void
getpictcolrs( /* get scanline from picture */
int yoff,
COLR *scan,
PNODE *p,
int xsiz,
int ysiz
)
{
int mx;
int my;
if (p->kid == NULL) { /* do this node */
setcolr(scan[0], colval(p->v,RED),
colval(p->v,GRN),
colval(p->v,BLU));
for (mx = 1; mx < xsiz; mx++)
copycolr(scan[mx], scan[0]);
return;
}
/* do kids */
mx = xsiz >> 1;
my = ysiz >> 1;
if (yoff < my) {
getpictcolrs(yoff, scan, p->kid+DL, mx, my);
getpictcolrs(yoff, scan+mx, p->kid+DR, xsiz-mx, my);
} else {
getpictcolrs(yoff-my, scan, p->kid+UL, mx, ysiz-my);
getpictcolrs(yoff-my, scan+mx, p->kid+UR, xsiz-mx, ysiz-my);
}
}
static void
initambfile( /* initialize ambient file */
int cre8
)
{
extern char *progname, *octname;
static char *mybuf = NULL;
#ifdef F_SETLKW
aflock(cre8 ? F_WRLCK : F_RDLCK);
#endif
SET_FILE_BINARY(ambfp);
if (mybuf == NULL)
mybuf = (char *)bmalloc(BUFSIZ+8);
setbuf(ambfp, mybuf);
if (cre8) { /* new file */
newheader("RADIANCE", ambfp);
fprintf(ambfp, "%s -av %g %g %g -aw %d -ab %d -aa %g ",
progname, colval(ambval,RED),
colval(ambval,GRN), colval(ambval,BLU),
ambvwt, ambounce, ambacc);
fprintf(ambfp, "-ad %d -as %d -ar %d ",
ambdiv, ambssamp, ambres);
if (octname != NULL)
fputs(octname, ambfp);
fputc('\n', ambfp);
fprintf(ambfp, "SOFTWARE= %s\n", VersionID);
fputnow(ambfp);
fputformat(AMBFMT, ambfp);
fputc('\n', ambfp);
putambmagic(ambfp);
} else if (checkheader(ambfp, AMBFMT, NULL) < 0 || !hasambmagic(ambfp))
error(USER, "bad ambient file");
}
static void
combine(void) /* combine pictures */
{
EPNODE *coldef[3], *brtdef;
COLOR *scanout;
double d;
register int i, j;
/* check defined variables */
for (j = 0; j < 3; j++) {
if (vardefined(vcolout[j]))
coldef[j] = eparse(vcolout[j]);
else
coldef[j] = NULL;
}
if (vardefined(vbrtout))
brtdef = eparse(vbrtout);
else
brtdef = NULL;
/* allocate scanline */
scanout = (COLOR *)emalloc(xres*sizeof(COLOR));
/* set input position */
yscan = ymax+MIDSCN;
/* combine files */
for (ypos = yres-1; ypos >= 0; ypos--) {
advance();
varset(vypos, '=', (double)ypos);
for (xpos = 0; xpos < xres; xpos++) {
xscan = (xpos+.5)*xmax/xres;
varset(vxpos, '=', (double)xpos);
eclock++;
if (brtdef != NULL) {
d = evalue(brtdef);
if (d < 0.0)
d = 0.0;
setcolor(scanout[xpos], d, d, d);
} else {
for (j = 0; j < 3; j++) {
if (coldef[j] != NULL) {
d = evalue(coldef[j]);
} else {
d = 0.0;
for (i = 0; i < nfiles; i++)
d += colval(input[i].scan[MIDSCN][xscan],j);
}
if (d < 0.0)
d = 0.0;
colval(scanout[xpos],j) = d;
}
}
}
if (fwritescan(scanout, xres, stdout) < 0) {
perror("write error");
quit(1);
}
}
efree((char *)scanout);
}
/* Return brightness of farthest ambient sample */
static double
back_ambval(AMBHEMI *hp, const int n1, const int n2, const int n3)
{
if (hp->sa[n1].d <= hp->sa[n2].d) {
if (hp->sa[n1].d <= hp->sa[n3].d)
return(colval(hp->sa[n1].v,CIEY));
return(colval(hp->sa[n3].v,CIEY));
}
if (hp->sa[n2].d <= hp->sa[n3].d)
return(colval(hp->sa[n2].v,CIEY));
return(colval(hp->sa[n3].v,CIEY));
}
