Imported Upstream version 1.6.3upstream/1.6.3

24 files changed, 1781 insertions, 400 deletions

diff --git a/icc/ClayRGB1998.icm b/icc/ClayRGB1998.icm
index 1eedf09..1c3a02e 100644
--- a/icc/ClayRGB1998.icm
+++ b/icc/ClayRGB1998.icm
diff --git a/icc/EBU3213_PAL.icm b/icc/EBU3213_PAL.icm
new file mode 100644
index 0000000..54cfed7
--- /dev/null
+++ b/icc/EBU3213_PAL.icm
diff --git a/icc/Jamfile b/icc/Jamfile
index abbeddb..9f27848 100644
--- a/icc/Jamfile
+++ b/icc/Jamfile
@@ -13,7 +13,9 @@ PREF_LINKFLAGS	= $(LINKDEBUGFLAG) ;	# Link debugging flags
 Libraries = libicc ;
 Executables = iccdump icclu ;
 Headers = icc.h ;
-Samples = sRGB.icm ClayRGB1998.icm lab2lab.icm ;
+Samples = sRGB.icm ClayRGB1998.icm EBU3213_PAL.icm SMPTE_RP145_NTSC.icm Rec709.icm
+          Rec2020.icm SMPTE431_P3.icm ProPhoto.icm ProPhotoLin.icm lab2lab.icm ;
+# Remember to add samples to ref/afiles !
 
 #Install
 InstallBin  $(DESTDIR)$(PREFIX)/bin : $(Executables) ;
@@ -36,19 +38,31 @@ LINKLIBS = libicc ;
 # All utils are made from a single source file 
 MainsFromSources icctest.c lutest.c iccdump.c icclu.c iccrw.c ;
 
+# This is an example program for making a matrix display profile
+MainsFromSources mkDispProf.c ;
+
+#MainsFromSources t.c ;
+
 if $(BUILD_JUNK) {
 
 #	MainsFromSources tt.c ;
 
 	MainsFromSources mksRGB.c ;
+#	MainsFromSources mkscRGB.c ;
 	MainsFromSources mkAdobeRGB.c ;
+	MainsFromSources mkEBU3213.c ;
+	MainsFromSources mkSMPTERP145.c ;
 	MainsFromSources mklab2lab.c ;
+	MainsFromSources mkRec709.c ;
+	MainsFromSources mkRec2020.c ;
+	MainsFromSources mkSMPTE431_P3.c ;
+	MainsFromSources mkProPhoto.c ;
 #	MainsFromSources icm2ary.c ;
 
 	# Check library is compatible with C++
 	Main cppcheck : cppcheck.cpp ;
 
-	# chech CIEDE2000
+	# check CIEDE2000
 	MainsFromSources testDE2K.c ;
 
 	#Monotonic behaviour checker
diff --git a/icc/License.txt b/icc/License.txt
index 9de79da..bd0c4f2 100644
--- a/icc/License.txt
+++ b/icc/License.txt
@@ -1,5 +1,5 @@
 *************************************************************************
-Copyright (c) 1997-2009 Graeme W. Gill
+Copyright (c) 1997-2013 Graeme W. Gill
 
 Permission is hereby granted, free of charge, to any person obtaining a copy
 of this software and associated documentation files (the "Software"), to deal
diff --git a/icc/ProPhoto.icm b/icc/ProPhoto.icm
new file mode 100644
index 0000000..3ed16cb
--- /dev/null
+++ b/icc/ProPhoto.icm
diff --git a/icc/ProPhotoLin.icm b/icc/ProPhotoLin.icm
new file mode 100644
index 0000000..579b903
--- /dev/null
+++ b/icc/ProPhotoLin.icm
diff --git a/icc/Readme.txt b/icc/Readme.txt
index 0ec425e..d39e9da 100644
--- a/icc/Readme.txt
+++ b/icc/Readme.txt
@@ -5,7 +5,7 @@ This version is part of Argyll V 1.50
 
 -------------------------------------------
 
-Date 22 September 2012, Version 2.14
+Date 22 September 2013, Version 2.15
 
 This distribution contains source code which implements the reading and
 writing of color profile files that conform to the International Color
@@ -70,12 +70,6 @@ In summary this library provides:
      system file and memory sub-systems.
    * Loads Tag Types on demand to conserve memory space.
 
-Changes from V2.11
-
-Many changes have been made to support ArgyllCMS.
-A double memory free bug when iccdump'ing a profile
-that has duplicate tags has been fixed.
-
 Package contents:
 
  icclib.zip    ZIP archive of the following files
diff --git a/icc/Rec2020.icm b/icc/Rec2020.icm
new file mode 100644
index 0000000..09d5ccf
--- /dev/null
+++ b/icc/Rec2020.icm
diff --git a/icc/Rec709.icm b/icc/Rec709.icm
new file mode 100644
index 0000000..46140bd
--- /dev/null
+++ b/icc/Rec709.icm
diff --git a/icc/SMPTE431_P3.icm b/icc/SMPTE431_P3.icm
new file mode 100644
index 0000000..f3861be
--- /dev/null
+++ b/icc/SMPTE431_P3.icm
diff --git a/icc/SMPTE_RP145_NTSC.icm b/icc/SMPTE_RP145_NTSC.icm
new file mode 100644
index 0000000..a6ce7f1
--- /dev/null
+++ b/icc/SMPTE_RP145_NTSC.icm
diff --git a/icc/afiles b/icc/afiles
index 7df3ba5..acb730e 100644
--- a/icc/afiles
+++ b/icc/afiles
@@ -20,7 +20,14 @@ icctest.c
 lutest.c
 mcheck.c
 testDE2K.c
-makezip.ksh
+mkDispProf.c
 sRGB.icm
 ClayRGB1998.icm
 lab2lab.icm
+EBU3213_PAL.icm
+SMPTE_RP145_NTSC.icm
+Rec709.icm
+Rec2020.icm
+SMPTE431_P3.icm
+ProPhoto.icm
+ProPhotoLin.icm
diff --git a/icc/icc.c b/icc/icc.c
index 68668d0..7dfe519 100644
--- a/icc/icc.c
+++ b/icc/icc.c
@@ -7,7 +7,7 @@
  * Date:    2002/04/22
  * Version: 2.15
  *
- * Copyright 1997 - 2012 Graeme W. Gill
+ * Copyright 1997 - 2013 Graeme W. Gill
  *
  * This material is licensed with an "MIT" free use license:-
  * see the License.txt file in this directory for licensing details.
@@ -51,10 +51,10 @@
 
 #define _ICC_C_				/* Turn on implimentation code */
 
-#undef DEBUG_SETLUT			/* Show each value being set in setting lut contents */
-#undef DEBUG_SETLUT_CLIP		/* Show clipped values when setting LUT */
-#undef DEBUG_LULUT			/* Show each value being looked up from lut contents */
-#undef DEBUG_LLULUT			/* Debug individual lookup steps (not fully implemented) */
+#undef DEBUG_SETLUT			/* [Und] Show each value being set in setting lut contents */
+#undef DEBUG_SETLUT_CLIP	/* [Und] Show clipped values when setting LUT */
+#undef DEBUG_LULUT			/* [Und] Show each value being looked up from lut contents */
+#undef DEBUG_LLULUT			/* [Und] Debug individual lookup steps (not fully implemented) */
 
 #include <stdio.h>
 #include <stdlib.h>
@@ -127,6 +127,10 @@
 #define DBLLL(xxx) 
 #endif
 
+#ifndef M_PI
+# define M_PI 3.14159265358979323846
+#endif
+
 /* =========================================================== */
 /* Overflow protected unsigned int arithmatic functions. */
 /* These functions saturate rather than wrapping around. */
@@ -706,6 +710,12 @@ static int write_S15Fixed16Number(double d, char *p) {
 	return 0;
 }
 
+static double round_S15Fixed16Number(double d) {
+	d = floor(d * 65536.0 + 0.5);		/* Beware! (int)(d + 0.5) doesn't work! */
+	d = d/65536.0;
+	return d;
+}
+
 /* Device coordinate as 8 bit value range 0.0 - 1.0 */
 static double read_DCS8Number(char *p) {
 	unsigned int rv;
@@ -775,7 +785,7 @@ static void read_PCSNumber(icc *icp, icColorSpaceSignature csig, double pcs[3],
 	if (csig == icmSigPCSData)
 		csig = icp->header->pcs;
 	if (csig == icSigLabData) {
-		if (icp->ver != 0)
+		if (icp->ver >= icmVersion4_1)
 			csig = icmSigLabV4Data;
 		else
 			csig = icmSigLabV2Data;
@@ -820,7 +830,7 @@ static int write_PCSNumber(icc *icp, icColorSpaceSignature csig, double pcs[3],
 	if (csig == icmSigPCSData)
 		csig = icp->header->pcs;
 	if (csig == icSigLabData) {
-		if (icp->ver != 0)
+		if (icp->ver >= icmVersion4_1)
 			csig = icmSigLabV4Data;
 		else
 			csig = icmSigLabV2Data;
@@ -5374,6 +5384,257 @@ double *in		/* Input array[outputChan] */
 }
 
 /* ----------------------------------------------- */
+/* Tune a single interpolated value. Based on lookup_clut functions (above) */
+
+/* Helper function to fine tune a single value interpolation */
+/* Return 0 on success, 1 if input clipping occured, 2 if output clipping occured */
+int icmLut_tune_value_nl(
+icmLut *p,		/* Pointer to Lut object */
+double *out,	/* Output array[inputChan] */
+double *in		/* Input array[outputChan] */
+) {
+	icc *icp = p->icp;
+	int rv = 0;
+	double *gp;					/* Pointer to grid cube base */
+	double co[MAX_CHAN];		/* Coordinate offset with the grid cell */
+	double *gw, GW[1 << 8];		/* weight for each grid cube corner */
+	double cout[MAX_CHAN];		/* Current output value */
+
+	if (p->inputChan <= 8) {
+		gw = GW;				/* Use stack allocation */
+	} else {
+		if ((gw = (double *) icp->al->malloc(icp->al, sat_mul((1 << p->inputChan), sizeof(double)))) == NULL) {
+			sprintf(icp->err,"icmLut_lookup_clut: malloc() failed");
+			return icp->errc = 2;
+		}
+	}
+
+	/* We are using an multi-linear (ie. Trilinear for 3D input) interpolation. */
+	/* The implementation here uses more multiplies that some other schemes, */
+	/* (for instance, see "Tri-Linear Interpolation" by Steve Hill, */
+	/* Graphics Gems IV, page 521), but has less involved bookeeping, */
+	/* needs less local storage for intermediate output values, does fewer */
+	/* output and intermediate value reads, and fp multiplies are fast on */
+	/* todays processors! */
+
+	/* Compute base index into grid and coordinate offsets */
+	{
+		unsigned int e;
+		double clutPoints_1 = (double)(p->clutPoints-1);
+		int    clutPoints_2 = p->clutPoints-2;
+		gp = p->clutTable;		/* Base of grid array */
+
+		for (e = 0; e < p->inputChan; e++) {
+			unsigned int x;
+			double val;
+			val = in[e] * clutPoints_1;
+			if (val < 0.0) {
+				val = 0.0;
+				rv |= 1;
+			} else if (val > clutPoints_1) {
+				val = clutPoints_1;
+				rv |= 1;
+			}
+			x = (unsigned int)floor(val);	/* Grid coordinate */
+			if (x > clutPoints_2)
+				x = clutPoints_2;
+			co[e] = val - (double)x;	/* 1.0 - weight */
+			gp += x * p->dinc[e];		/* Add index offset for base of cube */
+		}
+	}
+	/* Compute corner weights needed for interpolation */
+	{
+		unsigned int e;
+		int i, g = 1;
+		gw[0] = 1.0;
+		for (e = 0; e < p->inputChan; e++) {
+			for (i = 0; i < g; i++) {
+				gw[g+i] = gw[i] * co[e];
+				gw[i] *= (1.0 - co[e]);
+			}
+			g *= 2;
+		}
+	}
+	/* Now compute the current output value, and distribute the correction */
+	{
+		int i;
+		unsigned int f;
+		double w, *d, ww = 0.0;
+		for (f = 0; f < p->outputChan; f++)
+			cout[f] = 0.0;
+		for (i = 0; i < (1 << p->inputChan); i++) {	/* For all other corners of cube */
+			w = gw[i];				/* Strength reduce */
+			ww += w * w;			/* Sum of weights squared */
+			d = gp + p->dcube[i];
+			for (f = 0; f < p->outputChan; f++)
+				cout[f] += w * d[f];
+		}
+
+		/* We distribute the correction needed in proportion to the */
+		/* interpolation weighting, so the biggest correction is to the */
+		/* closest vertex. */
+
+		for (f = 0; f < p->outputChan; f++)
+			cout[f] = (out[f] - cout[f])/ww;	/* Amount to distribute */
+
+		for (i = 0; i < (1 << p->inputChan); i++) {	/* For all other corners of cube */
+			w = gw[i];				/* Strength reduce */
+			d = gp + p->dcube[i];
+			for (f = 0; f < p->outputChan; f++) {
+				d[f] += w * cout[f];			/* Apply correction */
+				if (d[f] < 0.0) {
+					d[f] = 0.0;
+					rv |= 2;
+				} else if (d[f] > 1.0) {
+					d[f] = 1.0;
+					rv |= 2;
+				} 
+			}
+		}
+	}
+
+	if (gw != GW)
+		icp->al->free(icp->al, (void *)gw);
+	return rv;
+}
+
+/* Helper function to fine tune a single value interpolation */
+/* Return 0 on success, 1 if input clipping occured, 2 if output clipping occured */
+int icmLut_tune_value_sx(
+icmLut *p,		/* Pointer to Lut object */
+double *out,	/* Output array[inputChan] */
+double *in		/* Input array[outputChan] */
+) {
+	int rv = 0;
+	double *gp;					/* Pointer to grid cube base */
+	double co[MAX_CHAN];		/* Coordinate offset with the grid cell */
+	int    si[MAX_CHAN];		/* co[] Sort index, [0] = smalest */
+	double cout[MAX_CHAN];		/* Current output value */
+
+	/* We are using a simplex (ie. tetrahedral for 3D input) interpolation. */
+	/* This method is more appropriate for XYZ/RGB/CMYK input spaces, */
+
+	/* Compute base index into grid and coordinate offsets */
+	{
+		unsigned int e;
+		double clutPoints_1 = (double)(p->clutPoints-1);
+		int    clutPoints_2 = p->clutPoints-2;
+		gp = p->clutTable;		/* Base of grid array */
+
+		for (e = 0; e < p->inputChan; e++) {
+			unsigned int x;
+			double val;
+			val = in[e] * clutPoints_1;
+			if (val < 0.0) {
+				val = 0.0;
+				rv |= 1;
+			} else if (val > clutPoints_1) {
+				val = clutPoints_1;
+				rv |= 1;
+			}
+			x = (unsigned int)floor(val);		/* Grid coordinate */
+			if (x > clutPoints_2)
+				x = clutPoints_2;
+			co[e] = val - (double)x;	/* 1.0 - weight */
+			gp += x * p->dinc[e];		/* Add index offset for base of cube */
+		}
+	}
+	/* Do insertion sort on coordinates, smallest to largest. */
+	{
+		int f, vf;
+		unsigned int e;
+		double v;
+		for (e = 0; e < p->inputChan; e++)
+			si[e] = e;						/* Initial unsorted indexes */
+
+		for (e = 1; e < p->inputChan; e++) {
+			f = e;
+			v = co[si[f]];
+			vf = f;
+			while (f > 0 && co[si[f-1]] > v) {
+				si[f] = si[f-1];
+				f--;
+			}
+			si[f] = vf;
+		}
+	}
+	/* Now compute the current output value, and distribute the correction */
+	{
+		unsigned int e, f;
+		double w, ww = 0.0;		/* Current vertex weight, sum of weights squared */
+		double *ogp = gp;		/* Pointer to grid cube base */
+
+		w = 1.0 - co[si[p->inputChan-1]];		/* Vertex at base of cell */
+		ww += w * w;							/* Sum of weights squared */
+		for (f = 0; f < p->outputChan; f++)
+			cout[f] = w * gp[f];
+
+		for (e = p->inputChan-1; e > 0; e--) {	/* Middle verticies */
+			w = co[si[e]] - co[si[e-1]];
+			ww += w * w;							/* Sum of weights squared */
+			gp += p->dinc[si[e]];				/* Move to top of cell in next largest dimension */
+			for (f = 0; f < p->outputChan; f++)
+				cout[f] += w * gp[f];
+		}
+
+		w = co[si[0]];
+		ww += w * w;							/* Sum of weights squared */
+		gp += p->dinc[si[0]];					/* Far corner from base of cell */
+		for (f = 0; f < p->outputChan; f++)
+			cout[f] += w * gp[f];
+
+		/* We distribute the correction needed in proportion to the */
+		/* interpolation weighting, so the biggest correction is to the */
+		/* closest vertex. */
+		for (f = 0; f < p->outputChan; f++)
+			cout[f] = (out[f] - cout[f])/ww;	/* Amount to distribute */
+
+		gp = ogp;
+		w = 1.0 - co[si[p->inputChan-1]];		/* Vertex at base of cell */
+		for (f = 0; f < p->outputChan; f++) {
+			gp[f] += w * cout[f];			/* Apply correction */
+			if (gp[f] < 0.0) {
+				gp[f] = 0.0;
+				rv |= 2;
+			} else if (gp[f] > 1.0) {
+				gp[f] = 1.0;
+				rv |= 2;
+			}
+		}
+
+		for (e = p->inputChan-1; e > 0; e--) {	/* Middle verticies */
+			w = co[si[e]] - co[si[e-1]];
+			gp += p->dinc[si[e]];				/* Move to top of cell in next largest dimension */
+			for (f = 0; f < p->outputChan; f++) {
+				gp[f] += w * cout[f];			/* Apply correction */
+				if (gp[f] < 0.0) {
+					gp[f] = 0.0;
+					rv |= 2;
+				} else if (gp[f] > 1.0) {
+					gp[f] = 1.0;
+					rv |= 2;
+				}
+			}
+		}
+
+		w = co[si[0]];
+		gp += p->dinc[si[0]];					/* Far corner from base of cell */
+		for (f = 0; f < p->outputChan; f++) {
+			gp[f] += w * cout[f];			/* Apply correction */
+			if (gp[f] < 0.0) {
+				gp[f] = 0.0;
+				rv |= 2;
+			} else if (gp[f] > 1.0) {
+				gp[f] = 1.0;
+				rv |= 2;
+			}
+		}
+	}
+	return rv;
+}
+
+
+/* ----------------------------------------------- */
 /* Pseudo - Hilbert count sequencer */
 
