src/common/tonemap.c

#ifndef lint
static const char       RCSid[] = "$Id: tonemap.c,v 3.27 2006/06/07 17:52:03 schorsch Exp $";
#endif
/*
 * Tone mapping functions.
 * See tonemap.h for detailed function descriptions.
 * Added von Kries white-balance calculations 10/01 (GW).
 *
 * Externals declared in tonemap.h
 */

#include "copyright.h"

#include        <stdio.h>
#include        <math.h>
#include        "tmprivat.h"
#include        "tmerrmsg.h"

#define exp10(x)        exp(M_LN10*(x))

                                        /* our list of conversion packages */
struct tmPackage        *tmPkg[TM_MAXPKG];
int     tmNumPkgs = 0;                  /* number of registered packages */

                                        /* luminance->brightness lookup */
static TMbright         *tmFloat2BrtLUT = NULL;

#define tmCvLumLUfp(pf) tmFloat2BrtLUT[*(int32 *)(pf) >> 15]


TMstruct *
tmInit(                                 /* initialize new tone mapping */
int     flags,
RGBPRIMP        monpri,
double  gamval
)
{
        COLORMAT        cmat;
        TMstruct        *tmnew;
        int     i;
                                                /* allocate structure */
        tmnew = (TMstruct *)malloc(sizeof(TMstruct));
        if (tmnew == NULL)
                return(NULL);

        tmnew->flags = flags & ~TM_F_UNIMPL;
        if (tmnew->flags & TM_F_BW)
                tmnew->flags &= ~TM_F_MESOPIC;
                                                /* set monitor transform */
        if (monpri == NULL || monpri == stdprims || tmnew->flags & TM_F_BW) {
                tmnew->monpri = stdprims;
                tmnew->clf[RED] = rgb2xyzmat[1][0];
                tmnew->clf[GRN] = rgb2xyzmat[1][1];
                tmnew->clf[BLU] = rgb2xyzmat[1][2];
        } else {
                comprgb2xyzmat(cmat, tmnew->monpri=monpri);
                tmnew->clf[RED] = cmat[1][0];
                tmnew->clf[GRN] = cmat[1][1];
                tmnew->clf[BLU] = cmat[1][2];
        }
                                                /* set gamma value */
        if (gamval < MINGAM)
                tmnew->mongam = DEFGAM;
        else
                tmnew->mongam = gamval;
                                                /* set color divisors */
        for (i = 0; i < 3; i++)
                tmnew->cdiv[i] = 256.*pow(tmnew->clf[i], 1./tmnew->mongam);

                                                /* set input transform */
        tmnew->inppri = tmnew->monpri;
        tmnew->cmat[0][0] = tmnew->cmat[1][1] = tmnew->cmat[2][2] =
                        tmnew->inpsf = WHTEFFICACY;
        tmnew->cmat[0][1] = tmnew->cmat[0][2] = tmnew->cmat[1][0] =
        tmnew->cmat[1][2] = tmnew->cmat[2][0] = tmnew->cmat[2][1] = 0.;
        tmnew->inpdat = NULL;
        tmnew->hbrmin = 10; tmnew->hbrmax = -10;
        tmnew->histo = NULL;
        tmnew->mbrmin = 10; tmnew->mbrmax = -10;
        tmnew->lumap = NULL;
                                                /* zero private data */
        for (i = TM_MAXPKG; i--; )
                tmnew->pd[i] = NULL;
        tmnew->lastError = TM_E_OK;
        tmnew->lastFunc = "NoErr";
                                                /* return new TMstruct */
        return(tmnew);
}


int
tmSetSpace(                     /* set input color space for conversions */
TMstruct        *tms,
RGBPRIMP        pri,
double  sf,
MEM_PTR dat
)
{
        static const char funcName[] = "tmSetSpace";
        int     i, j;
                                                /* error check */
        if (tms == NULL)
                returnErr(TM_E_TMINVAL);
        if (sf <= 1e-12)
                returnErr(TM_E_ILLEGAL);
                                                /* check if no change */
        if (pri == tms->inppri && FEQ(sf, tms->inpsf) && dat == tms->inpdat)
                returnOK;
        tms->inppri = pri;                      /* let's set it */
        tms->inpsf = sf;
        tms->inpdat = dat;

        if (tms->flags & TM_F_BW) {             /* color doesn't matter */
                tms->monpri = tms->inppri;              /* eliminate xform */
                if (tms->inppri == TM_XYZPRIM) {
                        tms->clf[CIEX] = tms->clf[CIEZ] = 0.;
                        tms->clf[CIEY] = 1.;
                } else {
                        comprgb2xyzmat(tms->cmat, tms->monpri);
                        tms->clf[RED] = tms->cmat[1][0];
                        tms->clf[GRN] = tms->cmat[1][1];
                        tms->clf[BLU] = tms->cmat[1][2];
                }
                tms->cmat[0][0] = tms->cmat[1][1] = tms->cmat[2][2] =
                                tms->inpsf;
                tms->cmat[0][1] = tms->cmat[0][2] = tms->cmat[1][0] =
                tms->cmat[1][2] = tms->cmat[2][0] = tms->cmat[2][1] = 0.;

        } else if (tms->inppri == TM_XYZPRIM)   /* input is XYZ */
                compxyz2rgbWBmat(tms->cmat, tms->monpri);

        else {                                  /* input is RGB */
                if (tms->inppri != tms->monpri &&
                                PRIMEQ(tms->inppri, tms->monpri))
                        tms->inppri = tms->monpri;      /* no xform */
                comprgb2rgbWBmat(tms->cmat, tms->inppri, tms->monpri);
        }
        for (i = 0; i < 3; i++)
                for (j = 0; j < 3; j++)
                        tms->cmat[i][j] *= tms->inpsf;
                                                /* set color divisors */
        for (i = 0; i < 3; i++)
                if (tms->clf[i] > .001)
                        tms->cdiv[i] =
                                256.*pow(tms->clf[i], 1./tms->mongam);
                else
                        tms->cdiv[i] = 1;
                                                /* notify packages */
        for (i = tmNumPkgs; i--; )
                if (tms->pd[i] != NULL && tmPkg[i]->NewSpace != NULL)
                        (*tmPkg[i]->NewSpace)(tms);
        returnOK;
}


void
tmClearHisto(                           /* clear current histogram */
TMstruct        *tms
)
{
        if (tms == NULL || tms->histo == NULL)
                return;
        free((MEM_PTR)tms->histo);
        tms->histo = NULL;
}


TMbright
tmCvLuminance(                          /* convert a single luminance */
double  lum
)
{
        double  d;

