[0] >= 0.0 && v->Fxyz[1] >= 0.0 && v->Fxyz[2] < 0.0) { + if (v->Gxyz[0] >= 0.0 && v->Gxyz[1] >= 0.0 && v->Gxyz[2] < 0.0) { /* Convert Yxy to XYZ */ - double x = v->Fxyz[0]; - double y = v->Fxyz[1]; /* If Y == 1.0, then X+Y+Z = 1/y */ + double x = v->Gxyz[0]; + double y = v->Gxyz[1]; /* If Y == 1.0, then X+Y+Z = 1/y */ double z = 1.0 - x - y; - vc->Fxyz[0] = x/y * vc->Fxyz[1]; - vc->Fxyz[2] = z/y * vc->Fxyz[1]; + vc->Gxyz[0] = x/y * vc->Gxyz[1]; + vc->Gxyz[2] = z/y * vc->Gxyz[1]; + *set = 1; } } @@ -2068,11 +2782,11 @@ main(int argc, char *argv[]) { /* the intents and pcsor appropriately. */ if (li.mode > 0) { - if ((li.gmi.usecas & 0xff) != 0) { + if ((li.gmi.usecas & 0xff) >= 0x2) { li.pcsor = icxSigJabData; /* Use CAM as PCS */ isJab = 1; - if ((li.gmi.usecas & 0xff) == 0x2) { /* Absolute Appearance space */ + if ((li.gmi.usecas & 0xff) == 0x3) { /* Absolute Appearance space */ double mxw; li.in.intent = li.out.intent = li.abs_intent = icxAbsAppearance; @@ -2090,13 +2804,16 @@ main(int argc, char *argv[]) { /* Set the output vc to be the same as the input */ li.out.vc = li.in.vc; /* Structure copy */ - } else { + } else { /* usecas & ff == 0x2 */ /* Not Abs Appearance space */ li.in.intent = li.out.intent = li.abs_intent = icxAppearance; } } else { - /* Not Appearance space */ - li.in.intent = li.out.intent = li.abs_intent = icAbsoluteColorimetric; + /* Not Appearance space - use L*a*b* */ + if ((li.gmi.usecas & 0xff) == 0) + li.in.intent = li.out.intent = li.abs_intent = icRelativeColorimetric; + else + li.in.intent = li.out.intent = li.abs_intent = icAbsoluteColorimetric; } } @@ -2114,13 +2831,15 @@ main(int argc, char *argv[]) { fl |= ICX_MERGE_CLUT; #endif -#ifdef NEVER - printf("~1 input space flags = 0x%x\n",fl); - printf("~1 input space intent = %s\n",icx2str(icmRenderingIntent,li.in.intent)); - printf("~1 input space pcs = %s\n",icx2str(icmColorSpaceSignature,li.pcsor)); - printf("~1 input space viewing conditions =\n"); xicc_dump_viewcond(&li.in.vc); - printf("~1 input space inking =\n"); xicc_dump_inking(&li.in.ink); -#endif + if (li.verb && li.mode > 0) { +// printf("Input space flags = 0x%x\n",fl); +// printf("Input space intent = %s\n",icx2str(icmRenderingIntent,li.in.intent)); +// printf("Input space pcs = %s\n",icx2str(icmColorSpaceSignature,li.pcsor)); + if (li.in.vc_set || li.out.vc_set) + printf("Input space viewing conditions =\n"), xicc_dump_viewcond(&li.in.vc); +// printf("Input space inking =\n"); xicc_dump_inking(&li.in.ink); + } + if ((li.in.luo = li.in.x->get_luobj(li.in.x, fl, icmFwd, li.in.intent, li.pcsor, icmLuOrdNorm, &li.in.vc, &li.in.ink)) == NULL) { error("get xlookup object failed: %d, %s",li.in.x->errc,li.in.x->err); @@ -2151,6 +2870,7 @@ main(int argc, char *argv[]) { && (li.in.alg == icmMatrixFwdType || li.in.alg == icmMatrixBwdType || li.in.csp == icSigXYZData)) { li.in.lcurve = 1; /* Use Y to L* and L* to Y for input */ + if (li.in.csp == icSigXYZData) { li.in.lcurve = 2; /* Use real Y to L* and L* to Y for input */ li.in.nocurve = 1; /* Don't trust the curve that comes with it */ @@ -2218,6 +2938,10 @@ main(int argc, char *argv[]) { /* Get native PCS space */ li.out.luo->lutspaces(li.out.luo, &natpcs, NULL, NULL, NULL, NULL); + /* Get details of overall conversion */ + li.out.luo->spaces(li.out.luo, NULL, NULL, &li.out.csp, &li.out.chan, &li.out.alg, + NULL, NULL, NULL); + } else { /* Using inverse A2B Lut for output conversion */ fl = flb; @@ -2230,13 +2954,14 @@ main(int argc, char *argv[]) { if (li.verb) printf("Loading output inverse A2B table\n"); -#ifdef NEVER - printf("~1 output space flags = 0x%x\n",fl); - printf("~1 output space intent = %s\n",icx2str(icmRenderingIntent,li.out.intent)); - printf("~1 output space pcs = %s\n",icx2str(icmColorSpaceSignature,li.pcsor)); - printf("~1 output space viewing conditions =\n"); xicc_dump_viewcond(&li.out.vc); - printf("~1 output space inking =\n"); xicc_dump_inking(&li.out.ink); -#endif + if (li.verb) { +// printf("Output space flags = 0x%x\n",fl); +// printf("Output space intent = %s\n",icx2str(icmRenderingIntent,li.out.intent)); +// printf("Output space pcs = %s\n",icx2str(icmColorSpaceSignature,li.pcsor)); + if (li.in.vc_set || li.out.vc_set) + printf("Output space viewing conditions =\n"), xicc_dump_viewcond(&li.out.vc); +// printf("Output space inking =\n"); xicc_dump_inking(&li.out.ink); + } if ((li.out.luo = li.out.x->get_luobj(li.out.x, fl, icmFwd, li.out.intent, li.pcsor, icmLuOrdNorm, &li.out.vc, @@ -2404,7 +3129,7 @@ main(int argc, char *argv[]) { if (li.out.nocurve == 0 && natpcs == icSigXYZData && (li.out.alg == icmMatrixFwdType || li.out.alg == icmMatrixBwdType || li.out.csp == icSigXYZData)) { - li.out.lcurve = 1; /* Use Y to L* and L* to Y for output */ + li.out.lcurve = 1; /* Use Y to L* and L* to Y for output */ if (li.out.csp == icSigXYZData) { li.out.lcurve = 2; /* Use real Y to L* and L* to Y for output */ li.out.nocurve = 1; /* Don't trust the curve that comes with it */ @@ -2414,6 +3139,138 @@ main(int argc, char *argv[]) { } } + /* - - - - - - - - - - - - - - - - - - - */ + /* Sanity checking */ + + if (li.cal != NULL) { + if (li.cal->colspace != li.out.csp) { + error("Calibration space %s doesn't match output profile %s", + icm2str(icmColorSpaceSignature, li.cal->colspace), + icm2str(icmColorSpaceSignature, li.out.csp)); + } + } + + if (li.tdlut) { + + /* eeColor format. */ + if (li.tdlut == 1) { + + if (li.in.csp != icSigRgbData) + error("Input profile must be RGB to output eeColor 3DLut"); + + if (li.out.csp != icSigRgbData) + error("Output profile must be RGB to output eeColor 3DLut"); + } + + /* MadVR format. */ + else if (li.tdlut == 2) { + + if (li.in.csp != icSigRgbData) + error("Input profile must be RGB to output MadVR 3DLut"); + + if (li.out.csp != icSigRgbData) + error("Output profile must be RGB to output MadVR 3DLut"); + } + + if (li.in.tvenc) { + if (li.in.csp != icSigRgbData) + error("Input profile must be RGB to use video encoding option"); + } + if (li.out.tvenc) { + if (li.out.csp != icSigRgbData) + error("Output profile must be RGB to use video encoding option"); + } + } + + /* 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 !!!! @@ -2466,6 +3323,14 @@ 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 */ @@ -2579,8 +3444,16 @@ main(int argc, char *argv[]) { /* Values that must be set before writing */ wh->deviceClass = icSigLinkClass; /* We are creating a link ! */ - wh->colorSpace = li.in.h->colorSpace; /* Input profile device space */ - wh->pcs = li.out.h->colorSpace; /* Output profile device space */ + if (li.in.tvenc >= 2) { + wh->colorSpace = icSigYCbCrData; /* Use YCbCr encoding */ + } else { + wh->colorSpace = li.in.h->colorSpace; /* Input profile device space */ + } + if (li.out.tvenc >= 2) { + wh->pcs = icSigYCbCrData; /* Use YCbCr encoding */ + } else { + wh->pcs = li.out.h->colorSpace; /* Output profile device space */ + } if (li.mode > 0) { wh->renderingIntent = li.gmi.icci; /* Closest ICC intent */ } else { @@ -2897,6 +3770,8 @@ main(int argc, char *argv[]) { /* 16 bit input device -> output device lut: */ { int inputEnt, outputEnt, clutPoints; + int *apxls_min = NULL, *apxls_max = NULL; + int tapxls_min[MAX_CHAN], tapxls_max[MAX_CHAN]; icmLut *wo; /* Setup the cLUT resolutions */ @@ -2933,7 +3808,7 @@ main(int argc, char *argv[]) { break; case 3: if (li.quality >= 3) - clutPoints = 52; + clutPoints = 53; else if (li.quality == 2) clutPoints = 33; else if (li.quality == 1) @@ -2945,7 +3820,7 @@ main(int argc, char *argv[]) { if (li.quality >= 3) clutPoints = 33; else if (li.quality == 2) - clutPoints = 18; + clutPoints = 17; else if (li.quality == 1) clutPoints = 9; else @@ -2953,15 +3828,15 @@ main(int argc, char *argv[]) { break; case 5: if (li.quality >= 3) - clutPoints = 18; + clutPoints = 17; else if (li.quality == 2) - clutPoints = 16; + clutPoints = 15; else clutPoints = 9; break; case 6: if (li.quality >= 3) - clutPoints = 12; + clutPoints = 13; else if (li.quality == 2) clutPoints = 9; else @@ -2969,7 +3844,7 @@ main(int argc, char *argv[]) { break; case 7: if (li.quality >= 3) - clutPoints = 8; + clutPoints = 9; else if (li.quality == 2) clutPoints = 7; else @@ -3004,6 +3879,47 @@ main(int argc, char *argv[]) { if (out_curve_res > outputEnt) outputEnt = out_curve_res; + /* Sanity checking */ + if (li.in.tvenc >= 2) { /* YCbCr encoded input */ + if ((clutPoints & 1) == 0) + warning("Making grid resolution is even - this is not ideal for YCbCr input"); + } + if (li.in.tvenc != 0 && clutPoints != 65 && clutPoints != 129 && clutPoints != 256) + warning("Video or YCbCr encoded inputs will work best with grid res. of 65 (got %d)",clutPoints); + if (li.tdlut == 1) { /* eeColor encoded input */ + if (clutPoints != 65) + warning("eeColor 3DLut needs grid resolution of 65 (got %d)",clutPoints); + inputEnt = 1024; + outputEnt = 4096; /* Ideally 8192 */ + + } else if (li.tdlut == 2) { + if (clutPoints != 65 && clutPoints != 129 && clutPoints != 256) + warning("MadVR 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 */ + /* Grid index is not adjusted if it's within 10% of device value limits */ + if (li.in.tvenc == 1) { /* Video 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); + apxls_max[i] = (int)(235.0/255.0 * (clutPoints-1.0) + 0.1); + } + } else if (li.in.tvenc >= 2) { /* 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); + } + } + /* Link Lut = AToB0 */ if ((wo = (icmLut *)wr_icc->add_tag( @@ -3018,6 +3934,11 @@ main(int argc, char *argv[]) { wo->clutPoints = clutPoints; wo->outputEnt = outputEnt; + if (clutPoints == 256) { /* MadVR special */ + wr_icc->allowclutPoints256 = 1; + warning("Creating non-standard 256 res. cLUT ICC profile !!!!"); + } + if (wo->allocate((icmBase *)wo) != 0) /* Allocate space */ error("allocate failed: %d, %s",wr_icc->errc,wr_icc->err); @@ -3033,29 +3954,55 @@ main(int argc, char *argv[]) { if (li.verb) printf("Filling