src/common/tmapluv.c

#ifndef lint
static const char       RCSid[] = "$Id$";
#endif
/*
 * Routines for tone-mapping LogLuv encoded pixels.
 *
 * Externals declared in tmaptiff.h
 */

#include "copyright.h"

#define LOGLUV_PUBLIC           1

#include <stdio.h>
#include <string.h>
#include <math.h>
#include "tiffio.h"
#include "tmprivat.h"
#include "tmaptiff.h"

#ifndef BSD
#define bzero(d,n)              (void)memset(d,0,n)
#endif
#define uvflgop(p,uv,op)        ((p)->rgbflg[(uv)>>5] op (1L<<((uv)&0x1f)))
#define isuvset(p,uv)           uvflgop(p,uv,&)
#define setuv(p,uv)             uvflgop(p,uv,|=)
#define clruv(p,uv)             uvflgop(p,uv,&=~)
#define clruvall(p)             bzero((MEM_PTR)(p)->rgbflg,sizeof((p)->rgbflg))

#ifdef NOPROTO
static MEM_PTR  luv32Init();
static void     luv32NewSpace();
static MEM_PTR  luv24Init();
static void     luv24NewSpace();
#else
static MEM_PTR  luv32Init(struct tmStruct *);
static void     luv32NewSpace(struct tmStruct *);
static MEM_PTR  luv24Init(struct tmStruct *);
static void     luv24NewSpace(struct tmStruct *);
#endif

typedef struct {
        int     offset;                 /* computed luminance offset */
        BYTE    rgbval[1<<16][3];       /* computed RGB value for given uv */
        uint32  rgbflg[1<<(16-5)];      /* flags for computed values */
} LUV32DATA;                    /* LogLuv 32-bit conversion data */

#define UVNEU                   ((int)(UVSCALE*U_NEU)<<8 \
                                        | (int)(UVSCALE*V_NEU))

static struct tmPackage  luv32Pkg = {   /* 32-bit package functions */
        luv32Init, luv32NewSpace, free
};
static int      luv32Reg = -1;          /* 32-bit package reg. number */

typedef struct {
        int     offset;                 /* computed luminance offset */
        BYTE    rgbval[1<<14][3];       /* computed rgb value for uv index */
        uint32  rgbflg[1<<(14-5)];      /* flags for computed values */
} LUV24DATA;                    /* LogLuv 24-bit conversion data */

static struct tmPackage  luv24Pkg = {   /* 24-bit package functions */
        luv24Init, luv24NewSpace, free
};
static int      luv24Reg = -1;          /* 24-bit package reg. number */

static int      uv14neu = -1;           /* neutral index for 14-bit (u',v') */


static void
uv2rgb(rgb, tm, uvp)                    /* compute RGB from uv coordinate */
BYTE    rgb[3];
register struct tmStruct        *tm;
double  uvp[2];
{       /* Should check that tm->inppri==TM_XYZPRIM beforehand... */
        double  d, x, y;
        COLOR   XYZ, RGB;
                                        /* convert to XYZ */
        d = 1./(6.*uvp[0] - 16.*uvp[1] + 12.);
        x = 9.*uvp[0] * d;
        y = 4.*uvp[1] * d;
        XYZ[CIEY] = 1./tm->inpsf;
        XYZ[CIEX] = x/y * XYZ[CIEY];
        XYZ[CIEZ] = (1.-x-y)/y * XYZ[CIEY];
                                        /* convert to RGB and clip */
        colortrans(RGB, tm->cmat, XYZ);
        clipgamut(RGB, 1., CGAMUT_LOWER, cblack, cwhite);
                                        /* perform final scaling & gamma */
        d = tm->clf[RED] * RGB[RED];
        rgb[RED] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
        d = tm->clf[GRN] * RGB[GRN];
        rgb[GRN] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
        d = tm->clf[BLU] * RGB[BLU];
        rgb[BLU] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
}


static TMbright
compmeshift(li, uvp)                    /* compute mesopic color shift */
TMbright        li;             /* encoded world luminance */
double  uvp[2];                 /* world (u',v') -> returned desaturated */
{
        double  scotrat;
        register double d;

