From 094535c010320967639e8e86f974d878e80baa72 Mon Sep 17 00:00:00 2001
From: =?UTF-8?q?J=C3=B6rg=20Frings-F=C3=BCrst?= <debian@jff-webhosting.net>
Date: Fri, 1 May 2015 16:13:57 +0200
Subject: Imported Upstream version 1.7.0

---
 xicc/bt1886.c | 351 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 351 insertions(+)
 create mode 100644 xicc/bt1886.c

(limited to 'xicc/bt1886.c')

diff --git a/xicc/bt1886.c b/xicc/bt1886.c
new file mode 100644
index 0000000..3f94dbe
--- /dev/null
+++ b/xicc/bt1886.c
@@ -0,0 +1,351 @@
+
+/* 
+ * Author:  Graeme W. Gill
+ * Date:    16/8/13
+ * Version: 1.00
+ *
+ * Copyright 2013, 2014 Graeme W. Gill
+ * All rights reserved.
+ *
+ * This material is licenced under the GNU AFFERO GENERAL PUB LICENSE Version 3 :-
+ * see the License.txt file for licencing details.
+ *
+ */
+
+/* BT.1886 stype input offset transfer curve, */
+/* + general gamma + input + output offset curve support. */
+
+#include <sys/types.h>
+#include <string.h>
+#include <ctype.h>
+#ifdef __sun
+#include <unistd.h>
+#endif
+#if defined(__IBMC__) && defined(_M_IX86)
+#include <float.h>
+#endif
+#include "numlib.h"
+#include "icc.h"		/* definitions for this library */
+#include "bt1886.h"		/* definitions for this library */
+
+#undef DEBUG
+
+/* BT.1886 support */
+/* This is both a EOTF curve, and a white point */
+/* adjustment. */
+
+/* Compute technical gamma from effective gamma in BT.1886 style */
+
+/* Info for optimization */
+typedef struct {
+	double wp;			/* 100% input target */ 
+	double thyr;		/* 50% input target */
+	double bp;			/* 0% input target */
+} gam_fits;
+
+/* gamma + input offset function handed to powell() */
+static double gam_fit(void *dd, double *v) {
+	gam_fits *gf = (gam_fits *)dd;
+	double gamma = v[0];
+	double a, b;
+	double rv = 0.0;
+	double t1, t2;
+
+	if (gamma < 0.0) {
+		rv += 100.0 * -gamma;
+		gamma = 1e-4;
+	}
+
+	t1 = pow(gf->bp, 1.0/gamma);
+	t2 = pow(gf->wp, 1.0/gamma);
+	b = t1/(t2 - t1);						/* Offset */
+	a = pow(t2 - t1, gamma);				/* Gain */
+
+	/* Comput 50% output for this technical gamma */
+	/* (All values are without output offset being added in) */
+	t1 = a * pow((0.5 + b), gamma);
+	t1 = t1 - gf->thyr;
+	rv += t1 * t1;
+	
+	return rv;
+}
+
+/* Given the effective gamma and the output offset Y, */
+/* return the technical gamma needed for the correct 50% response. */
+static double xicc_tech_gamma(
+	double egamma,			/* effective gamma needed */
+	double off,				/* Output offset required */
+	double outoprop			/* Prop. of offset to be accounted for on output */
+) {
+	gam_fits gf;
+	double outo;
+	double op[1], sa[1], rv;
+
+	if (off <= 0.0) {
+		return egamma;
+	}
+
+	/* We set up targets without outo being added */
+	outo = off * outoprop; 		/* Offset acounted for in output */
+	gf.bp = off - outo;			/* Black value for 0 % input */
+	gf.wp = 1.0 - outo;			/* White value for 100% input */
+	gf.thyr = pow(0.5, egamma) - outo;	/* Advetised 50% target */
+
+	op[0] = egamma;
+	sa[0] = 0.1;
+
+	if (powell(&rv, 1, op, sa, 1e-6, 500, gam_fit, (void *)&gf, NULL, NULL) != 0)
+		warning("Computing effective gamma and input offset is inaccurate");
+
+	return op[0];
+}
+
+/* Set the bt1886_info to a default do nothing state */