in Lut table\n"); #ifdef DEBUG_ONE -#define DBGNO 1 /* Up to 10 */ +#define DBGNO 3 /* 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] = 1.0; - in[0][1] = 1.0; - in[0][2] = 1.0; +// in[0][0] = 0.2; +// in[0][1] = 0.2; +// in[0][2] = 0.8; + +// in[0][0] = 0.5; +// in[0][1] = 0.5; +// in[0][2] = 0.5; + +// in[0][0] = ((235-16)/255.0 * 0.5) + 16/255.0; +// in[0][1] = ((235-16)/255.0 * 0.5) + 16/255.0; +// in[0][2] = ((235-16)/255.0 * 0.5) + 16/255.0; + +// in[0][3] = 0.0; + +// in[0][0] = 16.0/255.0; +// in[0][1] = 16.0/255.0; +// 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[1][0] = 1.0; - in[1][1] = 1.0; - in[1][2] = 1.0; + 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; + for (i = 0; i < DBGNO; i++) { - printf("Input %f %f %f %f\n",in[i][0], in[i][1], in[i][2], in[i][3]); + printf("Input %f %f %f %*\n",in[i][0], in[i][1], in[i][2], in[i][3]); devi_devip((void *)&li, out, in[i]); + printf("Input' %f %f %f %*\n",out[0], out[1], out[2], out[3]); 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("Output %f %f %f %f\n\n",out[0], out[1], out[2], out[3]); + printf("Out %f %f %f %*\n\n",out[0], out[1], out[2], out[3]); } } #endif /* NEVER */ @@ -3069,8 +4016,13 @@ main(int argc, char *argv[]) { ; li.total = itotal; /* Allow for extra lookups due to ICM_CLUT_SET_APXLS */ - for (itotal = 1, ui = 0; ui < li.in.chan; ui++, itotal *= (clutPoints-1)) - ; + if (apxls_min != NULL && apxls_max != NULL) { + for (itotal = 1, ui = 0; ui < li.in.chan; ui++) + itotal *= (apxls_max[ui] - apxls_min[ui]); + } else { + for (itotal = 1, ui = 0; ui < li.in.chan; ui++) + itotal *= (clutPoints-1); + } li.total += itotal; li.count = 0; printf(" 0%%"); fflush(stdout); @@ -3086,7 +4038,8 @@ main(int argc, char *argv[]) { NULL, NULL, /* Use default input colorspace range */ devip_devop, /* devi' -> devo' transfer function */ NULL, NULL, /* Default output colorspace range */ - devop_devo /* Output transfer tables, devo'->devo */ + devop_devo, /* Output transfer tables, devo'->devo */ + apxls_min, apxls_max /* Limit APXLS to inside colorspace */ ) != 0) { error("Setting 16 bit Lut failed: %d, %s",wr_icc->errc,wr_icc->err); } @@ -3107,13 +4060,88 @@ 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 */ + /* 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. */ + if (li.in.tvenc) { + icmLut *lut; + double ival[MXDO]; /* Black input value */ + double oval[MXDO]; /* Correct output value for black */ + + if ((lut = (icmLut *)wr_icc->read_tag(wr_icc, icSigAToB0Tag)) == NULL) + error("unableto locate A2B tag: %d, %s",wr_icc->errc,wr_icc->err); + + ival[0] = ival[1] = ival[2] = 0.0; /* RGB black input */ + + /* 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 */ + icmRec601_RGBd_2_YPbPr(ival, ival); + icmRecXXX_YPbPr_2_YCbCr(ival, ival); + } else if (li.out.tvenc == 3) { /* 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 */ + 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 */ + icmRec2020_NCL_RGBd_2_YPbPr(ival, ival); + icmRecXXX_YPbPr_2_YCbCr(ival, ival); + } else if (li.out.tvenc == 6) { /* 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); + + /* 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 + 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]); + } + if (li.verb) printf("Writing out file\n"); /* Write the file out */ if ((rv = wr_icc->write(wr_icc,wr_fp,0)) != 0) error ("Write file: %d, %s",rv,wr_icc->err); - + + /* eeColor format */ + if (li.tdlut == 1) { + write_eeColor1DinputLuts(&li, tdlut_name); + if (write_eeColor3DLut(wr_icc, tdlut_name)) + error ("Write file '%s' failed",tdlut_name); + write_eeColor1DoutputLuts(&li, tdlut_name); + } + + /* MadVR format */ + else if (li.tdlut == 2) { + if (write_MadVR_3DLut(&li, wr_icc, tdlut_name)) + error ("Write file '%s' failed",tdlut_name); + } + wr_icc->del(wr_icc); wr_fp->del(wr_fp); @@ -3276,6 +4304,9 @@ main(int argc, char *argv[]) { li.abs_icc->del(li.abs_icc); li.abs_fp->del(li.abs_fp); } + if (li.cal != NULL) { + li.cal->del(li.cal); + } li.in.luo->del(li.in.luo); li.in.x->del(li.in.x); @@ -3290,9 +4321,420 @@ main(int argc, char *argv[]) { return 0; } +/* ===================================================================== */ +/* Write a eeColor 1DLut input LUT files */ +/* Return nz on error */ +int write_eeColor1DinputLuts(clink *li, char *tdlut_name) { + char fname[MAXNAMEL+1+20], *xl; + int i, j, k; + + for (j = 0; j < 3; j++) { + icmFile *fp; + double in[3], out[3]; + + strncpy(fname,tdlut_name,MAXNAMEL-1); fname[MAXNAMEL-1] = '\000'; + if ((xl = strrchr(fname, '.')) == NULL) /* Figure where extention is */ + xl = fname + strlen(fname); + + if (j == 0) + strcpy(xl,"-first1dred.txt"); + else if (j == 1) + strcpy(xl,"-first1dgreen.txt"); + else + strcpy(xl,"-first1dblue.txt"); + + if ((fp = new_icmFileStd_name(fname,"w")) == NULL) + error ("write_eeColor1DinputLuts: Can't open file '%s'",fname); + + 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. */ + + /* 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. */ + + /* 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]); + } + for (i = 0; i < lut->outputChan; i++) { + fp->gprintf(fp," %.6f",lut->clutTable[ix + i]); + } + + fp->gprintf(fp,"\n"); + + DC_INC(gc); + } + } + 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) { + 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; + + /* 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)) + == NULL) + error("write_eeColor3DLut: get luobj failed: %d, %s",icc->errc,icc->err); + + /* Cast to Lut lookup - safe because that's all that collink does */ + lut = (icmLuLut *)luo; + + /* Open up the 3dlut file for writing */ + if ((fp = new_icmFileStd_name(fname,"w")) == NULL) + error ("write_eeColor3DLut: Can't open file '%s'",fname); + + DC_INIT(gc); + + ord[0] = 1; ord[1] = 0; ord[2] = 2; /* Fastest to slowest G R B */ + + while (!DC_DONE(gc)) { + double in[3], out[3]; + + /* 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; + + 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]); + + for (i = 0; i < 3; i++) + fp->gprintf(fp," %.6f",out[i]); + for (i = 0; i < 3; i++) + fp->gprintf(fp," %.6f",out[i]); + + fp->gprintf(fp,"\n"); + + 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 */ +int write_eeColor1DoutputLuts(clink *li, char *tdlut_name) { + char fname[MAXNAMEL+1+20], *xl; + int i, j, k; + + for (j = 0; j < 3; j++) { + icmFile *fp; + double in[3], out[3]; + + strncpy(fname,tdlut_name,MAXNAMEL-1); fname[MAXNAMEL-1] = '\000'; + if ((xl = strrchr(fname, '.')) == NULL) /* Figure where extention is */ + xl = fname + strlen(fname); + + if (j == 0) + strcpy(xl,"-second1dred.txt"); + else