        if (li >= BMESUPPER)
                return(li);
        scotrat = (.767676768 - 1.02356902*uvp[1])/uvp[0] - .343434343;
        if (li <= BMESLOWER) {
                d = 0.;
                uvp[0] = U_NEU; uvp[1] = V_NEU;
        } else {
                d = (tmMesofact[li-BMESLOWER] + .5) * (1./256.);
                uvp[0] = d*uvp[0] + (1.-d)*U_NEU;
                uvp[1] = d*uvp[1] + (1.-d)*V_NEU;
        }
        /*
        d = li + (double)TM_BRTSCALE*log(d + (1.-d)*scotrat);
        */
        d = d + (1.-d)*scotrat;
        d -= 1.;                        /* Taylor expansion of log(x) about 1 */
        d = d*(1. + d*(-.5 + d*(1./3. + d*-.125)));
        d = li + (double)TM_BRTSCALE*d;
        return((TMbright)(d>0. ? d+.5 : d-.5));
}


int
tmCvLuv32(ls, cs, luvs, len)            /* convert raw 32-bit LogLuv values */
TMbright        *ls;
BYTE    *cs;
uint32  *luvs;
int     len;
{
        static char     funcName[] = "tmCvLuv32";
        double  uvp[2];
        register LUV32DATA      *ld;
        register int    i, j;
                                        /* check arguments */
        if (tmTop == NULL)
                returnErr(TM_E_TMINVAL);
        if (ls == NULL | luvs == NULL | len < 0)
                returnErr(TM_E_ILLEGAL);
                                        /* check package registration */
        if (luv32Reg < 0) {
                if ((luv32Reg = tmRegPkg(&luv32Pkg)) < 0)
                        returnErr(TM_E_CODERR1);
                tmMkMesofact();
        }
                                        /* get package data */
        if ((ld = (LUV32DATA *)tmPkgData(tmTop,luv32Reg)) == NULL)
                returnErr(TM_E_NOMEM);
                                        /* convert each pixel */
        for (i = len; i--; ) {
                j = luvs[i] >> 16;              /* get luminance */
                if (j & 0x8000)                 /* negative luminance */
                        ls[i] = TM_NOBRT;       /* assign bogus value */
                else                            /* else convert to lnL */
                        ls[i] = (BRT2SCALE(j) >> 8) - ld->offset;
                if (cs == TM_NOCHROM)           /* no color? */
                        continue;
                                                /* get chrominance */
                if (tmTop->flags & TM_F_MESOPIC && ls[i] < BMESUPPER) {
                        uvp[0] = 1./UVSCALE*((luvs[i]>>8 & 0xff) + .5);
                        uvp[1] = 1./UVSCALE*((luvs[i] & 0xff) + .5);
                        ls[i] = compmeshift(ls[i], uvp);
                        j = tmTop->flags&TM_F_BW || ls[i]<BMESLOWER
                                        ? UVNEU
                                        : (int)(uvp[0]*UVSCALE)<<8
                                                | (int)(uvp[1]*UVSCALE);
                } else {
                        j = tmTop->flags&TM_F_BW ? UVNEU : luvs[i]&0xffff;
                }
                if (!isuvset(ld, j)) {
                        uvp[0] = 1./UVSCALE*((j>>8) + .5);
                        uvp[1] = 1./UVSCALE*((j & 0xff) + .5);
                        uv2rgb(ld->rgbval[j], tmTop, uvp);
                        setuv(ld, j);
                }
                cs[3*i  ] = ld->rgbval[j][RED];
                cs[3*i+1] = ld->rgbval[j][GRN];
                cs[3*i+2] = ld->rgbval[j][BLU];
        }
        returnOK;
}


