src/px/pcond3.c

#ifndef lint
static const char       RCSid[] = "$Id: pcond3.c,v 3.13 2003/05/13 17:58:33 greg Exp $";
#endif
/*
 * Routines for computing and applying brightness mapping.
 */

#include <string.h>

#include "pcond.h"


#define CVRATIO         0.025           /* fraction of samples allowed > env. */

#define LN_10           2.30258509299404568402
#define exp10(x)        exp(LN_10*(x))

double  modhist[HISTRES];               /* modified histogram */
double  mhistot;                        /* modified histogram total */
double  cumf[HISTRES+1];                /* cumulative distribution function */


getfixations(fp)                /* load fixation history list */
FILE    *fp;
{
#define FIXHUNK         128
        RESOLU  fvres;
        int     pos[2];
        register int    px, py, i;
                                /* initialize our resolution struct */
        if ((fvres.rt=inpres.rt)&YMAJOR) {
                fvres.xr = fvxr;
                fvres.yr = fvyr;
        } else {
                fvres.xr = fvyr;
                fvres.yr = fvxr;
        }
                                /* read each picture position */
        while (fscanf(fp, "%d %d", &pos[0], &pos[1]) == 2) {
                                /* convert to closest index in foveal image */
                loc2pix(pos, &fvres,
                                (pos[0]+.5)/inpres.xr, (pos[1]+.5)/inpres.yr);
                                /* include nine neighborhood samples */
                for (px = pos[0]-1; px <= pos[0]+1; px++) {
                        if (px < 0 || px >= fvxr)
                                continue;
                        for (py = pos[1]-1; py <= pos[1]+1; py++) {
                                if (py < 0 || py >= fvyr)
                                        continue;
                                for (i = nfixations; i-- > 0; )
                                        if (fixlst[i][0] == px &&
                                                        fixlst[i][1] == py)
                                                break;
                                if (i >= 0)
                                        continue;       /* already there */
                                if (nfixations % FIXHUNK == 0) {
                                        if (nfixations)
                                                fixlst = (short (*)[2])
                                                        realloc((void *)fixlst,
                                                        (nfixations+FIXHUNK)*
                                                        2*sizeof(short));
                                        else
                                                fixlst = (short (*)[2])malloc(
                                                        FIXHUNK*2*sizeof(short)
                                                        );
                                        if (fixlst == NULL)
                                                syserror("malloc");
                                }
                                fixlst[nfixations][0] = px;
                                fixlst[nfixations][1] = py;
                                nfixations++;
                        }
                }
        }
        if (!feof(fp)) {
                fprintf(stderr, "%s: format error reading fixation data\n",
                                progname);
                exit(1);
        }
#undef  FIXHUNK
}


gethisto(fp)                    /* load precomputed luminance histogram */
FILE    *fp;
{
        double  histo[MAXPREHIST];
        double  histart, histep;
        double  l, b, lastb, w;
        int     n;
        register int    i;
                                        /* load data */
        for (i = 0; i < MAXPREHIST &&
                        fscanf(fp, "%lf %lf", &b, &histo[i]) == 2; i++) {
                if (i > 1 && fabs(b - lastb - histep) > .001) {
                        fprintf(stderr,
                                "%s: uneven step size in histogram data\n",
                                        progname);
                        exit(1);
                }
                if (i == 1)
                        if ((histep = b - (histart = lastb)) <= FTINY) {
                                fprintf(stderr,
                                        "%s: illegal step in histogram data\n",
                                                progname);
                                exit(1);
                        }
                lastb = b;
        }
        if (i < 2 || !feof(fp)) {
                fprintf(stderr,
                "%s: format/length error loading histogram (log10L %f at %d)\n",
                                progname, b, i);
                exit(1);
        }
        n = i;
        histart *= LN_10;
        histep *= LN_10;
                                        /* find extrema */
        for (i = 0; i < n && histo[i] <= FTINY; i++)
                ;
        bwmin = histart + (i-.001)*histep;
        for (i = n; i-- && histo[i] <= FTINY; )
                ;
        bwmax = histart + (i+1.001)*histep;
        if (bwmax > Bl(LMAX))
                bwmax = Bl(LMAX);
        if (bwmin < Bl(LMIN))
                bwmin = Bl(LMIN);
        else                            /* duplicate bottom bin */
                bwmin = bwmax - (bwmax-bwmin)*HISTRES/(HISTRES-1);
                                        /* convert histogram */
        bwavg = 0.; histot = 0.;
        for (i = 0; i < HISTRES; i++)
                bwhist[i] = 0.;
        for (i = 0, b = histart; i < n; i++, b += histep) {
                if (b < bwmin+FTINY) continue;
                if (b >= bwmax-FTINY) break;
                w = histo[i];
                bwavg += w*b;
                bwhist[bwhi(b)] += w;
                histot += w;
        }
        bwavg /= histot;
        if (bwmin > Bl(LMIN)+FTINY) {   /* add false samples at bottom */
                bwhist[1] *= 0.5;
                bwhist[0] += bwhist[1];
        }
}