+void bt1886_setnop(bt1886_info *p) {
+	icmXYZ2XYZ(p->w, icmD50);
+	p->ingo = 0.0;
+	p->outsc = 1.0;
+	p->outo = 0.0;
+	p->outL = 0.0;
+	p->tab[1] = 0.0;
+	p->tab[2] = 0.0;
+}
+
+/* Setup the bt1886_info for the given target black point, proportion of */
+/* offset to be accounted for on output, and gamma. */
+/* wp XYZ simply sets the L*a*b* reference */
+/* Pure BT.1886 will have outopro = 0.0 and gamma = 2.4 */
+void bt1886_setup(
+bt1886_info *p,
+icmXYZNumber *w,	/* wp used for L*a*b* conversion */
+double *XYZbp,		/* normalised bp used for black offset and black point hue "bend" */
+double outoprop,	/* 0..1 proportion of output black point compensation */
+double gamma,		/* technical or effective gamma */
+int effg			/* nz if effective gamma, z if technical gamma */
+) {
+	double Lab[3], ino, bkipow, wtipow;
+
+	icmXYZ2XYZ(p->w, *w);
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886_setup wp.Y %f, bp.Y %f, outprop %f, gamma %f, effg %d", p->w.Y, XYZbp[1], outoprop, gamma, effg);
+#endif
+
+	if (effg) {
+		p->gamma = xicc_tech_gamma(gamma, XYZbp[1], outoprop);
+#ifdef DEBUG
+		a1logd(g_log, 2, "bt1886_setup tgamma %f", p->gamma);
+#endif
+	} else {
+		p->gamma = gamma;
+	}
+
+	icmXYZ2Lab(&p->w, Lab, XYZbp);
+
+	p->outL   = Lab[0];		/* For bp blend comp. */
+	p->tab[0] = Lab[1];		/* a* b* correction needed */
+	p->tab[1] = Lab[2];
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886_setup bend Lab = %f %f %f", p->outL, p->tab[0], p->tab[1]);
+#endif
+
+	if (XYZbp[1] < 0.0)
+		XYZbp[1] = 0.0;
+
+
+	p->outo = XYZbp[1] * outoprop; 		/* Offset acounted for in output */
+	ino = XYZbp[1] - p->outo;			/* Balance of offset accounted for in input */
+
+	bkipow = pow(ino, 1.0/p->gamma);				/* Input offset black to 1/pow */
+	wtipow = pow((1.0 - p->outo), 1.0/p->gamma);	/* Input offset white to 1/pow */
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886_setup outo %f, ino %f, bkipow %f, wtipow %f", p->outo, ino, bkipow, wtipow);
+#endif
+
+	p->ingo = bkipow/(wtipow - bkipow);			/* non-linear Y that makes input offset */
+												/* proportion of black point */
+	p->outsc = pow(wtipow - bkipow, p->gamma);	/* Scale to make input of 1 map to */
+												/* 1.0 - p->outo */
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886_setup ingo %f, outsc %f", p->ingo, p->outsc);
+#endif
+}
+
+/* Apply BT.1886 eotf curve to the device RGB value */
+/* to produce a linear light RGB. We pass xvYCC out of range values through. */
+void bt1886_fwd_curve(bt1886_info *p, double *out, double *in) {
+	int j;
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886    Dev RGB in %f %f %f, pow %f\n", in[0],in[1],in[2], p->gamma);
+	a1logd(g_log, 2, "outo %f, outsc %f, pow %f\n", p->outo, p->outsc, 1.0/p->gamma);
+	a1logd(g_log, 2, "ingo %f, pow %f, outsc %f, outo %f\n", p->ingo, p->gamma, p->outsc,p->outo);
+#endif
+
+	for (j = 0; j < 3; j++) {
+		int neg = 0;
+		double vv = in[j];
+	
+		if (vv < 0.0) {			/* Allow for xvYCC */
+			neg = 1;
+			vv = -vv;
+		}
+		/* Apply input offset */
+		vv += p->ingo;
+		
+		/* Apply power and scale */
+		if (vv > 0.0)
+			vv = p->outsc * pow(vv, p->gamma);
+
+		/* Apply output portion of offset */
+		vv += p->outo;
+