int
tmCvLuv24(ls, cs, luvs, len)            /* convert raw 24-bit LogLuv values */
TMbright        *ls;
BYTE    *cs;
uint32  *luvs;
int     len;
{
        char    funcName[] = "tmCvLuv24";
        double  uvp[2];
        register LUV24DATA      *ld;
        register int    i, j;
                                        /* check arguments */
        if (tmTop == NULL)
                returnErr(TM_E_TMINVAL);
        if (ls == NULL | luvs == NULL | len < 0)
                returnErr(TM_E_ILLEGAL);
                                        /* check package registration */
        if (luv24Reg < 0) {
                if ((luv24Reg = tmRegPkg(&luv24Pkg)) < 0)
                        returnErr(TM_E_CODERR1);
                tmMkMesofact();
        }
                                        /* get package data */
        if ((ld = (LUV24DATA *)tmPkgData(tmTop,luv24Reg)) == NULL)
                returnErr(TM_E_NOMEM);
                                        /* convert each pixel */
        for (i = len; i--; ) {
                j = luvs[i] >> 14;              /* get luminance */
                ls[i] = (BRT2SCALE(j) >> 6) - ld->offset;
                if (cs == TM_NOCHROM)           /* no color? */
                        continue;
                                                /* get chrominance */
                if (tmTop->flags & TM_F_MESOPIC && ls[i] < BMESUPPER) {
                        if (uv_decode(uvp, uvp+1, luvs[i]&0x3fff) < 0) {
                                uvp[0] = U_NEU;         /* should barf? */
                                uvp[1] = V_NEU;
                        }
                        ls[i] = compmeshift(ls[i], uvp);
                        if (tmTop->flags&TM_F_BW || ls[i]<BMESLOWER
                                        || (j = uv_encode(uvp[0], uvp[1],
                                                SGILOGENCODE_NODITHER)) < 0)
                                j = uv14neu;
                } else {
                        j = tmTop->flags&TM_F_BW ? uv14neu : luvs[i]&0x3fff;
                }
                if (!isuvset(ld, j)) {
                        if (uv_decode(&uvp[0], &uvp[1], j) < 0) {
                                uvp[0] = U_NEU; uvp[1] = V_NEU;
                        }
                        uv2rgb(ld->rgbval[j], tmTop, uvp);
                        setuv(ld, j);
                }
                cs[3*i  ] = ld->rgbval[j][RED];
                cs[3*i+1] = ld->rgbval[j][GRN];
                cs[3*i+2] = ld->rgbval[j][BLU];
        }
        returnOK;
}


int
tmCvL16(ls, l16s, len)                  /* convert 16-bit LogL values */
TMbright        *ls;
uint16  *l16s;
int     len;
{
        static char     funcName[] = "tmCvL16";
        static double   lastsf;
        static int      offset;
        register int    i;
                                        /* check arguments */
        if (tmTop == NULL)
                returnErr(TM_E_TMINVAL);
        if (ls == NULL | l16s == NULL | len < 0)
                returnErr(TM_E_ILLEGAL);
                                        /* check scaling offset */
        if (!FEQ(tmTop->inpsf, lastsf)) {
                offset = BRT2SCALE(64);
                if (tmTop->inpsf > 1.0001)
                        offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
                else if (tmTop->inpsf < 0.9999)
                        offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
                lastsf = tmTop->inpsf;
        }
                                        /* convert each pixel */
        for (i = len; i--; ) {
                if (l16s[i] & 0x8000)           /* negative luminance */
                        ls[i] = TM_NOBRT;       /* assign bogus value */
                else                            /* else convert to lnL */
                        ls[i] = (BRT2SCALE(l16s[i]) >> 8) - offset;
        }
        returnOK;
}


static void
luv32NewSpace(tm)               /* initialize 32-bit LogLuv color space */
struct tmStruct *tm;
{
        register LUV32DATA      *ld;

        if (tm->inppri != TM_XYZPRIM) {         /* panic time! */
                fputs("Improper input color space in luv32NewSpace!\n", stderr);
                exit(1);
        }
        ld = (LUV32DATA *)tm->pd[luv32Reg];
        ld->offset = BRT2SCALE(64);
        if (tm->inpsf > 1.0001)
                ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
        else if (tm->inpsf < 0.9999)
                ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
        clruvall(ld);
}


static MEM_PTR
luv32Init(tm)                   /* allocate data for 32-bit LogLuv decoder */
struct tmStruct *tm;
{
        register LUV32DATA      *ld;

        ld = (LUV32DATA *)malloc(sizeof(LUV32DATA));
        if (ld == NULL)
                return(NULL);
        tm->pd[luv32Reg] = (MEM_PTR)ld;
        luv32NewSpace(tm);
        return((MEM_PTR)ld);
}


static void
luv24NewSpace(tm)               /* initialize 24-bit LogLuv color space */
struct tmStruct *tm;
{
        register LUV24DATA      *ld;