extern double
cielum( /* compute (scotopic) luminance of CIE color */
COLOR xyz,
int scotopic
)
{
if (scotopic) /* approximate */
return(colval(xyz,CIEY) *
(1.33*(1. + (colval(xyz,CIEY)+colval(xyz,CIEZ))/
colval(xyz,CIEX)) - 1.68));
return(colval(xyz,CIEY));
}
static int
aclrscan2( /* get an ASCII color scanline */
register COLOR *scan,
register int len,
FILE *fp
)
{
while (len-- > 0) {
colval(scan[0],RED) = fltv(scanint(fp));
colval(scan[0],GRN) = fltv(scanint(fp));
colval(scan[0],BLU) = fltv(scanint(fp));
scan++;
}
return(0);
}
static double
l_expos( /* return picture exposure */
char *nam
)
{
int fn, n;
double d;
d = argument(1);
if (d <= -0.5 || d >= nfiles+0.5) {
errno = EDOM;
return(0.0);
}
if (d < 0.5)
return((double)nfiles);
fn = d - 0.5;
if (nam == vbrtexp)
return((*ourbright)(input[fn].expos));
n = 3;
while (n--)
if (nam == vcolexp[n])
return(colval(input[fn].expos,n));
eputs("Bad call to l_expos()!\n");
quit(1);
return 1; /* pro forma return */
}
static void
putmapping(void) /* put out color mapping */
{
static char cchar[3] = {'r', 'g', 'b'};
register int i, j;
/* print brightness mapping */
for (j = 0; j < 3; j++) {
printf("%cxa(i) : select(i", cchar[j]);
for (i = 0; i < NMBNEU; i++)
printf(",%g", colval(bramp[i][0],j));
printf(");\n");
printf("%cya(i) : select(i", cchar[j]);
for (i = 0; i < NMBNEU; i++)
printf(",%g", colval(bramp[i][1],j));
printf(");\n");
printf("%cfi(n) = if(n-%g, %d, if(%cxa(n+1)-%c, n, %cfi(n+1)));\n",
cchar[j], NMBNEU-1.5, NMBNEU-1, cchar[j],
cchar[j], cchar[j]);
printf("%cndx = %cfi(1);\n", cchar[j], cchar[j]);
printf("%c%c = ((%cxa(%cndx+1)-%c)*%cya(%cndx) + ",
cchar[j], scanning?'n':'o', cchar[j],
cchar[j], cchar[j], cchar[j], cchar[j]);
printf("(%c-%cxa(%cndx))*%cya(%cndx+1)) /\n",
cchar[j], cchar[j], cchar[j],
cchar[j], cchar[j]);
printf("\t\t(%cxa(%cndx+1) - %cxa(%cndx)) ;\n",
cchar[j], cchar[j], cchar[j], cchar[j]);
}
/* print color mapping */
if (scanning) {
printf("r = ri(1); g = gi(1); b = bi(1);\n");
printf("ro = %g*rn + %g*gn + %g*bn ;\n",
solmat[0][0], solmat[0][1], solmat[0][2]);
printf("go = %g*rn + %g*gn + %g*bn ;\n",
solmat[1][0], solmat[1][1], solmat[1][2]);
printf("bo = %g*rn + %g*gn + %g*bn ;\n",
solmat[2][0], solmat[2][1], solmat[2][2]);
} else {
printf("r1 = ri(1); g1 = gi(1); b1 = bi(1);\n");
printf("r = %g*r1 + %g*g1 + %g*b1 ;\n",
solmat[0][0], solmat[0][1], solmat[0][2]);
printf("g = %g*r1 + %g*g1 + %g*b1 ;\n",
solmat[1][0], solmat[1][1], solmat[1][2]);
printf("b = %g*r1 + %g*g1 + %g*b1 ;\n",
solmat[2][0], solmat[2][1], solmat[2][2]);
}
}
static double
l_colin( /* return color value for picture */
register char *nam
)
{
int fn;
register int n, xoff, yoff;
double d;
d = argument(1);
if (d <= -0.5 || d >= nfiles+0.5) {
errno = EDOM;
return(0.0);
}
if (d < 0.5)
return((double)nfiles);
fn = d - 0.5;
xoff = yoff = 0;
n = nargum();
if (n >= 2) {
d = argument(2);
if (d < 0.0) {
xoff = d-.5;
if (xscan+xoff < 0)
xoff = -xscan;
} else {