 /* This multi-dimensional count sequence is a distributed */
@@ -5550,35 +5811,44 @@ static int getNormFunc(
 
 #define CLIP_MARGIN 0.005		/* Margine to allow before reporting clipping = 0.5% */
 
+/* NOTE that ICM_CLUT_SET_FILTER turns out to be not very useful, */
+/* as it can result in reversals. Could #ifdef out the code ?? */
+
 /* Helper function to set multiple Lut tables simultaneously. */
 /* Note that these tables all have to be compatible in */
 /* having the same configuration and resolution. */
 /* Set errc and return error number in underlying icc */
-/* Set warnc if there is clipping in the output values */
-/* 1 = input table, 2 = main clut, 3 = clut midpoin, 4 = midpoint interp, 5 = output table */
+/* Set warnc if there is clipping in the output values: */
+/*  1 = input table, 2 = main clut, 3 = clut midpoint, 4 = midpoint interp, 5 = output table */
+/* Note that clutfunc in[] value has "index under", ie: */
+/* at ((int *)in)[-chan-1], and for primary grid is simply the */
+/* grid index (ie. 5,3,8), and for the center of cells grid, is */
+/* the -index-1, ie. -6,-3,-8 */
 int icmSetMultiLutTables(
-	int ntables,							/* Number of tables to be set, 1..n */
-	icmLut **pp,							/* Pointer to array of Lut objects */
-	int     flags,							/* Setting flags */
-	void   *cbctx,							/* Opaque callback context pointer value */
-	icColorSpaceSignature insig, 			/* Input color space */
-	icColorSpaceSignature outsig, 			/* Output color space */
+	int ntables,						/* Number of tables to be set, 1..n */
+	icmLut **pp,						/* Pointer to array of Lut objects */
+	int     flags,						/* Setting flags */
+	void   *cbctx,						/* Opaque callback context pointer value */
+	icColorSpaceSignature insig, 		/* Input color space */
+	icColorSpaceSignature outsig, 		/* Output color space */
 	void (*infunc)(void *cbctx, double *out, double *in),
 							/* Input transfer function, inspace->inspace' (NULL = default) */
 							/* Will be called ntables times for each input grid value */
-	double *inmin, double *inmax,			/* Maximum range of inspace' values */
-											/* (NULL = default) */
+	double *inmin, double *inmax,		/* Maximum range of inspace' values */
+										/* (NULL = default) */
 	void (*clutfunc)(void *cbntx, double *out, double *in),
 							/* inspace' -> outspace[ntables]' transfer function */
 							/* will be called once for each input' grid value, and */
 							/* ntables output values should be written consecutively */
 							/* to out[]. */
-	double *clutmin, double *clutmax,		/* Maximum range of outspace' values */
-											/* (NULL = default) */
-	void (*outfunc)(void *cbntx, double *out, double *in))
+	double *clutmin, double *clutmax,	/* Maximum range of outspace' values */
+										/* (NULL = default) */
+	void (*outfunc)(void *cbntx, double *out, double *in),
 								/* Output transfer function, outspace'->outspace (NULL = deflt) */
 								/* Will be called ntables times on each output value */
-{
+	int *apxls_gmin, int *apxls_gmax	/* If not NULL, the grid indexes not to be affected */
+										/* by ICM_CLUT_SET_APXLS, defaulting to 0..>clutPoints-1 */
+) {
 	icmLut *p, *pn;				/* Pointer to 0'th nd tn'th Lut object */
 	icc *icp;					/* Pointer to common icc */
 	int tn;
@@ -5594,6 +5864,7 @@ int icmSetMultiLutTables(
 	double *_iv, *iv, *ivn;	/* Real index value/table value */
 	double imin[MAX_CHAN], imax[MAX_CHAN];
 	double omin[MAX_CHAN], omax[MAX_CHAN];
+	int def_apxls_gmin[MAX_CHAN], def_apxls_gmax[MAX_CHAN];
 	void (*ifromindex)(double *out, double *in);	/* Index to input color space function */
 	void (*itoentry)(double *out, double *in);		/* Input color space to entry function */
 	void (*ifromentry)(double *out, double *in);	/* Entry to input color space function */
@@ -5806,6 +6077,17 @@ int icmSetMultiLutTables(
 
 	/* Allocate space for cell center value lookup */
 	if (flags & ICM_CLUT_SET_APXLS) {
+		if (apxls_gmin == NULL) {
+			apxls_gmin = def_apxls_gmin;
+			for (e = 0; e < p->inputChan; e++)
+				apxls_gmin[e] = 0;
+		}
+		if (apxls_gmax == NULL) {
+			apxls_gmax = def_apxls_gmax;
+			for (e = 0; e < p->inputChan; e++)
+				apxls_gmax[e] = p->clutPoints-1;
+		}
+
 		if ((clutTable2 = (double **) icp->al->calloc(icp->al,sizeof(double *), ntables)) == NULL) {
 			sprintf(icp->err,"icmLut_set_tables malloc of cube center array failed");
 			icp->al->free(icp->al, _iv);
@@ -5884,7 +6166,7 @@ int icmSetMultiLutTables(
 			ti += ii[e] * p->dinc[e];				/* Clut index */
 			iv[e] = ii[e]/(p->clutPoints-1.0);		/* Vertex coordinates */
 			iv[e] = iv[e] * (imax[e] - imin[e]) + imin[e]; /* Undo expansion to 0.0 - 1.0 */
-			*((int *)&iv[-((int)e)-1]) = ii[e];	/* Trick to supply grid index in iv[] */
+			*((int *)&iv[-((int)e)-1]) = ii[e];		/* Trick to supply grid index in iv[] */
 		}
 	
 		if (flags & ICM_CLUT_SET_FILTER) {
@@ -5941,12 +6223,13 @@ int icmSetMultiLutTables(
 		if (clutTable2 != NULL) {
 
 			for (e = 0; e < p->inputChan; e++) {
-				if (ii[e] >= (p->clutPoints-1))
-					break;										/* Don't lookup beyond last */
+				if (ii[e] < apxls_gmin[e]
+				 || ii[e] >= apxls_gmax[e])
+					break;							/* Don't lookup outside least squares area */
 				iv[e] = (ii[e] + 0.5)/(p->clutPoints-1.0);		/* Vertex coordinates + 0.5 */
 				iv[e] = iv[e] * (imax[e] - imin[e]) + imin[e]; /* Undo expansion to 0.0 - 1.0 */
-				*((int *)&iv[-((int)e)-1]) = ii[e];	/* Trick to supply grid index in iv[] */
-													/* (Not this is only the base for +0.5) */
+				*((int *)&iv[-((int)e)-1]) = -ii[e]-1;	/* Trick to supply -ve grid index in iv[] */
+											    /* (Not this is only the base for +0.5 center) */
 			}
 
 			if (e >= p->inputChan) {	/* We're not on the last row */
@@ -5995,7 +6278,7 @@ int icmSetMultiLutTables(
 #define APXLS_DIFF_THRHESH 0.2
 	/* Deal with cell center value, aproximate least squares adjustment. */
 	/* Subtract some of the mean of the surrounding center values from each grid value. */
-	/* Skip the edges so that things like the white point are not changed. */
+	/* Skip the range edges so that things like the white point or Video sync are not changed. */
 	/* Avoid modifying the value if the difference between the */
 	/* interpolated value and the current value is too great, */
 	/* and there is the possibility of different color aliases. */
@@ -6005,9 +6288,9 @@ int icmSetMultiLutTables(
 		int ee;
 		double cw = 1.0/(double)(1 << p->inputChan);		/* Weight for each cube corner */
 
-		/* For each cell center point except last row */  
+		/* For each cell center point except last row because we access ii[e]+1 */  
 		for (e = 0; e < p->inputChan; e++)
-			ii[e] = 0;	/* init coords */
+			ii[e] = apxls_gmin[e];	/* init coords */
 
 		/* Compute linear interpolated value from center values */
 		for (ee = 0; ee < p->inputChan;) {
@@ -6051,14 +6334,15 @@ int icmSetMultiLutTables(
 						}
 						pn->clutTable[ti + f] = vv;
 					}
+					DBGSL(("nix %s apxls ov %s\n",icmPiv(p->inputChan, ii), icmPdv(pn->outputChan, ivn)));
 				}
 			}
 
 			/* Increment coord */
 			for (ee = 0; ee < p->inputChan; ee++) {
-				if (++ii[ee] < (p->clutPoints-2))		/* Don't go through upper edge */
+				if (++ii[ee] < (apxls_gmax[ee]-1))		/* Stop short of upper row of clutTable2 */
 					break;	/* No carry */
-				ii[ee] = 0;
+				ii[ee] = apxls_gmin[ee];
 			}
 		}
 
@@ -6069,6 +6353,7 @@ int icmSetMultiLutTables(
 	}
 
 	/* Apply any smoothing in the clipped region to the resulting clutTable */
+	/* !!! should avoid smoothing outside apxls_gmin[e] & apxls_gmax[e] region !!! */
 	if (clutTable3 != NULL) {
 		double *clutTable1;		/* Copy of current unfilted values */
 		FCOUNT(cc, MAX_CHAN, p->inputChan);   /* Surrounding counter */
@@ -6180,7 +6465,7 @@ int icmSetMultiLutTables(
 		free(clutTable3);
 	}
 
-	/* Create the output table entry values */
+	/* Create the 1D output table entry values */
 	for (tn = 0; tn < ntables; tn++) {
 		pn = pp[tn];
 		for (n = 0; n < pn->outputEnt; n++) {
@@ -6239,19 +6524,21 @@ int icmSetMultiLutTables(
 /* Set errc and return error number */
 /* Set warnc if there is clipping in the output values */
 static int icmLut_set_tables (
-icmLut *p,									/* Pointer to Lut object */
-int     flags,							/* Setting flags */
-void   *cbctx,								/* Opaque callback context pointer value */
-icColorSpaceSignature insig, 				/* Input color space */
-icColorSpaceSignature outsig, 				/* Output color space */
+icmLut *p,							/* Pointer to Lut object */
+int     flags,						/* Setting flags */
+void   *cbctx,						/* Opaque callback context pointer value */
+icColorSpaceSignature insig, 		/* Input color space */
+icColorSpaceSignature outsig, 		/* Output color space */
 void (*infunc)(void *cbcntx, double *out, double *in),
 								/* Input transfer function, inspace->inspace' (NULL = default) */
-double *inmin, double *inmax,				/* Maximum range of inspace' values (NULL = default) */
+double *inmin, double *inmax,		/* Maximum range of inspace' values (NULL = default) */
 void (*clutfunc)(void *cbctx, double *out, double *in),
 								/* inspace' -> outspace' transfer function */
-double *clutmin, double *clutmax,			/* Maximum range of outspace' values (NULL = default) */
-void (*outfunc)(void *cbctx, double *out, double *in)
-								/* Output transfer function, outspace'->outspace (NULL = deflt) */
+double *clutmin, double *clutmax,	/* Maximum range of outspace' values (NULL = default) */
+void (*outfunc)(void *cbctx, double *out, double *in),
+									/* Output transfer function, outspace'->outspace (NULL = deflt) */
+int *apxls_gmin, int *apxls_gmax	/* If not NULL, the grid indexes not to be affected */
+									/* by ICM_CLUT_SET_APXLS, defaulting to 0..>clutPoints-1 */
 ) {
 	struct _icmLut *pp[3];
 	
@@ -6263,7 +6550,8 @@ void (*outfunc)(void *cbctx, double *out, double *in)
 	                            inmin, inmax,
 	                            clutfunc,
 	                            clutmin, clutmax,
-	                            outfunc);
+	                            outfunc,
+	                            apxls_gmin, apxls_gmax);
 }
 
 /* - - - - - - - - - - - - - - - - */
@@ -6347,16 +6635,8 @@ static int icmLut_read(
 	p->outputChan = read_UInt8Number(bp+9);
 	p->clutPoints = read_UInt8Number(bp+10);
 
-	/* Sanity check */
-	if (p->inputChan > MAX_CHAN) {
-		sprintf(icp->err,"icmLut_read: Can't handle > %d input channels\n",MAX_CHAN);
-		return icp->errc = 1;
-	}
-
-	if (p->outputChan > MAX_CHAN) {
-		sprintf(icp->err,"icmLut_read: Can't handle > %d output channels\n",MAX_CHAN);
-		return icp->errc = 1;
-	}
+	if (icp->allowclutPoints256 && p->clutPoints == 0)		/* Special case */
+		p->clutPoints = 256;
 
 	/* Read 3x3 transform matrix */
 	for (j = 0; j < 3; j++) {		/* Rows */
@@ -6375,7 +6655,7 @@ static int icmLut_read(
 		bp = buf+52;
 	}
 
-	/* Sanity check dimensions. This protects against */
+	/* Sanity check tag size. This protects against */
 	/* subsequent integer overflows involving the dimensions. */
 	if ((size = icmLut_get_size((icmBase *)p)) == UINT_MAX
 	 || size > len) {
@@ -6384,12 +6664,15 @@ static int icmLut_read(
 		return icp->errc = 1;
 	}
 
-	/* Read the input tables */
-	size = (p->inputChan * p->inputEnt);
+	/* Sanity check the dimensions and resolution values agains limits, */
+	/* allocate space for them and generate internal offset tables. */
 	if ((rv = p->allocate((icmBase *)p)) != 0) {
 		icp->al->free(icp->al, buf);
 		return rv;
 	}
+
+	/* Read the input tables */
+	size = (p->inputChan * p->inputEnt);
 	if (p->ttype == icSigLut8Type) {
 		for (i = 0; i < size; i++, bp += 1)
 			p->inputTable[i] = read_DCS8Number(bp);
@@ -6400,10 +6683,6 @@ static int icmLut_read(
 
 	/* Read the clut table */
 	size = (p->outputChan * sat_pow(p->clutPoints,p->inputChan));
-	if ((rv = p->allocate((icmBase *)p)) != 0) {
-		icp->al->free(icp->al, buf);
-		return rv;
-	}
 	if (p->ttype == icSigLut8Type) {
 		for (i = 0; i < size; i++, bp += 1)
 			p->clutTable[i] = read_DCS8Number(bp);
@@ -6414,10 +6693,6 @@ static int icmLut_read(
 
 	/* Read the output tables */
 	size = (p->outputChan * p->outputEnt);
-	if ((rv = p->allocate((icmBase *)p)) != 0) {
-		icp->al->free(icp->al, buf);
-		return rv;
-	}
 	if (p->ttype == icSigLut8Type) {
 		for (i = 0; i < size; i++, bp += 1)
 			p->outputTable[i] = read_DCS8Number(bp);
@@ -6426,20 +6701,6 @@ static int icmLut_read(
 			p->outputTable[i] = read_DCS16Number(bp);
 	}
 
-	/* Private: compute dimensional increment though clut */
-	/* Note that first channel varies least rapidly. */
-	i = p->inputChan-1;
-	p->dinc[i--] = p->outputChan;
-	for (; i < p->inputChan; i--)
-		p->dinc[i] = p->dinc[i+1] * p->clutPoints;
-
-	/* Private: compute offsets from base of cube to other corners */
-	for (p->dcube[0] = 0, g = 1, j = 0; j < p->inputChan; j++) {
-		for (i = 0; i < g; i++)
-			p->dcube[g+i] = p->dcube[i] + p->dinc[j];
-		g *= 2;
-	}
-
 	icp->al->free(icp->al, buf);
 	return 0;
 }
@@ -6486,10 +6747,19 @@ static int icmLut_write(
 		icp->al->free(icp->al, buf);
 		return icp->errc = rv;
 	}
-	if ((rv = write_UInt8Number(p->clutPoints, bp+10)) != 0) {
-		sprintf(icp->err,"icmLut_write: write_UInt8Number() failed");
-		icp->al->free(icp->al, buf);
-		return icp->errc = rv;
+	
+	if (icp->allowclutPoints256 && p->clutPoints == 256) {
+		if ((rv = write_UInt8Number(0, bp+10)) != 0) {
+			sprintf(icp->err,"icmLut_write: write_UInt8Number() failed");
+			icp->al->free(icp->al, buf);
+			return icp->errc = rv;
+		}
+	} else {
+		if ((rv = write_UInt8Number(p->clutPoints, bp+10)) != 0) {
+			sprintf(icp->err,"icmLut_write: write_UInt8Number() failed");
+			icp->al->free(icp->al, buf);
+			return icp->errc = rv;
+		}
 	}
 
 	write_UInt8Number(0, bp+11);		/* Set padding to 0 */
@@ -6678,7 +6948,9 @@ static void icmLut_dump(
 	}
 }
 