        if (tm->inppri != TM_XYZPRIM) {         /* panic time! */
                fputs("Improper input color space in luv24NewSpace!\n", stderr);
                exit(1);
        }
        ld = (LUV24DATA *)tm->pd[luv24Reg];
        ld->offset = BRT2SCALE(12);
        if (tm->inpsf > 1.0001)
                ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
        else if (tm->inpsf < 0.9999)
                ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
        clruvall(ld);
}


static MEM_PTR
luv24Init(tm)                   /* allocate data for 24-bit LogLuv decoder */
struct tmStruct *tm;
{
        register LUV24DATA      *ld;

        ld = (LUV24DATA *)malloc(sizeof(LUV24DATA));
        if (ld == NULL)
                return(NULL);
        tm->pd[luv24Reg] = (MEM_PTR)ld;
        if (uv14neu < 0)                /* initialize neutral color index */
                uv14neu = uv_encode(U_NEU, V_NEU, SGILOGENCODE_NODITHER);
        luv24NewSpace(tm);
        return((MEM_PTR)ld);
}
Revision:	3.5
Committed:	Tue Feb 25 02:47:22 2003 UTC (22 years, 8 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R5
Changes since 3.4:	+1 -56 lines
Log Message:	Replaced inline copyright notice with #include "copyright.h"
#	User	Rev	Content
1	gwlarson	3.1	#ifndef lint
2	greg	3.4	static const char RCSid[] = "$Id$";
3	gwlarson	3.1	#endif
4			/*
5			* Routines for tone-mapping LogLuv encoded pixels.
6	greg	3.4	*
7			* Externals declared in tmaptiff.h
8			*/
9
10	greg	3.5	#include "copyright.h"
11	gwlarson	3.1
12	greg	3.4	#define LOGLUV_PUBLIC 1
13
14	gwlarson	3.1	#include <stdio.h>
15	greg	3.4	#include <string.h>
16	gwlarson	3.1	#include <math.h>
17			#include "tiffio.h"
18			#include "tmprivat.h"
19	greg	3.4	#include "tmaptiff.h"
20	gwlarson	3.1
21			#ifndef BSD
22			#define bzero(d,n) (void)memset(d,0,n)
23			#endif
24			#define uvflgop(p,uv,op) ((p)->rgbflg[(uv)>>5] op (1L<<((uv)&0x1f)))
25			#define isuvset(p,uv) uvflgop(p,uv,&)
26			#define setuv(p,uv) uvflgop(p,uv,\|=)
27			#define clruv(p,uv) uvflgop(p,uv,&=~)
28			#define clruvall(p) bzero((MEM_PTR)(p)->rgbflg,sizeof((p)->rgbflg))
29
30	greg	3.4	#ifdef NOPROTO
31	gwlarson	3.1	static MEM_PTR luv32Init();
32			static void luv32NewSpace();
33			static MEM_PTR luv24Init();
34			static void luv24NewSpace();
35	greg	3.4	#else
36			static MEM_PTR luv32Init(struct tmStruct *);
37			static void luv32NewSpace(struct tmStruct *);
38			static MEM_PTR luv24Init(struct tmStruct *);
39			static void luv24NewSpace(struct tmStruct *);
40			#endif
41	gwlarson	3.1
42			typedef struct {
43			int offset; /* computed luminance offset */
44			BYTE rgbval[1<<16][3]; /* computed RGB value for given uv */
45			uint32 rgbflg[1<<(16-5)]; /* flags for computed values */
46			} LUV32DATA; /* LogLuv 32-bit conversion data */
47
48			#define UVNEU ((int)(UVSCALE*U_NEU)<<8 \
49			\| (int)(UVSCALE*V_NEU))
50
51			static struct tmPackage luv32Pkg = { /* 32-bit package functions */
52			luv32Init, luv32NewSpace, free
53			};
54			static int luv32Reg = -1; /* 32-bit package reg. number */
55
56			typedef struct {
57			int offset; /* computed luminance offset */