+		if (neg)
+			vv = -vv;
+
+		out[j] = vv;
+	}
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 linear RGB out %f %f %f\n", out[0],out[1],out[2]);
+#endif
+}
+
+/* Apply inverse BT.1886 eotf curve to the linear light RGB to produce */
+/* device RGB values. We pass xvYCC out of range values through. */
+void bt1886_bwd_curve(bt1886_info *p, double *out, double *in) {
+	int j;
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 linear RGB in %f %f %f\n", in[0],in[1],in[2]);
+	a1logd(g_log, 2, "outo %f, outsc %f, pow %f, ingo %f\n", p->outo, p->outsc, 1.0/p->gamma,p->ingo);
+#endif
+
+	for (j = 0; j < 3; j++) {
+		int neg = 0;
+		double vv = in[j];
+	
+		if (vv < 0.0) {			/* Allow for xvYCC */
+			neg = 1;
+			vv = -vv;
+		}
+
+		/* Un-apply output portion of offset */
+		vv -= p->outo;
+
+		/* Un-apply power and scale */
+		if (vv > 0.0)
+			vv = pow(vv/p->outsc, 1.0/p->gamma);
+
+		/* Un-apply input offset */
+		vv -= p->ingo;
+		
+		if (neg)
+			vv = -vv;
+
+		out[j] = vv;
+	}
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886   Dev RGB out %f %f %f\n", in[0],in[1],in[2]);
+#endif
+}
+
+/* Apply BT.1886 processing black point hue adjustment to the XYZ value */
+void bt1886_wp_adjust(bt1886_info *p, double *out, double *in) {
+	double vv;
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 XYZ wp adj. in %f %f %f\n", in[0],in[1],in[2]);
+#endif
+
+	icmXYZ2Lab(&p->w, out, in);
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 Lab wp adj. in %f %f %f\n", out[0],out[1],out[2]);
+#endif
+
+	/* Blend ab to required black point offset p->tab[] as L approaches black. */
+	vv = (out[0] - p->outL)/(100.0 - p->outL);	/* 0 at bp, 1 at wp */
+	vv = 1.0 - vv;
+	if (vv < 0.0)
+		vv = 0.0;
+	else if (vv > 1.0)
+		vv = 1.0;
+	vv = pow(vv, 40.0);
+
+	out[1] += vv * p->tab[0];
+	out[2] += vv * p->tab[1];
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 Lab after wp adj. %f %f %f\n", out[0],out[1],out[2]);
+#endif
+
+	icmLab2XYZ(&p->w, out, out);
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 XYZ after wp adj. %f %f %f\n", out[0],out[1],out[2]);
+#endif
+}
+
+
+/* Apply inverse BT.1886 processing black point hue adjustment to the XYZ value */
+void bt1886_inv_wp_adjust(bt1886_info *p, double *out, double *in) {
+	double vv;
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 XYZ inv. wp adj. in %f %f %f\n", in[0],in[1],in[2]);
+#endif
+
+	icmXYZ2Lab(&p->w, out, in);
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 Lab inv. wp adj. in %f %f %f\n", out[0],out[1],out[2]);
+#endif
+
+	/* Blend ab to required black point offset p->tab[] as L approaches black. */
+	vv = (out[0] - p->outL)/(100.0 - p->outL);	/* 0 at bp, 1 at wp */
+	vv = 1.0 - vv;
+	if (vv < 0.0)
+		vv = 0.0;
+	else if (vv > 1.0)
+		vv = 1.0;
+	vv = pow(vv, 40.0);
+
+	out[1] -= vv * p->tab[0];
+	out[2] -= vv * p->tab[1];
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 Lab after inv. wp adj. %f %f %f\n", out[0],out[1],out[2]);
+#endif
+
+	icmLab2XYZ(&p->w, out, out);
+
+#ifdef DEBUG
+	a1logd(g_log, 2, "bt1886 XYZ after inv. wp adj. %f %f %f\n", out[0],out[1],out[2]);
+#endif
+}
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-- 
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