#ifdef isfinite
        if (!isfinite(lum) || lum <= TM_NOLUM)
#else
        if (lum <= TM_NOLUM)
#endif
                return(TM_NOBRT);
        d = TM_BRTSCALE*log(lum);
        if (d > 0.)
                return((TMbright)(d+.5));
        return((TMbright)(d-.5));
}


int
tmCvLums(                               /* convert luminances using lookup */
TMbright        *ls,
float           *scan,
int             len
)
{
        if (tmFloat2BrtLUT == NULL) {   /* initialize lookup table */
                int32   i;
                tmFloat2BrtLUT = (TMbright *)malloc(sizeof(TMbright)*0x10000);
                if (tmFloat2BrtLUT == NULL)
                        return(TM_E_NOMEM);
                for (i = 0; i < 0x10000; i++) {
                        int32   l = (i<<1 | 1) << 14;
#ifndef isfinite
                        if ((l & 0x7f800000) == 0x7f800000)
                                tmFloat2BrtLUT[i] = TM_NOBRT;
                        else
#endif
                        tmFloat2BrtLUT[i] = tmCvLuminance(*(float *)&l);
                }
        }
        if (len <= 0)
                return(TM_E_OK);
        if ((ls == NULL) | (scan == NULL))
                return(TM_E_ILLEGAL);
        while (len--) {
                if (*scan <= TM_NOLUM) {
                        *ls++ = TM_NOBRT;
                        ++scan;
                        continue;
                }
                *ls++ = tmCvLumLUfp(scan++);
        }
        return(TM_E_OK);
}


int
tmCvGrays(                              /* convert float gray values */
TMstruct        *tms,
TMbright        *ls,
float           *scan,
int             len
)
{
        static const char funcName[] = "tmCvGrays";
        int     i;

        if (tms == NULL)
                returnErr(TM_E_TMINVAL);
        if ((ls == NULL) | (scan == NULL) | (len < 0))
                returnErr(TM_E_ILLEGAL);
        if (tmFloat2BrtLUT == NULL)                     /* initialize */
                tmCvLums(NULL, NULL, 0);
        for (i = len; i--; ) {
                float   lum = tms->inpsf * scan[i];
                if (lum <= TM_NOLUM)
                        ls[i] = TM_NOBRT;
                else
                        ls[i] = tmCvLumLUfp(&lum);
        }
        returnOK;
}


int
tmCvColors(                             /* convert float colors */
TMstruct        *tms,
TMbright        *ls,
BYTE    *cs,
COLOR   *scan,
int     len
)
{
        static const char funcName[] = "tmCvColors";
        static BYTE     gamtab[1024];
        static double   curgam = .0;
        COLOR   cmon;
        float   lum, slum, d;
        int     i;

        if (tms == NULL)
                returnErr(TM_E_TMINVAL);
        if ((ls == NULL) | (scan == NULL) | (len < 0))
                returnErr(TM_E_ILLEGAL);
        if (tmFloat2BrtLUT == NULL)                     /* initialize */
                tmCvLums(NULL, NULL, 0);
        if (cs != TM_NOCHROM && fabs(tms->mongam - curgam) > .02) {
                curgam = tms->mongam;                   /* (re)build table */
                for (i = 1024; i--; )
                        gamtab[i] = (int)(256.*pow((i+.5)/1024., 1./curgam));
        }
        for (i = len; i--; ) {
                if (tmNeedMatrix(tms)) {                /* get monitor RGB */
                        colortrans(cmon, tms->cmat, scan[i]);
                } else {
                        cmon[RED] = tms->inpsf*scan[i][RED];
                        cmon[GRN] = tms->inpsf*scan[i][GRN];
                        cmon[BLU] = tms->inpsf*scan[i][BLU];
                }
#ifdef isfinite
                if (!isfinite(cmon[RED]) || cmon[RED] < .0f) cmon[RED] = .0f;
                if (!isfinite(cmon[GRN]) || cmon[GRN] < .0f) cmon[GRN] = .0f;
                if (!isfinite(cmon[BLU]) || cmon[BLU] < .0f) cmon[BLU] = .0f;
#else
                if (cmon[RED] < .0f) cmon[RED] = .0f;
                if (cmon[GRN] < .0f) cmon[GRN] = .0f;
                if (cmon[BLU] < .0f) cmon[BLU] = .0f;
#endif
                                                        /* world luminance */
                lum =   tms->clf[RED]*cmon[RED] +
                        tms->clf[GRN]*cmon[GRN] +
                        tms->clf[BLU]*cmon[BLU] ;
                if (lum <= TM_NOLUM) {                  /* convert brightness */
                        lum = cmon[RED] = cmon[GRN] = cmon[BLU] = TM_NOLUM;
                        ls[i] = TM_NOBRT;
                } else
                        ls[i] = tmCvLumLUfp(&lum);
                if (cs == TM_NOCHROM)                   /* no color? */
                        continue;
                if (tms->flags & TM_F_MESOPIC && lum < LMESUPPER) {
                        slum = scotlum(cmon);           /* mesopic adj. */
                        if (lum < LMESLOWER) {
                                cmon[RED] = cmon[GRN] = cmon[BLU] = slum;
                        } else {
                                d = (lum - LMESLOWER)/(LMESUPPER - LMESLOWER);
                                if (tms->flags & TM_F_BW)
                                        cmon[RED] = cmon[GRN] =
                                                        cmon[BLU] = d*lum;
                                else
                                        scalecolor(cmon, d);
                                d = (1.f-d)*slum;
                                cmon[RED] += d;
                                cmon[GRN] += d;
                                cmon[BLU] += d;
                        }
                } else if (tms->flags & TM_F_BW) {
                        cmon[RED] = cmon[GRN] = cmon[BLU] = lum;
                }
                d = tms->clf[RED]*cmon[RED]/lum;
                cs[3*i  ] = d>=.999f ? 255 : gamtab[(int)(1024.f*d)];
                d = tms->clf[GRN]*cmon[GRN]/lum;
                cs[3*i+1] = d>=.999f ? 255 : gamtab[(int)(1024.f*d)];
                d = tms->clf[BLU]*cmon[BLU]/lum;
                cs[3*i+2] = d>=.999f ? 255 : gamtab[(int)(1024.f*d)];
        }
        returnOK;
}


int
tmAddHisto(                             /* add values to histogram */
TMstruct        *tms,
TMbright        *ls,
int     len,
int     wt
)
{
        static const char funcName[] = "tmAddHisto";
        int     oldorig=0, oldlen, horig, hlen;
        int     i, j;