xoff = d+.5;
if (xscan+xoff >= xmax)
xoff = xmax-1-xscan;
}
}
if (n >= 3) {
d = argument(3);
if (d < 0.0) {
yoff = d-.5;
if (yoff+MIDSCN < 0)
yoff = -MIDSCN;
if (yscan+yoff < 0)
yoff = -yscan;
} else {
yoff = d+.5;
if (yoff+MIDSCN >= WINSIZ)
yoff = WINSIZ-1-MIDSCN;
if (yscan+yoff >= ymax)
yoff = ymax-1-yscan;
}
}
if (nam == vbrtin)
return((*ourbright)(input[fn].scan[MIDSCN+yoff][xscan+xoff]));
n = 3;
while (n--)
if (nam == vcolin[n])
return(colval(input[fn].scan[MIDSCN+yoff][xscan+xoff],n));
eputs("Bad call to l_colin()!\n");
quit(1);
return 1; /* pro forma return */
}
static void
valtopix(void) /* convert values to a pixel file */
{
int dogamma;
register COLOR *scanln;
int y;
register int x;
scanln = (COLOR *)malloc(scanlen(&picres)*sizeof(COLOR));
if (scanln == NULL) {
fprintf(stderr, "%s: out of memory\n", progname);
quit(1);
}
dogamma = gamcor < .95 || gamcor > 1.05;
set_io();
for (y = 0; y < numscans(&picres); y++) {
for (x = 0; x < scanlen(&picres); x++) {
if (!dataonly) {
fscanf(fin, "%*d %*d");
if (fin2 != NULL) {
fscanf(fin2, "%*d %*d");
fscanf(fin3, "%*d %*d");
}
}
if ((*getval)(scanln[x]) < 0) {
fprintf(stderr, "%s: read error\n", progname);
quit(1);
}
if (dogamma)
setcolor(scanln[x],
pow(colval(scanln[x],RED), gamcor),
pow(colval(scanln[x],GRN), gamcor),
pow(colval(scanln[x],BLU), gamcor));
if (doexposure)
multcolor(scanln[x], exposure);
}
if (fwritescan(scanln, scanlen(&picres), stdout) < 0) {
fprintf(stderr, "%s: write error\n", progname);
quit(1);
}
}
free((void *)scanln);
}
void
lightinit() /* initialize lighting */
{
GLfloat ambv[4];
if (!dolights)
return;
glPushAttrib(GL_LIGHTING_BIT);
if (expval <= FTINY && bright(ambval) > FTINY)
expval = 0.2/bright(ambval);
ambv[0] = expval*colval(ambval,RED);
ambv[1] = expval*colval(ambval,GRN);
ambv[2] = expval*colval(ambval,BLU);
ambv[3] = 1.;
glLightModelfv(GL_LIGHT_MODEL_AMBIENT, ambv);
glCallList(lightlist = newglist());
rgl_checkerr("in lightinit");
nlights = 0;
}
static int
bgryscan2( /* get a binary greyscale scanline */
register COLOR *scan,
int len,
register FILE *fp
)
{
register int c;
while (len-- > 0) {
if ((c = getby2(fp)) == EOF)
return(-1);
colval(scan[0],RED) =
colval(scan[0],GRN) =
colval(scan[0],BLU) = fltv(c);
scan++;
}
return(0);
}
static int
setbrdfunc( /* set up brdf function and variables */
BRDFDAT *np
)
{
FVECT vec;
if (setfunc(np->mp, np->pr) == 0)
return(0); /* it's OK, setfunc says we're done */
/* else (re)assign special variables */
multv3(vec, np->pnorm, funcxf.xfm);
varset("NxP", '=', vec[0]/funcxf.sca);
varset("NyP", '=', vec[1]/funcxf.sca);
varset("NzP", '=', vec[2]/funcxf.sca);
varset("RdotP", '=', np->pdot <= -1.0 ? -1.0 :
np->pdot >= 1.0 ? 1.0 : np->pdot);
varset("CrP", '=', colval(np->mcolor,RED));
varset("CgP", '=', colval(np->mcolor,GRN));
varset("CbP", '=', colval(np->mcolor,BLU));
return(1);
}
static int
checkhead( /* deal with line from header */
char *line,
void *p
)
{
char fmt[32];
double d;