double
centprob(x, y)                  /* center-weighting probability function */
int     x, y;
{
        double  xr, yr, p;
                                /* paraboloid, 0 at 90 degrees from center */
        xr = (x - .5*(fvxr-1))/90.;     /* 180 degree fisheye has fv?r == 90 */
        yr = (y - .5*(fvyr-1))/90.;
        p = 1. - xr*xr - yr*yr;
        return(p < 0. ? 0. : p);
}


comphist()                      /* create foveal sampling histogram */
{
        double  l, b, w, lwmin, lwmax;
        register int    x, y;
                                        /* check for precalculated histogram */
        if (what2do&DO_PREHIST)
                return;
        lwmin = 1e10;                   /* find extrema */
        lwmax = 0.;
        for (y = 0; y < fvyr; y++)
                for (x = 0; x < fvxr; x++) {
                        l = plum(fovscan(y)[x]);
                        if (l < lwmin) lwmin = l;
                        if (l > lwmax) lwmax = l;
                }
        lwmax *= 1.01;
        if (lwmax > LMAX)
                lwmax = LMAX;
        bwmax = Bl(lwmax);
        if (lwmin < LMIN) {
                lwmin = LMIN;
                bwmin = Bl(LMIN);
        } else {                        /* duplicate bottom bin */
                bwmin = bwmax - (bwmax-Bl(lwmin))*HISTRES/(HISTRES-1);
                lwmin = Lb(bwmin);
        }
                                        /* (re)compute histogram */
        bwavg = 0.;
        histot = 0.;
        for (x = 0; x < HISTRES; x++)
                bwhist[x] = 0.;
                                        /* global average */
        if (!(what2do&DO_FIXHIST) || fixfrac < 1.-FTINY)
                for (y = 0; y < fvyr; y++)
                        for (x = 0; x < fvxr; x++) {
                                l = plum(fovscan(y)[x]);
                                if (l < lwmin+FTINY) continue;
                                if (l >= lwmax-FTINY) continue;
                                b = Bl(l);
                                w = what2do&DO_CWEIGHT ? centprob(x,y) : 1.;
                                bwavg += w*b;
                                bwhist[bwhi(b)] += w;
                                histot += w;
                        }
                                        /* average fixation points */
        if (what2do&DO_FIXHIST && nfixations > 0) {
                if (histot > FTINY)
                        w = fixfrac/(1.-fixfrac)*histot/nfixations;
                else
                        w = 1.;
                for (x = 0; x < nfixations; x++) {
                        l = plum(fovscan(fixlst[x][1])[fixlst[x][0]]);
                        if (l < lwmin+FTINY) continue;
                        if (l >= lwmax-FTINY) continue;
                        b = Bl(l);
                        bwavg += w*b;
                        bwhist[bwhi(b)] += w;
                        histot += w;
                }
        }
        bwavg /= histot;
        if (lwmin > LMIN+FTINY) {       /* add false samples at bottom */
                bwhist[1] *= 0.5;
                bwhist[0] += bwhist[1];
        }
}


mkcumf()                        /* make cumulative distribution function */
{
        register int    i;
        register double sum;

        mhistot = 0.;           /* compute modified total */
        for (i = 0; i < HISTRES; i++)
                mhistot += modhist[i];

