diff options
Diffstat (limited to 'gamut/gammap.c')
-rw-r--r--[-rwxr-xr-x] | gamut/gammap.c | 667 |
1 files changed, 318 insertions, 349 deletions
diff --git a/gamut/gammap.c b/gamut/gammap.c index e276b99..638a2cd 100755..100644 --- a/gamut/gammap.c +++ b/gamut/gammap.c @@ -65,9 +65,13 @@ #undef PLOT_LMAP /* [Und] Plot L map */ #undef PLOT_GAMUTS /* [Und] Save (part mapped) input and output gamuts as */ /* src.wrl, img.wrl, dst.wrl, gmsrc.wrl */ -#undef PLOT_3DKNEES /* [Und] Plot each 3D compression knee */ +#undef PLOT_3DKNEES /* [Und] Plot the 3D compression knees */ #undef CHECK_NEARMAP /* [Und] Check how accurately near map vectors are represented by rspl */ -#undef DUMP_GREY_AXIS_POINTS /* [Und] Dump grey axis map 3d->3d points */ + +#define USE_GLUMKNF /* [Define] Enable luminence knee function points */ +#define USE_GREYMAP /* [Define] Enable 3D->3D mapping points down the grey axis */ +#define USE_GAMKNF /* [Define] Enable 3D knee function points */ +#define USE_BOUND /* [Define] Enable grid boundary anchor points */ #undef SHOW_NEIGBORS /* [Und] Show nearsmth neigbors in gammap.wrl */ @@ -76,13 +80,6 @@ #define XRES 100 /* [100] Res of plots */ - /* Functionality */ -#define USE_GLUMKNF /* [Define] Enable luminence knee function points else linear */ -#define USE_GREYMAP /* [Define] Enable 3D->3D mapping points down the grey axis */ -#define USE_GAMKNF /* [Define] Enable 3D knee function points */ -#define USE_BOUND /* [Define] Enable grid boundary anchor points */ - - /* The locus.ts file can contain source locus(es) that will be plotted */ /* as cones in red, with the destination plotted in white. They can */ /* be created from .tif files using xicc/tiffgmts utility. */ @@ -151,6 +148,7 @@ struct { #include <fcntl.h> #include <string.h> #include <math.h> +#include "counters.h" #include "icc.h" #include "numlib.h" #include "xicc.h" @@ -170,17 +168,11 @@ typedef struct { double satenh; /* Saturation engancement value */ } adjustsat; -/* Callback context for fixing 1D Lut white and black points */ -typedef struct { - double twb[2], awb[2]; /* Target and Actual black, white */ -} adjust1wb; - /* Callback context for making clut relative to white and black points */ typedef struct { double mat[3][4]; } adjustwb; -static void adjust1_wb_func(void *pp, double *out, double *in); static void inv_grey_func(void *pp, double *out, double *in); static void adjust_wb_func(void *pp, double *out, double *in); static void adjust_sat_func(void *pp, double *out, double *in); @@ -200,7 +192,7 @@ gammapweights pweights[] = { { 0.1, /* Cusp luminance alignment weighting 0 = none, 1 = full */ 0.0, /* Cusp chroma alignment weighting 0 = none, 1 = full */ - 0.2 /* Cusp hue alignment weighting 0 = none, 1 = full */ + 0.3 /* Cusp hue alignment weighting 0 = none, 1 = full */ }, 2.0, /* Alignment twist power, 0 = linear, 1 = curve, 2+ late curve */ 1.00 /* Chroma expansion 1 = none */ @@ -214,9 +206,9 @@ gammapweights pweights[] = { 1.0, /* Absolute error overall weight */ 0.8, /* Hue dominance vs l+c, 0 - 1 */ - 0.8, /* [0.8] White l dominance vs, c, 0 - 1 */ - 0.45, /* [0.45] Grey l dominance vs, c, 0 - 1 */ - 0.94, /* [0.94] Black l dominance vs, c, 0 - 1 */ + 0.8, /* White l dominance vs, c, 0 - 1 */ + 0.5, /* Grey l dominance vs, c, 0 - 1 */ + 0.97, /* Black l dominance vs, c, 0 - 1 */ 0.4, /* White l blend start radius, 0 - 1, at white = 0 */ 0.7, /* Black l blend power, linear = 1.0, enhance < 1.0 */ @@ -225,15 +217,14 @@ gammapweights pweights[] = { 10.0 /* L error extra xover threshold in DE */ }, { /* Relative vector smoothing */ - 20.0, 30.0, /* Relative Smoothing radius L* H* */ - 0.9 /* Degree of smoothing */ + 25.0, 35.0 /* Relative Smoothing radius L* H* */ }, { /* Weighting of excessive compression error, which is */ /* the src->dst vector length over the available dst depth. */ /* The depth is half the distance to the intersection of the */ /* vector to the other side of the gamut. (doesn't get triggered much ?) */ - 5.0, /* [5] Compression depth weight */ - 5.0 /* [5] Expansion depth weight */ + 10.0, /* Compression depth weight */ + 10.0 /* Expansion depth weight */ }, { 0.0 /* Fine tuning expansion weight, 0 - 1 */ @@ -270,8 +261,7 @@ gammapweights pweights[] = { -1.0 /* L error xover threshold in DE */ }, { /* Relative error preservation using smoothing */ - 20.0, 10.0, /* Relative Smoothing radius L* H* */ - 0.5 /* Degree of smoothing */ + 20.0, 10.0 /* Relative Smoothing radius L* H* */ }, { /* Weighting of excessive compression error, which is */ /* the src->dst vector length over the available dst depth. */ @@ -303,7 +293,7 @@ gammapweights pweights[] = { }, { /* Weighting of absolute error of destination from source */ -1.0, /* Absolute error overall weight */ - -1.0, /* Hue dominance vs l+c, 0 - 1 */ + 0.8, /* Hue dominance vs l+c, 0 - 1 */ -1.0, /* White l dominance vs, c, 0 - 1 */ -1.0, /* Grey l dominance vs, c, 0 - 1 */ @@ -316,8 +306,7 @@ gammapweights pweights[] = { -1.0 /* L error xover threshold in DE */ }, { /* Relative error preservation using smoothing */ - -1.0, 15.0, /* Relative Smoothing radius L* H* */ - -1.0 /* Degree of smoothing */ + -1.0, 15.0 /* Relative Smoothing radius L* H* */ }, { /* Weighting of excessive compression error, which is */ /* the src->dst vector length over the available dst depth. */ @@ -335,61 +324,7 @@ gammapweights pweights[] = { gmm_end, } }; -double psmooth = 2.0; /* [2.0] Level of RSPL smoothing for perceptual, 1 = nominal */ - -/* Lightness Preserving Perceptual mapping weights, where preserving lightness */ -/* and hue has the highest priority, followed by smoothness and proportionality. */ -/* Chroma is basically sacrificed. */ -gammapweights lpweights[] = { - { - gmm_default, /* Non hue specific defaults */ - { /* Cusp alignment control */ - { - 0.0, /* [0.2] Cusp luminance alignment weighting 0 = none, 1 = full */ - 0.0, /* [0.0] Cusp chroma alignment weighting 0 = none, 1 = full */ - 0.0 /* [0.3] Cusp hue alignment weighting 0 = none, 1 = full */ - }, - 2.0, /* Alignment twist power, 0 = linear, 1 = curve, 2+ late curve */ - 1.00 /* Chroma expansion 1 = none */ - }, - { /* Radial weighting (currently broken - need to fix) */ - 0.0, /* Radial error overall weight, 0 + */ - 0.1, /* Radial hue dominance vs l+c, 0 - 1 */ - 1.0 /* Radial l dominance vs, c, 0 - 1 */ - }, - { /* Weighting of absolute error of destination from source */ - 1.0, /* Absolute error overall weight */ - 0.90, /* [0.9] Hue dominance vs l+c, 0 - 1 */ - - 0.98, /* White l dominance vs, c, 0 - 1 */ - 0.95, /* Grey l dominance vs, c, 0 - 1 */ - 0.99, /* Black l dominance vs, c, 0 - 1 */ - - 0.4, /* White l blend start radius, 0 - 1, at white = 0 */ - 0.7, /* Black l blend power, linear = 1.0, enhance < 1.0 */ - - 1.0, /* L error extra power with size, none = 1.0 */ - 100.0 /* L error extra xover threshold in DE */ - }, - { /* Relative vector smoothing */ - 6.0, 30.0, /* Relative Smoothing radius L* H* */ - 0.9 /* [0.9] Degree of smoothing */ - }, - { /* Weighting of excessive compression error, which is */ - /* the src->dst vector length over the available dst depth. */ - /* (This compromizes constanl L near white and black, so minimize) */ - 0.0, /* Compression depth weight */ - 0.0 /* Expansion depth weight */ - }, - { - 0.0 /* Fine tuning expansion weight, 0 - 1 */ - } - }, - { - gmm_end, - } -}; -double lpsmooth = 1.0; /* [1.0] Level of RSPL smoothing for ligtness pres perc, 1 = nominal */ +double psmooth = 4.0; /* [5.0] Level of RSPL smoothing for perceptual, 1 = nominal */ /* Saturation mapping weights, where saturation has priority over smoothness */ gammapweights sweights[] = { @@ -414,25 +349,24 @@ gammapweights sweights[] = { 0.4, /* Hue dominance vs l+c, 0 - 1 */ 0.6, /* White l dominance vs, c, 0 - 1 */ - 0.3, /* Grey l dominance vs, c, 0 - 1 */ - 0.7, /* Black l dominance vs, c, 0 - 1 */ + 0.4, /* Grey l dominance vs, c, 0 - 1 */ + 0.6, /* Black l dominance vs, c, 0 - 1 */ 0.5, /* wl blend start radius, 0 - 1 */ 1.0, /* bl blend power, linear = 1.0, enhance < 1.0 */ - 1.5, /* L error extra power with size, none = 1.0 */ - 20.0 /* L error extra xover threshold in DE */ + 1.0, /* L error extra power with size, none = 1.0 */ + 10.0 /* L error extra xover threshold in DE */ }, { /* Relative vector smoothing */ - 15.0, 20.0, /* Relative Smoothing radius L* H* */ - 0.8 /* [0.8] Degree of smoothing */ + 20.0, 25.0 /* Relative Smoothing radius L* H* */ }, { /* Weighting of excessive compression error, which is */ /* the src->dst vector length over the available dst depth. */ /* The depth is half the distance to the intersection of the */ /* vector to the other side of the gamut. (doesn't get triggered much ?) */ - 5.0, /* Compression depth weight */ - 5.0 /* Expansion depth weight */ + 10.0, /* Compression depth weight */ + 10.0 /* Expansion depth weight */ }, { 0.5 /* Fine tuning expansion weight, 0 - 1 */ @@ -469,8 +403,7 @@ gammapweights sweights[] = { -1.0 /* L error xover threshold in DE */ }, { /* Relative error preservation using smoothing */ - 10.0, 15.0, /* Relative smoothing radius */ - 0.5 /* Degree of smoothing */ + 10.0, 15.0 /* Relative smoothing radius */ }, { /* Weighting of excessive compression error, which is */ /* the src->dst vector length over the available dst depth. */ @@ -487,9 +420,7 @@ gammapweights sweights[] = { gmm_end } }; -/* The cusp alignment tends to upset the vector smoothing (not exactly sure why), */ -/* so use more rspl smoothing to compensate. */ -double ssmooth = 4.0; /* [1.0] Level of RSPL smoothing for saturation */ +double ssmooth = 2.0; /* Level of RSPL smoothing for saturation */ /* * Notes: @@ -520,7 +451,7 @@ static void map_trans(void *cntx, double out[3], double in[3]); gammap *new_gammap( int verb, /* Verbose flag */ gamut *sc_gam, /* Source colorspace gamut */ - gamut *isi_gam, /* Input source image gamut (NULL if none) */ + gamut *si_gam, /* Source image gamut (NULL if none) */ gamut *d_gam, /* Destination colorspace gamut */ icxGMappingIntent *gmi, /* Gamut mapping specification */ int src_kbp, /* Use K only black point as src gamut black point */ @@ -532,10 +463,9 @@ gammap *new_gammap( double *mx, /* for rspl grid. */ char *diagname /* If non-NULL, write a gamut mapping diagnostic WRL */ ) { - gammap *s; /* This */ - gamut *si_gam = NULL; /* Source image gamut (intersected with sc_gam) */ - gamut *scl_gam; /* Source colorspace gamut with rotation and L mapping applied */ - gamut *sil_gam; /* Source image gamut with rotation and L mapping applied */ + gammap *s; /* This */ + gamut *scl_gam; /* Source colorspace gamut with rotation and L mapping applied */ + gamut *sil_gam; /* Source image gamut with rotation and L mapping applied */ double s_cs_wp[3]; /* Source colorspace white point */ double s_cs_bp[3]; /* Source colorspace black point */ @@ -561,11 +491,7 @@ gammap *new_gammap( double d_mt_wp[3]; /* Overall destination mapping white point (used for finetune) */ double d_mt_bp[3]; /* Overall destination mapping black point (used for finetune) */ -#ifdef USE_BOUND - int surfpnts = 1; /* Add grid surface anchor points */ -#else - int surfpnts = 0; /* Don't add grid surface points */ -#endif + int defrgrid = 6; /* mapping range surface default anchor point resolution */ int nres = 512; /* Neutral axis resolution */ cow lpnts[10]; /* Mapping points to create grey axis map */ int revrspl = 0; /* Reverse grey axis rspl construction */ @@ -578,14 +504,10 @@ gammap *new_gammap( # pragma message("################ A gammap.c PLOT is #defined #########################") #endif -#ifndef USE_BOUND -# pragma message("################ gammap.c USE_BOUND not set #########################") -#endif - if (verb) { xicc_dump_gmi(gmi); printf("Gamut map resolution: %d\n",mapres); - if (isi_gam != NULL) + if (si_gam != NULL) printf("Image gamut supplied\n"); } @@ -600,15 +522,18 @@ gammap *new_gammap( /* Now create everything */ - /* Grab the colorspace white and black points */ + /* Grab the white and black points */ if (src_kbp) { - if (sc_gam->getwb(sc_gam, s_cs_wp, NULL, s_cs_bp, NULL, NULL, NULL)) { + // ~~99 Hmm. Shouldn't this be colorspace rather than gamut ???? + if (sc_gam->getwb(sc_gam, NULL, NULL, NULL, s_cs_wp, NULL, s_cs_bp)) { +// if (sc_gam->getwb(sc_gam, s_cs_wp, NULL, s_cs_bp, NULL, NULL, NULL)) fprintf(stderr,"gamut map: Unable to read source colorspace white and black points\n"); free(s); return NULL; } } else { - if (sc_gam->getwb(sc_gam, s_cs_wp, s_cs_bp, NULL, NULL, NULL, NULL)) { + if (sc_gam->getwb(sc_gam, NULL, NULL, NULL, s_cs_wp, s_cs_bp, NULL)) { +// if (sc_gam->getwb(sc_gam, s_cs_wp, s_cs_bp, NULL, NULL, NULL, NULL)) fprintf(stderr,"gamut map: Unable to read source colorspace white and black points\n"); free(s); return NULL; @@ -616,40 +541,16 @@ gammap *new_gammap( } /* If source space is source gamut */ - if (isi_gam == NULL || isi_gam == sc_gam) { + if (si_gam == NULL) { si_gam = sc_gam; for (j = 0; j < 3; j++) { s_ga_wp[j] = s_cs_wp[j]; s_ga_bp[j] = s_cs_bp[j]; } - /* Else have explicit image gamut */ + /* Else have explicit sourcegamut */ } else { -#ifdef VERBOSE - if (verb) { /* Check that image gamut is within colorspace */ - double scwp[3], scbp[3]; - double imwp[3], imbp[3]; - - sc_gam->getwb(sc_gam, NULL, NULL, NULL, scwp, scbp, NULL); - isi_gam->getwb(isi_gam, NULL, NULL, NULL, imwp, imbp, NULL); - - if (imwp[0] > (scwp[0] + 1e-4) - || imbp[0] < (scbp[0] - 1e-4)) { - printf("Warning: image gamut is bigger than src colorspace!\n"); - } - - } -#endif - /* Intersect it with the source colorspace gamut in case */ - /* something strange is going on. (mismatched appearance params ?) */ - if ((si_gam = new_gamut(0.0, 0, 0)) == NULL) { - fprintf(stderr,"gamut map: new_gamut failed\n"); - free(s); - return NULL; - } - si_gam->intersect(si_gam, isi_gam, sc_gam); - if (src_kbp) { if (si_gam->getwb(si_gam, NULL, NULL, NULL, s_ga_wp, NULL, s_ga_bp)) { fprintf(stderr,"gamut map: Unable to read source gamut white and black points\n"); @@ -663,21 +564,42 @@ gammap *new_gammap( return NULL; } } + + /* Guard against silliness. Image must be within colorspace */ + if (s_ga_wp[0] > s_cs_wp[0]) { + int j; + double t; +#ifdef VERBOSE + if (verb) + printf("Fixing wayward image white point\n"); +#endif + t = (s_cs_wp[0] - s_ga_bp[0])/(s_ga_wp[0] - s_ga_bp[0]); + for (j = 0; j < 3; j++) + s_ga_wp[j] = s_ga_bp[j] + t * (s_ga_wp[j] - s_ga_bp[j]); + + } + if (s_ga_bp[0] < s_cs_bp[0]) { + int j; + double t; +#ifdef VERBOSE + if (verb) + printf("Fixing wayward image black point\n"); +#endif + t = (s_cs_bp[0] - s_ga_wp[0])/(s_ga_bp[0] - s_ga_wp[0]); + for (j = 0; j < 3; j++) + s_ga_bp[j] = s_ga_wp[j] + t * (s_ga_bp[j] - s_ga_wp[j]); + } } if (dst_kbp) { if (d_gam->getwb(d_gam, NULL, NULL, NULL, d_cs_wp, NULL, d_cs_bp)) { fprintf(stderr,"gamut map: Unable to read destination white and black