COLOR ctmp;
if (formatval(fmt, line)) {
if (!strcmp(fmt, CIEFMT))
mybright = &xyz_bright;
else if (!strcmp(fmt, COLRFMT))
mybright = &rgb_bright;
else
wrongformat++;
} else if (original && isexpos(line)) {
d = 1.0/exposval(line);
scalecolor(exposure, d);
doexposure++;
} else if (original && iscolcor(line)) {
colcorval(ctmp, line);
setcolor(exposure, colval(exposure,RED)/colval(ctmp,RED),
colval(exposure,GRN)/colval(ctmp,GRN),
colval(exposure,BLU)/colval(ctmp,BLU));
doexposure++;
} else if (header)
fputs(line, stdout);
return(0);
}
static void
ppm2ra2( /* convert 2-byte Pixmap to Radiance picture */
colorscanf_t *getscan
)
{
COLOR *scanout;
double mult;
int y;
register int x;
/* allocate scanline */
scanout = (COLOR *)malloc(xmax*sizeof(COLOR));
if (scanout == NULL)
quiterr("out of memory in ppm2ra2");
if (bradj)
mult = pow(2., (double)bradj);
/* convert image */
for (y = ymax-1; y >= 0; y--) {
if ((*getscan)(scanout, xmax, stdin) < 0)
quiterr("error reading Pixmap");
for (x = (gamcor>1.01)|(gamcor<0.99)?xmax:0; x--; ) {
colval(scanout[x],RED) =
pow(colval(scanout[x],RED), gamcor);
colval(scanout[x],GRN) =
pow(colval(scanout[x],GRN), gamcor);
colval(scanout[x],BLU) =
pow(colval(scanout[x],BLU), gamcor);
}
for (x = bradj?xmax:0; x--; )
scalecolor(scanout[x], mult);
if (fwritescan(scanout, xmax, stdout) < 0)
quiterr("error writing Radiance picture");
}
/* free scanline */
free((void *)scanout);
}
void printdefaults()
/* print default values to stdout */
{
#ifdef EVALDRC_HACK
/* EvalDRC support */
puts("-A\t\t\t\t# angular source file");
#endif
puts("-ae mod\t\t\t\t# exclude modifier");
puts("-aE file\t\t\t\t# exclude modifiers from file");
puts("-ai mod\t\t\t\t# include modifier");
puts("-aI file\t\t\t\t# include modifiers from file");
#ifdef PMAP_EKSPERTZ
puts("-api xmin ymin zmin xmax ymax zmax\t# region of interest");
#endif
puts("-apg file nPhotons\t\t\t# global photon map");
puts("-apc file nPhotons\t\t\t# caustic photon map");
puts("-apd file nPhotons\t\t\t# direct photon map");
puts("-app file nPhotons bwidth\t\t# precomputed global photon map");
puts("-apv file nPhotons\t\t\t# volume photon map");
puts("-apC file nPhotons\t\t\t# contribution photon map");
printf("-apD %f\t\t\t\t# predistribution factor\n", preDistrib);
printf("-apM %d\t\t\t\t\t# max predistrib passes\n", maxPreDistrib);
#if 1
/* Kept for backwards compat, will be gradually phased out by -lD, -lr */
printf("-apm %ld\t\t\t\t# limit photon bounces\n", photonMaxBounce);
#endif
puts("-apo mod\t\t\t\t# photon port modifier");
puts("-apO file\t\t\t\t# photon ports from file");
printf("-apP %f\t\t\t\t# precomputation factor\n", finalGather);
printf("-apr %d\t\t\t\t\t# random seed\n", randSeed);
puts("-aps mod\t\t\t\t# antimatter sensor modifier");
puts("-apS file\t\t\t\t# antimatter sensors from file");
printf(backvis ? "-bv+\t\t\t\t\t# back face visibility on\n"
: "-bv-\t\t\t\t\t# back face visibility off\n");