        sum = 0.;               /* compute cumulative function */
        for (i = 0; i < HISTRES; i++) {
                cumf[i] = sum/mhistot;
                sum += modhist[i];
        }
        cumf[HISTRES] = 1.;
}


double
cf(b)                           /* return cumulative function at b */
double  b;
{
        double  x;
        register int    i;

        i = x = HISTRES*(b - bwmin)/(bwmax - bwmin);
        x -= (double)i;
        return(cumf[i]*(1.-x) + cumf[i+1]*x);
}


double
BLw(Lw)                         /* map world luminance to display brightness */
double  Lw;
{
        double  b;

        if (Lw <= LMIN || (b = Bl(Lw)) <= bwmin+FTINY)
                return(Bldmin);
        if (b >= bwmax-FTINY)
                return(Bldmax);
        return(Bldmin + cf(b)*(Bldmax-Bldmin));
}


double
htcontrs(La)            /* human threshold contrast sensitivity, dL(La) */
double  La;
{
        double  l10La, l10dL;
                                /* formula taken from Ferwerda et al. [SG96] */
        if (La < 1.148e-4)
                return(1.38e-3);
        l10La = log10(La);
        if (l10La < -1.44)              /* rod response regime */
                l10dL = pow(.405*l10La + 1.6, 2.18) - 2.86;
        else if (l10La < -.0184)
                l10dL = l10La - .395;
        else if (l10La < 1.9)           /* cone response regime */
                l10dL = pow(.249*l10La + .65, 2.7) - .72;
        else
                l10dL = l10La - 1.255;

        return(exp10(l10dL));
}


double
clampf(Lw)                      /* histogram clamping function */
double  Lw;
{
        double  bLw, ratio;

        bLw = BLw(Lw);          /* apply current brightness map */
        ratio = what2do&DO_HSENS ? htcontrs(Lb(bLw))/htcontrs(Lw) : Lb(bLw)/Lw;
        return(ratio/(Lb1(bLw)*(Bldmax-Bldmin)*Bl1(Lw)));
}

double
crfactor(Lw)                    /* contrast reduction factor */
double  Lw;
{
        int     i = HISTRES*(Bl(Lw) - bwmin)/(bwmax - bwmin);
        double  bLw, ratio, Tdb;

        if (i <= 0)
                return(1.0);
        if (i >= HISTRES)
                return(1.0);
        bLw = BLw(Lw);
        ratio = what2do&DO_HSENS ? htcontrs(Lb(bLw))/htcontrs(Lw) : Lb(bLw)/Lw;
        Tdb = mhistot * (bwmax - bwmin) / HISTRES;
        return(modhist[i]*Lb1(bLw)*(Bldmax-Bldmin)*Bl1(Lw)/(Tdb*ratio));
}


#if ADJ_VEIL
mkcrfimage()                    /* compute contrast reduction factor image */
{
        int     i;
        float   *crfptr;
        COLOR   *fovptr;

        if (crfimg == NULL)
                crfimg = (float *)malloc(fvxr*fvyr*sizeof(float));
        if (crfimg == NULL)
                syserror("malloc");
        crfptr = crfimg;
        fovptr = fovimg;
        for (i = fvxr*fvyr; i--; crfptr++, fovptr++)
                crfptr[0] = crfactor(plum(fovptr[0]));
}
#endif


int
mkbrmap()                       /* make dynamic range map */
{
        double  Tdb, b, s;
        double  ceiling, trimmings;
        register int    i;
                                        /* copy initial histogram */
        memcpy((void *)modhist, (void *)bwhist, sizeof(modhist));
        s = (bwmax - bwmin)/HISTRES;    /* s is delta b */
                                        /* loop until satisfactory */
        do {
                mkcumf();                       /* sync brightness mapping */
                if (mhistot <= histot*CVRATIO)
                        return(-1);             /* no compression needed! */
                Tdb = mhistot * s;
                trimmings = 0.;                 /* clip to envelope */
                for (i = 0, b = bwmin + .5*s; i < HISTRES; i++, b += s) {
                        ceiling = Tdb*clampf(Lb(b));
                        if (modhist[i] > ceiling) {
                                trimmings += modhist[i] - ceiling;
                                modhist[i] = ceiling;
                        }
                }
        } while (trimmings > histot*CVRATIO);