-/* Allocate variable sized data elements */
+/* Sanity check the input & output dimensions, and */
+/* allocate variable sized data elements, and */
+/* generate internal dimension offset tables */
 static int icmLut_allocate(
 	icmBase *pp
 ) {
@@ -6686,7 +6958,7 @@ static int icmLut_allocate(
 	icmLut *p = (icmLut *)pp;
 	icc *icp = p->icp;
 
-	/* Sanity check */
+	/* Sanity check, so that dinc[] comp. won't fail */
 	if (p->inputChan < 1) {
 		sprintf(icp->err,"icmLut_alloc: Can't handle %d input channels\n",p->inputChan);
 		return icp->errc = 1;
@@ -6800,6 +7072,8 @@ static icmBase *new_icmLut(
 	icmLut *p;
 	if ((p = (icmLut *) icp->al->calloc(icp->al,1,sizeof(icmLut))) == NULL)
 		return NULL;
+	p->icp      = icp;
+
 	p->ttype    = icSigLut16Type;
 	p->refcount = 1;
 	p->get_size = icmLut_get_size;
@@ -6820,8 +7094,7 @@ static icmBase *new_icmLut(
 
 	/* Set method */
 	p->set_tables = icmLut_set_tables;
-
-	p->icp      = icp;
+	p->tune_value = icmLut_tune_value_sx;		/* Default to most likely simplex */
 
 	/* Set matrix to reasonable default */
 	for (i = 0; i < 3; i++)
@@ -7941,7 +8214,7 @@ static int icmColorantTable_allocate(
 	if (p->count != p->_count) {
 		unsigned int i;
 		if (ovr_mul(p->count, sizeof(icmColorantTableVal))) {
-			sprintf(icp->err,"icmColorantTable_alloc: count overflow (%d of %ld bytes)",p->count,sizeof(icmColorantTableVal));
+			sprintf(icp->err,"icmColorantTable_alloc: count overflow (%d of %lu bytes)",p->count,sizeof(icmColorantTableVal));
 			return icp->errc = 1;
 		}
 		if (p->data != NULL)
@@ -10784,10 +11057,18 @@ static int icmHeader_read(
     p->cmmId = read_SInt32Number(buf + 4);	/* CMM for profile */
 	tt       = read_UInt8Number(buf + 8);	/* Raw major version number */
     p->majv  = (tt >> 4) * 10 + (tt & 0xf);	/* Integer major version number */
-	icp->ver = p->majv > 3 ? 1 : 0;			/* Set major version flag in icc */
-	tt       = read_UInt8Number(buf + 9);	/* Raw minor/bug fix version numbers */
+	tt       = read_UInt8Number(buf + 9);	/* Raw minor & bug fix version numbers */
     p->minv  = (tt >> 4);					/* Integer minor version number */
     p->bfv   = (tt & 0xf);					/* Integer bug fix version number */
+	if (p->majv < 3) {						/* Set version class */
+    	if (p->minv >= 4)
+			icp->ver = icmVersion2_4;
+		else if (p->minv >= 3)
+			icp->ver = icmVersion2_3;
+		else
+			icp->ver = icmVersionDefault;
+	} else
+		icp->ver = icmVersion4_1;
 	p->deviceClass = (icProfileClassSignature)
 	           read_SInt32Number(buf + 12);	/* Type of profile */
     p->colorSpace = (icColorSpaceSignature)
@@ -10814,13 +11095,13 @@ static int icmHeader_read(
 	}
     p->creator = read_SInt32Number(buf + 80);	/* Profile creator */
 
-	for (tt = 0; tt < 16; tt++)
-		p->id[tt] = icp->ver ? read_UInt8Number(buf + 84 + tt) : 0;	/* Profile ID */
+	for (tt = 0; tt < 16; tt++)					/* Profile ID */
+		p->id[tt] = icp->ver >= icmVersion4_1 ? read_UInt8Number(buf + 84 + tt) : 0;
 
 	icp->al->free(icp->al, buf);
 
 #ifndef ENABLE_V4
-	if (icp->ver) {
+	if (icp->ver >= icmVersion4_1) {
 		sprintf(icp->err,"icmHeader_read: ICC V4 not supported!");
 		return icp->errc = 1;
 	}
@@ -10869,6 +11150,7 @@ static int icmHeader_write(
 		icp->al->free(icp->al, buf);
 		return icp->errc = 1;
 	}
+	// ~~~ Hmm. We're not checking ->ver is >= corresponding header version number ~~
 	tt = ((p->majv/10) << 4) + (p->majv % 10);
 	if ((rv = write_UInt8Number(tt, buf + 8)) != 0) {	/* Raw major version number */
 		sprintf(icp->err,"icmHeader_write: Uint8Number major version");
@@ -10946,7 +11228,7 @@ static int icmHeader_write(
 		icp->al->free(icp->al, buf);
 		return icp->errc = rv;
 	}
-	if (doid == 0 && icp->ver) {	/* ID is V4.0+ feature */
+	if (doid == 0 && icp->ver >= icmVersion4_1) {	/* ID is V4.0+ feature */
 		for (tt = 0; tt < 16; tt++) {
 		    if ((rv = write_UInt8Number(p->id[tt], buf + 84 + tt)) != 0) { /* Profile ID */
 				sprintf(icp->err,"icmHeader_write: UInt8Number creator");
@@ -10992,7 +11274,7 @@ static void icmHeader_dump(
 	op->gprintf(op,"  Rndrng Intnt = %s\n", string_RenderingIntent(p->renderingIntent));
 	op->gprintf(op,"  Illuminant   = %s\n", string_XYZNumber_and_Lab(&p->illuminant));
 	op->gprintf(op,"  Creator      = %s\n", tag2str(p->creator));	/* ~~~ */
-	if (p->icp->ver) {	/* V4.0+ feature */
+	if (p->icp->ver >= icmVersion4_1) {	/* V4.0+ feature */
 		for (i = 0; i < 16; i++) {		/* Check if ID has been set */
 			if (p->id[i] != 0)
 				break;
@@ -11369,10 +11651,15 @@ static int check_icc_legal(
 			/* Found entry, so now check that all the required tags are present. */
 			for (j = 0; tagchecktable[i].tags[j] != icMaxEnumType; j++) {
 				if (p->find_tag(p, tagchecktable[i].tags[j]) != 0) {	/* Not present! */
+#ifdef NEVER
+					printf("icc_check_legal: deviceClass %s is missing required tag %s", tag2str(sig), tag2str(tagchecktable[i].tags[j]));
+#endif
 					if (tagchecktable[i].chans == -200
 					 || tagchecktable[i].chans == -dchans) {	/* But can try next table */
 						break;
 					}
+					/* ~~99 Hmm. Should report all possible missing tags from */
+					/* previous failed tables ~~~999 */
 					sprintf(p->err,"icc_check_legal: deviceClass %s is missing required tag %s",
 					               tag2str(sig), tag2str(tagchecktable[i].tags[j]));
 					return p->errc = 1;
@@ -11776,7 +12063,7 @@ static int icc_write_x(
 
 	/* If V4.0+, Compute the MD5 id for the profile. */
 	/* We do this by writing to a fake icmFile */
-	if (p->ver) {
+	if (p->ver >= icmVersion4_1) {
 		icmMD5 *md5 = NULL;
 		icmFile *ofp, *dfp = NULL;
 
@@ -11796,13 +12083,13 @@ static int icc_write_x(
 		ofp = p->fp;
 		p->fp = dfp;
 
-		/* Dumy write the header */
+		/* Dummy write the header */
 		if ((rv = p->header->write(p->header, 0, 1)) != 0) {
 			p->al->free(p->al, buf);
 			return rv;
 		}
 	
-		/* Dumy write the tag table */
+		/* Dummy write the tag table */
 		if (   p->fp->seek(p->fp, 128) != 0
 		    || p->fp->write(p->fp, buf, 1, len) != len) {
 			sprintf(p->err,"icc_write: seek() or write() failed");
@@ -11810,7 +12097,7 @@ static int icc_write_x(
 			return p->errc = 1;
 		}
 	
-		/* Dumy write all the tag element data */
+		/* Dummy write all the tag element data */
 		/* (We invert meaning of touched here) */
 		for (i = 0; i < p->count; i++) {	/* For all the tag element data */
 			if (p->data[i].objp->touched == 0)
@@ -12197,8 +12484,8 @@ static icmBase *icc_read_tag_ix(
 }
 
 /* Read the tag element data of the first matching, and return a pointer to the object */
-/* Returns NULL if error - icc->errc will contain:         */
-/* 2 if not found                                          */
+/* Returns NULL if error - icc->errc will contain: */
+/* 2 if not found */
 /* Doesn't read uknown type tags */
 static icmBase *icc_read_tag(
 	icc *p,
@@ -12222,7 +12509,7 @@ static icmBase *icc_read_tag(
 }
 
 /* Read the tag element data of the first matching, and return a pointer to the object */
-/* Returns NULL if error.
+/* Returns NULL if error. */
 /* Returns an icmSigUnknownType object if the tag type isn't handled by a specific object. */
 /* NOTE: we don't handle tag duplication - you'll always get the first in the file. */
 static icmBase *icc_read_tag_any(
@@ -12651,6 +12938,25 @@ static void Lut_Luv2Lut(double *out, double *in) {
 }
 
 /* - - - - - - - - - - - - - - - - */
+/* Convert YCbCr to Lut number */
+/* We are assuming full range here. foot/head scaling */
+/* should be done outside the icc profile. */
+
+/* Convert Lut table index/value to YCbCr */
+static void Lut_Lut2YCbCr(double *out, double *in) {
+	out[0] = in[0];			/* Y */
+	out[1] = in[1] - 0.5;	/* Cb */
+	out[2] = in[2] - 0.5;	/* Cr */
+}
+
+/* Convert YCbCr to Lut table index/value */
+static void Lut_YCbCr2Lut(double *out, double *in) {
+	out[0] = in[0];			/* Y */
+	out[1] = in[1] + 0.5;	/* Cb */
+	out[2] = in[2] + 0.5;	/* Cr */
+}
+
+/* - - - - - - - - - - - - - - - - */
 /* Default N component conversions */
 static void Lut_N(double *out, double *in, int nc) {
 	for (--nc; nc >= 0; nc--)
@@ -12749,7 +13055,6 @@ static void Lut_15(double *out, double *in) {
 
 /* Function table - match conversions to color spaces. */
 /* Anything not here, we don't know how to convert. */
-/* (ie. YCbCr) */
 static struct {
 	icColorSpaceSignature csig;
 	void (*fromLut)(double *out, double *in);	/* from Lut index/entry */
@@ -12764,6 +13069,7 @@ static struct {
 	{icmSigLV2Data,    Lut_Lut2LV2_16,   Lut_L2LutV2_16 },
 	{icmSigLV4Data,    Lut_Lut2LV4_16,   Lut_L2LutV4_16 },
 	{icSigLuvData,     Lut_Lut2Luv,      Lut_Luv2Lut },
+	{icSigYCbCrData,   Lut_Lut2YCbCr,    Lut_YCbCr2Lut },
 	{icSigYxyData,     Lut_3,            Lut_3 },
 	{icSigRgbData,     Lut_3,            Lut_3 },
 	{icSigGrayData,    Lut_1,            Lut_1 },
@@ -12837,7 +13143,7 @@ static int getNormFunc(
 		if (tagType == icSigLut16Type)	/* Lut16 retains legacy encoding */
 			csig = icmSigLabV2Data;
 		else {							/* Other tag types use version specific encoding */
-			if (icp->ver)
+			if (icp->ver >= icmVersion4_1)
 				csig = icmSigLabV4Data;
 			else
 				csig = icmSigLabV2Data;
@@ -12870,7 +13176,6 @@ static int getNormFunc(
 
 /* Function table - match ranges to color spaces. */
 /* Anything not here, we don't know how to convert. */
-/* (ie. YCbCr) */
 /* Hmm. we're not handling Lab8 properly ?? ~~~8888 */
 static struct {
 	icColorSpaceSignature csig;
@@ -12889,7 +13194,7 @@ static struct {
 	{icmSigLV4Data,    1, { 0.0 }, { 100.0 } }, 
 	{icSigLuvData,     0, { 0.0, -128.0, -128.0 },
 	                      { 100.0, 127.0 + 255.0/256.0, 127.0 + 255.0/256.0 } },
-	{icSigYCbCrData,   1, { 0.0 }, { 1.0 } },			/* ??? */
+	{icSigYCbCrData,   0, { 0.0, -0.5, -0.5 }, { 1.0, 0.5, 0.5 } },		/* Full range */
 	{icSigYxyData,     1, { 0.0 }, { 1.0 } },			/* ??? */
 	{icSigRgbData,     1, { 0.0 }, { 1.0 } },
 	{icSigGrayData,    1, { 0.0 }, { 1.0 } },
@@ -12940,7 +13245,7 @@ static int getRange(
 		if (tagType == icSigLut16Type)	/* Lut16 retains legacy encoding */
 			csig = icmSigLabV2Data;
 		else {							/* Other tag types use version specific encoding */
-			if (icp->ver)
+			if (icp->ver >= icmVersion4_1)
 				csig = icmSigLabV4Data;
 			else
 				csig = icmSigLabV2Data;
@@ -12974,8 +13279,8 @@ static int getRange(
 	return 0;
 }
 
-/* ============================================= */
-/* Misc. support functions.                      */
+/* =============================================================== */
+/* Misc. support functions.                                        */
 
 /* Clamp a 3 vector to be +ve */
 void icmClamp3(double out[3], double in[3]) {
@@ -12998,6 +13303,20 @@ void icmSub3(double out[3], double in1[3], double in2[3]) {
 	out[2] = in1[2] - in2[2];
 }
 
+/* Divide two 3 vectors, out = in1/in2 */
+void icmDiv3(double out[3], double in1[3], double in2[3]) {
+	out[0] = in1[0]/in2[0];
+	out[1] = in1[1]/in2[1];
+	out[2] = in1[2]/in2[2];
+}
+
+/* Multiply two 3 vectors, out = in1 * in2 */
+void icmMul3(double out[3], double in1[3], double in2[3]) {
+	out[0] = in1[0] * in2[0];
+	out[1] = in1[1] * in2[1];
+	out[2] = in1[2] * in2[2];
+}
+
 /* - - - - - - - - - - - - - - - - - - - - - - - - */
 
 /* Set a 3x3 matrix to unity */
@@ -13307,6 +13626,18 @@ void icmBlend3(double out[3], double in0[3], double in1[3], double bf) {
 	out[2] = (1.0 - bf) * in0[2] + bf * in1[2];
 }
 
+/* Clip a vector to the range 0.0 .. 1.0 */
+void icmClip3(double out[3], double in[3]) {
+	int j;
+	for (j = 0; j < 3; j++) {
+		out[j] = in[j];
+		if (out[j] < 0.0)
+			out[j] = 0.0;
+		else if (out[j] > 1.0)
+			out[j] = 1.0;
+	}
+}
+
 /* Normalise a 3 vector to the given length. Return nz if not normalisable */
 int icmNormalize3(double out[3], double in[3], double len) {
 	double tt = sqrt(in[0] * in[0] + in[1] * in[1] + in[2] * in[2]);
@@ -13681,6 +14012,74 @@ double icmPlaneDist3(double eq[4], double p[3]) {
 }
 