58			BYTE rgbval[1<<14][3]; /* computed rgb value for uv index */
59			uint32 rgbflg[1<<(14-5)]; /* flags for computed values */
60			} LUV24DATA; /* LogLuv 24-bit conversion data */
61
62			static struct tmPackage luv24Pkg = { /* 24-bit package functions */
63			luv24Init, luv24NewSpace, free
64			};
65			static int luv24Reg = -1; /* 24-bit package reg. number */
66
67			static int uv14neu = -1; /* neutral index for 14-bit (u',v') */
68
69
70	greg	3.4	static void
71	gwlarson	3.1	uv2rgb(rgb, tm, uvp) /* compute RGB from uv coordinate */
72			BYTE rgb[3];
73			register struct tmStruct *tm;
74			double uvp[2];
75			{ /* Should check that tm->inppri==TM_XYZPRIM beforehand... */
76			double d, x, y;
77	gwlarson	3.2	COLOR XYZ, RGB;
78	gwlarson	3.1	/* convert to XYZ */
79			d = 1./(6.uvp[0] - 16.uvp[1] + 12.);
80			x = 9.uvp[0] d;
81			y = 4.uvp[1] d;
82			XYZ[CIEY] = 1./tm->inpsf;
83			XYZ[CIEX] = x/y * XYZ[CIEY];
84			XYZ[CIEZ] = (1.-x-y)/y * XYZ[CIEY];
85			/* convert to RGB and clip */
86			colortrans(RGB, tm->cmat, XYZ);
87	greg	3.4	clipgamut(RGB, 1., CGAMUT_LOWER, cblack, cwhite);
88	gwlarson	3.1	/* perform final scaling & gamma */
89			d = tm->clf[RED] * RGB[RED];
90			rgb[RED] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
91			d = tm->clf[GRN] * RGB[GRN];
92			rgb[GRN] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
93			d = tm->clf[BLU] * RGB[BLU];
94			rgb[BLU] = d>=.999 ? 255 : (int)(256.*pow(d, 1./tm->mongam));
95			}
96
97
98			static TMbright
99			compmeshift(li, uvp) /* compute mesopic color shift */
100			TMbright li; /* encoded world luminance */
101			double uvp[2]; /* world (u',v') -> returned desaturated */
102			{
103	greg	3.4	double scotrat;
104			register double d;
105	gwlarson	3.2
106			if (li >= BMESUPPER)
107			return(li);
108	greg	3.4	scotrat = (.767676768 - 1.02356902*uvp[1])/uvp[0] - .343434343;
109	gwlarson	3.2	if (li <= BMESLOWER) {
110			d = 0.;
111			uvp[0] = U_NEU; uvp[1] = V_NEU;
112			} else {
113	greg	3.4	d = (tmMesofact[li-BMESLOWER] + .5) * (1./256.);
114	gwlarson	3.2	uvp[0] = duvp[0] + (1.-d)U_NEU;
115			uvp[1] = duvp[1] + (1.-d)V_NEU;
116			}
117	greg	3.4	/*
118			d = li + (double)TM_BRTSCALElog(d + (1.-d)scotrat);
119			*/
120			d = d + (1.-d)*scotrat;
121			d -= 1.; /* Taylor expansion of log(x) about 1 */
122			d = d(1. + d(-.5 + d(1./3. + d-.125)));
123			d = li + (double)TM_BRTSCALE*d;
124			return((TMbright)(d>0. ? d+.5 : d-.5));
125	gwlarson	3.1	}
126
127
128			int
129			tmCvLuv32(ls, cs, luvs, len) /* convert raw 32-bit LogLuv values */
130			TMbright *ls;
131			BYTE *cs;
132			uint32 *luvs;
133			int len;
134			{
135			static char funcName[] = "tmCvLuv32";
136			double uvp[2];
137			register LUV32DATA *ld;
138			register int i, j;
139			/* check arguments */
140			if (tmTop == NULL)
141			returnErr(TM_E_TMINVAL);
142			if (ls == NULL \| luvs == NULL \| len < 0)
143			returnErr(TM_E_ILLEGAL);
144			/* check package registration */
145	greg	3.4	if (luv32Reg < 0) {
146			if ((luv32Reg = tmRegPkg(&luv32Pkg)) < 0)
147			returnErr(TM_E_CODERR1);
148			tmMkMesofact();
149			}
150	gwlarson	3.1	/* get package data */
151			if ((ld = (LUV32DATA *)tmPkgData(tmTop,luv32Reg)) == NULL)