points\n"); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } } else { if (d_gam->getwb(d_gam, NULL, NULL, NULL, d_cs_wp, d_cs_bp, NULL)) { fprintf(stderr,"gamut map: Unable to read destination white and black points\n"); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } @@ -950,7 +872,7 @@ glumknf = 1.0; /* If we have a gamut (ie. image) range that is smaller than the */ /* L range of the colorspace, then use its white and black L values */ /* as the source to be compressed to the destination L range. */ - /* We expand only a colorspace range, not an image gamut range. */ + /* We expand only a colorspace range, not a gamut/image range. */ { double swL, dwL; /* Source and destination white point L */ double sbL, dbL; /* Source and destination black point L */ @@ -963,14 +885,14 @@ glumknf = 1.0; dwL = gmi->glumwexf * dr_cs_wp[0] + (1.0 - gmi->glumwexf) * sr_cs_wp[0]; } else { - if (sr_cs_wp[0] > dr_cs_wp[0]) { /* Colorspace needs compression */ + if (sr_ga_wp[0] > dr_cs_wp[0]) { /* Gamut or colorspace needs compression */ - swL = (1.0 - gmi->glumwcpf) * dr_cs_wp[0] + gmi->glumwcpf * sr_cs_wp[0]; + swL = (1.0 - gmi->glumwcpf) * dr_cs_wp[0] + gmi->glumwcpf * sr_ga_wp[0]; dwL = dr_cs_wp[0]; } else { /* Neither needed */ - swL = sr_cs_wp[0]; - dwL = sr_cs_wp[0]; + swL = sr_ga_wp[0]; + dwL = sr_ga_wp[0]; } } @@ -980,14 +902,14 @@ glumknf = 1.0; dbL = gmi->glumbexf * dr_cs_bp[0] + (1.0 - gmi->glumbexf) * sr_cs_bp[0]; } else { - if (sr_cs_bp[0] < dr_cs_bp[0]) { /* Colorspace needs compression */ + if (sr_ga_bp[0] < dr_cs_bp[0]) { /* Gamut or colorspace needs compression */ - sbL = (1.0 - gmi->glumbcpf) * dr_cs_bp[0] + gmi->glumbcpf * sr_cs_bp[0]; + sbL = (1.0 - gmi->glumbcpf) * dr_cs_bp[0] + gmi->glumbcpf * sr_ga_bp[0]; dbL = dr_cs_bp[0]; } else { /* Neither needed */ - sbL = sr_cs_bp[0]; - dbL = sr_cs_bp[0]; + sbL = sr_ga_bp[0]; + dbL = sr_ga_bp[0]; } } @@ -1046,21 +968,24 @@ glumknf = 1.0; lpnts[ngreyp].v[0] = dbL; lpnts[ngreyp++].w = 10.0; /* Must go through here */ -#ifndef USE_GLUMKNF - /* make sure curve is firmly anchored */ - lpnts[ngreyp].p[0] = 0.3 * lpnts[ngreyp-1].p[0] + 0.7 * lpnts[ngreyp-2].p[0]; - lpnts[ngreyp].v[0] = 0.3 * lpnts[ngreyp-1].v[0] + 0.7 * lpnts[ngreyp-2].v[0]; - lpnts[ngreyp++].w = 1.0; - - lpnts[ngreyp].p[0] = 0.7 * lpnts[ngreyp-2].p[0] + 0.3 * lpnts[ngreyp-3].p[0]; - lpnts[ngreyp].v[0] = 0.7 * lpnts[ngreyp-2].v[0] + 0.3 * lpnts[ngreyp-3].v[0]; - lpnts[ngreyp++].w = 1.0; -#else /* USE_GLUMKNF */ - { - double cppos = 0.50; /* [0.50] Center point ratio between black and white */ +#ifdef USE_GLUMKNF + if (gmi->glumknf < 0.05) +#endif /* USE_GLUMKNF */ + { /* make sure curve is firmly anchored */ + lpnts[ngreyp].p[0] = 0.3 * lpnts[ngreyp-1].p[0] + 0.7 * lpnts[ngreyp-2].p[0]; + lpnts[ngreyp].v[0] = 0.3 * lpnts[ngreyp-1].v[0] + 0.7 * lpnts[ngreyp-2].v[0]; + lpnts[ngreyp++].w = 1.0; + + lpnts[ngreyp].p[0] = 0.7 * lpnts[ngreyp-2].p[0] + 0.3 * lpnts[ngreyp-3].p[0]; + lpnts[ngreyp].v[0] = 0.7 * lpnts[ngreyp-2].v[0] + 0.3 * lpnts[ngreyp-3].v[0]; + lpnts[ngreyp++].w = 1.0; + } +#ifdef USE_GLUMKNF + else { /* There is at least some weight in knee points */ + double cppos = 0.50; /* Center point ratio between black and white */ double cpll, cplv; /* Center point location and value */ - double kpwpos = 0.30; /* [0.30] White knee point location prop. towards center */ - double kpbpos = 0.15; /* [0.15] Black knee point location prop. towards center */ + double kpwpos = 0.30; /* White knee point location prop. towards center */ + double kpbpos = 0.20; /* Black knee point location prop. towards center */ double kwl, kbl, kwv, kbv; /* Knee point values and locations */ double kwx, kbx; /* Knee point extra */ @@ -1069,20 +994,20 @@ glumknf = 1.0; printf("%sdbL = %f, dwL = %f\n", revrspl ? "(swapped) ": "", dbL,dwL); #endif - /* Center point location. Make lightly weighted */ - /* center the perceptual source, to try and maintain */ - /* the absolute source grey in the output, while */ - /* still allowing some of the knee compression/expansion to creep */ - /* into the other half. */ + /* Center point location */ cpll = cppos * (swL - sbL) + sbL; + // ~~?? would this be better if the output + // was scaled by dwL/swL ? cplv = cppos * (swL - sbL) + sbL; #ifdef PLOT_LMAP printf("cpll = %f, cplv = %f\n",cpll, cplv); #endif - /* Add weakish center point */ + +#ifdef NEVER /* Don't use a center point */ lpnts[ngreyp].p[0] = cpll; lpnts[ngreyp].v[0] = cplv; - lpnts[ngreyp++].w = 0.5; + lpnts[ngreyp++].w = 5.0; +#endif //printf("~1 black half diff = %f\n",dbL - sbL); //printf("~1 white half diff = %f\n",dwL - swL); @@ -1096,7 +1021,7 @@ glumknf = 1.0; // ~~ weigting of black point and white point differences kwx = 0.6 * (dbL - sbL) + 1.0 * (swL - dwL); kbx = 1.0 * (dbL - sbL) + 0.6 * (swL - dwL); - + //kwx = 0.0; //kbx = 0.0; //glumknf = 0.0; @@ -1110,6 +1035,7 @@ glumknf = 1.0; if (kbv < dbL) /* Sanity check */ kbv = dbL; + #ifdef PLOT_LMAP printf("using