#if ADJ_VEIL
        mkcrfimage();                   /* contrast reduction image */
#endif

        return(0);                      /* we got it */
}


scotscan(scan, xres)            /* apply scotopic color sensitivity loss */
COLOR   *scan;
int     xres;
{
        COLOR   ctmp;
        double  incolor, b, Lw;
        register int    i;

        for (i = 0; i < xres; i++) {
                Lw = plum(scan[i]);
                if (Lw >= TopMesopic)
                        incolor = 1.;
                else if (Lw <= BotMesopic)
                        incolor = 0.;
                else
                        incolor = (Lw - BotMesopic) /
                                        (TopMesopic - BotMesopic);
                if (incolor < 1.-FTINY) {
                        b = (1.-incolor)*slum(scan[i])*inpexp/SWNORM;
                        if (lumf == rgblum) b /= WHTEFFICACY;
                        setcolor(ctmp, b, b, b);
                        if (incolor <= FTINY)
                                setcolor(scan[i], 0., 0., 0.);
                        else
                                scalecolor(scan[i], incolor);
                        addcolor(scan[i], ctmp);
                }
        }
}


mapscan(scan, xres)             /* apply tone mapping operator to scanline */
COLOR   *scan;
int     xres;
{
        double  mult, Lw, b;
        register int    x;

        for (x = 0; x < xres; x++) {
                Lw = plum(scan[x]);
                if (Lw < LMIN) {
                        setcolor(scan[x], 0., 0., 0.);
                        continue;
                }
                b = BLw(Lw);            /* apply brightness mapping */
                mult = (Lb(b) - ldmin)/(ldmax - ldmin)/(Lw*inpexp);
                if (lumf == rgblum) mult *= WHTEFFICACY;
                scalecolor(scan[x], mult);
        }
}


putmapping(fp)                  /* put out mapping function */
FILE    *fp;
{
        double  b, s;
        register int    i;
        double  wlum, sf, dlum;