        if (tms == NULL)
                returnErr(TM_E_TMINVAL);
        if (len < 0)
                returnErr(TM_E_ILLEGAL);
        if (len == 0)
                returnOK;
                                                /* first, grow limits */
        if (tms->histo == NULL) {
                for (i = len; i-- && ls[i] < MINBRT; )
                        ;
                if (i < 0)
                        returnOK;
                tms->hbrmin = tms->hbrmax = ls[i];
                oldlen = 0;
        } else {
                oldorig = (tms->hbrmin-MINBRT)/HISTEP;
                oldlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - oldorig;
        }
        for (i = len; i--; ) {
                if ((j = ls[i]) < MINBRT)
                        continue;
                if (j < tms->hbrmin)
                        tms->hbrmin = j;
                else if (j > tms->hbrmax)
                        tms->hbrmax = j;
        }
        horig = (tms->hbrmin-MINBRT)/HISTEP;
        hlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - horig;
        if (hlen > oldlen) {                    /* (re)allocate histogram */
                int     *newhist = (int *)calloc(hlen, sizeof(int));
                if (newhist == NULL)
                        returnErr(TM_E_NOMEM);
                if (oldlen) {                   /* copy and free old */
                        for (i = oldlen, j = i+oldorig-horig; i; )
                                newhist[--j] = tms->histo[--i];
                        free((MEM_PTR)tms->histo);
                }
                tms->histo = newhist;
        }
        if (wt == 0)
                returnOK;
        for (i = len; i--; )                    /* add in new counts */
                if (ls[i] >= MINBRT)
                        tms->histo[ (ls[i]-MINBRT)/HISTEP - horig ] += wt;
        returnOK;
}


static double
htcontrs(               /* 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));
}


static int
tmNewMap(                       /* allocate new tone-mapping array */
TMstruct        *tms
)
{
        if (tms->lumap != NULL && (tms->mbrmax - tms->mbrmin) !=
                                        (tms->hbrmax - tms->hbrmin)) {
                free((MEM_PTR)tms->lumap);
                tms->lumap = NULL;
        }
        tms->mbrmin = tms->hbrmin;
        tms->mbrmax = tms->hbrmax;
        if (tms->mbrmin > tms->mbrmax)
                return 0;
        if (tms->lumap == NULL)
                tms->lumap = (unsigned short *)malloc(sizeof(unsigned short)*
                                        (tms->mbrmax-tms->mbrmin+1));
        return(tms->lumap != NULL);
}


int
tmFixedMapping(                 /* compute fixed, linear tone-mapping */
TMstruct        *tms,
double  expmult,
double  gamval
)
{
        static const char funcName[] = "tmFixedMapping";
        double          d;
        int     i;
        
        if (!tmNewMap(tms))
                returnErr(TM_E_NOMEM);
        if (expmult <= .0)
                expmult = 1.;
        if (gamval < MINGAM)
                gamval = tms->mongam;
        d = log(expmult/tms->inpsf);
        for (i = tms->mbrmax-tms->mbrmin+1; i--; ) {
                double  val = 256. * exp(
                        ( d + (tms->mbrmin+i)*(1./TM_BRTSCALE) )
                        / gamval);
                tms->lumap[i] = val >= (double)0xffff ? 0xffff : (int)val;
        }
        returnOK;
}


int
tmComputeMapping(                       /* compute histogram tone-mapping */
TMstruct        *tms,
double  gamval,
double  Lddyn,
double  Ldmax
)
{
        static const char funcName[] = "tmComputeMapping";
        int     *histo;
        float   *cumf;
        int     brt0, histlen, threshold, ceiling, trimmings;
        double  logLddyn, Ldmin, Ldavg, Lwavg, Tr, Lw, Ld;
        int32   histot;
        double  sum;
        double  d;
        int     i, j;

        if (tms == NULL || tms->histo == NULL)
                returnErr(TM_E_TMINVAL);
                                        /* check arguments */
        if (Lddyn < MINLDDYN) Lddyn = DEFLDDYN;
        if (Ldmax < MINLDMAX) Ldmax = DEFLDMAX;
        if (gamval < MINGAM) gamval = tms->mongam;
                                        /* compute handy values */
        Ldmin = Ldmax/Lddyn;
        logLddyn = log(Lddyn);
        Ldavg = sqrt(Ldmax*Ldmin);
        i = (tms->hbrmin-MINBRT)/HISTEP;
        brt0 = MINBRT + HISTEP/2 + i*HISTEP;
        histlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - i;
                                        /* histogram total and mean */
        histot = 0; sum = 0;
        j = brt0 + histlen*HISTEP;
        for (i = histlen; i--; ) {
                histot += tms->histo[i];
                sum += (j -= HISTEP) * tms->histo[i];
        }
        threshold = histot*0.005 + .5;
        if (threshold < 4)
                returnErr(TM_E_TMFAIL);
        Lwavg = tmLuminance( (double)sum / histot );
                                        /* allocate space for mapping */
        if (!tmNewMap(tms))
                returnErr(TM_E_NOMEM);
                                        /* use linear tone mapping? */
        if (tms->flags & TM_F_LINEAR)
                goto linearmap;
                                        /* clamp histogram */
        histo = (int *)malloc(histlen*sizeof(int));
        cumf = (float *)malloc((histlen+2)*sizeof(float));
        if ((histo == NULL) | (cumf == NULL))
                returnErr(TM_E_NOMEM);
        cumf[histlen+1] = 1.;           /* guard for assignment code */
        for (i = histlen; i--; )        /* make malleable copy */
                histo[i] = tms->histo[i];
        do {                            /* iterate to solution */
                sum = 0;                /* cumulative probability */
                for (i = 0; i < histlen; i++) {
                        cumf[i] = (double)sum/histot;
                        sum += histo[i];
                }
                cumf[histlen] = 1.;
                Tr = histot * (double)(tms->hbrmax - tms->hbrmin) /
                        ((double)histlen*TM_BRTSCALE) / logLddyn;
                ceiling = Tr + 1.;
                trimmings = 0;          /* clip to envelope */
                for (i = histlen; i--; ) {
                        if (tms->flags & TM_F_HCONTR) {
                                Lw = tmLuminance(brt0 + i*HISTEP);
                                Ld = Ldmin * exp( logLddyn *
                                        .5*(cumf[i]+cumf[i+1]) );
                                ceiling = Tr * (htcontrs(Ld) * Lw) /
                                        (htcontrs(Lw) * Ld) + 1.;
                        }
                        if (histo[i] > ceiling) {
                                trimmings += histo[i] - ceiling;
                                histo[i] = ceiling;
                        }
                }
                                        /* check if we're out of data */
                if ((histot -= trimmings) <= threshold) {
                        free((MEM_PTR)histo);
                        free((MEM_PTR)cumf);
                        goto linearmap;
                }
        } while (trimmings > threshold);
                                        /* assign tone-mapping */
        for (i = tms->mbrmax-tms->mbrmin+1; i--; ) {
                j = d = (double)i/(tms->mbrmax-tms->mbrmin)*histlen;
                d -= (double)j;
                Ld = Ldmin*exp(logLddyn*((1.-d)*cumf[j]+d*cumf[j+1]));
                d = (Ld - Ldmin)/(Ldmax - Ldmin);
                tms->lumap[i] = 256.*pow(d, 1./gamval);
        }
        free((MEM_PTR)histo);           /* clean up and return */
        free((MEM_PTR)cumf);
        returnOK;
linearmap:                              /* linear tone-mapping */
        if (tms->flags & TM_F_HCONTR)
                d = htcontrs(Ldavg) / htcontrs(Lwavg);
        else
                d = Ldavg / Lwavg;
        return(tmFixedMapping(tms, tms->inpsf*d/Ldmax, gamval));
}