kbl = %f, kbv = %f\n",kbl, kbv); printf("using kwl = %f, kwv = %f\n",kwl, kwv); @@ -1119,110 +1045,68 @@ glumknf = 1.0; lpnts[ngreyp].p[0] = kwl; lpnts[ngreyp].v[0] = kwv; lpnts[ngreyp++].w = gmi->glumknf * gmi->glumknf; - + /* Emphasise points to cause black "knee" curve */ lpnts[ngreyp].p[0] = kbl; lpnts[ngreyp].v[0] = kbv; lpnts[ngreyp++].w = 1.5 * gmi->glumknf * 1.5 * gmi->glumknf; } #endif /* USE_GLUMKNF */ + } - /* Create RSPL */ - { - datai il, ih; - datao ol, oh; - double avgdev[MXDO]; - int gres = 256; - - /* Create a 1D rspl, that is used to */ - /* form the overall L compression mapping. */ - if ((s->grey = new_rspl(RSPL_NOFLAGS, 1, 1)) == NULL) /* Allocate 1D -> 1D */ - error("gamut: grey new_rspl failed"); - - il[0] = -1.0; /* Set possible input range */ - ih[0] = 101.0; - ol[0] = 0.0; /* Set normalisation output range */ - oh[0] = 100.0; + /* We now create the 1D rspl L map, that compresses or expands the luminence */ + /* range, independent of grey axis alignment, or gamut compression. */ + /* Because the rspl isn't symetrical when we swap X & Y, and we would */ + /* like a conversion from profile A to B to be the inverse of profile B to A */ + /* (as much as possible), we contrive here to always create a compression */ + /* RSPL, and create an inverse for it, and swap the two of them so that */ + /* the transform is correct and has an accurate inverse available. */ + { + datai il, ih; + datao ol, oh; + double avgdev[MXDO]; + int gres = 256; + + /* Create a 1D rspl, that is used to */ + /* form the overall L compression mapping. */ + if ((s->grey = new_rspl(RSPL_NOFLAGS, 1, 1)) == NULL) /* Allocate 1D -> 1D */ + error("gamut: grey new_rspl failed"); + + il[0] = -1.0; /* Set possible input range */ + ih[0] = 101.0; + ol[0] = 0.0; /* Set normalisation output range */ + oh[0] = 100.0; #ifdef NEVER /* Dump out the L mapping points */ - { - int i; - printf("1D rspl L mapping points:\n"); - for (i = 0; i < ngreyp; i++) - printf("%d %f -> %f (w %f)\n",i,lpnts[i].p[0],lpnts[i].v[0],lpnts[i].w); - } + { + int i; + printf("1D rspl L mapping points:\n"); + for (i = 0; i < ngreyp; i++) + printf("%d %f -> %f (w %f)\n",i,lpnts[i].p[0],lpnts[i].v[0],lpnts[i].w); + } #endif - /* Create spline from the data points, with appropriate smoothness. */ - avgdev[0] = GAMMAP_RSPLAVGDEV; - if (s->grey->fit_rspl_w(s->grey, GAMMAP_RSPLFLAGS, lpnts, ngreyp, il, ih, &gres, ol, oh, 5.0, avgdev, NULL)) { - fprintf(stderr,"Warning: Grey axis mapping is non-monotonic - may not be very smooth ?\n"); - } - - /* Fine tune the rspl, to make sure that the white and black */ - /* point mapping is precise */ - { - co cp; - adjust1wb cx; /* Adjustment context */ - - /* Lookup actual black & white */ - cp.p[0] = sbL; - s->grey->interp(s->grey, &cp); - cx.awb[0] = cp.v[0]; - - cp.p[0] = swL; - s->grey->interp(s->grey, &cp); - cx.awb[1] = cp.v[0]; - - /* Set target black and white */ - cx.twb[0] = dbL; - cx.twb[1] = dwL; - - /* Fine tune the 3D->3D mapping */ - s->grey->re_set_rspl( - s->grey, /* this */ - 0, /* Combination of flags */ - (void *)&cx, /* Opaque function context */ - adjust1_wb_func /* Function to set from */ - ); - -#ifdef VERBOSE - if (verb) { - printf("Before tuning, L map White/Black is %f %f, should be %f %f\n", - cx.awb[1], cx.awb[0], dwL, dbL); - - /* Lookup fine tuned black & white */ - cp.p[0] = sbL; - s->grey->interp(s->grey, &cp); - cx.awb[0] = cp.v[0]; - - cp.p[0] = swL; - s->grey->interp(s->grey, &cp); - cx.awb[1] = cp.v[0]; - - printf("After tuning, L map White/Black is %f %f, should be %f %f\n", - cx.awb[1], cx.awb[0], dwL, dbL); - } -#endif /* VERBOSE */ - } - + /* Create spline from the data points, with appropriate smoothness. */ + avgdev[0] = GAMMAP_RSPLAVGDEV; + if (s->grey->fit_rspl_w(s->grey, GAMMAP_RSPLFLAGS, lpnts, ngreyp, il, ih, &gres, ol, oh, 5.0, avgdev, NULL)) { + fprintf(stderr,"Warning: Grey axis mapping is non-monotonic - may not be very smooth ?\n"); + } - /* Create an inverse mapping too, for reverse gamut and/or expansion. */ - il[0] = -1.0; /* Set possible input range */ - ih[0] = 101.0; - ol[0] = 0.0; /* Set normalisation output range */ - oh[0] = 100.0; + /* Create an inverse mapping too, for reverse gamut and/or expansion. */ + il[0] = -1.0; /* Set possible input range */ + ih[0] = 101.0; + ol[0] = 0.0; /* Set normalisation output range */ + oh[0] = 100.0; - if ((s->igrey = new_rspl(RSPL_NOFLAGS, 1, 1)) == NULL) /* Allocate 1D -> 1D */ - error("gamut: igrey new_rspl failed"); - - /* Create it from inverse lookups of s->grey */ - s->igrey->set_rspl(s->igrey, 0, (void *)s->grey, inv_grey_func, il, ih, &gres, ol, oh); + if ((s->igrey = new_rspl(RSPL_NOFLAGS, 1, 1)) == NULL) /* Allocate 1D -> 1D */ + error("gamut: igrey new_rspl failed"); + + /* Create it from inverse lookups of s->grey */ + s->igrey->set_rspl(s->igrey, 0, (void *)s->grey, inv_grey_func, il, ih, &gres, ol, oh); - if (revrspl) { /* Swap to compensate for swapping of