 /* - - - - - - - - - - - - - - - - - - - - - - - - */
+/* Given 2 2D points, compute a plane equation. */
+/* The normal will be right handed given the order of the points */
+/* The plane equation will be the 2 normal components and the constant. */
+/* Return nz if any points are cooincident or co-linear */
+int icmPlaneEqn2(double eq[3], double p0[2], double p1[2]) {
+	double ll, v1[3];
+
+	/* Compute vectors along edge */
+	v1[0] = p1[0] - p0[0];
+	v1[1] = p1[1] - p0[1];
+
+	/* Normal to vector */
+	eq[0] =  v1[1];
+	eq[1] = -v1[0];
+
+	/* Normalise the equation */
+	ll = sqrt(eq[0] * eq[0] + eq[1] * eq[1]);
+	if (ll < 1e-10) {
+		return 1;
+	}
+	eq[0] /= ll;
+	eq[1] /= ll;
+
+	/* Compute the plane equation constant */
+	eq[2] = - (eq[0] * p0[0])
+	        - (eq[1] * p0[1]);
+
+	return 0;
+}
+
+/* Given a 2D point and a plane equation, return the signed */
+/* distance from the plane. The distance will be +ve if the point */
+/* is to the right of the plane formed by two points in order */
+double icmPlaneDist2(double eq[3], double p[2]) {
+	double rv;
+
+	rv = eq[0] * p[0]
+	   + eq[1] * p[1]
+	   + eq[2];
+
+	return rv;
+}
+
+/* Given two infinite 2D lines define by 4 points, compute the intersection. */
+/* Return nz if there is no intersection (lines are parallel) */
+int icmLineIntersect2(double res[2], double p1[2], double p2[2], double p3[2], double p4[2]) {
+	/* Compute by determinants */
+	double x1y2_y1x2 = p1[0] * p2[1] - p1[1] * p2[0];
+	double x3y4_y3x4 = p3[0] * p4[1] - p3[1] * p4[0];
+	double x1_x2     = p1[0] - p2[0];
+	double y1_y2     = p1[1] - p2[1];
+	double x3_x4     = p3[0] - p4[0];
+	double y3_y4     = p3[1] - p4[1];
+	double num;							/* Numerator */
+
+	num = x1_x2 * y3_y4 - y1_y2 * x3_x4;
+
+	if (fabs(num) < 1e-10)
+		return 1;
+
+	res[0] = (x1y2_y1x2 * x3_x4 - x1_x2 * x3y4_y3x4)/num;
+	res[1] = (x1y2_y1x2 * y3_y4 - y1_y2 * x3y4_y3x4)/num;
+
+	return 0;
+}
+
+
+/* - - - - - - - - - - - - - - - - - - - - - - - - */
 /* CIE Y (range 0 .. 1) to perceptual CIE 1976 L* (range 0 .. 100) */
 double
 icmY2L(double val) {
@@ -13778,7 +14177,7 @@ void icmLCh2Lab(double *out, double *in) {
 	out[2] = C * sin(h);
 }
 
-/* Lab to LCh */
+/* Lab to LCh (general to polar, works with Luv too) */
 void icmLab2LCh(double *out, double *in) {
 	double C, h;
 
@@ -13883,9 +14282,6 @@ extern ICCLIB_API void icmLuv2XYZ(icmXYZNumber *w, double *out, double *in) {
 	out[2] = Z;
 }
 
-/* NOTE :- none of the following seven have been protected */
-/* against arithmmetic issues (ie. for black) */
-
 /* CIE XYZ to perceptual CIE 1976 UCS diagram Yu'v'*/
 /* (Yu'v' is a better chromaticity space than Yxy) */
 extern ICCLIB_API void icmXYZ21976UCS(double *out, double *in) {
@@ -13893,8 +14289,15 @@ extern ICCLIB_API void icmXYZ21976UCS(double *out, double *in) {
 	double den, u, v;
 
 	den = (X + 15.0 * Y + 3.0 * Z);
-	u = (4.0 * X) / den;
-	v = (9.0 * Y) / den;
+
+	if (den < 1e-9) {
+		Y = 0.0;
+		u = 4.0/19.0;
+		v = 9.0/19.0;
+	} else {
+		u = (4.0 * X) / den;
+		v = (9.0 * Y) / den;
+	}
 	
 	out[0] = Y;
 	out[1] = u;
@@ -13909,8 +14312,12 @@ extern ICCLIB_API void icm1976UCS2XYZ(double *out, double *in) {
 	u = in[1];
 	v = in[2];
 
-	X = ((9.0 * u * Y)/(4.0 * v));
-	Z = -(((20.0 * v + 3.0 * u - 12.0) * Y)/(4.0 * v));
+	if (v < 1e-9) {
+		X = Y = Z = 0.0;
+	} else {
+		X = ((9.0 * u * Y)/(4.0 * v));
+		Z = -(((20.0 * v + 3.0 * u - 12.0) * Y)/(4.0 * v));
+	}
 
 	out[0] = X;
 	out[1] = Y;
@@ -13922,10 +14329,18 @@ extern ICCLIB_API void icm1976UCS2XYZ(double *out, double *in) {
 /*  in computing color temperatures.) */
 extern ICCLIB_API void icmXYZ21960UCS(double *out, double *in) {
 	double X = in[0], Y = in[1], Z = in[2];
-	double u, v;
+	double den, u, v;
 
-	u = (4.0 * X) / (X + 15.0 * Y + 3.0 * Z);
-	v = (6.0 * Y) / (X + 15.0 * Y + 3.0 * Z);
+	den = (X + 15.0 * Y + 3.0 * Z);
+
+	if (den < 1e-9) {
+		Y = 0.0;
+		u = 4.0/19.0;
+		v = 6.0/19.0;
+	} else {
+		u = (4.0 * X) / den; 
+		v = (6.0 * Y) / den;
+	}
 	
 	out[0] = Y;
 	out[1] = u;
@@ -13940,8 +14355,12 @@ extern ICCLIB_API void icm1960UCS2XYZ(double *out, double *in) {
 	u = in[1];
 	v = in[2];
 
-	X = ((3.0 * u * Y)/(2.0 * v));
-	Z = -(((10.0 * v + u - 4.0) * Y)/(2.0 * v));
+	if (v < 1e-9) {
+		X = Y = Z = 0.0;
+	} else {
+		X = ((3.0 * u * Y)/(2.0 * v));
+		Z = -(((10.0 * v + u - 4.0) * Y)/(2.0 * v));
+	}
 
 	out[0] = X;
 	out[1] = Y;
@@ -13989,6 +14408,7 @@ extern ICCLIB_API void icm1964WUV2XYZ(icmXYZNumber *w, double *out, double *in)
 }
 
 /* CIE CIE1960 UCS to perceptual CIE 1964 WUV (U*V*W*) */
+/* (This is used in computing CRI) */
 extern ICCLIB_API void icm1960UCS21964WUV(icmXYZNumber *w, double *out, double *in) {
 	double W, U, V;
 	double wucs[3];
@@ -14006,6 +14426,7 @@ extern ICCLIB_API void icm1960UCS21964WUV(icmXYZNumber *w, double *out, double *
 }
 
 /* - - - - - - - - - - - - - - - - - - - - - - - - */
+/* NOTE :- that these values are for the 1931 standard observer */
 
 /* available D50 Illuminant */
 icmXYZNumber icmD50 = { 		/* Profile illuminant - D50 */
@@ -14041,6 +14462,7 @@ double icmD65_100_ary3[3] = { 	/* Profile illuminant - D65, scaled to 100 */
 	95.05, 100.00, 108.90
 };
 
+
 /* Default black point */
 icmXYZNumber icmBlack = {
     0.0000, 0.0000, 0.0000
@@ -14126,7 +14548,7 @@ double icmCIE94sq(double Lab0[3], double Lab1[3]) {
 		c12 = sqrt(c1 * c2);	/* Symetric chromanance */
 
 		/* delta chromanance squared */
-		dc = c2 - c1;
+		dc = c1 - c2;
 		dcsq = dc * dc;
 	}
 
@@ -14137,8 +14559,8 @@ double icmCIE94sq(double Lab0[3], double Lab1[3]) {
 		double sc, sh;
 
 		/* Weighting factors for delta chromanance & delta hue */
-		sc = 1.0 + 0.048 * c12;
-		sh = 1.0 + 0.014 * c12;
+		sc = 1.0 + 0.045 * c12;
+		sh = 1.0 + 0.015 * c12;
 		return dlsq + dcsq/(sc * sc) + dhsq/(sh * sh);
 	}
 }
@@ -14286,7 +14708,7 @@ double icmCIE2K(double *Lab0, double *Lab1) {
 }
 
 /* Return the CIEDE2000 Delta E color difference measure for two XYZ values */
-extern ICCLIB_API double icmXYZCIE2K(icmXYZNumber *w, double *in0, double *in1) {
+ICCLIB_API double icmXYZCIE2K(icmXYZNumber *w, double *in0, double *in1) {
 	double lab0[3], lab1[3];
 
 	icmXYZ2Lab(w, lab0, in0);
@@ -14295,12 +14717,15 @@ extern ICCLIB_API double icmXYZCIE2K(icmXYZNumber *w, double *in0, double *in1)
 }
 
 
+
 /* - - - - - - - - - - - - - - - - - - - - - - - - */
 /* Chromatic adaptation transform utility */
 /* Return a 3x3 chromatic adaptation matrix */
 /* Use icmMulBy3x3(dst, mat, src) */
+/* NOTE that to transform primaries they */
+/* must be mat[XYZ][RGB] format! */
 void icmChromAdaptMatrix(
-	int flags,				/* Use bradford, Transform given matrix flags */
+	int flags,				/* Use Bradford, Transform given matrix flags */
 	icmXYZNumber d_wp,		/* Destination white point */
 	icmXYZNumber s_wp,		/* Source white point */
 	double mat[3][3]		/* Destination matrix */
@@ -14376,7 +14801,7 @@ int icmRGBprim2matrix(
 	icmXYZNumber red,		/* Red colorant */
 	icmXYZNumber green,		/* Green colorant */
 	icmXYZNumber blue,		/* Blue colorant */
-	double mat[3][3]		/* Destination matrix */
+	double mat[3][3]		/* Destination matrix[RGB][XYZ] */
 ) {
 	double tmat[3][3];
 	double t[3];
@@ -14409,19 +14834,73 @@ int icmRGBprim2matrix(
 
 	/* Now formulate the transform matrix */
 	mat[0][0] = red.X   * t[0];
-	mat[0][1] = green.X * t[1];
-	mat[0][2] = blue.X  * t[2];
-	mat[1][0] = red.Y   * t[0];
+	mat[1][0] = green.X * t[1];
+	mat[2][0] = blue.X  * t[2];
+	mat[0][1] = red.Y   * t[0];
 	mat[1][1] = green.Y * t[1];
-	mat[1][2] = blue.Y  * t[2];
-	mat[2][0] = red.Z   * t[0];
-	mat[2][1] = green.Z * t[1];
+	mat[2][1] = blue.Y  * t[2];
+	mat[0][2] = red.Z   * t[0];
+	mat[1][2] = green.Z * t[1];
 	mat[2][2] = blue.Z  * t[2];
 
 	return 0;
 }
 
 /* - - - - - - - - - - - - - - - - - - - - - - - - */
+/* Pre-round RGB device primary values to ensure that */
+/* the sum of the quantized primaries is the same as */
+/* the quantized sum. */
+void quantizeRGBprimsS15Fixed16(
+	double mat[3][3]		/* matrix[RGB][XYZ] */
+) {
+	int i, j;
+	double sum[3];
+
+//	printf("D50 = %f %f %f\n",icmD50.X, icmD50.Y, icmD50.Z);
+
+	/* Compute target sum of primary XYZ */
+	for (i = 0; i < 3; i++) {
+		sum[i] = 0.0;
+		for (j = 0; j < 3; j++)
+			sum[i] += mat[j][i];
+	}
+//	printf("Sum = %f %f %f\n",sum[0], sum[1], sum[2]);
+
+	/* Pre-quantize the primary XYZ's, and then ensure that the */
+	/* sum of the quantized values is the quantized sum by assigning */
+	/* the rounding error to the largest component. */
+	for (i = 0; i < 3; i++) {
+		int bix = 0;
+		double bval = -1e9;
+
+		/* locate the largest and quantize each component */
+		for (j = 0; j < 3; j++) {
+			if (fabs(mat[j][i]) > bval) {	/* Locate largest */
+				bix = j;
+				bval = fabs(mat[j][i]);
+			} 
+			mat[j][i] = round_S15Fixed16Number(mat[j][i]);
+		}
+
+		/* Compute the value the largest has to be */
+		/* to ensure that sum of the quantized values is */
+		/* equal to the quantized sum */
+		for (j = 0; j < 3; j++) {
+			if (j == bix)
+				continue;
+			sum[i] -= mat[j][i];
+		}
+		mat[bix][i] = round_S15Fixed16Number(sum[i]);
+
+		/* Check the sum of the quantized values */
+//		sum[i] = 0.0;
+//		for (j = 0; j < 3; j++)
+//			sum[i] += mat[j][i];
+	}
+//	printf("Q Sum = %f %f %f\n",sum[0], sum[1], sum[2]);
+}
+
+/* - - - - - - - - - - - - - - - - - - - - - - - - */
 /* Some PCS utility functions */
 
 /* Clip Lab, while maintaining hue angle. */
@@ -14525,7 +15004,426 @@ int icmClipXYZ(double out[3], double in[3]) {
 	return 1;
 }
 