printf("-dp %.1f\t\t\t\t# PDF samples / sr\n", pdfSamples);
printf("-ds %f\t\t\t\t# source partition size ratio\n", srcsizerat);
printf("-e %s\t\t\t\t# diagnostics output file\n", diagFile);
printf(clobber ? "-fo+\t\t\t\t\t# force overwrite\n"
: "-fo-\t\t\t\t\t# do not overwrite\n");
#ifdef PMAP_EKSPERTZ
/* NU STUFF for Ze Exspertz! */
printf("-ld %.1f\t\t\t\t\t# limit photon distance\n", photonMaxDist);
printf("-lr %ld\t\t\t\t# limit photon bounces\n", photonMaxBounce);
#endif
printf("-ma %.2f %.2f %.2f\t\t\t# scattering albedo\n",
colval(salbedo,RED), colval(salbedo,GRN), colval(salbedo,BLU));
printf("-me %.2e %.2e %.2e\t\t# extinction coefficient\n",
colval(cextinction,RED), colval(cextinction,GRN),
colval(cextinction,BLU));
printf("-mg %.2f\t\t\t\t# scattering eccentricity\n", seccg);
#if NIX
/* Multiprocessing on NIX only */
printf("-n %d\t\t\t\t\t# number of parallel processes\n", nproc);
#endif
printf("-t %-9d\t\t\t\t# time between reports\n", photonRepTime);
printf(verbose ? "-v+\t\t\t\t\t# verbose console output\n"
: "-v-\t\t\t\t\t# terse console output\n");
}
static int
rmx_load_rgbe(RMATRIX *rm, FILE *fp)
{
COLOR *scan = (COLOR *)malloc(sizeof(COLOR)*rm->ncols);
int i, j;
if (scan == NULL)
return(0);
for (i = 0; i < rm->nrows; i++) {
if (freadscan(scan, rm->ncols, fp) < 0) {
free(scan);
return(0);
}
for (j = rm->ncols; j--; ) {
rmx_lval(rm,i,j,0) = colval(scan[j],RED);
rmx_lval(rm,i,j,1) = colval(scan[j],GRN);
rmx_lval(rm,i,j,2) = colval(scan[j],BLU);
}
}
free(scan);
return(1);
}
extern void
raycontrib( /* compute (cumulative) ray contribution */
RREAL rc[3],
const RAY *r,
int flags
)
{
double eext[3];
int i;
eext[0] = eext[1] = eext[2] = 0.;
rc[0] = rc[1] = rc[2] = 1.;
while (r != NULL && r->crtype&flags) {
for (i = 3; i--; ) {
rc[i] *= colval(r->rcoef,i);
eext[i] += r->rot * colval(r->cext,i);
}
r = r->parent;
}
for (i = 3; i--; )
rc[i] *= (eext[i] <= FTINY) ? 1. :
(eext[i] > 92.) ? 0. : exp(-eext[i]);
}
static void
mbscan( /* apply macbethcal adj. to scaline */
COLOR *sl,
int len,
register struct mbc *mb
)
{
double d;
register int i, j;
while (len--) {
colortrans(sl[0], mb->cmat, sl[0]);
clipgamut(sl[0], greypoint(sl[0]), CGAMUT, mb->cmin, mb->cmax);
for (i = 0; i < 3; i++) {
d = colval(sl[0],i);
for (j = 0; j < 4 && mb->xa[i][j+1] <= d; j++)
;
colval(sl[0],i) = ( (mb->xa[i][j+1] - d)*mb->ya[i][j] +
(d - mb->xa[i][j])*mb->ya[i][j+1] ) /
(mb->xa[i][j+1] - mb->xa[i][j]);
}
sl++;
}
}
int bigdiff(COLOR c1, COLOR c2, double md) { /* c1 delta c2 > md? */
int i;
for (i = 0; i < 3; i++)
if (colval(c1,i)-colval(c2,i) > md*colval(c2,i) ||
colval(c2,i)-colval(c1,i) > md*colval(c1,i)) {
return(1);
}
return(0);
}
extern double
rgblum( /* compute (scotopic) luminance of RGB color */
COLOR clr,
int scotopic
)
{
if (scotopic) /* approximate */
return( WHTSEFFICACY * (colval(clr,RED)*.062 +
colval(clr,GRN)*.608 + colval(clr,BLU)*.330) );
return( WHTEFFICACY * (colval(clr,RED)*inrgb2xyz[1][0] +
colval(clr,GRN)*inrgb2xyz[1][1] +