        sf = scalef*inpexp;
        if (lumf == cielum) sf *= WHTEFFICACY;
        s = (bwmax - bwmin)/HISTRES;
        for (i = 0, b = bwmin + .5*s; i < HISTRES; i++, b += s) {
                wlum = Lb(b);
                if (what2do&DO_LINEAR) {
                        dlum = sf*wlum;
                        if (dlum > ldmax) dlum = ldmax;
                        else if (dlum < ldmin) dlum = ldmin;
                        fprintf(fp, "%e %e\n", wlum, dlum);
                } else
                        fprintf(fp, "%e %e\n", wlum, Lb(BLw(wlum)));
        }
}
Revision:	3.14
Committed:	Mon Jun 30 14:59:12 2003 UTC (22 years, 4 months ago) by schorsch
Content type:	text/plain
Branch:	MAIN
Changes since 3.13:	+4 -2 lines
Log Message:	Replaced most outdated BSD function calls with their posix equivalents, and cleaned up a few other platform dependencies.
#	User	Rev	Content
1	greg	3.1	#ifndef lint
2	schorsch	3.14	static const char RCSid[] = "$Id: pcond3.c,v 3.13 2003/05/13 17:58:33 greg Exp $";
3	greg	3.1	#endif
4			/*
5			* Routines for computing and applying brightness mapping.
6			*/
7
8	schorsch	3.14	#include <string.h>
9
10	greg	3.1	#include "pcond.h"
11
12
13	greg	3.5	#define CVRATIO 0.025 /* fraction of samples allowed > env. */
14	greg	3.1
15	gwlarson	3.10	#define LN_10 2.30258509299404568402
16			#define exp10(x) exp(LN_10*(x))
17	greg	3.1
18	greg	3.11	double modhist[HISTRES]; /* modified histogram */
19	greg	3.5	double mhistot; /* modified histogram total */
20	greg	3.11	double cumf[HISTRES+1]; /* cumulative distribution function */
21	greg	3.1
22
23	greg	3.8	getfixations(fp) /* load fixation history list */
24			FILE *fp;
25			{
26			#define FIXHUNK 128
27			RESOLU fvres;
28			int pos[2];
29			register int px, py, i;
30			/* initialize our resolution struct */
31	greg	3.11	if ((fvres.rt=inpres.rt)&YMAJOR) {
32	greg	3.8	fvres.xr = fvxr;
33			fvres.yr = fvyr;
34			} else {
35			fvres.xr = fvyr;
36			fvres.yr = fvxr;
37			}
38			/* read each picture position */
39			while (fscanf(fp, "%d %d", &pos[0], &pos[1]) == 2) {
40			/* convert to closest index in foveal image */
41			loc2pix(pos, &fvres,
42			(pos[0]+.5)/inpres.xr, (pos[1]+.5)/inpres.yr);
43			/* include nine neighborhood samples */
44			for (px = pos[0]-1; px <= pos[0]+1; px++) {
45			if (px < 0 \|\| px >= fvxr)
46			continue;
47			for (py = pos[1]-1; py <= pos[1]+1; py++) {
48			if (py < 0 \|\| py >= fvyr)
49			continue;
50			for (i = nfixations; i-- > 0; )
51			if (fixlst[i][0] == px &&
52			fixlst[i][1] == py)
53			break;
54			if (i >= 0)
55			continue; /* already there */
56			if (nfixations % FIXHUNK == 0) {
57			if (nfixations)
58			fixlst = (short (*)[2])
59	greg	3.12	realloc((void *)fixlst,
60	greg	3.8	(nfixations+FIXHUNK)*
61			2*sizeof(short));
62			else
63			fixlst = (short (*)[2])malloc(
64			FIXHUNK2sizeof(short)
65			);
66			if (fixlst == NULL)
67			syserror("malloc");
68			}
69			fixlst[nfixations][0] = px;
70			fixlst[nfixations][1] = py;
71			nfixations++;
72			}
73			}
74			}
75			if (!feof(fp)) {
76			fprintf(stderr, "%s: format error reading fixation data\n",
77			progname);
78			exit(1);
79			}
80			#undef FIXHUNK
81			}
82
83
84	gwlarson	3.10	gethisto(fp) /* load precomputed luminance histogram */
85			FILE *fp;
86			{
87	greg	3.11	double histo[MAXPREHIST];
88	gwlarson	3.10	double histart, histep;
89			double l, b, lastb, w;
90			int n;