int
tmMapPixels(                    /* apply tone-mapping to pixel(s) */
TMstruct        *tms,
BYTE    *ps,
TMbright        *ls,
BYTE    *cs,
int     len
)
{
        static const char funcName[] = "tmMapPixels";
        int32   li, pv;

        if (tms == NULL || tms->lumap == NULL)
                returnErr(TM_E_TMINVAL);
        if ((ps == NULL) | (ls == NULL) | (len < 0))
                returnErr(TM_E_ILLEGAL);
        while (len--) {
                if ((li = *ls++) < tms->mbrmin) {
                        li = 0;
                } else {
                        if (li > tms->mbrmax)
                                li = tms->mbrmax;
                        li = tms->lumap[li - tms->mbrmin];
                }
                if (cs == TM_NOCHROM)
                        *ps++ = li>255 ? 255 : li;
                else {
                        pv = *cs++ * li / tms->cdiv[RED];
                        *ps++ = pv>255 ? 255 : pv;
                        pv = *cs++ * li / tms->cdiv[GRN];
                        *ps++ = pv>255 ? 255 : pv;
                        pv = *cs++ * li / tms->cdiv[BLU];
                        *ps++ = pv>255 ? 255 : pv;
                }
        }
        returnOK;
}


TMstruct *
tmDup(                          /* duplicate top tone mapping */
TMstruct        *tms
)
{
        int     len;
        int     i;
        TMstruct        *tmnew;

        if (tms == NULL)                /* anything to duplicate? */
                return(NULL);
        tmnew = (TMstruct *)malloc(sizeof(TMstruct));
        if (tmnew == NULL)
                return(NULL);
        *tmnew = *tms;          /* copy everything */
        if (tmnew->histo != NULL) {     /* duplicate histogram */
                len = (tmnew->hbrmax-MINBRT)/HISTEP + 1 -
                                (tmnew->hbrmin-MINBRT)/HISTEP;
                tmnew->histo = (int *)malloc(len*sizeof(int));
                if (tmnew->histo != NULL)
                        for (i = len; i--; )
                                tmnew->histo[i] = tms->histo[i];
        }
        if (tmnew->lumap != NULL) {     /* duplicate luminance mapping */
                len = tmnew->mbrmax-tmnew->mbrmin+1;
                tmnew->lumap = (unsigned short *)malloc(
                                                len*sizeof(unsigned short) );
                if (tmnew->lumap != NULL)
                        for (i = len; i--; )
                                tmnew->lumap[i] = tms->lumap[i];
        }
                                        /* clear package data */
        for (i = tmNumPkgs; i--; )
                tmnew->pd[i] = NULL;
                                        /* return copy */
        return(tmnew);
}


void
tmDone(tms)                     /* done with tone mapping -- destroy it */
TMstruct        *tms;
{
        int     i;
                                        /* NULL arg. is equiv. to tms */
        if (tms == NULL)
                return;
                                        /* free tables */
        if (tms->histo != NULL)
                free((MEM_PTR)tms->histo);
        if (tms->lumap != NULL)
                free((MEM_PTR)tms->lumap);
                                        /* free private data */
        for (i = tmNumPkgs; i--; )
                if (tms->pd[i] != NULL)
                        (*tmPkg[i]->Free)(tms->pd[i]);
        free((MEM_PTR)tms);             /* free basic structure */
}

/******************** Shared but Private library routines *********************/

BYTE    tmMesofact[BMESUPPER-BMESLOWER];

void
tmMkMesofact()                          /* build mesopic lookup factor table */
{
        int     i;

        if (tmMesofact[BMESUPPER-BMESLOWER-1])
                return;

        for (i = BMESLOWER; i < BMESUPPER; i++)
                tmMesofact[i-BMESLOWER] = 256. *
                                (tmLuminance(i) - LMESLOWER) /
                                (LMESUPPER - LMESLOWER);
}