152			returnErr(TM_E_NOMEM);
153			/* convert each pixel */
154			for (i = len; i--; ) {
155			j = luvs[i] >> 16; /* get luminance */
156			if (j & 0x8000) /* negative luminance */
157	gwlarson	3.3	ls[i] = TM_NOBRT; /* assign bogus value */
158	gwlarson	3.1	else /* else convert to lnL */
159	greg	3.4	ls[i] = (BRT2SCALE(j) >> 8) - ld->offset;
160	gwlarson	3.1	if (cs == TM_NOCHROM) /* no color? */
161			continue;
162			/* get chrominance */
163			if (tmTop->flags & TM_F_MESOPIC && ls[i] < BMESUPPER) {
164			uvp[0] = 1./UVSCALE*((luvs[i]>>8 & 0xff) + .5);
165			uvp[1] = 1./UVSCALE*((luvs[i] & 0xff) + .5);
166			ls[i] = compmeshift(ls[i], uvp);
167	gwlarson	3.2	j = tmTop->flags&TM_F_BW \|\| ls[i]<BMESLOWER
168	gwlarson	3.1	? UVNEU
169			: (int)(uvp[0]*UVSCALE)<<8
170			\| (int)(uvp[1]*UVSCALE);
171			} else {
172			j = tmTop->flags&TM_F_BW ? UVNEU : luvs[i]&0xffff;
173			}
174			if (!isuvset(ld, j)) {
175	greg	3.4	uvp[0] = 1./UVSCALE*((j>>8) + .5);
176			uvp[1] = 1./UVSCALE*((j & 0xff) + .5);
177	gwlarson	3.1	uv2rgb(ld->rgbval[j], tmTop, uvp);
178			setuv(ld, j);
179			}
180			cs[3*i ] = ld->rgbval[j][RED];
181			cs[3*i+1] = ld->rgbval[j][GRN];
182			cs[3*i+2] = ld->rgbval[j][BLU];
183			}
184			returnOK;
185			}
186
187
188			int
189			tmCvLuv24(ls, cs, luvs, len) /* convert raw 24-bit LogLuv values */
190			TMbright *ls;
191			BYTE *cs;
192			uint32 *luvs;
193			int len;
194			{
195			char funcName[] = "tmCvLuv24";
196			double uvp[2];
197			register LUV24DATA *ld;
198			register int i, j;
199			/* check arguments */
200			if (tmTop == NULL)
201			returnErr(TM_E_TMINVAL);
202			if (ls == NULL \| luvs == NULL \| len < 0)
203			returnErr(TM_E_ILLEGAL);
204			/* check package registration */
205	greg	3.4	if (luv24Reg < 0) {
206			if ((luv24Reg = tmRegPkg(&luv24Pkg)) < 0)
207			returnErr(TM_E_CODERR1);
208			tmMkMesofact();
209			}
210	gwlarson	3.1	/* get package data */
211			if ((ld = (LUV24DATA *)tmPkgData(tmTop,luv24Reg)) == NULL)
212			returnErr(TM_E_NOMEM);
213			/* convert each pixel */
214			for (i = len; i--; ) {
215			j = luvs[i] >> 14; /* get luminance */
216	greg	3.4	ls[i] = (BRT2SCALE(j) >> 6) - ld->offset;
217	gwlarson	3.1	if (cs == TM_NOCHROM) /* no color? */
218			continue;
219			/* get chrominance */
220			if (tmTop->flags & TM_F_MESOPIC && ls[i] < BMESUPPER) {
221	greg	3.4	if (uv_decode(uvp, uvp+1, luvs[i]&0x3fff) < 0) {
222	gwlarson	3.1	uvp[0] = U_NEU; /* should barf? */
223			uvp[1] = V_NEU;
224			}
225			ls[i] = compmeshift(ls[i], uvp);
226	gwlarson	3.2	if (tmTop->flags&TM_F_BW \|\| ls[i]<BMESLOWER
227	greg	3.4	\|\| (j = uv_encode(uvp[0], uvp[1],
228			SGILOGENCODE_NODITHER)) < 0)
229	gwlarson	3.1	j = uv14neu;
230			} else {
231			j = tmTop->flags&TM_F_BW ? uv14neu : luvs[i]&0x3fff;
232			}
233			if (!isuvset(ld, j)) {
234	greg	3.4	if (uv_decode(&uvp[0], &uvp[1], j) < 0) {
235	gwlarson	3.2	uvp[0] = U_NEU; uvp[1] = V_NEU;
236	gwlarson	3.1	}
237			uv2rgb(ld->rgbval[j], tmTop, uvp);
238			setuv(ld, j);
239			}
240			cs[3*i ] = ld->rgbval[j][RED];
241			cs[3*i+1] = ld->rgbval[j][GRN];
242			cs[3*i+2] = ld->rgbval[j][BLU];
243			}
244			returnOK;
245			}
246
247
248			int