colval(clr,BLU)*inrgb2xyz[1][2]) );
}
/* Compute direction gradient from a hemispherical sampling */
static void
ambdirgrad(AMBHEMI *hp, FVECT uv[2], float dg[2])
{
AMBSAMP *ap;
double dgsum[2];
int n;
FVECT vd;
double gfact;
dgsum[0] = dgsum[1] = 0.0; /* sum values times -tan(theta) */
for (ap = hp->sa, n = hp->ns*hp->ns; n--; ap++) {
/* use vector for azimuth + 90deg */
VSUB(vd, ap->p, hp->rp->rop);
/* brightness over cosine factor */
gfact = colval(ap->v,CIEY) / DOT(hp->rp->ron, vd);
/* sine = proj_radius/vd_length */
dgsum[0] -= DOT(uv[1], vd) * gfact;
dgsum[1] += DOT(uv[0], vd) * gfact;
}
dg[0] = dgsum[0] / (hp->ns*hp->ns);
dg[1] = dgsum[1] / (hp->ns*hp->ns);
}
void
traceray( /* trace a single ray */
char *s
)
{
RAY thisray;
char buf[512];
thisray.rmax = 0.0;
if (!sscanvec(s, thisray.rorg) ||
!sscanvec(sskip2(s,3), thisray.rdir)) {
int x, y;
if (dev->getcur == NULL)
return;
(*dev->comout)("Pick ray\n");
if ((*dev->getcur)(&x, &y) == ABORT)
return;
if ((thisray.rmax = viewray(thisray.rorg, thisray.rdir,
&ourview, (x+.5)/hresolu, (y+.5)/vresolu)) < -FTINY) {
error(COMMAND, "not on image");
return;
}
} else if (normalize(thisray.rdir) == 0.0) {
error(COMMAND, "zero ray direction");
return;
}
ray_trace(&thisray);
if (thisray.ro == NULL)
(*dev->comout)("ray hit nothing");
else {
OBJREC *mat = NULL;
OBJREC *mod = NULL;
char matspec[256];
OBJREC *ino;
matspec[0] = '\0';
if (thisray.ro->omod != OVOID) {
mod = objptr(thisray.ro->omod);
mat = findmaterial(mod);
}
if (thisray.rod < 0.0)
strcpy(matspec, "back of ");
if (mod != NULL) {
strcat(matspec, mod->oname);
if (mat != mod && mat != NULL)
sprintf(matspec+strlen(matspec),
" (%s)", mat->oname);
} else
strcat(matspec, VOIDID);
sprintf(buf, "ray hit %s %s \"%s\"", matspec,
ofun[thisray.ro->otype].funame,
thisray.ro->oname);
if ((ino = objptr(thisray.robj)) != thisray.ro)
sprintf(buf+strlen(buf), " in %s \"%s\"",
ofun[ino->otype].funame, ino->oname);
(*dev->comout)(buf);
(*dev->comin)(buf, NULL);
if (thisray.rot >= FHUGE)
(*dev->comout)("at infinity");
else {
sprintf(buf, "at (%.6g %.6g %.6g) (%.6g)",
thisray.rop[0], thisray.rop[1],
thisray.rop[2], raydistance(&thisray));
(*dev->comout)(buf);
}
(*dev->comin)(buf, NULL);
sprintf(buf, "value (%.5g %.5g %.5g) (%.3gL)",
colval(thisray.rcol,RED),
colval(thisray.rcol,GRN),
colval(thisray.rcol,BLU),
luminance(thisray.rcol));
(*dev->comout)(buf);
}
(*dev->comin)(buf, NULL);
}
static void
getmbcalfile( /* load macbethcal file */
char *fn,
register struct mbc *mb
)
{
char buf[128];
FILE *fp;
int inpflags = 0;
register int i;
if ((fp = fopen(fn, "r")) == NULL)
syserror(fn);
while (fgets(buf, sizeof(buf), fp) != NULL) {
if (!(inpflags & 01) &&
sscanf(buf,
"rxa(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->xa[0][0], &mb->xa[0][1],
&mb->xa[0][2], &mb->xa[0][3],
&mb->xa[0][4], &mb->xa[0][5]
) == 6)
inpflags |= 01;
else if (!(inpflags & 02) &&
sscanf(buf,