int
tmErrorReturn(                          /* error return (with message) */
const char      *func,
TMstruct        *tms,
int     err
)
{
        if (tms != NULL) {
                tms->lastFunc = func;
                tms->lastError = err;
                if (tms->flags & TM_F_NOSTDERR)
                        return(err);
        }
        fputs(func, stderr);
        fputs(": ", stderr);
        fputs(tmErrorMessage[err], stderr);
        fputs("!\n", stderr);
        return(err);
}
Revision:	3.28
Committed:	Wed Aug 9 16:26:54 2006 UTC (17 years, 8 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R8
Changes since 3.27:	+6 -4 lines
Log Message:	Fixed overflow condition on fixed linear tone-mapping
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: tonemap.c,v 3.27 2006/06/07 17:52:03 schorsch Exp $";
3	#endif
4	/*
5	* Tone mapping functions.
6	* See tonemap.h for detailed function descriptions.
7	* Added von Kries white-balance calculations 10/01 (GW).
8	*
9	* Externals declared in tonemap.h
10	*/
11
12	#include "copyright.h"
13
14	#include <stdio.h>
15	#include <math.h>
16	#include "tmprivat.h"
17	#include "tmerrmsg.h"
18
19	#define exp10(x) exp(M_LN10*(x))
20
21	/* our list of conversion packages */
22	struct tmPackage *tmPkg[TM_MAXPKG];
23	int tmNumPkgs = 0; /* number of registered packages */
24
25	/* luminance->brightness lookup */
26	static TMbright *tmFloat2BrtLUT = NULL;
27
28	#define tmCvLumLUfp(pf) tmFloat2BrtLUT[(int32 )(pf) >> 15]
29
30
31	TMstruct *
32	tmInit( /* initialize new tone mapping */
33	int flags,
34	RGBPRIMP monpri,
35	double gamval
36	)
37	{
38	COLORMAT cmat;
39	TMstruct *tmnew;
40	int i;
41	/* allocate structure */
42	tmnew = (TMstruct *)malloc(sizeof(TMstruct));
43	if (tmnew == NULL)
44	return(NULL);
45
46	tmnew->flags = flags & ~TM_F_UNIMPL;
47	if (tmnew->flags & TM_F_BW)
48	tmnew->flags &= ~TM_F_MESOPIC;
49	/* set monitor transform */
50	if (monpri == NULL \|\| monpri == stdprims \|\| tmnew->flags & TM_F_BW) {
51	tmnew->monpri = stdprims;
52	tmnew->clf[RED] = rgb2xyzmat[1][0];
53	tmnew->clf[GRN] = rgb2xyzmat[1][1];
54	tmnew->clf[BLU] = rgb2xyzmat[1][2];
55	} else {
56	comprgb2xyzmat(cmat, tmnew->monpri=monpri);
57	tmnew->clf[RED] = cmat[1][0];
58	tmnew->clf[GRN] = cmat[1][1];
59	tmnew->clf[BLU] = cmat[1][2];
60	}
61	/* set gamma value */
62	if (gamval < MINGAM)
63	tmnew->mongam = DEFGAM;
64	else
65	tmnew->mongam = gamval;
66	/* set color divisors */
67	for (i = 0; i < 3; i++)
68	tmnew->cdiv[i] = 256.*pow(tmnew->clf[i], 1./tmnew->mongam);
69
70	/* set input transform */
71	tmnew->inppri = tmnew->monpri;
72	tmnew->cmat[0][0] = tmnew->cmat[1][1] = tmnew->cmat[2][2] =
73	tmnew->inpsf = WHTEFFICACY;
74	tmnew->cmat[0][1] = tmnew->cmat[0][2] = tmnew->cmat[1][0] =
75	tmnew->cmat[1][2] = tmnew->cmat[2][0] = tmnew->cmat[2][1] = 0.;
76	tmnew->inpdat = NULL;
77	tmnew->hbrmin = 10; tmnew->hbrmax = -10;
78	tmnew->histo = NULL;
79	tmnew->mbrmin = 10; tmnew->mbrmax = -10;
80	tmnew->lumap = NULL;
81	/* zero private data */
82	for (i = TM_MAXPKG; i--; )
83	tmnew->pd[i] = NULL;
84	tmnew->lastError = TM_E_OK;
85	tmnew->lastFunc = "NoErr";
86	/* return new TMstruct */
87	return(tmnew);
88	}
89
90
91	int
92	tmSetSpace( /* set input color space for conversions */
93	TMstruct *tms,
94	RGBPRIMP pri,
95	double sf,
96	MEM_PTR dat
97	)
98	{
99	static const char funcName[] = "tmSetSpace";
100	int i, j;
101	/* error check */
102	if (tms == NULL)
103	returnErr(TM_E_TMINVAL);
104	if (sf <= 1e-12)
105	returnErr(TM_E_ILLEGAL);
106	/* check if no change */
107	if (pri == tms->inppri && FEQ(sf, tms->inpsf) && dat == tms->inpdat)
108	returnOK;
109	tms->inppri = pri; /* let's set it */
110	tms->inpsf = sf;
111	tms->inpdat = dat;
112
113	if (tms->flags & TM_F_BW) { /* color doesn't matter */
114	tms->monpri = tms->inppri; /* eliminate xform */
115	if (tms->inppri == TM_XYZPRIM) {
116	tms->clf[CIEX] = tms->clf[CIEZ] = 0.;
117	tms->clf[CIEY] = 1.;
118	} else {
119	comprgb2xyzmat(tms->cmat, tms->monpri);
120	tms->clf[RED] = tms->cmat[1][0];
121	tms->clf[GRN] = tms->cmat[1][1];
122	tms->clf[BLU] = tms->cmat[1][2];
123	}
124	tms->cmat[0][0] = tms->cmat[1][1] = tms->cmat[2][2] =
125	tms->inpsf;
126	tms->cmat[0][1] = tms->cmat[0][2] = tms->cmat[1][0] =
127	tms->cmat[1][2] = tms->cmat[2][0] = tms->cmat[2][1] = 0.;
128
129	} else if (tms->inppri == TM_XYZPRIM) /* input is XYZ */
130	compxyz2rgbWBmat(tms->cmat, tms->monpri);
131
132	else { /* input is RGB */
133	if (tms->inppri != tms->monpri &&
134	PRIMEQ(tms->inppri, tms->monpri))
135	tms->inppri = tms->monpri; /* no xform */
136	comprgb2rgbWBmat(tms->cmat, tms->inppri, tms->monpri);
137	}
138	for (i = 0; i < 3; i++)
139	for (j = 0; j < 3; j++)
140	tms->cmat[i][j] *= tms->inpsf;
141	/* set color divisors */
142	for (i = 0; i < 3; i++)
143	if (tms->clf[i] > .001)
144	tms->cdiv[i] =
145	256.*pow(tms->clf[i], 1./tms->mongam);