-/* - - - - - - - - - - - - - - - - - - - - - - - - */
+/* --------------------------------------------------------------- */
+/* Some video specific functions */
+
+/* Convert Lut table index/value to YPbPr */
+/* (Same as Lut_Lut2YPbPr() ) */ 
+void icmLut2YPbPr(double *out, double *in) {
+	out[0] = in[0];			/* Y */
+	out[1] = in[1] - 0.5;	/* Cb */
+	out[2] = in[2] - 0.5;	/* Cr */
+}
+
+/* Convert YPbPr to Lut table index/value */
+/* (Same as Lut_YPbPr2Lut() ) */ 
+void icmYPbPr2Lut(double *out, double *in) {
+	out[0] = in[0];			/* Y */
+	out[1] = in[1] + 0.5;	/* Cb */
+	out[2] = in[2] + 0.5;	/* Cr */
+}
+
+/* Convert Rec601 RGB' into YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+/* [From the Rec601 spec. ] */
+void icmRec601_RGBd_2_YPbPr(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 0.299 * in[0] + 0.587 * in[1] + 0.114 * in[2];
+
+	tt[1] =     -0.299 /1.772 * in[0]
+	      +     -0.587 /1.772 * in[1]
+          + (1.0-0.114)/1.772 * in[2];
+
+	tt[2] = (1.0-0.299)/1.402 * in[0]
+	      +     -0.587 /1.402 * in[1]
+          +     -0.114 /1.402 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec601 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+/* [Inverse of above] */
+void icmRec601_YPbPr_2_RGBd(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 1.000000000 * in[0] +  0.000000000 * in[1] +  1.402000000 * in[2];
+	tt[1] = 1.000000000 * in[0] + -0.344136286 * in[1] + -0.714136286 * in[2];
+	tt[2] = 1.000000000 * in[0] +  1.772000000 * in[1] +  0.000000000 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+
+/* Convert Rec709 1150/60/2:1 RGB' into YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+/* [From the Rec709 specification] */
+void icmRec709_RGBd_2_YPbPr(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 0.2126 * in[0] + 0.7152 * in[1] + 0.0722 * in[2];
+
+	tt[1] = 0.5389 * -0.2126 * in[0]
+	      + 0.5389 * -0.7152 * in[1]
+          + 0.5389 * (1.0-0.0722) * in[2];
+
+	tt[2] = 0.6350 * (1.0-0.2126) * in[0]
+	      + 0.6350 * -0.7152 * in[1]
+          + 0.6350 * -0.0722 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec709 1150/60/2:1 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+/* [Inverse of above] */
+void icmRec709_YPbPr_2_RGBd(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 1.000000000 * in[0] +  0.000000000 * in[1] +  1.574803150 * in[2];
+	tt[1] = 1.000000000 * in[0] + -0.187327487 * in[1] + -0.468125209 * in[2];
+	tt[2] = 1.000000000 * in[0] +  1.855631843 * in[1] +  0.000000000 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec709 1250/50/2:1 RGB' into YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+/* [From the Rec709 specification] */
+void icmRec709_50_RGBd_2_YPbPr(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 0.299 * in[0] + 0.587 * in[1] + 0.114 * in[2];
+
+	tt[1] = 0.564 * -0.299 * in[0]
+	      + 0.564 * -0.587 * in[1]
+          + 0.564 * (1.0-0.114) * in[2];
+
+	tt[2] = 0.713 * (1.0-0.299) * in[0]
+	      + 0.713 * -0.587 * in[1]
+          + 0.713 * -0.114 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec709 1250/50/2:1 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+/* [Inverse of above] */
+void icmRec709_50_YPbPr_2_RGBd(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 1.000000000 * in[0] +  0.000000000 * in[1] +  1.402524544 * in[2];
+	tt[1] = 1.000000000 * in[0] + -0.344340136 * in[1] + -0.714403473 * in[2];
+	tt[2] = 1.000000000 * in[0] +  1.773049645 * in[1] +  0.000000000 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+
+/* Convert Rec2020 RGB' into Non-constant liminance YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+/* [From the Rec2020 specification] */
+void icmRec2020_NCL_RGBd_2_YPbPr(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 0.2627 * in[0] + 0.6780 * in[1] + 0.0593 * in[2];
+
+	tt[1] = 1/1.8814 * -0.2627 * in[0]
+	      + 1/1.8814 * -0.6780 * in[1]
+          + 1/1.8814 * (1.0-0.0593) * in[2];
+
+	tt[2] = 1/1.4746 * (1.0-0.2627) * in[0]
+	      + 1/1.4746 * -0.6780 * in[1]
+          + 1/1.4746 * -0.0593 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec2020 Non-constant liminance YPbPr into RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+/* [Inverse of above] */
+void icmRec2020_NCL_YPbPr_2_RGBd(double out[3], double in[3]) {
+	double tt[3];
+
+	tt[0] = 1.000000000 * in[0] +  0.000000000 * in[1] +  1.474600000 * in[2];
+	tt[1] = 1.000000000 * in[0] + -0.164553127 * in[1] + -0.571353127 * in[2];
+	tt[2] = 1.000000000 * in[0] +  1.881400000 * in[1] +  0.000000000 * in[2];
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec2020 RGB' into Constant liminance YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+/* [From the Rec2020 specification] */
+void icmRec2020_CL_RGBd_2_YPbPr(double out[3], double in[3]) {
+	int i;
+	double tt[3];
+
+	/* Convert RGB' to RGB */
+	for (i = 0; i < 3; i++) {
+		if (in[i] < (4.5 * 0.0181))
+			tt[i] = in[i]/4.5;
+		else
+			tt[i] = pow((in[i] + 0.0993)/1.0993, 1.0/0.45);
+	}
+
+	/* Y value */
+	tt[0] = 0.2627 * tt[0] + 0.6780 * tt[1] + 0.0593 * tt[2];
+
+	/* Y' value */
+	if (tt[0] < 0.0181)
+		tt[0] = tt[0] * 4.5;
+	else
+		tt[0] = 1.0993 * pow(tt[0], 0.45) - 0.0993;
+
+	tt[1] = in[2] - tt[0];
+	if (tt[1] <= 0.0)
+		tt[1] /= 1.9404;
+	else
+		tt[1] /= 1.5816;
+
+	tt[2] = in[0] - tt[0];
+	if (tt[2] <= 0.0)
+		tt[2] /= 1.7184;
+	else
+		tt[2] /= 0.9936;
+
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+/* Convert Rec2020 Constant liminance YPbPr into RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+/* [Inverse of above] */
+void icmRec2020_CL_YPbPr_2_RGBd(double out[3], double in[3]) {
+	int i;
+	double tin[3], tt[3];
+
+	/* Y' */
+	tin[0] = in[0];
+
+	/* B' - Y' */
+	if (in[1] <= 0.0)
+		tin[1] = 1.9404 * in[1];
+	else
+		tin[1] = 1.5816 * in[1];
+
+	/* R' - Y' */
+	if (in[2] <= 0.0)
+		tin[2] = 1.7184 * in[2];
+	else
+		tin[2] = 0.9936 * in[2];
+
+
+	/* R' */
+	tt[0] = tin[2] + tin[0];
+
+	/* Y' */
+	tt[1] = tin[0];
+
+	/* B' */
+	tt[2] = tin[1] + tin[0];
+
+	/* Convert RYB' to RYB */
+	for (i = 0; i < 3; i++) {
+		if (tt[i] < (4.5 * 0.0181))
+			tin[i] = tt[i]/4.5;
+		else
+			tin[i] = pow((tt[i] + 0.0993)/1.0993, 1.0/0.45);
+	}
+	
+	/* G */
+	tt[1] = (tin[1] - 0.2627 * tin[0] - 0.0593 * tin[2])/0.6780;
+
+	/* G' */
+	if (tt[1] < 0.0181)
+		tt[1] = tt[1] * 4.5;
+	else
+		tt[1] = 1.0993 * pow(tt[1], 0.45) - 0.0993;
+	
+	out[0] = tt[0];
+	out[1] = tt[1];
+	out[2] = tt[2];
+}
+
+
+/* Convert Rec601/Rec709/Rec2020 YPbPr to YCbCr Video range. */
+/* input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, */
+/* output 16/255 .. 235/255, 16/255 .. 240/255, 16/255 .. 240/255 */ 
+void icmRecXXX_YPbPr_2_YCbCr(double out[3], double in[3]) {
+	out[0] = ((235.0 - 16.0) * in[0] + 16.0)/255.0;
+	out[1] = ((128.0 - 16.0) * 2.0 * in[1] + 128.0)/255.0;
+	out[2] = ((128.0 - 16.0) * 2.0 * in[2] + 128.0)/255.0;
+}
+
+/* Convert Rec601/Rec709/Rec2020 Video YCbCr to YPbPr range. */
+/* input 16/255 .. 235/255, 16/255 .. 240/255, 16/255 .. 240/255 */ 
+/* output 0..1, -0.5 .. 0.5, -0.5 .. 0.5, */
+void icmRecXXX_YCbCr_2_YPbPr(double out[3], double in[3]) {
+	out[0] = (255.0 * in[0] - 16.0)/(235.0 - 16.0);
+	out[1] = (255.0 * in[1] - 128.0)/(2.0 * (128.0 - 16.0));
+	out[2] = (255.0 * in[2] - 128.0)/(2.0 * (128.0 - 16.0));
+}
+
+/* Convert full range RGB to Video range 16..235 RGB */
+void icmRGB_2_VidRGB(double out[3], double in[3]) {
+	out[0] = ((235.0 - 16.0) * in[0] + 16.0)/255.0;
+	out[1] = ((235.0 - 16.0) * in[1] + 16.0)/255.0;
+	out[2] = ((235.0 - 16.0) * in[2] + 16.0)/255.0;
+}
+
+/* Convert Video range 16..235 RGB to full range RGB */
+/* Return nz if outside RGB range */
+void icmVidRGB_2_RGB(double out[3], double in[3]) {
+	out[0] = (255.0 * in[0] - 16.0)/(235.0 - 16.0);
+	out[1] = (255.0 * in[1] - 16.0)/(235.0 - 16.0);
+	out[2] = (255.0 * in[2] - 16.0)/(235.0 - 16.0);
+}
+
+/* =============================================================== */
+/* PS 3.14-2009, Digital Imaging and Communications in Medicine */
+/* (DICOM) Part 14: Grayscale Standard Display Function */
+
+/* JND index value 1..1023 to L 0.05 .. 3993.404 cd/m^2 */
+static double icmDICOM_fwd_nl(double jnd) {
+	double a = -1.3011877;
+	double b = -2.5840191e-2;
+	double c =  8.0242636e-2;
+	double d = -1.0320229e-1;
+	double e =  1.3646699e-1;
+	double f =  2.8745620e-2;
+	double g = -2.5468404e-2;
+	double h = -3.1978977e-3;
+	double k =  1.2992634e-4;
+	double m =  1.3635334e-3;
+	double jj, num, den, rv;
+
+	jj = jnd = log(jnd);
+
+	num = a;
+	den = 1.0;
+	num += c * jj;
+	den += b * jj;
+	jj *= jnd;
+	num += e * jj;
+	den += d * jj;
+	jj *= jnd;
+	num += g * jj;
+	den += f * jj;
+	jj *= jnd;
+	num += m * jj;
+	den += h * jj;
+	jj *= jnd;
+	den += k * jj;
+	
+	rv = pow(10.0, num/den);
+
+	return rv;
+}
+
+/* JND index value 1..1023 to L 0.05 .. 3993.404 cd/m^2 */
+double icmDICOM_fwd(double jnd) {
+
+	if (jnd < 0.5)
+		jnd = 0.5;
+	if (jnd > 1024.0)
+		jnd = 1024.0;
+
+	return icmDICOM_fwd_nl(jnd);
+}
+
+/* L 0.05 .. 3993.404 cd/m^2 to JND index value 1..1023 */
+/* This is not super accurate -  typically to 0.03 .. 0.1 jne. */
+static double icmDICOM_bwd_apx(double L) {
+	double A = 71.498068;
+	double B = 94.593053;
+	double C = 41.912053;
+	double D =  9.8247004;
+	double E =  0.28175407;
+	double F = -1.1878455;
+	double G = -0.18014349;
+	double H =  0.14710899;
+	double I = -0.017046845;
+	double rv, LL;
+
+	if (L < 0.049982) {			/* == jnd 0.5 */
+		return 0.5;
+	}
+	if (L > 4019.354716)		/* == jnd 1024 */
+		L = 4019.354716;
+
+	LL = L = log10(L);
+	rv = A;
+	rv += B * LL;
+	LL *= L;
+	rv += C * LL;
+	LL *= L;
+	rv += D * LL;
+	LL *= L;
+	rv += E * LL;
+	LL *= L;
+	rv += F * LL;
+	LL *= L;
+	rv += G * LL;
+	LL *= L;
+	rv += H * LL;
+	LL *= L;
+	rv += I * LL;
+
+	return rv;
+}
+
+/* L 0.05 .. 3993.404 cd/m^2 to JND index value 1..1023 */
+/* Polish the aproximate solution twice using Newton's itteration */
+double icmDICOM_bwd(double L) {
+	double rv, Lc, prv, pLc, de;
+	int i;
+
+	if (L < 0.045848) 			/* == jnd 0.5 */
+		L = 0.045848;
+	if (L > 4019.354716)		/* == jnd 1024 */
+		L = 4019.354716;
+
+	/* Approx solution */
+	rv = icmDICOM_bwd_apx(L);
+
+	/* Compute aprox derivative */
+	Lc = icmDICOM_fwd_nl(rv);
+
+	prv = rv + 0.01;
+	pLc = icmDICOM_fwd_nl(prv);
+
+	do {
+		de = (rv - prv)/(Lc - pLc);
+		prv = rv;
+		rv -= (Lc - L) * de;
+		pLc = Lc;
+		Lc = icmDICOM_fwd_nl(rv);
+	} while (fabs(Lc - L) > 1e-8);
+
+	return rv;
+}
+
+
+/* =============================================================== */
 
 /* Object for computing RFC 1321 MD5 checksums. */
 /* Derived from Colin Plumb's 1993 public domain code. */
@@ -16169,25 +17067,25 @@ double *in			/* Vector of input values */
 	icmLut *lut = p->lut;
 	double temp[MAX_CHAN];
 
-	DBGLL(("icmLuLut_lookup: in = %s\n", icmPdv(p->inputChan, in)));
+	DBGLL(("icmLuLut_lookup: in = %s\n", icmPdv(p->lut->inputChan, in)));
 	rv |= p->in_abs(p,temp,in);						/* Possible absolute conversion */
-	DBGLL(("icmLuLut_lookup: in_abs = %s\n", icmPdv(p->inputChan, temp)));
+	DBGLL(("icmLuLut_lookup: in_abs = %s\n", icmPdv(p->lut->inputChan, temp)));
 	if (p->usematrix) {
 		rv |= lut->lookup_matrix(lut,temp,temp);/* If XYZ, multiply by non-unity matrix */
-		DBGLL(("icmLuLut_lookup: matrix = %s\n", icmPdv(p->inputChan, temp)));
+		DBGLL(("icmLuLut_lookup: matrix = %s\n", icmPdv(p->lut->inputChan, temp)));
 	}
 	p->in_normf(temp, temp);					/* Normalize for input color space */
-	DBGLL(("icmLuLut_lookup: norm = %s\n", icmPdv(p->inputChan, temp)));
+	DBGLL(("icmLuLut_lookup: norm = %s\n", icmPdv(p->lut->inputChan, temp)));
 	rv |= lut->lookup_input(lut,temp,temp);		/* Lookup though input tables */
-	DBGLL(("icmLuLut_lookup: input = %s\n", icmPdv(p->inputChan, temp)));
+	DBGLL(("icmLuLut_lookup: input = %s\n", icmPdv(p->lut->inputChan, temp)));
 	rv |= p->lookup_clut(lut,out,temp);			/* Lookup though clut tables */
-	DBGLL(("icmLuLut_lookup: clut = %s\n", icmPdv(p->outputChan, out)));
+	DBGLL(("icmLuLut_lookup: clut = %s\n", icmPdv(p->lut->outputChan, out)));
 	rv |= lut->lookup_output(lut,out,out);		/* Lookup though output tables */
-	DBGLL(("icmLuLut_lookup: output = %s\n", icmPdv(p->outputChan, out)));
+	DBGLL(("icmLuLut_lookup: output = %s\n", icmPdv(p->lut->outputChan, out)));
 	p->out_denormf(out,out);					/* Normalize for output color space */
-	DBGLL(("icmLuLut_lookup: denorm = %s\n", icmPdv(p->outputChan, out)));
+	DBGLL(("icmLuLut_lookup: denorm = %s\n", icmPdv(p->lut->outputChan, out)));
 	rv |= p->out_abs(p,out,out);				/* Possible absolute conversion */
-	DBGLL(("icmLuLut_lookup: out_abse = %s\n", icmPdv(p->outputChan, out)));
+	DBGLL(("icmLuLut_lookup: out_abse = %s\n", icmPdv(p->lut->outputChan, out)));
 
 	return rv;
 }
@@ -16891,8 +17789,10 @@ icc_new_icmLuLut(
 
 		if (use_sx) {
 			p->lookup_clut = p->lut->lookup_clut_sx;
+			p->lut->tune_value = icmLut_tune_value_sx;
 		} else {
 			p->lookup_clut = p->lut->lookup_clut_nl;
+			p->lut->tune_value = icmLut_tune_value_nl;
 		}
 	}
 #else	/* Development code */
@@ -17665,7 +18565,7 @@ icmAlloc *al			/* Memory allocator */
 	if ((p = (icc *) al->calloc(al, 1,sizeof(icc))) == NULL) {
 		return NULL;
 	}
-	p->ver = 0;			/* default is V2 profile */
+	p->ver = icmVersionDefault;		/* default is V2.2.0 profile */
 
 	p->al = al;			/* Heap allocator */
 
diff --git a/icc/icc.h b/icc/icc.h
index 7c3a65b..ba66581 100644
--- a/icc/icc.h
+++ b/icc/icc.h
@@ -8,7 +8,7 @@
  * Date:    1999/11/29
  * Version: 2.15
  *
- * Copyright 1997 - 2012 Graeme W. Gill
+ * Copyright 1997 - 2013 Graeme W. Gill
  *
  * This material is licensed with an "MIT" free use license:-
  * see the License.txt file in this directory for licensing details.
@@ -30,8 +30,8 @@
 
 /* Version of icclib release */
 
-#define ICCLIB_VERSION 0x020016
-#define ICCLIB_VERSION_STR "2.16"
+#define ICCLIB_VERSION 0x020017
+#define ICCLIB_VERSION_STR "2.17"
 
 #undef ENABLE_V4		/* V4 is not fully implemented */
 
@@ -778,8 +778,20 @@ struct _icmLut {
 								/* inspace' -> outspace' transfer function */
 		double *clutmin, double *clutmax,		/* Maximum range of outspace' values */
 												/* (NULL = default) */
-		void (*outfunc)(void *cbntx, double *out, double *in));
+		void (*outfunc)(void *cbntx, double *out, double *in),
 								/* Output transfer function, outspace'->outspace (NULL = deflt) */
+		int *apxls_gmin, int *apxls_gmax	/* If not NULL, the grid indexes not to be affected */
+										/* by ICM_CLUT_SET_APXLS, defaulting to 0..>clutPoints-1 */
+	);
+
+	/* Helper function to fine tune a single value interpolation */
+	/* Return 0 on success, 1 if input clipping occured, 2 if output clipping occured */
+	/* To guarantee the optimal function, an icmLuLut needs to be create. */
+	/* The default will be to assume simplex interpolation will be used. */
+	int (*tune_value) (
+		struct _icmLut *p,				/* Pointer to Lut object */
+		double *out,					/* Target value */
+		double *in);					/* Input value */
 		
 }; typedef struct _icmLut icmLut;
 
@@ -792,27 +804,29 @@ struct _icmLut {
 /* If ICM_CLUT_SET_FILTER is set, the per grid node filtering radius */
 /* is returned in clutfunc out[-1], out[-2] etc for each table */
 int icmSetMultiLutTables(
-	int ntables,							/* Number of tables to be set, 1..n */
-	struct _icmLut **p,						/* Pointer to Lut object */
-	int     flags,							/* Setting flags */
-	void   *cbctx,							/* Opaque callback context pointer value */
-	icColorSpaceSignature insig, 			/* Input color space */
-	icColorSpaceSignature outsig, 			/* Output color space */
+	int ntables,						/* Number of tables to be set, 1..n */
+	struct _icmLut **p,					/* Pointer to Lut object */
+	int     flags,						/* Setting flags */
+	void   *cbctx,						/* Opaque callback context pointer value */
+	icColorSpaceSignature insig, 		/* Input color space */
+	icColorSpaceSignature outsig, 		/* Output color space */
 	void (*infunc)(void *cbctx, double *out, double *in),
 							/* Input transfer function, inspace->inspace' (NULL = default) */
 							/* Will be called ntables times each input grid value */
-	double *inmin, double *inmax,			/* Maximum range of inspace' values */
-											/* (NULL = default) */
+	double *inmin, double *inmax,		/* Maximum range of inspace' values */
+										/* (NULL = default) */
 	void (*clutfunc)(void *cbntx, double *out, double *in),
 							/* inspace' -> outspace[ntables]' transfer function */
 							/* will be called once for each input' grid value, and */
 							/* ntables output values should be written consecutively */
 							/* to out[]. */
-	double *clutmin, double *clutmax,		/* Maximum range of outspace' values */
-											/* (NULL = default) */
-	void (*outfunc)(void *cbntx, double *out, double *in)
+	double *clutmin, double *clutmax,	/* Maximum range of outspace' values */
+										/* (NULL = default) */
+	void (*outfunc)(void *cbntx, double *out, double *in),
 								/* Output transfer function, outspace'->outspace (NULL = deflt) */
 								/* Will be called ntables times on each output value */
+	int *apxls_gmin, int *apxls_gmax	/* If not NULL, the grid indexes not to be affected */
+										/* by ICM_CLUT_SET_APXLS, defaulting to 0..>clutPoints-1 */
 );
 		