91			register int i;
92			/* load data */
93			for (i = 0; i < MAXPREHIST &&
94	greg	3.11	fscanf(fp, "%lf %lf", &b, &histo[i]) == 2; i++) {
95			if (i > 1 && fabs(b - lastb - histep) > .001) {
96	gwlarson	3.10	fprintf(stderr,
97			"%s: uneven step size in histogram data\n",
98			progname);
99			exit(1);
100			}
101			if (i == 1)
102	greg	3.11	if ((histep = b - (histart = lastb)) <= FTINY) {
103			fprintf(stderr,
104			"%s: illegal step in histogram data\n",
105			progname);
106			exit(1);
107			}
108	gwlarson	3.10	lastb = b;
109			}
110			if (i < 2 \|\| !feof(fp)) {
111			fprintf(stderr,
112			"%s: format/length error loading histogram (log10L %f at %d)\n",
113			progname, b, i);
114			exit(1);
115			}
116			n = i;
117			histart *= LN_10;
118			histep *= LN_10;
119			/* find extrema */
120			for (i = 0; i < n && histo[i] <= FTINY; i++)
121			;
122	greg	3.11	bwmin = histart + (i-.001)*histep;
123	gwlarson	3.10	for (i = n; i-- && histo[i] <= FTINY; )
124			;
125	greg	3.11	bwmax = histart + (i+1.001)*histep;
126	gwlarson	3.10	if (bwmax > Bl(LMAX))
127			bwmax = Bl(LMAX);
128			if (bwmin < Bl(LMIN))
129			bwmin = Bl(LMIN);
130			else /* duplicate bottom bin */
131			bwmin = bwmax - (bwmax-bwmin)*HISTRES/(HISTRES-1);
132			/* convert histogram */
133			bwavg = 0.; histot = 0.;
134			for (i = 0; i < HISTRES; i++)
135			bwhist[i] = 0.;
136			for (i = 0, b = histart; i < n; i++, b += histep) {
137	greg	3.11	if (b < bwmin+FTINY) continue;
138			if (b >= bwmax-FTINY) break;
139	gwlarson	3.10	w = histo[i];
140			bwavg += w*b;
141			bwhist[bwhi(b)] += w;
142			histot += w;
143			}
144			bwavg /= histot;
145			if (bwmin > Bl(LMIN)+FTINY) { /* add false samples at bottom */
146			bwhist[1] *= 0.5;
147			bwhist[0] += bwhist[1];
148			}
149			}
150
151
152	greg	3.8	double
153			centprob(x, y) /* center-weighting probability function */
154			int x, y;
155			{
156			double xr, yr, p;
157			/* paraboloid, 0 at 90 degrees from center */
158			xr = (x - .5(fvxr-1))/90.; / 180 degree fisheye has fv?r == 90 */
159			yr = (y - .5*(fvyr-1))/90.;
160			p = 1. - xrxr - yryr;
161			return(p < 0. ? 0. : p);
162			}
163
164
165			comphist() /* create foveal sampling histogram */
166			{
167			double l, b, w, lwmin, lwmax;
168			register int x, y;
169	gwlarson	3.10	/* check for precalculated histogram */
170			if (what2do&DO_PREHIST)
171			return;
172	greg	3.8	lwmin = 1e10; /* find extrema */
173			lwmax = 0.;
174			for (y = 0; y < fvyr; y++)
175			for (x = 0; x < fvxr; x++) {
176			l = plum(fovscan(y)[x]);
177			if (l < lwmin) lwmin = l;
178			if (l > lwmax) lwmax = l;
179			}
180	greg	3.9	lwmax *= 1.01;
181			if (lwmax > LMAX)
182			lwmax = LMAX;
183	greg	3.8	bwmax = Bl(lwmax);
184	greg	3.9	if (lwmin < LMIN) {
185			lwmin = LMIN;
186			bwmin = Bl(LMIN);
187			} else { /* duplicate bottom bin */
188			bwmin = bwmax - (bwmax-Bl(lwmin))*HISTRES/(HISTRES-1);
189			lwmin = Lb(bwmin);
190			}
191	greg	3.8	/* (re)compute histogram */
192			bwavg = 0.;
193			histot = 0.;
194			for (x = 0; x < HISTRES; x++)
195			bwhist[x] = 0.;
196			/* global average */
197			if (!(what2do&DO_FIXHIST) \|\| fixfrac < 1.-FTINY)
198			for (y = 0; y < fvyr; y++)
199			for (x = 0; x < fvxr; x++) {
200			l = plum(fovscan(y)[x]);
201	greg	3.11	if (l < lwmin+FTINY) continue;
202			if (l >= lwmax-FTINY) continue;
203	greg	3.8	b = Bl(l);
204			w = what2do&DO_CWEIGHT ? centprob(x,y) : 1.;