146	else
147	tms->cdiv[i] = 1;
148	/* notify packages */
149	for (i = tmNumPkgs; i--; )
150	if (tms->pd[i] != NULL && tmPkg[i]->NewSpace != NULL)
151	(*tmPkg[i]->NewSpace)(tms);
152	returnOK;
153	}
154
155
156	void
157	tmClearHisto( /* clear current histogram */
158	TMstruct *tms
159	)
160	{
161	if (tms == NULL \|\| tms->histo == NULL)
162	return;
163	free((MEM_PTR)tms->histo);
164	tms->histo = NULL;
165	}
166
167
168	TMbright
169	tmCvLuminance( /* convert a single luminance */
170	double lum
171	)
172	{
173	double d;
174
175	#ifdef isfinite
176	if (!isfinite(lum) \|\| lum <= TM_NOLUM)
177	#else
178	if (lum <= TM_NOLUM)
179	#endif
180	return(TM_NOBRT);
181	d = TM_BRTSCALE*log(lum);
182	if (d > 0.)
183	return((TMbright)(d+.5));
184	return((TMbright)(d-.5));
185	}
186
187
188	int
189	tmCvLums( /* convert luminances using lookup */
190	TMbright *ls,
191	float *scan,
192	int len
193	)
194	{
195	if (tmFloat2BrtLUT == NULL) { /* initialize lookup table */
196	int32 i;
197	tmFloat2BrtLUT = (TMbright )malloc(sizeof(TMbright)0x10000);
198	if (tmFloat2BrtLUT == NULL)
199	return(TM_E_NOMEM);
200	for (i = 0; i < 0x10000; i++) {
201	int32 l = (i<<1 \| 1) << 14;
202	#ifndef isfinite
203	if ((l & 0x7f800000) == 0x7f800000)
204	tmFloat2BrtLUT[i] = TM_NOBRT;
205	else
206	#endif
207	tmFloat2BrtLUT[i] = tmCvLuminance((float )&l);
208	}
209	}
210	if (len <= 0)
211	return(TM_E_OK);
212	if ((ls == NULL) \| (scan == NULL))
213	return(TM_E_ILLEGAL);
214	while (len--) {
215	if (*scan <= TM_NOLUM) {
216	*ls++ = TM_NOBRT;
217	++scan;
218	continue;
219	}
220	*ls++ = tmCvLumLUfp(scan++);
221	}
222	return(TM_E_OK);
223	}
224
225
226	int
227	tmCvGrays( /* convert float gray values */
228	TMstruct *tms,
229	TMbright *ls,
230	float *scan,
231	int len
232	)
233	{
234	static const char funcName[] = "tmCvGrays";
235	int i;
236
237	if (tms == NULL)
238	returnErr(TM_E_TMINVAL);
239	if ((ls == NULL) \| (scan == NULL) \| (len < 0))
240	returnErr(TM_E_ILLEGAL);
241	if (tmFloat2BrtLUT == NULL) /* initialize */
242	tmCvLums(NULL, NULL, 0);
243	for (i = len; i--; ) {
244	float lum = tms->inpsf * scan[i];
245	if (lum <= TM_NOLUM)
246	ls[i] = TM_NOBRT;
247	else
248	ls[i] = tmCvLumLUfp(&lum);
249	}
250	returnOK;
251	}
252
253
254	int
255	tmCvColors( /* convert float colors */
256	TMstruct *tms,
257	TMbright *ls,
258	BYTE *cs,
259	COLOR *scan,
260	int len
261	)
262	{
263	static const char funcName[] = "tmCvColors";
264	static BYTE gamtab[1024];
265	static double curgam = .0;
266	COLOR cmon;
267	float lum, slum, d;
268	int i;
269
270	if (tms == NULL)
271	returnErr(TM_E_TMINVAL);
272	if ((ls == NULL) \| (scan == NULL) \| (len < 0))
273	returnErr(TM_E_ILLEGAL);
274	if (tmFloat2BrtLUT == NULL) /* initialize */
275	tmCvLums(NULL, NULL, 0);
276	if (cs != TM_NOCHROM && fabs(tms->mongam - curgam) > .02) {
277	curgam = tms->mongam; /* (re)build table */
278	for (i = 1024; i--; )
279	gamtab[i] = (int)(256.*pow((i+.5)/1024., 1./curgam));
280	}
281	for (i = len; i--; ) {
282	if (tmNeedMatrix(tms)) { /* get monitor RGB */
283	colortrans(cmon, tms->cmat, scan[i]);
284	} else {
285	cmon[RED] = tms->inpsf*scan[i][RED];
286	cmon[GRN] = tms->inpsf*scan[i][GRN];
287	cmon[BLU] = tms->inpsf*scan[i][BLU];
288	}
289	#ifdef isfinite
290	if (!isfinite(cmon[RED]) \|\| cmon[RED] < .0f) cmon[RED] = .0f;
291	if (!isfinite(cmon[GRN]) \|\| cmon[GRN] < .0f) cmon[GRN] = .0f;
292	if (!isfinite(cmon[BLU]) \|\| cmon[BLU] < .0f) cmon[BLU] = .0f;
293	#else
294	if (cmon[RED] < .0f) cmon[RED] = .0f;
295	if (cmon[GRN] < .0f) cmon[GRN] = .0f;
296	if (cmon[BLU] < .0f) cmon[BLU] = .0f;
297	#endif
298	/* world luminance */
299	lum = tms->clf[RED]*cmon[RED] +
300	tms->clf[GRN]*cmon[GRN] +
301	tms->clf[BLU]*cmon[BLU] ;
302	if (lum <= TM_NOLUM) { /* convert brightness */
303	lum = cmon[RED] = cmon[GRN] = cmon[BLU] = TM_NOLUM;
304	ls[i] = TM_NOBRT;
305	} else
306	ls[i] = tmCvLumLUfp(&lum);
307	if (cs == TM_NOCHROM) /* no color? */
308	continue;
309	if (tms->flags & TM_F_MESOPIC && lum < LMESUPPER) {
310	slum = scotlum(cmon); /* mesopic adj. */
311	if (lum < LMESLOWER) {
312	cmon[RED] = cmon[GRN] = cmon[BLU] = slum;
313	} else {
314	d = (lum - LMESLOWER)/(LMESUPPER - LMESLOWER);
315	if (tms->flags & TM_F_BW)
316	cmon[RED] = cmon[GRN] =
317	cmon[BLU] = d*lum;
318	else
319	scalecolor(cmon, d);
320	d = (1.f-d)*slum;
321	cmon[RED] += d;
322	cmon[GRN] += d;
323	cmon[BLU] += d;
324	}
325	} else if (tms->flags & TM_F_BW) {
326	cmon[RED] = cmon[GRN] = cmon[BLU] = lum;
327	}
328	d = tms->clf[RED]*cmon[RED]/lum;
329	cs[3i ] = d>=.999f ? 255 : gamtab[(int)(1024.fd)];
330	d = tms->clf[GRN]*cmon[GRN]/lum;
331	cs[3i+1] = d>=.999f ? 255 : gamtab[(int)(1024.fd)];
332	d = tms->clf[BLU]*cmon[BLU]/lum;
333	cs[3i+2] = d>=.999f ? 255 : gamtab[(int)(1024.fd)];
334	}
335	returnOK;
336	}
337
338
339	int
340	tmAddHisto( /* add values to histogram */
341	TMstruct *tms,