 /* - - - - - - - - - - - - - - - - - - - - -  */
@@ -1487,6 +1501,8 @@ struct _icc {
 	int              errc;				/* Error code */
 	int              warnc;				/* Warning code */
 
+	int              allowclutPoints256; /* Non standard - allow 256 res cLUT */
+
   /* Private: ? */
 	icmAlloc        *al;				/* Heap allocator */
 	int              del_al;			/* NZ if heap allocator should be deleted */
@@ -1652,135 +1668,9 @@ extern ICCLIB_API unsigned int icmCSSig2nchan(icColorSpaceSignature sig);
 /* 1 if it is a colorant based colorspace, and 2 if it is not a colorant based space */
 extern ICCLIB_API unsigned int icmCSSig2chanNames( icColorSpaceSignature sig, char *cvals[]);
 
-
-/* Simple macro to transfer an array to an XYZ number */
-#define icmAry2XYZ(xyz, ary) ((xyz).X = (ary)[0], (xyz).Y = (ary)[1], (xyz).Z = (ary)[2])
-
-/* And the reverse */
-#define icmXYZ2Ary(ary, xyz) ((ary)[0] = (xyz).X, (ary)[1] = (xyz).Y, (ary)[2] = (xyz).Z)
-
-/* Simple macro to transfer an XYZ number to an XYZ number */
-#define icmXYZ2XYZ(d_xyz, s_xyz) ((d_xyz).X = (s_xyz).X, (d_xyz).Y = (s_xyz).Y, \
-                                  (d_xyz).Z = (s_xyz).Z)
-
-/* Simple macro to transfer an 3array to 3array */
-/* Hmm. Same as icmCpy3 */
-#define icmAry2Ary(d_ary, s_ary) ((d_ary)[0] = (s_ary)[0], (d_ary)[1] = (s_ary)[1], \
-                                  (d_ary)[2] = (s_ary)[2])
-
-/* CIE Y (range 0 .. 1) to perceptual CIE 1976 L* (range 0 .. 100) */
-double icmY2L(double val);
-
-/* Perceptual CIE 1976 L* (range 0 .. 100) to CIE Y (range 0 .. 1) */
-double icmL2Y(double val);
-
-/* CIE XYZ to perceptual Lab */
-extern ICCLIB_API void icmXYZ2Lab(icmXYZNumber *w, double *out, double *in);
-
-/* Perceptual Lab to CIE XYZ */
-extern ICCLIB_API void icmLab2XYZ(icmXYZNumber *w, double *out, double *in);
-
-/* LCh to Lab */
-extern ICCLIB_API void icmLCh2Lab(double *out, double *in);
-
-/* Lab to LCh */
-extern ICCLIB_API void icmLab2LCh(double *out, double *in);
-
-/* XYZ to Yxy */
-extern ICCLIB_API void icmXYZ2Yxy(double *out, double *in);
-
-/* Yxy to XYZ */
-extern ICCLIB_API void icmYxy2XYZ(double *out, double *in);
-
-/* CIE XYZ to perceptual Luv */
-extern ICCLIB_API void icmXYZ2Luv(icmXYZNumber *w, double *out, double *in);
-
-/* Perceptual Luv to CIE XYZ */
-extern ICCLIB_API void icmLuv2XYZ(icmXYZNumber *w, double *out, double *in);
-
-
-/* NOTE :- none of the following seven have been protected */
-/* against arithmmetic issues (ie. for black) */
-
-/* CIE XYZ to perceptual CIE 1976 UCS diagram Yu'v'*/
-/* (Yu'v' is a better chromaticity space than Yxy) */
-extern ICCLIB_API void icmXYZ21976UCS(double *out, double *in);
-
-/* Perceptual CIE 1976 UCS diagram Yu'v' to CIE XYZ */
-extern ICCLIB_API void icm1976UCS2XYZ(double *out, double *in);
-
-/* CIE XYZ to perceptual CIE 1960 UCS */
-/* (This was obsoleted by the 1976UCS, but is still used */
-/*  in computing color temperatures.) */
-extern ICCLIB_API void icmXYZ21960UCS(double *out, double *in);
-
-/* Perceptual CIE 1960 UCS to CIE XYZ */
-extern ICCLIB_API void icm1960UCS2XYZ(double *out, double *in);
-
-/* CIE XYZ to perceptual CIE 1964 WUV (U*V*W*) */
-/* (This is obsolete but still used in computing CRI) */
-extern ICCLIB_API void icmXYZ21964WUV(icmXYZNumber *w, double *out, double *in);
-
-/* Perceptual CIE 1964 WUV (U*V*W*) to CIE XYZ */
-extern ICCLIB_API void icm1964WUV2XYZ(icmXYZNumber *w, double *out, double *in);
-
-/* CIE CIE1960 UCS to perceptual CIE 1964 WUV (U*V*W*) */
-extern ICCLIB_API void icm1960UCS21964WUV(icmXYZNumber *w, double *out, double *in);
-
-
-/* The standard D50 illuminant value */
-extern icmXYZNumber icmD50;
-extern icmXYZNumber icmD50_100;		/* Scaled to 100 */
-double icmD50_ary3[3];				/* As an array */
-double icmD50_100_ary3[3];			/* Scaled to 100 as an array */
-
-/* The standard D65 illuminant value */
-extern icmXYZNumber icmD65;
-extern icmXYZNumber icmD65_100;		/* Scaled to 100 */
-double icmD65_ary3[3];				/* As an array */
-double icmD65_100_ary3[3];			/* Scaled to 100 as an array */
-
-/* The default black value */
-extern icmXYZNumber icmBlack;
-
-
-/* Initialise a pseudo-hilbert grid counter, return total usable count. */
-extern ICCLIB_API unsigned psh_init(psh *p, int di, unsigned int res, int co[]);
-
-/* Reset the counter */
-extern ICCLIB_API void psh_reset(psh *p);
-
-/* Increment pseudo-hilbert coordinates */
-/* Return non-zero if count rolls over to 0 */
-extern ICCLIB_API int psh_inc(psh *p, int co[]);
-
-
-/* RGB primaries to device to RGB->XYZ transform matrix */
-/* Return non-zero if matrix would be singular */
-int icmRGBprim2matrix(
-	icmXYZNumber white,		/* White point */
-	icmXYZNumber red,		/* Red colorant */
-	icmXYZNumber green,		/* Green colorant */
-	icmXYZNumber blue,		/* Blue colorant */
-	double mat[3][3]		/* Destination matrix */
-);
-
-/* Chromatic Adaption transform utility */
-/* Return a 3x3 chromatic adaption matrix */
-/* Use icmMulBy3x3(dst, mat, src) */
-
-#define ICM_CAM_BRADFORD	0x0001	/* Use Bradford sharpened response space */
-#define ICM_CAM_MULMATRIX	0x0002	/* Transform the given matrix */
-
-void icmChromAdaptMatrix(
-	int flags,				/* Flags as defined below */
-	icmXYZNumber d_wp,		/* Destination white point */
-	icmXYZNumber s_wp,		/* Source white point */
-	double mat[3][3]		/* Destination matrix */
-);
-
 /* - - - - - - - - - - - - - - */
-/* Set a 3 vector */
+
+/* Set a 3 vector to the same value */
 #define icmSet3(d_ary, s_val) ((d_ary)[0] = (s_val), (d_ary)[1] = (s_val), \
                               (d_ary)[2] = (s_val))
 
@@ -1801,6 +1691,16 @@ void icmSub3(double out[3], double in1[3], double in2[3]);
 
 #define ICMSUB3(o, i, j) ((o)[0] = (i)[0] - (j)[0], (o)[1] = (i)[1] - (j)[1], (o)[2] = (i)[2] - (j)[2])
 
+/* Divide two 3 vectors, out = in1/in2 */
+void icmDiv3(double out[3], double in1[3], double in2[3]);
+
+#define ICMDIV3(o, i, j) ((o)[0] = (i)[0]/(j)[0], (o)[1] = (i)[1]/(j)[1], (o)[2] = (i)[2]/(j)[2])
+
+/* Multiply two 3 vectors, out = in1 * in2 */
+void icmMul3(double out[3], double in1[3], double in2[3]);
+
+#define ICMMUL3(o, i, j) ((o)[0] = (i)[0] * (j)[0], (o)[1] = (i)[1] * (j)[1], (o)[2] = (i)[2] * (j)[2])
+
 /* Compute the dot product of two 3 vectors */
 double icmDot3(double in1[3], double in2[3]);
 
@@ -1822,10 +1722,13 @@ double icmNorm3(double in[3]);
 /* Scale a 3 vector by the given ratio */
 void icmScale3(double out[3], double in[3], double rat);
 
+#define ICMSCALE3(o, i, j) ((o)[0] = (i)[0] * (j), (o)[1] = (i)[1] * (j), (o)[2] = (i)[2] * (j))
+
 /* Compute a blend between in0 and in1 */
 void icmBlend3(double out[3], double in0[3], double in1[3], double bf);
 
-#define ICMSCALE3(o, i, j) ((o)[0] = (i)[0] * (j), (o)[1] = (i)[1] * (j), (o)[2] = (i)[2] * (j))
+/* Clip a vector to the range 0.0 .. 1.0 */
+void icmClip3(double out[3], double in[3]);
 
 /* Normalise a 3 vector to the given length. Return nz if not normalisable */
 int icmNormalize3(double out[3], double in[3], double len);
@@ -1922,9 +1825,128 @@ double icmPlaneDist3(double eq[4], double p[3]);
 
 /* - - - - - - - - - - - - - - - - - - - - - - - */
 
+/* Given 2 2D points, compute a plane equation. */
+/* The normal will be right handed given the order of the points */
+/* The plane equation will be the 2 normal components and the constant. */
+/* Return nz if any points are cooincident or co-linear */
+int icmPlaneEqn2(double eq[3], double p0[2], double p1[2]);
+
+/* Given a 2D point and a plane equation, return the signed */
+/* distance from the plane */
+double icmPlaneDist2(double eq[3], double p[2]);
+
+/* Given two infinite 2D lines define by two pairs of points, compute the intersection. */
+/* Return nz if there is no intersection (lines are parallel) */
+int icmLineIntersect2(double res[2], double p1[2], double p2[2], double p3[2], double p4[2]);
+
 /* Multiply 2 array by 2x2 transform matrix */
 void icmMulBy2x2(double out[2], double mat[2][2], double in[2]);
 
+/* - - - - - - - - - - - - - - */
+
+/* Simple macro to transfer an array to an XYZ number */
+#define icmAry2XYZ(xyz, ary) ((xyz).X = (ary)[0], (xyz).Y = (ary)[1], (xyz).Z = (ary)[2])
+
+/* And the reverse */
+#define icmXYZ2Ary(ary, xyz) ((ary)[0] = (xyz).X, (ary)[1] = (xyz).Y, (ary)[2] = (xyz).Z)
+
+/* Simple macro to transfer an XYZ number to an XYZ number */
+#define icmXYZ2XYZ(d_xyz, s_xyz) ((d_xyz).X = (s_xyz).X, (d_xyz).Y = (s_xyz).Y, \
+                                  (d_xyz).Z = (s_xyz).Z)
+
+/* Simple macro to transfer an 3array to 3array */
+/* Hmm. Same as icmCpy3 */
+#define icmAry2Ary(d_ary, s_ary) ((d_ary)[0] = (s_ary)[0], (d_ary)[1] = (s_ary)[1], \
+                                  (d_ary)[2] = (s_ary)[2])
+
+/* CIE Y (range 0 .. 1) to perceptual CIE 1976 L* (range 0 .. 100) */
+double icmY2L(double val);
+
+/* Perceptual CIE 1976 L* (range 0 .. 100) to CIE Y (range 0 .. 1) */
+double icmL2Y(double val);
+
+/* CIE XYZ to perceptual Lab */
+extern ICCLIB_API void icmXYZ2Lab(icmXYZNumber *w, double *out, double *in);
+
+/* Perceptual Lab to CIE XYZ */
+extern ICCLIB_API void icmLab2XYZ(icmXYZNumber *w, double *out, double *in);
+
+/* LCh to Lab */
+extern ICCLIB_API void icmLCh2Lab(double *out, double *in);
+
+/* Lab to LCh */
+extern ICCLIB_API void icmLab2LCh(double *out, double *in);
+
+/* XYZ to Yxy */
+extern ICCLIB_API void icmXYZ2Yxy(double *out, double *in);
+
+/* Yxy to XYZ */
+extern ICCLIB_API void icmYxy2XYZ(double *out, double *in);
+
+/* CIE XYZ to perceptual Luv */
+extern ICCLIB_API void icmXYZ2Luv(icmXYZNumber *w, double *out, double *in);
+
+/* Perceptual Luv to CIE XYZ */
+extern ICCLIB_API void icmLuv2XYZ(icmXYZNumber *w, double *out, double *in);
+
+
+/* CIE XYZ to perceptual CIE 1976 UCS diagram Yu'v'*/
+/* (Yu'v' is a better chromaticity space than Yxy) */
+extern ICCLIB_API void icmXYZ21976UCS(double *out, double *in);
+
+/* Perceptual CIE 1976 UCS diagram Yu'v' to CIE XYZ */
+extern ICCLIB_API void icm1976UCS2XYZ(double *out, double *in);
+
+
+/* CIE XYZ to perceptual CIE 1960 UCS */
+/* (This was obsoleted by the 1976UCS, but is still used */
+/*  in computing color temperatures.) */
+extern ICCLIB_API void icmXYZ21960UCS(double *out, double *in);
+
+/* Perceptual CIE 1960 UCS to CIE XYZ */
+extern ICCLIB_API void icm1960UCS2XYZ(double *out, double *in);
+
+
+/* CIE XYZ to perceptual CIE 1964 WUV (U*V*W*) */
+/* (This is obsolete but still used in computing CRI) */
+extern ICCLIB_API void icmXYZ21964WUV(icmXYZNumber *w, double *out, double *in);
+
+/* Perceptual CIE 1964 WUV (U*V*W*) to CIE XYZ */
+extern ICCLIB_API void icm1964WUV2XYZ(icmXYZNumber *w, double *out, double *in);
+
+/* CIE CIE1960 UCS to perceptual CIE 1964 WUV (U*V*W*) */
+extern ICCLIB_API void icm1960UCS21964WUV(icmXYZNumber *w, double *out, double *in);
+
+
+/* NOTE :- that these values are for the 1931 standard observer */
+
+/* The standard D50 illuminant value */
+extern icmXYZNumber icmD50;
+extern icmXYZNumber icmD50_100;		/* Scaled to 100 */
+extern double icmD50_ary3[3];				/* As an array */
+extern double icmD50_100_ary3[3];			/* Scaled to 100 as an array */
+
+/* The standard D65 illuminant value */
+extern icmXYZNumber icmD65;
+extern icmXYZNumber icmD65_100;		/* Scaled to 100 */
+extern double icmD65_ary3[3];				/* As an array */
+extern double icmD65_100_ary3[3];			/* Scaled to 100 as an array */
+
+
+/* The default black value */
+extern icmXYZNumber icmBlack;
+
+
+/* Initialise a pseudo-hilbert grid counter, return total usable count. */
+extern ICCLIB_API unsigned psh_init(psh *p, int di, unsigned int res, int co[]);
+
+/* Reset the counter */
+extern ICCLIB_API void psh_reset(psh *p);
+
+/* Increment pseudo-hilbert coordinates */
+/* Return non-zero if count rolls over to 0 */
+extern ICCLIB_API int psh_inc(psh *p, int co[]);
+
 /* - - - - - - - - - - - - - - - - - - - - - - - */
 
 /* Return the normal Delta E given two Lab values */
@@ -1956,6 +1978,7 @@ extern ICCLIB_API double icmCIE2Ksq(double *in0, double *in1);
 /* Return the CIEDE2000 Delta E color difference measure for two XYZ values */
 extern ICCLIB_API double icmXYZCIE2K(icmXYZNumber *w, double *in0, double *in1);
 
+
 /* - - - - - - - - - - - - - - - - - - - - - - - */
 /* Clip Lab, while maintaining hue angle. */
 /* Return nz if clipping occured */
@@ -1966,6 +1989,122 @@ int icmClipLab(double out[3], double in[3]);
 int icmClipXYZ(double out[3], double in[3]);
 