249			tmCvL16(ls, l16s, len) /* convert 16-bit LogL values */
250			TMbright *ls;
251			uint16 *l16s;
252			int len;
253			{
254			static char funcName[] = "tmCvL16";
255			static double lastsf;
256			static int offset;
257			register int i;
258			/* check arguments */
259			if (tmTop == NULL)
260			returnErr(TM_E_TMINVAL);
261			if (ls == NULL \| l16s == NULL \| len < 0)
262			returnErr(TM_E_ILLEGAL);
263			/* check scaling offset */
264			if (!FEQ(tmTop->inpsf, lastsf)) {
265	greg	3.4	offset = BRT2SCALE(64);
266	gwlarson	3.1	if (tmTop->inpsf > 1.0001)
267			offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
268			else if (tmTop->inpsf < 0.9999)
269			offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
270			lastsf = tmTop->inpsf;
271			}
272			/* convert each pixel */
273			for (i = len; i--; ) {
274			if (l16s[i] & 0x8000) /* negative luminance */
275	gwlarson	3.3	ls[i] = TM_NOBRT; /* assign bogus value */
276	gwlarson	3.1	else /* else convert to lnL */
277	greg	3.4	ls[i] = (BRT2SCALE(l16s[i]) >> 8) - offset;
278	gwlarson	3.1	}
279			returnOK;
280			}
281
282
283			static void
284			luv32NewSpace(tm) /* initialize 32-bit LogLuv color space */
285			struct tmStruct *tm;
286			{
287			register LUV32DATA *ld;
288
289			if (tm->inppri != TM_XYZPRIM) { /* panic time! */
290			fputs("Improper input color space in luv32NewSpace!\n", stderr);
291			exit(1);
292			}
293			ld = (LUV32DATA *)tm->pd[luv32Reg];
294	greg	3.4	ld->offset = BRT2SCALE(64);
295	gwlarson	3.1	if (tm->inpsf > 1.0001)
296			ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
297			else if (tm->inpsf < 0.9999)
298			ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
299			clruvall(ld);
300			}
301
302
303			static MEM_PTR
304			luv32Init(tm) /* allocate data for 32-bit LogLuv decoder */
305			struct tmStruct *tm;
306			{
307			register LUV32DATA *ld;
308
309			ld = (LUV32DATA *)malloc(sizeof(LUV32DATA));
310			if (ld == NULL)
311			return(NULL);
312			tm->pd[luv32Reg] = (MEM_PTR)ld;
313			luv32NewSpace(tm);
314			return((MEM_PTR)ld);
315			}
316
317
318			static void
319			luv24NewSpace(tm) /* initialize 24-bit LogLuv color space */
320			struct tmStruct *tm;
321			{
322			register LUV24DATA *ld;
323
324			if (tm->inppri != TM_XYZPRIM) { /* panic time! */
325			fputs("Improper input color space in luv24NewSpace!\n", stderr);
326			exit(1);
327			}
328			ld = (LUV24DATA *)tm->pd[luv24Reg];
329	greg	3.4	ld->offset = BRT2SCALE(12);
330	gwlarson	3.1	if (tm->inpsf > 1.0001)
331			ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)+.5);
332			else if (tm->inpsf < 0.9999)
333			ld->offset -= (int)(TM_BRTSCALE*log(tmTop->inpsf)-.5);
334			clruvall(ld);
335			}
336
337
338			static MEM_PTR
339			luv24Init(tm) /* allocate data for 24-bit LogLuv decoder */
340			struct tmStruct *tm;
341			{
342			register LUV24DATA *ld;
343
344			ld = (LUV24DATA *)malloc(sizeof(LUV24DATA));
345			if (ld == NULL)
346			return(NULL);
347			tm->pd[luv24Reg] = (MEM_PTR)ld;
348	greg	3.4	if (uv14neu < 0) /* initialize neutral color index */
349			uv14neu = uv_encode(U_NEU, V_NEU, SGILOGENCODE_NODITHER);
350	gwlarson	3.1	luv24NewSpace(tm);
351			return((MEM_PTR)ld);
352			}