205	gwlarson	3.10	bwavg += w*b;
206	greg	3.8	bwhist[bwhi(b)] += w;
207			histot += w;
208			}
209			/* average fixation points */
210			if (what2do&DO_FIXHIST && nfixations > 0) {
211			if (histot > FTINY)
212			w = fixfrac/(1.-fixfrac)*histot/nfixations;
213			else
214			w = 1.;
215			for (x = 0; x < nfixations; x++) {
216			l = plum(fovscan(fixlst[x][1])[fixlst[x][0]]);
217	greg	3.11	if (l < lwmin+FTINY) continue;
218			if (l >= lwmax-FTINY) continue;
219	greg	3.8	b = Bl(l);
220	gwlarson	3.10	bwavg += w*b;
221	greg	3.8	bwhist[bwhi(b)] += w;
222			histot += w;
223			}
224			}
225			bwavg /= histot;
226	greg	3.9	if (lwmin > LMIN+FTINY) { /* add false samples at bottom */
227			bwhist[1] *= 0.5;
228			bwhist[0] += bwhist[1];
229			}
230	greg	3.8	}
231
232
233	greg	3.1	mkcumf() /* make cumulative distribution function */
234			{
235			register int i;
236	greg	3.5	register double sum;
237	greg	3.1
238	greg	3.5	mhistot = 0.; /* compute modified total */
239			for (i = 0; i < HISTRES; i++)
240			mhistot += modhist[i];
241
242			sum = 0.; /* compute cumulative function */
243			for (i = 0; i < HISTRES; i++) {
244			cumf[i] = sum/mhistot;
245	greg	3.1	sum += modhist[i];
246			}
247			cumf[HISTRES] = 1.;
248			}
249
250
251			double
252			cf(b) /* return cumulative function at b */
253			double b;
254			{
255			double x;
256			register int i;
257
258			i = x = HISTRES*(b - bwmin)/(bwmax - bwmin);
259			x -= (double)i;
260			return(cumf[i](1.-x) + cumf[i+1]x);
261			}
262
263
264			double
265			BLw(Lw) /* map world luminance to display brightness */
266			double Lw;
267			{
268			double b;
269
270			if (Lw <= LMIN \|\| (b = Bl(Lw)) <= bwmin+FTINY)
271			return(Bldmin);
272			if (b >= bwmax-FTINY)
273			return(Bldmax);
274	greg	3.4	return(Bldmin + cf(b)*(Bldmax-Bldmin));
275	greg	3.1	}
276
277
278			double
279			htcontrs(La) /* human threshold contrast sensitivity, dL(La) */
280			double La;
281			{
282			double l10La, l10dL;
283			/* formula taken from Ferwerda et al. [SG96] */
284			if (La < 1.148e-4)
285			return(1.38e-3);
286			l10La = log10(La);
287			if (l10La < -1.44) /* rod response regime */
288			l10dL = pow(.405*l10La + 1.6, 2.18) - 2.86;
289			else if (l10La < -.0184)
290			l10dL = l10La - .395;
291			else if (l10La < 1.9) /* cone response regime */
292			l10dL = pow(.249*l10La + .65, 2.7) - .72;
293			else
294			l10dL = l10La - 1.255;
295
296			return(exp10(l10dL));
297			}
298
299
300			double
301	greg	3.11	clampf(Lw) /* histogram clamping function */
302	greg	3.1	double Lw;
303			{
304			double bLw, ratio;
305
306			bLw = BLw(Lw); /* apply current brightness map */
307			ratio = what2do&DO_HSENS ? htcontrs(Lb(bLw))/htcontrs(Lw) : Lb(bLw)/Lw;
308			return(ratio/(Lb1(bLw)(Bldmax-Bldmin)Bl1(Lw)));
309			}
310
311	greg	3.11	double
312			crfactor(Lw) /* contrast reduction factor */
313			double Lw;
314			{
315			int i = HISTRES*(Bl(Lw) - bwmin)/(bwmax - bwmin);
316			double bLw, ratio, Tdb;
317
318			if (i <= 0)
319			return(1.0);
320			if (i >= HISTRES)
321			return(1.0);
322			bLw = BLw(Lw);
323			ratio = what2do&DO_HSENS ? htcontrs(Lb(bLw))/htcontrs(Lw) : Lb(bLw)/Lw;
324			Tdb = mhistot * (bwmax - bwmin) / HISTRES;
325			return(modhist[i]Lb1(bLw)(Bldmax-Bldmin)Bl1(Lw)/(Tdbratio));
326			}
327
328
329			#if ADJ_VEIL
330			mkcrfimage() /* compute contrast reduction factor image */
331			{
332			int i;
333			float *crfptr;
334			COLOR *fovptr;