 /* - - - - - - - - - - - - - - - - - - - - - - - */
+
+/* RGB primaries to device to RGB->XYZ transform matrix */
+/* Return non-zero if matrix would be singular */
+int icmRGBprim2matrix(
+	icmXYZNumber white,		/* White point */
+	icmXYZNumber red,		/* Red colorant */
+	icmXYZNumber green,		/* Green colorant */
+	icmXYZNumber blue,		/* Blue colorant */
+	double mat[3][3]		/* Destination matrix[RGB[XYZ] */
+);
+
+/* Chromatic Adaption transform utility */
+/* Return a 3x3 chromatic adaption matrix */
+/* Use icmMulBy3x3(dst, mat, src) */
+
+#define ICM_CAM_BRADFORD	0x0001	/* Use Bradford sharpened response space */
+#define ICM_CAM_MULMATRIX	0x0002	/* Transform the given matrix */
+									/* NOTE that to transform primaries they */
+									/* must be mat[XYZ][RGB] format! */
+
+void icmChromAdaptMatrix(
+	int flags,				/* Flags as defined below */
+	icmXYZNumber d_wp,		/* Destination white point */
+	icmXYZNumber s_wp,		/* Source white point */
+	double mat[3][3]		/* Destination matrix */
+);
+
+/* Pre-round RGB device primary values to ensure that */
+/* the sum of the quantized primaries is the same as */
+/* the quantized sum. */
+void quantizeRGBprimsS15Fixed16(
+	double mat[3][3]		/* matrix[RGB][XYZ] */
+);
+
+/* - - - - - - - - - - - - - - */
+/* Video functions */
+
+/* Convert Lut table index/value to YCbCr */
+void icmLut2YCbCr(double *out, double *in);
+
+/* Convert YCbCr to Lut table index/value */
+void icmYCbCr2Lut(double *out, double *in);
+
+
+/* Convert Rec601 RGB' into YPbPr, (== "full range YCbCr") */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+void icmRec601_RGBd_2_YPbPr(double out[3], double in[3]);
+
+/* Convert Rec601 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+void icmRec601_YPbPr_2_RGBd(double out[3], double in[3]);
+
+
+/* Convert Rec709 1150/60/2:1 RGB' into YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+void icmRec709_RGBd_2_YPbPr(double out[3], double in[3]);
+
+/* Convert Rec709 1150/60/2:1 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+void icmRec709_YPbPr_2_RGBd(double out[3], double in[3]);
+
+/* Convert Rec709 1250/50/2:1 RGB' into YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+void icmRec709_50_RGBd_2_YPbPr(double out[3], double in[3]);
+
+/* Convert Rec709 1250/50/2:1 YPbPr to RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+void icmRec709_50_YPbPr_2_RGBd(double out[3], double in[3]);
+
+
+/* Convert Rec2020 RGB' into Non-constant liminance YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+void icmRec2020_NCL_RGBd_2_YPbPr(double out[3], double in[3]);
+
+/* Convert Rec2020 Non-constant liminance YPbPr into RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+void icmRec2020_NCL_YPbPr_2_RGBd(double out[3], double in[3]);
+
+/* Convert Rec2020 RGB' into Constant liminance YPbPr, or "full range YCbCr" */
+/* where input 0..1, output 0..1, -0.5 .. 0.5, -0.5 .. 0.5 */
+void icmRec2020_CL_RGBd_2_YPbPr(double out[3], double in[3]);
+
+/* Convert Rec2020 Constant liminance YPbPr into RGB' (== "full range YCbCr") */
+/* where input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, output 0.0 .. 1 */
+void icmRec2020_CL_YPbPr_2_RGBd(double out[3], double in[3]);
+
+
+/* Convert Rec601/709/2020 YPbPr to YCbCr range. */
+/* input 0..1, -0.5 .. 0.5, -0.5 .. 0.5, */
+/* output 16/255 .. 235/255, 16/255 .. 240/255, 16/255 .. 240/255 */ 
+void icmRecXXX_YPbPr_2_YCbCr(double out[3], double in[3]);
+
+/* Convert Rec601/709/2020 YCbCr to YPbPr range. */
+/* input 16/255 .. 235/255, 16/255 .. 240/255, 16/255 .. 240/255 */ 
+/* output 0..1, -0.5 .. 0.5, -0.5 .. 0.5, */
+void icmRecXXX_YCbCr_2_YPbPr(double out[3], double in[3]);
+
+
+/* Convert full range RGB to Video range 16..235 RGB */
+void icmRGB_2_VidRGB(double out[3], double in[3]);
+
+/* Convert Video range 16..235 RGB to full range RGB */
+void icmVidRGB_2_RGB(double out[3], double in[3]);
+
+/* ---------------------------------------------------------- */
+/* PS 3.14-2009, Digital Imaging and Communications in Medicine */
+/* (DICOM) Part 14: Grayscale Standard Display Function */
+
+/* JND index value 1..1023 to L 0.05 .. 3993.404 cd/m^2 */
+double icmDICOM_fwd(double jnd);
+
+/* L 0.05 .. 3993.404 cd/m^2 to JND index value 1..1023 */
+double icmDICOM_bwd(double L);
+
+
+/* ---------------------------------------------------------- */
 /* Print an int vector to a string. */
 /* Returned static buffer is re-used every 5 calls. */
 char *icmPiv(int di, int *p);
@@ -1981,8 +2120,8 @@ char *icmPfv(int di, float *p);
 /* Print an 0..1 range XYZ as a D50 Lab string */
 /* Returned static buffer is re-used every 5 calls. */
 char *icmPLab(double *p);
+/* - - - - - - - - - - - - - - - - - - - - - - - */
 
-/* ---------------------------------------------------------- */
 
 #ifdef __cplusplus
 	}
diff --git a/icc/iccdump.c b/icc/iccdump.c
index aaf14f0..76959e7 100644
--- a/icc/iccdump.c
+++ b/icc/iccdump.c
@@ -182,6 +182,9 @@ main(int argc, char *argv[]) {
 			if ((rv = icco->read(icco,fp,offset)) != 0)
 				error ("%d, %s",rv,icco->err);
 		
+			if (icco->header->cmmId == str2tag("argl"))
+				icco->allowclutPoints256 = 1;
+
 			if (ntag_names > 0) {
 				int i;
 				for (i = 0; i < ntag_names; i++) {
diff --git a/icc/icclu.c b/icc/icclu.c
index ea32da0..80126da 100644
--- a/icc/icclu.c
+++ b/icc/icclu.c
@@ -245,6 +245,9 @@ main(int argc, char *argv[]) {
 	if ((rv = icco->read(icco,fp,0)) != 0)
 		error ("%d, %s",rv,icco->err);
 
+	if (icco->header->cmmId == str2tag("argl"))
+		icco->allowclutPoints256 = 1;
+
 	if (verb > 1) {
 		icmFile *op;
 		if ((op = new_icmFileStd_fp(stdout)) == NULL)
@@ -286,7 +289,7 @@ main(int argc, char *argv[]) {
 			continue;
 		}
 		/* For each input number */
-		for (bp = buf-1, nbp = buf, i = 0; i < MAX_CHAN; i++) {
+		for (nbp = buf, i = 0; i < MAX_CHAN; i++) {
 			bp = nbp;
 			in[i] = oin[i] = strtod(bp, &nbp);
 			if (nbp == bp)
@@ -310,19 +313,7 @@ main(int argc, char *argv[]) {
 		}
 
 		if (repYxy && ins == icSigYxyData) {
-			double Y = in[0];
-			double x = in[1];
-			double y = in[2];
-			double z = 1.0 - x - y;
-			double sum;
-			if (y < 1e-6) {
-				in[0] = in[1] = in[2] = 0.0;
-			} else {
-				sum = Y/y;
-				in[0] = x * sum;
-				in[1] = Y;
-				in[2] = z * sum;
-			}
+			icmYxy2XYZ(in, in);
 		}
 
 		/* Do conversion */
@@ -342,17 +333,7 @@ main(int argc, char *argv[]) {
 		}
 		
 		if (repYxy && outs == icSigYxyData) {
-			double X = out[0];
-			double Y = out[1];
-			double Z = out[2];
-			double sum = X + Y + Z;
-			if (sum < 1e-6) {
-				out[0] = out[1] = out[2] = 0.0;
-			} else {
-				out[0] = Y;
-				out[1] = X/sum;
-				out[2] = Y/sum;
-			}
+			icmXYZ2Yxy(out, out);
 		}
 
 		/* If device data and scale */
diff --git a/icc/icctest.c b/icc/icctest.c
index 97a3f62..e7534fb 100644
--- a/icc/icctest.c
+++ b/icc/icctest.c
@@ -111,6 +111,7 @@ main(
 	if (md5_test() != 0)
 		error ("MD5 checksum routine is faulty");
 
+
 	/* Outer loop does a number of file write/reads, */
 	/* in order to exercise random tests, and to test file offsets. */
 
@@ -199,8 +200,6 @@ main(
 		offset = rand_int(0,72789);
 	}
 
-	printf("\nTest completed OK\n");
-
 	return 0;
 }
 
@@ -325,9 +324,9 @@ int doit(
 
 		/* Values that are not normally set. Set them to non-defaults for testing */
 		wh->cmmId = str2tag("tst3");
-    	wh->majv = 3;					/* Default version 2.1.0 */
-		wh->minv = 2;
-		wh->bfv  = 1;
+    	wh->majv = 2;					/* Default version 2.1.0 */
+		wh->minv = 1;
+		wh->bfv  = 0;
     	wh->date.year    = rand_int(1900,3000);		/* Defaults to current date */
     	wh->date.month   = rand_int(1,12);
     	wh->date.day     = rand_int(1,31);
diff --git a/icc/lab2lab.icm b/icc/lab2lab.icm
index fe518e6..0b8a4b3 100644
--- a/icc/lab2lab.icm
+++ b/icc/lab2lab.icm
diff --git a/icc/log.txt b/icc/log.txt
index 97435b6..7c4bd83 100644
--- a/icc/log.txt
+++ b/icc/log.txt
@@ -1,7 +1,13 @@
 
  Change History: (See ArgyllCMS log.txt too)
 
- 2.15
+ 2.16
+	Clean up cLUT read code to make sanity checking
+	more explicit and remove redundant code.
+
+	Added special mode that interprets cLUT res of 0 as 256
+	for MadVR testing.
+
 	Change icc->read_tag() to only succeed if the tag type is
 	known, since the standard expectation of a non NULL
 	return type is that it is of a known type. Added new
diff --git a/icc/lutest.c b/icc/lutest.c
index e43fbc5..9bf127f 100644
--- a/icc/lutest.c
+++ b/icc/lutest.c
@@ -1995,13 +1995,15 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigRgbData, 				/* Input color space */
-				icSigXYZData, 				/* Output color space */
-				RGB_RGBp,					/* Input transfer function, RGB->RGB' (NULL = default) */
-				NULL, NULL,					/* Use default Maximum range of RGB' values */
-				RGBp_XYZp,					/* RGB' -> XYZ' transfer function */
-				xyzmin, xyzmax,				/* Make XYZ' range 0.0 - 1.0 for better precision */
-				XYZp_XYZ) != 0)				/* Output transfer function, XYZ'->XYZ (NULL = deflt) */
+				icSigRgbData, 		/* Input color space */
+				icSigXYZData, 		/* Output color space */
+				RGB_RGBp,			/* Input transfer function, RGB->RGB' (NULL = default) */
+				NULL, NULL,			/* Use default Maximum range of RGB' values */
+				RGBp_XYZp,			/* RGB' -> XYZ' transfer function */
+				xyzmin, xyzmax,		/* Make XYZ' range 0.0 - 1.0 for better precision */
+				XYZp_XYZ,			/* Output transfer function, XYZ'->XYZ (NULL = deflt) */
+				NULL, NULL
+		) != 0)
 			error("Setting 16 bit RGB->XYZ Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
 	/* 16 bit dev -> pcs lut - link intent 0 to intent 1 */
@@ -2126,13 +2128,15 @@ main(
 #endif
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigXYZData, 				/* Input color space */
-				icSigRgbData, 				/* Output color space */
-				XYZ_XYZp, 					/* Input transfer function, XYZ->XYZ' (NULL = default) */
-				xyzmin, xyzmax,				/* Make XYZ' range 0.0 - 1.0 for better precision */
-				XYZp_RGBp,					/* XYZ' -> RGB' transfer function */
-				rgbmin, rgbmax,				/* Make RGB' range 0.0 - 1.333 for less clip rounding */
-				RGBp_RGB) != 0)				/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				icSigXYZData, 		/* Input color space */
+				icSigRgbData, 		/* Output color space */
+				XYZ_XYZp, 			/* Input transfer function, XYZ->XYZ' (NULL = default) */
+				xyzmin, xyzmax,		/* Make XYZ' range 0.0 - 1.0 for better precision */
+				XYZp_RGBp,			/* XYZ' -> RGB' transfer function */
+				rgbmin, rgbmax,		/* Make RGB' range 0.0 - 1.333 for less clip rounding */
+				RGBp_RGB,			/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				NULL, NULL
+		) != 0)
 			error("Setting 16 bit XYZ->RGB Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 
 	}
@@ -2181,13 +2185,14 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigXYZData, 				/* Input color space */
-				icSigGrayData, 				/* Output color space */
-				XYZ_XYZp,					/* Input transfer function, XYZ->XYZ' (NULL = default) */
-				xyzmin, xyzmax,				/* Make XYZ' range 0.0 - 1.0 for better precision */
-				XYZp_BDIST,					/* XYZ' -> Boundary Distance transfer function */
-				NULL, NULL,					/* Default range from clut to output table */
-				BDIST_GAMMUT				/* Boundary Distance -> Out of gamut distance */
+				icSigXYZData, 		/* Input color space */
+				icSigGrayData, 		/* Output color space */
+				XYZ_XYZp,			/* Input transfer function, XYZ->XYZ' (NULL = default) */
+				xyzmin, xyzmax,		/* Make XYZ' range 0.0 - 1.0 for better precision */
+				XYZp_BDIST,			/* XYZ' -> Boundary Distance transfer function */
+				NULL, NULL,			/* Default range from clut to output table */
+				BDIST_GAMMUT,		/* Boundary Distance -> Out of gamut distance */
+				NULL, NULL
 		) != 0)
 			error("Setting 16 bit XYZ->Gammut Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
@@ -2559,13 +2564,14 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigRgbData, 				/* Input color space */
-				icSigLabData, 				/* Output color space */
-				RGB_RGBp,					/* Input transfer function, RGB->RGB' (NULL = default) */
-				NULL, NULL,					/* Use default Maximum range of RGB' values */
-				RGBp_Labp,					/* RGB' -> Lab' transfer function */
-				NULL, NULL,					/* Use default Maximum range of Lab' values */
-				Labp_Lab					/* Linear output transform Lab'->Lab */
+				icSigRgbData, 		/* Input color space */
+				icSigLabData, 		/* Output color space */
+				RGB_RGBp,			/* Input transfer function, RGB->RGB' (NULL = default) */
+				NULL, NULL,			/* Use default Maximum range of RGB' values */
+				RGBp_Labp,			/* RGB' -> Lab' transfer function */
+				NULL, NULL,			/* Use default Maximum range of Lab' values */
+				Labp_Lab,			/* Linear output transform Lab'->Lab */
+				NULL, NULL
 		) != 0)
 			error("Setting 16 bit RGB->Lab Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
@@ -2643,13 +2649,15 @@ main(
 #endif
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigLabData, 				/* Input color space */
-				icSigRgbData, 				/* Output color space */
-				Lab_Labp,					/* Linear input transform Lab->Lab' */
-				NULL, NULL,					/* Use default Lab' range */
-				Labp_RGBp,					/* Lab' -> RGB' transfer function */
-				rgbmin, rgbmax,				/* Make RGB' range 0.0 - 1.333 for less clip rounding */
-				RGBp_RGB) != 0)				/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				icSigLabData, 		/* Input color space */
+				icSigRgbData, 		/* Output color space */
+				Lab_Labp,			/* Linear input transform Lab->Lab' */
+				NULL, NULL,			/* Use default Lab' range */
+				Labp_RGBp,			/* Lab' -> RGB' transfer function */
+				rgbmin, rgbmax,		/* Make RGB' range 0.0 - 1.333 for less clip rounding */
+				RGBp_RGB,			/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				NULL, NULL
+		) != 0)
 			error("Setting 16 bit Lab->RGB Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 
 	}
@@ -2690,13 +2698,14 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigLabData, 				/* Input color space */
-				icSigGrayData, 				/* Output color space */
-				Lab_Labp,					/* Linear input transform Lab->Lab' */
-				NULL, NULL	,				/* Default Lab' range */
-				Labp_BDIST,					/* Lab' -> Boundary Distance transfer function */
-				NULL, NULL,					/* Default range from clut to output table */
-				BDIST_GAMMUT				/* Boundary Distance -> Out of gamut distance */
+				icSigLabData, 		/* Input color space */
+				icSigGrayData, 		/* Output color space */
+				Lab_Labp,			/* Linear input transform Lab->Lab' */
+				NULL, NULL,			/* Default Lab' range */
+				Labp_BDIST,			/* Lab' -> Boundary Distance transfer function */
+				NULL, NULL,			/* Default range from clut to output table */
+				BDIST_GAMMUT,		/* Boundary Distance -> Out of gamut distance */
+				NULL, NULL
 		) != 0)
 			error("Setting 16 bit Lab->Gammut Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
@@ -3065,13 +3074,14 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigRgbData, 				/* Input color space */
-				icSigLabData, 				/* Output color space */
-				RGB_RGBp,					/* Input transfer function, RGB->RGB' (NULL = default) */
-				NULL, NULL,					/* Use default Maximum range of RGB' values */
-				RGBp_Labp,					/* RGB' -> Lab' transfer function */
-				NULL, NULL,					/* Use default Maximum range of Lab' values */
-				Labp_Lab					/* Linear output transform Lab'->Lab */
+				icSigRgbData, 		/* Input color space */
+				icSigLabData, 		/* Output color space */
+				RGB_RGBp,			/* Input transfer function, RGB->RGB' (NULL = default) */
+				NULL, NULL,			/* Use default Maximum range of RGB' values */
+				RGBp_Labp,			/* RGB' -> Lab' transfer function */
+				NULL, NULL,			/* Use default Maximum range of Lab' values */
+				Labp_Lab,			/* Linear output transform Lab'->Lab */
+				NULL, NULL
 		) != 0)
 			error("Setting 8 bit RGB->Lab Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
@@ -3149,13 +3159,15 @@ main(
 #endif
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigLabData, 				/* Input color space */
-				icSigRgbData, 				/* Output color space */
-				Lab_Labp,					/* Linear input transform Lab->Lab' */
-				NULL, NULL,					/* Use default Lab' range */
-				Labp_RGBp,					/* Lab' -> RGB' transfer function */
-				rgbmin, rgbmax,				/* Make RGB' range 0.0 - 1.333 for less clip rounding */
-				RGBp_RGB) != 0)				/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				icSigLabData, 		/* Input color space */
+				icSigRgbData, 		/* Output color space */
+				Lab_Labp,			/* Linear input transform Lab->Lab' */
+				NULL, NULL,			/* Use default Lab' range */
+				Labp_RGBp,			/* Lab' -> RGB' transfer function */
+				rgbmin, rgbmax,		/* Make RGB' range 0.0 - 1.333 for less clip rounding */
+				RGBp_RGB,			/* Output transfer function, RGB'->RGB (NULL = deflt) */
+				NULL, NULL
+		) != 0)
 			error("Setting 8 bit Lab->RGB Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 
 	}
@@ -3196,13 +3208,14 @@ main(
 