342	TMbright *ls,
343	int len,
344	int wt
345	)
346	{
347	static const char funcName[] = "tmAddHisto";
348	int oldorig=0, oldlen, horig, hlen;
349	int i, j;
350
351	if (tms == NULL)
352	returnErr(TM_E_TMINVAL);
353	if (len < 0)
354	returnErr(TM_E_ILLEGAL);
355	if (len == 0)
356	returnOK;
357	/* first, grow limits */
358	if (tms->histo == NULL) {
359	for (i = len; i-- && ls[i] < MINBRT; )
360	;
361	if (i < 0)
362	returnOK;
363	tms->hbrmin = tms->hbrmax = ls[i];
364	oldlen = 0;
365	} else {
366	oldorig = (tms->hbrmin-MINBRT)/HISTEP;
367	oldlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - oldorig;
368	}
369	for (i = len; i--; ) {
370	if ((j = ls[i]) < MINBRT)
371	continue;
372	if (j < tms->hbrmin)
373	tms->hbrmin = j;
374	else if (j > tms->hbrmax)
375	tms->hbrmax = j;
376	}
377	horig = (tms->hbrmin-MINBRT)/HISTEP;
378	hlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - horig;
379	if (hlen > oldlen) { /* (re)allocate histogram */
380	int newhist = (int )calloc(hlen, sizeof(int));
381	if (newhist == NULL)
382	returnErr(TM_E_NOMEM);
383	if (oldlen) { /* copy and free old */
384	for (i = oldlen, j = i+oldorig-horig; i; )
385	newhist[--j] = tms->histo[--i];
386	free((MEM_PTR)tms->histo);
387	}
388	tms->histo = newhist;
389	}
390	if (wt == 0)
391	returnOK;
392	for (i = len; i--; ) /* add in new counts */
393	if (ls[i] >= MINBRT)
394	tms->histo[ (ls[i]-MINBRT)/HISTEP - horig ] += wt;
395	returnOK;
396	}
397
398
399	static double
400	htcontrs( /* human threshold contrast sensitivity, dL(La) */
401	double La
402	)
403	{
404	double l10La, l10dL;
405	/* formula taken from Ferwerda et al. [SG96] */
406	if (La < 1.148e-4)
407	return(1.38e-3);
408	l10La = log10(La);
409	if (l10La < -1.44) /* rod response regime */
410	l10dL = pow(.405*l10La + 1.6, 2.18) - 2.86;
411	else if (l10La < -.0184)
412	l10dL = l10La - .395;
413	else if (l10La < 1.9) /* cone response regime */
414	l10dL = pow(.249*l10La + .65, 2.7) - .72;
415	else
416	l10dL = l10La - 1.255;
417
418	return(exp10(l10dL));
419	}
420
421
422	static int
423	tmNewMap( /* allocate new tone-mapping array */
424	TMstruct *tms
425	)
426	{
427	if (tms->lumap != NULL && (tms->mbrmax - tms->mbrmin) !=
428	(tms->hbrmax - tms->hbrmin)) {
429	free((MEM_PTR)tms->lumap);
430	tms->lumap = NULL;
431	}
432	tms->mbrmin = tms->hbrmin;
433	tms->mbrmax = tms->hbrmax;
434	if (tms->mbrmin > tms->mbrmax)
435	return 0;
436	if (tms->lumap == NULL)
437	tms->lumap = (unsigned short )malloc(sizeof(unsigned short)
438	(tms->mbrmax-tms->mbrmin+1));
439	return(tms->lumap != NULL);
440	}
441
442
443	int
444	tmFixedMapping( /* compute fixed, linear tone-mapping */
445	TMstruct *tms,
446	double expmult,
447	double gamval
448	)
449	{
450	static const char funcName[] = "tmFixedMapping";
451	double d;
452	int i;
453
454	if (!tmNewMap(tms))
455	returnErr(TM_E_NOMEM);
456	if (expmult <= .0)
457	expmult = 1.;
458	if (gamval < MINGAM)
459	gamval = tms->mongam;
460	d = log(expmult/tms->inpsf);
461	for (i = tms->mbrmax-tms->mbrmin+1; i--; ) {
462	double val = 256. * exp(
463	( d + (tms->mbrmin+i)*(1./TM_BRTSCALE) )
464	/ gamval);
465	tms->lumap[i] = val >= (double)0xffff ? 0xffff : (int)val;
466	}
467	returnOK;
468	}
469
470
471	int
472	tmComputeMapping( /* compute histogram tone-mapping */
473	TMstruct *tms,
474	double gamval,
475	double Lddyn,
476	double Ldmax
477	)
478	{
479	static const char funcName[] = "tmComputeMapping";
480	int *histo;
481	float *cumf;
482	int brt0, histlen, threshold, ceiling, trimmings;
483	double logLddyn, Ldmin, Ldavg, Lwavg, Tr, Lw, Ld;
484	int32 histot;
485	double sum;
486	double d;
487	int i, j;
488
489	if (tms == NULL \|\| tms->histo == NULL)
490	returnErr(TM_E_TMINVAL);
491	/* check arguments */
492	if (Lddyn < MINLDDYN) Lddyn = DEFLDDYN;
493	if (Ldmax < MINLDMAX) Ldmax = DEFLDMAX;
494	if (gamval < MINGAM) gamval = tms->mongam;
495	/* compute handy values */
496	Ldmin = Ldmax/Lddyn;
497	logLddyn = log(Lddyn);
498	Ldavg = sqrt(Ldmax*Ldmin);
499	i = (tms->hbrmin-MINBRT)/HISTEP;
500	brt0 = MINBRT + HISTEP/2 + i*HISTEP;
501	histlen = (tms->hbrmax-MINBRT)/HISTEP + 1 - i;
502	/* histogram total and mean */
503	histot = 0; sum = 0;
504	j = brt0 + histlen*HISTEP;
505	for (i = histlen; i--; ) {
506	histot += tms->histo[i];
507	sum += (j -= HISTEP) * tms->histo[i];
508	}
509	threshold = histot*0.005 + .5;
510	if (threshold < 4)
511	returnErr(TM_E_TMFAIL);
512	Lwavg = tmLuminance( (double)sum / histot );
513	/* allocate space for mapping */
514	if (!tmNewMap(tms))
515	returnErr(TM_E_NOMEM);
516	/* use linear tone mapping? */
517	if (tms->flags & TM_F_LINEAR)
518	goto linearmap;
519	/* clamp histogram */
520	histo = (int )malloc(histlensizeof(int));
521	cumf = (float )malloc((histlen+2)sizeof(float));
522	if ((histo == NULL) \| (cumf == NULL))
523	returnErr(TM_E_NOMEM);
524	cumf[histlen+1] = 1.; /* guard for assignment code */