white and black points */ - rspl *tt = s->grey; - s->grey = s->igrey; - s->igrey = tt; - } + if (revrspl) { /* Swap to compensate for swapping of white and black points */ + rspl *tt = s->grey; + s->grey = s->igrey; + s->igrey = tt; } } @@ -1263,8 +1147,6 @@ glumknf = 1.0; if ((scl_gam = parttransgamut(s, sc_gam)) == NULL) { fprintf(stderr,"gamut map: parttransgamut failed\n"); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } @@ -1275,8 +1157,6 @@ glumknf = 1.0; else { if ((sil_gam = parttransgamut(s, si_gam)) == NULL) { fprintf(stderr,"gamut map: parttransgamut failed\n"); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } @@ -1289,6 +1169,7 @@ glumknf = 1.0; cow *gpnts = NULL; /* Mapping points to create gamut mapping */ int max_gpnts; int nspts; /* Number of source gamut surface points */ + int rgridpts; /* Number of range surface grid points */ int i, j; datai il, ih; datao ol, oh; @@ -1297,8 +1178,7 @@ glumknf = 1.0; nearsmth *nsm = NULL; /* Returned list of near smooth points */ int nnsm; /* Number of near smoothed points */ double brad = 0.0; /* Black bend radius */ - gammapweights xpweights[14], xlpweights[14], xsweights[14]; - /* Explicit perceptial, lightnes pp. and sat. weights */ + gammapweights xpweights[14], xsweights[14]; /* Explicit perceptial and sat. weights */ gammapweights xwh[14]; /* Structure holding blended weights */ double smooth = 1.0; /* Level of 3D RSPL smoothing, blend of psmooth and ssmooth */ vrml *wrl = NULL; /* Gamut mapping illustration (hulls + guide vectors) */ @@ -1313,9 +1193,17 @@ typedef struct { #endif /* PLOT_3DKNEES */ /* Get the maximum number of points that will be created */ - nspts = near_smooth_np(NULL, scl_gam, sil_gam, d_gam, xvra, 4, surfpnts ? mapres : 0); + nspts = near_smooth_np(scl_gam, sil_gam, d_gam, xvra); - max_gpnts = nres + nspts; + rgridpts = 0; +#ifdef USE_BOUND + if (defrgrid >= 2) { + rgridpts = defrgrid * defrgrid * defrgrid + - (defrgrid -2) * (defrgrid -2) * (defrgrid -2); + } +#endif + + max_gpnts = nres + 3 * nspts + rgridpts; if ((gpnts = (cow *)malloc(max_gpnts * sizeof(cow))) == NULL) { fprintf(stderr,"gamut map: Malloc of mapping setup points failed\n"); s->grey->del(s->grey); @@ -1323,8 +1211,6 @@ typedef struct { if (sil_gam != scl_gam) sil_gam->del(sil_gam); scl_gam->del(scl_gam); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } @@ -1365,10 +1251,8 @@ typedef struct { /* Create source grey axis point */ t = i/(nres - 1.0); -#ifdef NEVER /* Cover L = 0.0 to 100.0 */ t = ((100.0 * t) - sl_cs_bp[0])/(sl_cs_wp[0] - sl_cs_bp[0]); -#endif for (j = 0; j < 3; j++) gpnts[ngamp].p[j] = sl_cs_bp[j] + t * (sl_cs_wp[j] - sl_cs_bp[j]); @@ -1413,7 +1297,7 @@ typedef struct { gpnts[ngamp].w = wt; //printf("~1 t = %f, blended %f %f %f\n",t, gpnts[ngamp].v[0], gpnts[ngamp].v[1],gpnts[ngamp].v[2]); -#ifdef DUMP_GREY_AXIS_POINTS +#ifdef NEVER printf("Grey axis %d maps %f %f %f -> %f %f %f wit %f\n",ngamp, gpnts[ngamp].p[0], gpnts[ngamp].p[1], gpnts[ngamp].p[2], gpnts[ngamp].v[0], gpnts[ngamp].v[1], gpnts[ngamp].v[2], @@ -1486,7 +1370,6 @@ typedef struct { /* Convert from compact to explicit hextant weightings */ if (expand_weights(xpweights, pweights) - || expand_weights(xlpweights, lpweights) || expand_weights(xsweights, sweights)) { fprintf(stderr,"gamut map: expand_weights() failed\n"); s->grey->del(s->grey); @@ -1494,17 +1377,13 @@ typedef struct { if (sil_gam != scl_gam) sil_gam->del(sil_gam); scl_gam->del(scl_gam); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } - - /* Create weights as blend between perceptual, lightness pp. and saturation */ - near_xwblend3(xwh, xpweights, gmi->gampwf, xlpweights, gmi->gamlpwf, - xsweights, gmi->gamswf); - if ((gmi->gampwf + gmi->gamlpwf + gmi->gamswf) > 0.1) - smooth = (gmi->gampwf * psmooth) + (gmi->gamlpwf * lpsmooth) + (gmi->gamswf * ssmooth); + /* Create weights as blend between perceptual and saturation */ + near_xwblend(xwh, xpweights, gmi->gampwf, xsweights, gmi->gamswf); + if ((gmi->gampwf + gmi->gamswf) > 0.1) + smooth = (gmi->gampwf * psmooth) + (gmi->gamswf * ssmooth); /* Tweak gamut mappings according to extra cmy cusp flags or rel override */ if (dst_cmymap != 0 || rel_oride != 0) { @@ -1516,7 +1395,7 @@ typedef struct { nsm = near_smooth(verb, &nnsm, scl_gam, sil_gam, d_gam, src_kbp, dst_kbp, dr_cs_bp, xwh, gmi->gamcknf, gmi->gamxknf, gmi->gamcpf > 1e-6, gmi->gamexf > 1e-6, - xvra, mapres, smooth, 1.10, surfpnts, il, ih, ol, oh); + xvra, mapres, smooth, il, ih, ol, oh); if (nsm == NULL) { fprintf(stderr,"Creating smoothed near points failed\n"); s->grey->del(s->grey); @@ -1524,11 +1403,58 @@ typedef struct { if (sil_gam != scl_gam) sil_gam->del(sil_gam); scl_gam->del(scl_gam); - if (si_gam != sc_gam) - si_gam->del(si_gam); free(s); return NULL; } + /* --------------------------- */ + + /* Make sure the input range to encompasss the guide vectors. */ + for (i = 0; i < nnsm; i++) { + for (j = 0; j < 3; j++) { + if (nsm[i].sv[j] < il[j]) + il[j] = nsm[i].sv[j];; + if (nsm[i].sv[j] > ih[j]) + ih[j] = nsm[i].sv[j]; + } + } + +#ifdef NEVER + if (verb) { + fprintf(stderr,"Input bounding box:\n"); + fprintfstderr,("%f -> %f, %f -> %f, %f -> %f\n", + il[0], ih[0], il[1], ih[1], il[2], ih[2]); + } +#endif + + /* Now expand the bounding box by aprox 5% margin, but scale grid res */ + /* to match, so that the natural or given boundary still lies on the grid. */ + { + int xmapres; + double scale; + + xmapres = (int) ((mapres-1) * 0.05 + 0.5); + if (xmapres < 1) + xmapres = 1; + + scale = (double)(mapres-1 + xmapres)/(double)(mapres-1); + + for (j = 0; j < 3; j++) { + double low, high; + high = ih[j]; + low = il[j]; + ih[j] = (scale * (high - low)) + low; + il[j] = (scale * (low - high)) + high; + } + + mapres += 2 * xmapres; +#ifdef NEVER + if (verb) { + fprintf(stderr,"After incresing mapres to %d, input bounding box for 3D gamut mapping is:\n",mapres); + fprintf(stderr,"%f -> %f, %f -> %f, %f -> %f\n", + il[0], ih[0], il[1], ih[1], il[2], ih[2]); + } +#endif + } /* ---------------------------------------------------- */ /* Setup for diagnostic plot, that will have elements added */ @@ -1587,25 +1513,18 @@ typedef struct { for (i = 0; i < nnsm; i++) { double cpexf; /* The effective compression or expansion factor */ - /* Grid surface point */ - if (nsm[i].uflag != 0) { - cpexf = gmi->gamcpf; /* Assume compression */ + if (nsm[i].vflag == 0) { /* Unclear whether compression or expansion */ + /* Use larger to the the two factors */ + cpexf = gmi->gamcpf > gmi->gamexf ? gmi->gamcpf : gmi->gamexf; + + } else if (nsm[i].vflag == 1) { /* Compression */ + cpexf = gmi->gamcpf; + + } else if (nsm[i].vflag == 2) { /* Expansion */ + cpexf = gmi->gamexf; - /* Guide vector */ } else { - if (nsm[i].vflag == 0) { /* Unclear whether compression or expansion */ - /* Use larger to the the two factors */ - cpexf = gmi->gamcpf > gmi->gamexf ? gmi->gamcpf : gmi->gamexf; - - } else if (nsm[i].vflag == 1) { /* Compression */ - cpexf = gmi->gamcpf; - - } else if (nsm[i].vflag == 2) { /* Expansion */ - cpexf = gmi->gamexf; - - } else { - error("gammap: internal, unknown guide point flag"); - } + error("gammap: internal, unknown guide point flag"); } /* Compute destination value which is a blend */ @@ -1623,14 +1542,14 @@ typedef struct { gpnts[ngamp].p[j] = nsm[i].sv[j]; gpnts[ngamp].v[j] = nsm[i].div[j]; } - gpnts[ngamp++].w = nsm[i].w1; /* 1.01 for guide vectors, less for grid surface */ - + gpnts[ngamp++].w = 1.01; /* Main gamut surface mapping point */ + /* (Use 1.01 as a marker value) */ if (ngamp >= max_gpnts) error("gammap: internal, not enough space for mapping points B (%d > %d)\n",ngamp, max_gpnts); #ifdef USE_GAMKNF /* Add sub surface mapping point if available */ - if (nsm[i].uflag == 0 && nsm[i].vflag != 0) { /* Sub surface point is available */ + if (nsm[i].vflag != 0) { /* Sub surface point is available */ /* Compute destination value which is a blend */ /* between the source value and the knee adjusted destination */ @@ -1670,6 +1589,82 @@ typedef struct { if (ngamp >= max_gpnts) error("gammap: internal, not enough space for mapping points (%d > %d)\n",ngamp, max_gpnts); + /* Create preliminary gamut mapping rspl, without grid boundary values. */ + /* We use this to lookup the mapping for points on the source space gamut */ + /* that result from clipping our grid boundary points */ +#ifdef USE_BOUND + for (j = 0; j < 3; j++) { /* Set resolution for all axes */ + gres[j] = (mapres+1)/2; + avgdev[j] = GAMMAP_RSPLAVGDEV; + } + s->map = new_rspl(RSPL_NOFLAGS, 3, 3); /* Allocate 3D -> 3D */ + s->map->fit_rspl_w(s->map, GAMMAP_RSPLFLAGS, gpnts, ngamp, il, ih, gres, ol, oh, smooth, avgdev, NULL); + + /* Add input range grid surface anchor points to improve clipping behaviour. */ + if (defrgrid >= 2) { + DCOUNT(gc, 3, 3, 0, 0, defrgrid); + double cent[3]; + + sc_gam->getcent(d_gam, cent); + + DC_INIT(gc); + for (;;) { + /* If point is on the grid surface */ + if ( gc[0] == 0 || gc[0] == (defrgrid-1) + || gc[1] == 0 || gc[1] == (defrgrid-1) + || gc[2] == 0 || gc[2] == (defrgrid-1)) { + double grid2gamut, gamut2cent, ww; + co cp; + + /* Clip the point to the closest location on the source */ + /* colorspace gamut. */ + for (j = 0; j < 3; j++) + gpnts[ngamp].p[j] = il[j] + gc[j]/(defrgrid-1.0) * (ih[j] - il[j]); + sc_gam->nearest(sc_gam, cp.p, gpnts[ngamp].p); + + /* Then lookup the equivalent gamut mapped value */ + s->map->interp(s->map, &cp); + + for (j = 0; j < 3; j++) + gpnts[ngamp].v[j] = cp.v[j]; + + /* Compute the distance of the grid surface point to the to the */ + /* source colorspace gamut, as well as the distance from there */ + /* to the gamut center point. */ + for (grid2gamut = gamut2cent = 0.0, j = 0; j < 3; j++) { + double tt; + tt = gpnts[ngamp].p[j] - cp.p[j]; + grid2gamut += tt * tt; + tt = cp.p[j] - cent[j]; + gamut2cent += tt * tt; + } + grid2gamut = sqrt(grid2gamut); + gamut2cent = sqrt(gamut2cent); + + /* Make the weighting inversely related to distance, */ + /* to reduce influence on in gamut mapping shape, */ + /* while retaining some influence at the edge of the */ + /* grid. */ + ww = grid2gamut / gamut2cent; + if (ww > 1.0) + ww = 1.0; + + /* A low weight seems to be enough ? */ + /* the lower the better in terms of geting best hull mapping fidelity */ + gpnts[ngamp++].w = 0.05 * ww; + + if (ngamp >= max_gpnts) + error("gammap: internal, not enough space for mapping points E (%d > %d)\n",ngamp, max_gpnts); + } + DC_INC(gc); + if (DC_DONE(gc)) + break; + } + } +#else /* !USE_BOUND */ + printf("!!!! Warning - gammap boundary points disabled !!!!