 		/* Use helper function to do the hard work. */
 		if (wo->set_tables(wo, ICM_CLUT_SET_EXACT, NULL,
-				icSigLabData, 				/* Input color space */
-				icSigGrayData, 				/* Output color space */
-				Lab_Labp,					/* Linear input transform Lab->Lab' */
-				NULL, NULL	,				/* Default Lab' range */
-				Labp_BDIST,					/* Lab' -> Boundary Distance transfer function */
-				NULL, NULL,					/* Default range from clut to output table */
-				BDIST_GAMMUT				/* Boundary Distance -> Out of gamut distance */
+				icSigLabData, 		/* Input color space */
+				icSigGrayData, 		/* Output color space */
+				Lab_Labp,			/* Linear input transform Lab->Lab' */
+				NULL, NULL	,		/* Default Lab' range */
+				Labp_BDIST,			/* Lab' -> Boundary Distance transfer function */
+				NULL, NULL,			/* Default range from clut to output table */
+				BDIST_GAMMUT,		/* Boundary Distance -> Out of gamut distance */
+				NULL, NULL
 		) != 0)
 			error("Setting 16 bit Lab->Gammut Lut failed: %d, %s",wr_icco->errc,wr_icco->err);
 	}
diff --git a/icc/makezip.ksh b/icc/makezip.ksh
deleted file mode 100644
index f06efa4..0000000
--- a/icc/makezip.ksh
+++ /dev/null
@@ -1,6 +0,0 @@
-# Create icclib source distribution
-#jam
-#zip nt_iccdump.zip iccdump.exe
-#zip nt_icclu.zip icclu.exe
-rm icclib.zip
-zip -9 -ll icclib.zip Readme.txt License.txt todo.txt log.txt Jamfile Makefile Makefile.WNT Makefile.IBMNT Makefile.UNIX Makefile.OSX icc.c iccstd.c icc.h iccV42.h iccdump.c icclu.c iccrw.c icctest.c lutest.c
diff --git a/icc/mcheck.c b/icc/mcheck.c
index 9000650..54811c3 100644
--- a/icc/mcheck.c
+++ b/icc/mcheck.c
@@ -155,7 +155,7 @@ main(
 			error ("%d, %s",rd_icco->errc, rd_icco->err);
 	}
 	/* Get details of conversion */
-	luo->spaces(luo, &ins, &inn, &outs, NULL, &alg, NULL, NULL, NULL);
+	luo->spaces(luo, &ins, &inn, &outs, NULL, &alg, NULL, NULL, NULL, NULL);
 
 	if (alg != icmLutType) {
 		error("Expecting Lut based profile");
diff --git a/icc/mkDispProf.c b/icc/mkDispProf.c
new file mode 100644
index 0000000..bc70154
--- /dev/null
+++ b/icc/mkDispProf.c
@@ -0,0 +1,331 @@
+
+
+/* 
+ * Create an ICC V2.4 compatible matrix display profile.
+ *
+ * Author:  Graeme W. Gill
+ * Date:    8/2/2008
+ * Version: 1.00
+ *
+ * Copyright 2006 - 2014 Graeme W. Gill
+ *
+ * This material is licensed with an "MIT" free use license:-
+ * see the License.txt file in this directory for licensing details.
+ *
+ * Based on icc/lutest.c
+ */
+
+
+/*
+ * TTBD:
+ *
+ */
+
+#include <stdio.h>
+#include <stdlib.h>
+#include <stdarg.h>
+#include <fcntl.h>
+#include <string.h>
+#include <math.h>
+#include <time.h>
+#include "icc.h"
+
+void error(char *fmt, ...), warning(char *fmt, ...);
+
+void usage(void) {
+	fprintf(stderr,"Create a Matrix Display ICC profile\n");
+	fprintf(stderr,"Author: Graeme W. Gill\n");
+	fprintf(stderr,"usage: mkDispProf [-v level] outfile\n");
+	fprintf(stderr," -v                 Verbose\n");
+	exit(1);
+}
+
+/* sRGB like device gamma encoded value to linear value 0.0 .. 1.0 */
+static double gdv2dv(double iv) {
+	double ov;
+
+	if (iv < 0.04045)
+		ov = iv/12.92;
+	else
+		ov = pow((iv + 0.055)/1.055, 2.4);
+	return ov;
+}
+
+int
+main(
+int argc,
+char *argv[]
+) {
+	int fa,nfa;
+	char out_name[1000];
+	icmFile *wr_fp;
+	icc *wr_icco;
+	int rv = 0;
+	int verb = 0;
+
+	if (argc < 2)
+		usage();
+
+	/* Process the arguments */
+	for(fa = 1;fa < argc;fa++) {
+		nfa = fa;					/* skip to nfa if next argument is used */
+		if (argv[fa][0] == '-')	{	/* Look for any flags */
+			char *na = NULL;		/* next argument after flag, null if none */
+
+			if (argv[fa][2] != '\000')
+				na = &argv[fa][2];		/* next is directly after flag */
+			else {
+				if ((fa+1) < argc) {
+					if (argv[fa+1][0] != '-') {
+						nfa = fa + 1;
+						na = argv[nfa];		/* next is seperate non-flag argument */
+					}
+				}
+			}
+
+			if (argv[fa][1] == '?')
+				usage();
+
+			/* Verbosity */
+			else if (argv[fa][1] == 'v' || argv[fa][1] == 'V') {
+				verb = 1;
+			}
+
+			else 
+				usage();
+		}
+		else
+			break;
+	}
+
+	if (fa >= argc || argv[fa][0] == '-') usage();
+	strcpy(out_name,argv[fa]);
+
+	/* ---------------------------------------- */
+	/* Create a matrix/shaper based XYZ profile */
+	/* ---------------------------------------- */
+
+	/* Open up the file for writing */
+	if ((wr_fp = new_icmFileStd_name(out_name,"w")) == NULL)
+		error ("Write: Can't open file '%s'",out_name);
+
+	if ((wr_icco = new_icc()) == NULL)
+		error ("Write: Creation of ICC object failed");
+
+	/* Add all the tags required */
+
+	/* The header: */
+	{
+		icmHeader *wh = wr_icco->header;
+
+		/* Values that must be set before writing */
+		wh->deviceClass     = icSigDisplayClass;
+    	wh->colorSpace      = icSigRgbData;			/* It's RGB space */
+    	wh->pcs             = icSigXYZData;
+    	wh->renderingIntent = icPerceptual;
+
+		/* Values that should be set before writing */
+		wh->manufacturer = str2tag("????");
+    	wh->model        = str2tag("????");
+	}
+	/* Profile Description Tag: */
+	{
+		icmTextDescription *wo;
+		char *dst;
+
+		dst = "sRGB like Matrix Display profile";
+		if ((wo = (icmTextDescription *)wr_icco->add_tag(
+		           wr_icco, icSigProfileDescriptionTag,	icSigTextDescriptionType)) == NULL) 
+			error("add_tag failed: %d, %s",wr_icco->errc,wr_icco->err);
+
+		wo->size = strlen(dst)+1; 	/* Allocated and used size of desc, inc null */
+		wo->scCode = 0;
+		wo->scSize = strlen(dst)+1;
+		if (wo->scSize > 67)
+			error("Description scriptCode string longer than 67");
+		wo->allocate((icmBase *)wo);/* Allocate space */
+		strcpy(wo->desc, dst);		/* Copy the string in */
+		strcpy((char *)wo->scDesc, dst);	/* Copy the string in */
+	}
+	/* Copyright Tag: */
+	{
+		icmText *wo;
+		char *crt = "Copyright tag goes here";
+		if ((wo = (icmText *)wr_icco->add_tag(
+		           wr_icco, icSigCopyrightTag,	icSigTextType)) == NULL) 
+			error("add_tag failed: %d, %s",wr_icco->errc,wr_icco->err);
+
+		wo->size = strlen(crt)+1; 	/* Allocated and used size of text, inc null */
+		wo->allocate((icmBase *)wo);/* Allocate space */
+		strcpy(wo->data, crt);		/* Copy the text in */
+	}
+
+	/* Could add other relevant tags here, such as:
+
+	   Device Manufacturers Description Tag
+	   Device Model Description Tag
+	   Device technology Tag
+	   Viewing conditions Description Tag
+	   Viewing conditions
+	   Display Luminance Tag
+	   Measurement information Tag
+
+	   etc.
+	 */
+
+	/* Setup the primaries */
+	{
+		/* Compute primaries as XYZ */
+		icmXYZNumber wrgb[4] = {		/* Primaries in Yxy from the standard */
+			{ 1.0, 0.3127, 0.3290 },	/* White */
+			{ 1.0, 0.6400, 0.3300 },	/* Red */
+			{ 1.0, 0.3000, 0.6000 },	/* Green */
+			{ 1.0, 0.1500, 0.0600 }		/* Blue */
+		};
+		double mat[3][3];
+		int i;
+
+		/* Convert Yxy to XYZ */
+		for (i = 0; i < 4; i++) {
+			double v[3];
+
+			icmXYZ2Ary(v, wrgb[i]);
+			icmYxy2XYZ(v, v);
+			icmAry2XYZ(wrgb[i], v);
+		}
+
+		/* Convert XYZ to normalised 3x3 matrix */
+		icmRGBprim2matrix(wrgb[0], wrgb[1], wrgb[2], wrgb[3], mat);
+
+#ifdef NEVER		/* Dump XYZ of matrix */
+		printf("sRGB: XYZ\n");
+		printf("{ %f, %f, %f },	/* Red */\n"
+		       "{ %f, %f, %f },	/* Green */\n"
+		       "{ %f, %f, %f },	/* Blue */\n"
+		       "{ %f, %f, %f }  /* White */\n",
+		mat[0][0], mat[0][1], mat[0][2],
+		mat[1][0], mat[1][1], mat[1][2],
+		mat[2][0], mat[2][1], mat[2][2],
+		wrgb[0].X, wrgb[0].Y, wrgb[0].Z);
+#endif
+
+		/* White Point Tag: */
+		{
+			icmXYZArray *wo;
+
+			if ((wo = (icmXYZArray *)wr_icco->add_tag(
+			           wr_icco, icSigMediaWhitePointTag, icSigXYZArrayType)) == NULL) 
+				error("add_tag failed: %d, %s",wr_icco->errc,wr_icco->err);
+
+			wo->size = 1;
+			wo->allocate((icmBase *)wo);	/* Allocate space */
+			wo->data[0].X = wrgb[0].X;
+			wo->data[0].Y = wrgb[0].Y;
+			wo->data[0].Z = wrgb[0].Z; 
+		}
+		/* Black Point Tag: */
+		{
+			icmXYZArray *wo;
+
+			if ((wo = (icmXYZArray *)wr_icco->add_tag(
+			           wr_icco, icSigMediaBlackPointTag, icSigXYZArrayType)) == NULL) 
+				error("add_tag failed: %d, %s",wr_icco->errc,wr_icco->err);
+
+			wo->size = 1;
+			wo->allocate((icmBase *)wo);	/* Allocate space */
+			wo->data[0].X = 0.00;
+			wo->data[0].Y = 0.00;
+			wo->data[0].Z = 0.00;
+		}
+		/* Red, Green and Blue Colorant Tags: */
+		{
+			icmXYZArray *wor, *wog, *wob;
+			double fromAbs[3][3];
+			double d50m[3][3];
+
+			/* Convert to D50 adapated */
+			icmChromAdaptMatrix(ICM_CAM_BRADFORD, icmD50, wrgb[0], fromAbs);
+			icmMulBy3x3(d50m[0], fromAbs, mat[0]);
+			icmMulBy3x3(d50m[1], fromAbs, mat[1]);
+			icmMulBy3x3(d50m[2], fromAbs, mat[2]);
+
+			/* Make sure rounding doesn't wreck white point */
+			quantizeRGBprimsS15Fixed16(d50m);
+
+			if ((wor = (icmXYZArray *)wr_icco->add_tag(
+			           wr_icco, icSigRedColorantTag, icSigXYZArrayType)) == NULL) 
+					error("add_tag failed: %d, %s",rv,wr_icco->err);
+			if ((wog = (icmXYZArray *)wr_icco->add_tag(
+			           wr_icco, icSigGreenColorantTag, icSigXYZArrayType)) == NULL) 
+				error("add_tag failed: %d, %s",rv,wr_icco->err);
+			if ((wob = (icmXYZArray *)wr_icco->add_tag(
+			           wr_icco, icSigBlueColorantTag, icSigXYZArrayType)) == NULL) 
+				error("add_tag failed: %d, %s",rv,wr_icco->err);
+
+			wor->size = wog->size = wob->size = 1;
+			wor->allocate((icmBase *)wor);	/* Allocate space */
+			wog->allocate((icmBase *)wog);
+			wob->allocate((icmBase *)wob);
+			wor->data[0].X = d50m[0][0]; wor->data[0].Y = d50m[0][1]; wor->data[0].Z = d50m[0][2];
+			wog->data[0].X = d50m[1][0]; wog->data[0].Y = d50m[1][1]; wog->data[0].Z = d50m[1][2];
+			wob->data[0].X = d50m[2][0]; wob->data[0].Y = d50m[2][1]; wob->data[0].Z = d50m[2][2];
+		}
+	}
+	/* Red, Green and Blue Gamma Curve Tags: */
+	{
+		icmCurve *wor, *wog, *wob;
+		int i;
+
+		if ((wor = (icmCurve *)wr_icco->add_tag(
+		           wr_icco, icSigRedTRCTag, icSigCurveType)) == NULL) 
+			error("add_tag failed: %d, %s",rv,wr_icco->err);
+		wor->flag = icmCurveSpec;
+		wor->size = 1024;
+		wor->allocate((icmBase *)wor);	/* Allocate space */
+		for (i = 0; i < wor->size; i++)
+			wor->data[i] = gdv2dv(i/(wor->size-1.0));
+
+		/* Link other channels to the red */
+		if ((wog = (icmCurve *)wr_icco->link_tag(
+		           wr_icco, icSigGreenTRCTag, icSigRedTRCTag)) == NULL) 
+			error("link_tag failed: %d, %s",rv,wr_icco->err);
+		if ((wob = (icmCurve *)wr_icco->link_tag(
+		           wr_icco, icSigBlueTRCTag, icSigRedTRCTag)) == NULL) 
+			error("link_tag failed: %d, %s",rv,wr_icco->err);
+	}
+
+	/* Write the file out */
+	if ((rv = wr_icco->write(wr_icco,wr_fp,0)) != 0)
+		error ("Write file: %d, %s",rv,wr_icco->err);
+	
+	wr_icco->del(wr_icco);
+	wr_fp->del(wr_fp);
+
+	return 0;
+}
+
+/* ------------------------------------------------ */
+/* Basic printf type error() and warning() routines */
+
+void
+error(char *fmt, ...) {
+	va_list args;
+
+	fprintf(stderr,"mkDispProf: Error - ");
+	va_start(args, fmt);
+	vfprintf(stderr, fmt, args);
+	va_end(args);
+	fprintf(stderr, "\n");
+	exit (-1);
+}
+
+void
+warning(char *fmt, ...) {
+	va_list args;
+
+	fprintf(stderr,"mkDispProf: Warning - ");
+	va_start(args, fmt);
+	vfprintf(stderr, fmt, args);
+	va_end(args);
+	fprintf(stderr, "\n");
+}
diff --git a/icc/sRGB.icm b/icc/sRGB.icm
index db0355f..5491330 100644
--- a/icc/sRGB.icm
+++ b/icc/sRGB.icm