335
336			if (crfimg == NULL)
337			crfimg = (float )malloc(fvxrfvyr*sizeof(float));
338			if (crfimg == NULL)
339			syserror("malloc");
340			crfptr = crfimg;
341			fovptr = fovimg;
342			for (i = fvxr*fvyr; i--; crfptr++, fovptr++)
343			crfptr[0] = crfactor(plum(fovptr[0]));
344			}
345			#endif
346
347	greg	3.1
348			int
349			mkbrmap() /* make dynamic range map */
350			{
351	greg	3.11	double Tdb, b, s;
352	greg	3.5	double ceiling, trimmings;
353	greg	3.1	register int i;
354			/* copy initial histogram */
355	schorsch	3.14	memcpy((void )modhist, (void )bwhist, sizeof(modhist));
356	greg	3.11	s = (bwmax - bwmin)/HISTRES; /* s is delta b */
357	greg	3.1	/* loop until satisfactory */
358	greg	3.5	do {
359			mkcumf(); /* sync brightness mapping */
360			if (mhistot <= histot*CVRATIO)
361			return(-1); /* no compression needed! */
362	greg	3.11	Tdb = mhistot * s;
363	greg	3.5	trimmings = 0.; /* clip to envelope */
364	greg	3.1	for (i = 0, b = bwmin + .5*s; i < HISTRES; i++, b += s) {
365	greg	3.11	ceiling = Tdb*clampf(Lb(b));
366	greg	3.5	if (modhist[i] > ceiling) {
367			trimmings += modhist[i] - ceiling;
368			modhist[i] = ceiling;
369			}
370	greg	3.1	}
371	greg	3.5	} while (trimmings > histot*CVRATIO);
372
373	greg	3.11	#if ADJ_VEIL
374			mkcrfimage(); /* contrast reduction image */
375			#endif
376
377	greg	3.5	return(0); /* we got it */
378	greg	3.1	}
379
380
381			scotscan(scan, xres) /* apply scotopic color sensitivity loss */
382			COLOR *scan;
383			int xres;
384			{
385			COLOR ctmp;
386			double incolor, b, Lw;
387			register int i;
388
389			for (i = 0; i < xres; i++) {
390			Lw = plum(scan[i]);
391			if (Lw >= TopMesopic)
392			incolor = 1.;
393			else if (Lw <= BotMesopic)
394			incolor = 0.;
395			else
396			incolor = (Lw - BotMesopic) /
397			(TopMesopic - BotMesopic);
398			if (incolor < 1.-FTINY) {
399	greg	3.2	b = (1.-incolor)slum(scan[i])inpexp/SWNORM;
400			if (lumf == rgblum) b /= WHTEFFICACY;
401			setcolor(ctmp, b, b, b);
402	greg	3.1	if (incolor <= FTINY)
403			setcolor(scan[i], 0., 0., 0.);
404			else
405			scalecolor(scan[i], incolor);
406			addcolor(scan[i], ctmp);
407			}
408			}
409			}
410
411
412			mapscan(scan, xres) /* apply tone mapping operator to scanline */
413			COLOR *scan;
414			int xres;
415			{
416			double mult, Lw, b;
417	greg	3.11	register int x;
418	greg	3.1
419	greg	3.11	for (x = 0; x < xres; x++) {
420			Lw = plum(scan[x]);
421	greg	3.1	if (Lw < LMIN) {
422	greg	3.11	setcolor(scan[x], 0., 0., 0.);
423	greg	3.1	continue;
424			}
425	greg	3.11	b = BLw(Lw); /* apply brightness mapping */
426			mult = (Lb(b) - ldmin)/(ldmax - ldmin)/(Lw*inpexp);
427	greg	3.1	if (lumf == rgblum) mult *= WHTEFFICACY;
428	greg	3.11	scalecolor(scan[x], mult);
429	greg	3.4	}
430			}
431
432
433			putmapping(fp) /* put out mapping function */
434			FILE *fp;
435			{
436			double b, s;
437			register int i;
438	greg	3.7	double wlum, sf, dlum;
439	greg	3.4
440			sf = scalef*inpexp;
441			if (lumf == cielum) sf *= WHTEFFICACY;
442			s = (bwmax - bwmin)/HISTRES;
443			for (i = 0, b = bwmin + .5*s; i < HISTRES; i++, b += s) {
444			wlum = Lb(b);
445	greg	3.7	if (what2do&DO_LINEAR) {
446			dlum = sf*wlum;
447			if (dlum > ldmax) dlum = ldmax;
448			else if (dlum < ldmin) dlum = ldmin;
449			fprintf(fp, "%e %e\n", wlum, dlum);
450			} else
451	greg	3.4	fprintf(fp, "%e %e\n", wlum, Lb(BLw(wlum)));
452	greg	3.1	}
453			}