\n"); +#endif /* !USE_BOUND */ + /* --------------------------- */ /* Compute the output bounding values, and check input range hasn't changed */ for (i = 0; i < ngamp; i++) { @@ -1696,9 +1691,14 @@ typedef struct { #endif /* Create the final gamut mapping rspl. */ - /* [ How about converting to a delta filer ? ie. */ - /* create current filter, then create point list of delta from */ - /* smoothed value, filtering that and then un-deltering it ?? ] */ + /* [ The smoothing is not as useful as it should be, because */ + /* if it is increased it tends to push colors out of gamut */ + /* where they get clipped. Some cleverer scheme which makes */ + /* sure that smoothness errs on the side of more compression */ + /* is needed. - Addressed in nearsmth now ? ] */ + /* How about converting to a delta filer ? ie. */ + /* create curren filter, then create point list of delta from */ + /* smoothed value, filtering that and then un-deltering it ?? */ if (s->map != NULL) s->map->del(s->map); if (verb) @@ -1720,24 +1720,20 @@ typedef struct { /* (This isn't a good indication now that vectors have been adjusted */ /* to counteract the rspl smoothing at the edges.) */ if (verb) { - double de, avgde = 0.0, maxde = 0.0, num = 0.0; /* DE stats */ + double de, avgde = 0.0, maxde = 0.0; /* DE stats */ for (i = 0; i < nnsm; i++) { double av[3]; - if (nsm[i].uflag != 0) /* Ignore grid boundary points */ - continue; - /* Compute the mapping error */ dopartialmap2(s, av, nsm[i].sv); /* Just the rspl */ de = icmLabDE(nsm[i].div, av); avgde += de; - num++; if (de > maxde) maxde = de; } - printf("Gamut hull fit to guides: = avg %f, max %f\n",avgde/num,maxde); + printf("Gamut hull fit to guides: = avg %f, max %f\n",avgde/nnsm,maxde); } #endif /* CHECK_NEARMAP */ @@ -1834,10 +1830,6 @@ typedef struct { /* Show all neighbours */ wrl->start_line_set(wrl, 0); for (i = 0; i < nnsm; i++) { - - if (nsm[i].uflag != 0) /* Ignore grid boundary points */ - continue; - for (j = 0; j < XNNB; j++) { nearsmth *np = nsm[i].n[j]; /* Pointer to neighbor */ @@ -1873,8 +1865,6 @@ typedef struct { /* Locate the nearest source point */ for (ix = 0; ix < nnsm; ix++) { double dist = icmNorm33(pp, nsm[ix].sv); - if (nsm[i].uflag != 0) /* Ignore grid boundary points */ - continue; if (dist < bdist) { bdist = dist; bix = ix; @@ -1957,9 +1947,6 @@ typedef struct { double *ccc; double mdst[3]; - if (nsm[i].uflag != 0) /* Ignore grid boundary points */ - continue; - #if defined(SHOW_ACTUAL_VECTORS) || defined(SHOW_ACTUAL_VEC_DIFF) # ifdef SHOW_ACTUAL_VECTORS wrl->add_col_vertex(wrl, 0, nsm[i].sv, yellow); @@ -1996,8 +1983,6 @@ typedef struct { #if defined(SHOW_VECTOR_INDEXES) || defined(SHOW_SUB_PNTS) for (i = 0; i < nnsm; i++) { - if (nsm[i].uflag != 0) /* Ignore grid boundary points */ - continue; #ifdef SHOW_VECTOR_INDEXES { double cream[3] = { 0.7, 0.7, 0.5 }; @@ -2139,7 +2124,7 @@ typedef struct { icmMul3By3x4(vec, mat, vec); /* Intersect it with the source gamut */ - if (sil_gam->vector_isect(sil_gam, vec, cpoint, isect, + if (si_gam->vector_isect(si_gam, vec, cpoint, isect, NULL, NULL, NULL, NULL, NULL) == 0) { continue; } @@ -2194,7 +2179,7 @@ typedef struct { icmMul3By3x4(vec, mat, vec); /* Intersect it with the source gamut */ - if (sil_gam->vector_isect(sil_gam, vec, cpoint, isect, + if (si_gam->vector_isect(si_gam, vec, cpoint, isect, NULL, NULL, NULL, NULL, NULL) == 0) { warning("Ring %d vect %d diagnostic vector intersect failed",i,j); continue; @@ -2276,8 +2261,6 @@ typedef struct { if (sil_gam != scl_gam) sil_gam->del(sil_gam); scl_gam->del(scl_gam); - if (si_gam != sc_gam) - si_gam->del(si_gam); return s; } @@ -2468,20 +2451,6 @@ double *in /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ -/* Function to pass to rspl to re-set output values, */ -/* to adjust the 1D white and black points */ -static void -adjust1_wb_func( - void *pp, /* adjust1wb structure */ - double *out, /* output value to be adjusted */ - double *in /* corresponding input value */ -) { - adjust1wb *p = (adjust1wb *)pp; - - /* Do a linear re-mapping from actual to target */ - out[0] = (out[0] - p->awb[0]) * (p->twb[1] - p->twb[0])/(p->awb[1] - p->awb[0]) + p->twb[0]; -} - /* Function to pass to rspl to invert grey curve */ static void inv_grey_func( void *cntx, |