525	for (i = histlen; i--; ) /* make malleable copy */
526	histo[i] = tms->histo[i];
527	do { /* iterate to solution */
528	sum = 0; /* cumulative probability */
529	for (i = 0; i < histlen; i++) {
530	cumf[i] = (double)sum/histot;
531	sum += histo[i];
532	}
533	cumf[histlen] = 1.;
534	Tr = histot * (double)(tms->hbrmax - tms->hbrmin) /
535	((double)histlen*TM_BRTSCALE) / logLddyn;
536	ceiling = Tr + 1.;
537	trimmings = 0; /* clip to envelope */
538	for (i = histlen; i--; ) {
539	if (tms->flags & TM_F_HCONTR) {
540	Lw = tmLuminance(brt0 + i*HISTEP);
541	Ld = Ldmin * exp( logLddyn *
542	.5*(cumf[i]+cumf[i+1]) );
543	ceiling = Tr * (htcontrs(Ld) * Lw) /
544	(htcontrs(Lw) * Ld) + 1.;
545	}
546	if (histo[i] > ceiling) {
547	trimmings += histo[i] - ceiling;
548	histo[i] = ceiling;
549	}
550	}
551	/* check if we're out of data */
552	if ((histot -= trimmings) <= threshold) {
553	free((MEM_PTR)histo);
554	free((MEM_PTR)cumf);
555	goto linearmap;
556	}
557	} while (trimmings > threshold);
558	/* assign tone-mapping */
559	for (i = tms->mbrmax-tms->mbrmin+1; i--; ) {
560	j = d = (double)i/(tms->mbrmax-tms->mbrmin)*histlen;
561	d -= (double)j;
562	Ld = Ldminexp(logLddyn((1.-d)cumf[j]+dcumf[j+1]));
563	d = (Ld - Ldmin)/(Ldmax - Ldmin);
564	tms->lumap[i] = 256.*pow(d, 1./gamval);
565	}
566	free((MEM_PTR)histo); /* clean up and return */
567	free((MEM_PTR)cumf);
568	returnOK;
569	linearmap: /* linear tone-mapping */
570	if (tms->flags & TM_F_HCONTR)
571	d = htcontrs(Ldavg) / htcontrs(Lwavg);
572	else
573	d = Ldavg / Lwavg;
574	return(tmFixedMapping(tms, tms->inpsf*d/Ldmax, gamval));
575	}
576
577
578	int
579	tmMapPixels( /* apply tone-mapping to pixel(s) */
580	TMstruct *tms,
581	BYTE *ps,
582	TMbright *ls,
583	BYTE *cs,
584	int len
585	)
586	{
587	static const char funcName[] = "tmMapPixels";
588	int32 li, pv;
589
590	if (tms == NULL \|\| tms->lumap == NULL)
591	returnErr(TM_E_TMINVAL);
592	if ((ps == NULL) \| (ls == NULL) \| (len < 0))
593	returnErr(TM_E_ILLEGAL);
594	while (len--) {
595	if ((li = *ls++) < tms->mbrmin) {
596	li = 0;
597	} else {
598	if (li > tms->mbrmax)
599	li = tms->mbrmax;
600	li = tms->lumap[li - tms->mbrmin];
601	}
602	if (cs == TM_NOCHROM)
603	*ps++ = li>255 ? 255 : li;
604	else {
605	pv = cs++ li / tms->cdiv[RED];
606	*ps++ = pv>255 ? 255 : pv;
607	pv = cs++ li / tms->cdiv[GRN];
608	*ps++ = pv>255 ? 255 : pv;
609	pv = cs++ li / tms->cdiv[BLU];
610	*ps++ = pv>255 ? 255 : pv;
611	}
612	}
613	returnOK;
614	}
615
616
617
618
619	TMstruct *
620	tmDup( /* duplicate top tone mapping */
621	TMstruct *tms
622	)
623	{
624	int len;
625	int i;
626	TMstruct *tmnew;
627
628	if (tms == NULL) /* anything to duplicate? */
629	return(NULL);
630	tmnew = (TMstruct *)malloc(sizeof(TMstruct));
631	if (tmnew == NULL)
632	return(NULL);
633	tmnew = tms; /* copy everything */
634	if (tmnew->histo != NULL) { /* duplicate histogram */
635	len = (tmnew->hbrmax-MINBRT)/HISTEP + 1 -
636	(tmnew->hbrmin-MINBRT)/HISTEP;
637	tmnew->histo = (int )malloc(lensizeof(int));
638	if (tmnew->histo != NULL)
639	for (i = len; i--; )
640	tmnew->histo[i] = tms->histo[i];
641	}
642	if (tmnew->lumap != NULL) { /* duplicate luminance mapping */
643	len = tmnew->mbrmax-tmnew->mbrmin+1;
644	tmnew->lumap = (unsigned short *)malloc(
645	len*sizeof(unsigned short) );
646	if (tmnew->lumap != NULL)
647	for (i = len; i--; )
648	tmnew->lumap[i] = tms->lumap[i];
649	}
650	/* clear package data */
651	for (i = tmNumPkgs; i--; )
652	tmnew->pd[i] = NULL;
653	/* return copy */
654	return(tmnew);
655	}
656
657
658	void
659	tmDone(tms) /* done with tone mapping -- destroy it */
660	TMstruct *tms;
661	{
662	int i;
663	/* NULL arg. is equiv. to tms */
664	if (tms == NULL)
665	return;
666	/* free tables */
667	if (tms->histo != NULL)
668	free((MEM_PTR)tms->histo);
669	if (tms->lumap != NULL)
670	free((MEM_PTR)tms->lumap);
671	/* free private data */
672	for (i = tmNumPkgs; i--; )
673	if (tms->pd[i] != NULL)
674	(*tmPkg[i]->Free)(tms->pd[i]);
675	free((MEM_PTR)tms); /* free basic structure */
676	}
677
678	/****************** Shared but Private library routines *******************/
679
680	BYTE tmMesofact[BMESUPPER-BMESLOWER];
681
682	void
683	tmMkMesofact() /* build mesopic lookup factor table */
684	{
685	int i;
686
687	if (tmMesofact[BMESUPPER-BMESLOWER-1])
688	return;
689
690	for (i = BMESLOWER; i < BMESUPPER; i++)
691	tmMesofact[i-BMESLOWER] = 256. *
692	(tmLuminance(i) - LMESLOWER) /
693	(LMESUPPER - LMESLOWER);
694	}
695
696
697	int
698	tmErrorReturn( /* error return (with message) */
699	const char *func,
700	TMstruct *tms,
701	int err
702	)
703	{
704	if (tms != NULL) {
705	tms->lastFunc = func;
706	tms->lastError = err;
707	if (tms->flags & TM_F_NOSTDERR)
708	return(err);
709	}
710	fputs(func, stderr);
711	fputs(": ", stderr);
712	fputs(tmErrorMessage[err], stderr);
713	fputs("!\n", stderr);
714	return(err);
715	}