if (j == 1) + strcpy(xl,"-second1dgreen.txt"); + else + strcpy(xl,"-second1dblue.txt"); + + if ((fp = new_icmFileStd_name(fname,"w")) == NULL) + error ("write_eeColor1DoutputLuts: Can't open file '%s'",fname); + + for (i = 0; i < 8192; i++) { + for (k = 0; k < 3; k++) + in[k] = i/(8192-1.0); + devop_devo((void *)li, out, in); + fp->gprintf(fp,"%.6f\n",out[j]); + } + + if (fp->del(fp)) + error ("write_eeColor1DoutputLuts to '%s' failed",fname); + } + return 0; +} + +/* ===================================================================== */ +/* Write MadVR 3dlut file */ + +/* Return nz on error */ +int write_MadVR_3DLut(clink *li, icc *icc, char *fname) { + icmFile *fp; + ORD8 *h; + int of, hoff, clutsize; + int dov2 = 0; + double rgbw[4][3] = { /* RGB + White Yxy */ + { 1.0, 0.0, 0.0 }, + { 0.0, 1.0, 0.0 }, + { 0.0, 0.0, 1.0 }, + { 1.0, 1.0, 1.0 } + }; + int i; + + icmLuBase *luo; + + /* Get an absolute conversion object to lookup primaries */ + if ((luo = li->in.c->get_luobj(li->in.c, icmFwd, icAbsoluteColorimetric, icmSigDefaultData, icmLuOrdNorm)) + == NULL) + error ("write_MadVR_3DLut: %d, %s",icc->errc, icc->err); + + for (i = 0; i < 4; i++) { + if (luo->lookup(luo, rgbw[i], rgbw[i]) > 1) + error ("write_MadVR_3DLut: %d, %s",icc->errc,icc->err); + + icmXYZ2Yxy(rgbw[i], rgbw[i]); + } + + luo->del(luo); + + /* 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_MadVR_3DLut: %d, %s",icc->errc, icc->err); + + /* Open up the 3dlut file for writing */ + if ((fp = new_icmFileStd_name(fname,"w")) == NULL) + error("write_MadVR_3DLut: Can't open file '%s'",fname); + + /* Create the 3dlutheader */ + if ((h = (ORD8 *)calloc(0x4000, sizeof(ORD8))) == NULL) + error("write_MadVR_3DLut: failed to calloc 16384 bytes"); + + of = 0; + if (dov2) { + h[0] = '3'; h[1] = 'D'; h[2] = 'L'; h[3] = '2'; of += 4; /* Signature */ + } else { + h[0] = '3'; h[1] = 'D'; h[2] = 'L'; h[3] = 'T'; of += 4; /* Signature */ + } + write_ORD32_le(1, h + of); of += 4; /* File format version */ + strncpy((char *)h+of, "ArgyllCMS collink", 31); of += 32; /* Creation program */ + write_ORD64_le(ARGYLL_VERSION, h + of); of += 8; /* Program version */ + 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 */ + 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 */ + 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 */ + hoff = 0x200; + hoff += sprintf((char *)h+hoff, "Input_Primaries %f %f %f %f %f %f %f %f\r\n", /* For V0.66+ */ + rgbw[0][1], rgbw[0][2], rgbw[1][1], rgbw[1][2], + rgbw[2][1], rgbw[2][2], rgbw[3][1], rgbw[3][2]); +// hoff += sprintf((char *)h+hoff, "Input_Transfer_Function 1.0 0.0 0.45454545454545454545454545454545 0.0"); + + if (li->in.tvenc == 0) + hoff += sprintf((char *)h+hoff, "Input_Range 0 255\r\n"); + else + hoff += sprintf((char *)h+hoff, "Input_Range 16 235\r\n"); + if (li->out.tvenc == 0) + hoff += sprintf((char *)h+hoff, "Output_Range 0 255\r\n"); + else + hoff += sprintf((char *)h+hoff, "Output_Range 16 235\r\n"); + write_ORD32_le(hoff - 0x200 + 1, h + of); of += 4; /* Bytes of parameter data + nul */ + write_ORD32_le(0x4000, h + of); of += 4; /* Bytes to clut data */ + write_ORD32_le(0, h + of); of += 4; /* No compression */ + clutsize = (1 << (3 * 8)) * 3 * 2; + write_ORD32_le(clutsize, h + of); of += 4; /* Compressed clut size */ + write_ORD32_le(clutsize, h + of); of += 4; /* Uncompressed clut size */ + + if (li->verb) + printf("Writing 3dLut\n"); + + /* Write the 3dlutheader */ + if (fp->write(fp, h, 1, 0x4000) != 0x4000) + error ("write_MadVR_3DLut: write header failed"); + + /* Write the clut data */ + { + int i, j, k; + DCOUNT(gc, MAX_CHAN, 3, 0, 0, 256); + int ord[3]; /* Input channel order, fastest to slowest */ + ORD8 buf[3 * 2]; + + DC_INIT(gc); + + if (li->in.tvenc >= 2) { /* 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 */ + ord[0] = 2; ord[1] = 1; ord[2] = 0; /* B G R */ + } + + while (!DC_DONE(gc)) { + double in[3], out[3]; + int iout[3]; + + for (i = 0; i < 3; i++) + in[ord[i]] = gc[i]/255.0; + + if (luo->lookup(luo, out, in) > 1) + error ("write_MadVR_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]); + + if (li->in.tvenc == 7 || li->in.tvenc == 8) { /* xvYCC */ + for (i = 1; i < 3; i++) { /* Force 'sync' entry values on CbCr*/ + if (gc[i] == 0) { + out[i] = 0.0; + } else if (gc[i] == 255) { + out[i] = 1.0; + } + } + } + + if (li->out.tvenc == 0) { /* Full range 16 bits */ + iout[0] = (int)(out[0] * 0xffff + 0.5); + iout[1] = (int)(out[1] * 0xffff + 0.5); + iout[2] = (int)(out[2] * 0xffff + 0.5); + + } else { /* TV encoding - shifted by 8 bits */ + iout[0] = (int)(out[0] * 0xff00 + 0.5); + iout[1] = (int)(out[1] * 0xff00 + 0.5); + iout[2] = (int)(out[2] * 0xff00 + 0.5); + + } + + if (li->out.tvenc >= 2) { /* 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); + + } else { /* RGB order is BGR */ + write_ORD16_le(iout[2], buf + 0); + write_ORD16_le(iout[1], buf + 2); + write_ORD16_le(iout[0], buf + 4); + } + + if (fp->write(fp, buf, 1, 6) != 6) + error ("write_MadVR_3DLut: write clut data failed"); + + DC_INC(gc); + } + } + + /* Append a cal1 table to the 3dlut. */ + /* This can be used to ensure that the Graphics Card VideoLuts */ + /* are correctly setup to match what the 3dLut is expecting. */ + + /* Note that the calibration is full range, never TV encoded output values */ + + /* Format is (little endian): + 4 byte magic number 'cal1' + 4 byte version = 1 + 4 byte number per channel entries = 256 + 4 byte bytes per entry = 2 + [3][256] 2 byte entry values. Tables are in RGB order + */ + if (li->cal != NULL) { + ORD8 buf[4 * 4 + 3 * 256 * 2], *of = buf; + ORD32 magic, vers, entries, depth; + unsigned int val; + int i, j; + + if (li->verb) + printf("Appending %scalibration curves\n", li->addcal == 2 ? "" : "linear"); + + magic = ('c') + + ('a' << 8) + + ('l' << 16) + + ('1' << 24); + write_ORD32_le(magic, of); of += 4; /* Magic number */ + + vers = 1; + write_ORD32_le(vers, of); of += 4; /* Format version */ + + entries = 256; + write_ORD32_le(entries, of); of += 4; /* Number of entries per channel */ + + depth = 2; + write_ORD32_le(depth, of); of += 4; /* Depth per entry in bytes */ + + for (j = 0; j < 3; j++) { + for (i = 0; i < 256; i++) { + double v = i/255.0; + + if (li->addcal == 2) + v = li->cal->interp_ch(li->cal, j, v); + val = (int)(v * 65535.0 + 0.5); + write_ORD16_le(val, of); of += 2; + } + } + if (fp->write(fp, buf, 1, sizeof(buf)) != sizeof(buf)) + error ("write_MadVR_3DLut: write cal1 data failed"); + } + + if (fp->del(fp)) + error ("write_MadVR_3DLut: write to '%s' failed",fname); + luo->del(luo); + + return 0; +} -- cgit v1.2.3