"rya(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->ya[0][0], &mb->ya[0][1],
&mb->ya[0][2], &mb->ya[0][3],
&mb->ya[0][4], &mb->ya[0][5]
) == 6)
inpflags |= 02;
else if (!(inpflags & 04) &&
sscanf(buf,
"gxa(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->xa[1][0], &mb->xa[1][1],
&mb->xa[1][2], &mb->xa[1][3],
&mb->xa[1][4], &mb->xa[1][5]
) == 6)
inpflags |= 04;
else if (!(inpflags & 010) &&
sscanf(buf,
"gya(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->ya[1][0], &mb->ya[1][1],
&mb->ya[1][2], &mb->ya[1][3],
&mb->ya[1][4], &mb->ya[1][5]
) == 6)
inpflags |= 010;
else if (!(inpflags & 020) &&
sscanf(buf,
"bxa(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->xa[2][0], &mb->xa[2][1],
&mb->xa[2][2], &mb->xa[2][3],
&mb->xa[2][4], &mb->xa[2][5]
) == 6)
inpflags |= 020;
else if (!(inpflags & 040) &&
sscanf(buf,
"bya(i) : select(i,%f,%f,%f,%f,%f,%f)",
&mb->ya[2][0], &mb->ya[2][1],
&mb->ya[2][2], &mb->ya[2][3],
&mb->ya[2][4], &mb->ya[2][5]
) == 6)
inpflags |= 040;
else if (!(inpflags & 0100) &&
sscanf(buf,
"ro = %f*rn + %f*gn + %f*bn",
&mb->cmat[0][0], &mb->cmat[0][1],
&mb->cmat[0][2]) == 3)
inpflags |= 0100;
else if (!(inpflags & 0200) &&
sscanf(buf,
"go = %f*rn + %f*gn + %f*bn",
&mb->cmat[1][0], &mb->cmat[1][1],
&mb->cmat[1][2]) == 3)
inpflags |= 0200;
else if (!(inpflags & 0400) &&
sscanf(buf,
"bo = %f*rn + %f*gn + %f*bn",
&mb->cmat[2][0], &mb->cmat[2][1],
&mb->cmat[2][2]) == 3)
inpflags |= 0400;
}
if (inpflags != 0777) {
fprintf(stderr,
"%s: cannot grok macbethcal file \"%s\" (inpflags==0%o)\n",
progname, fn, inpflags);
exit(1);
}
fclose(fp);
/* compute gamut */
for (i = 0; i < 3; i++) {
colval(mb->cmin,i) = mb->xa[i][0] -
mb->ya[i][0] *
(mb->xa[i][1]-mb->xa[i][0]) /
(mb->ya[i][1]-mb->ya[i][0]);
colval(mb->cmax,i) = mb->xa[i][4] +
(1.-mb->ya[i][4]) *
(mb->xa[i][5] - mb->xa[i][4]) /
(mb->ya[i][5] - mb->ya[i][4]);
}
}
static int
ambsample( /* initial ambient division sample */
AMBHEMI *hp,
int i,
int j,
int n
)
{
AMBSAMP *ap = &ambsam(hp,i,j);
RAY ar;
int hlist[3], ii;
double spt[2], zd;
/* generate hemispherical sample */
/* ambient coefficient for weight */
if (ambacc > FTINY)
setcolor(ar.rcoef, AVGREFL, AVGREFL, AVGREFL);
else
copycolor(ar.rcoef, hp->acoef);
if (rayorigin(&ar, AMBIENT, hp->rp, ar.rcoef) < 0)
return(0);
if (ambacc > FTINY) {
multcolor(ar.rcoef, hp->acoef);
scalecolor(ar.rcoef, 1./AVGREFL);
}
hlist[0] = hp->rp->rno;
hlist[1] = j;
hlist[2] = i;
multisamp(spt, 2, urand(ilhash(hlist,3)+n));
resample:
SDsquare2disk(spt, (j+spt[1])/hp->ns, (i+spt[0])/hp->ns);
zd = sqrt(1. - spt[0]*spt[0] - spt[1]*spt[1]);
for (ii = 3; ii--; )
ar.rdir[ii] = spt[0]*hp->ux[ii] +
spt[1]*hp->uy[ii] +
zd*hp->rp->ron[ii];
checknorm(ar.rdir);
/* avoid coincident samples */
if (!n && ambcollision(hp, i, j, ar.rdir)) {
spt[0] = frandom(); spt[1] = frandom();
goto resample; /* reject this sample */
}
dimlist[ndims++] = AI(hp,i,j) + 90171;
rayvalue(&ar); /* evaluate ray */
ndims--;
zd = raydistance(&ar);
if (zd <= FTINY)
return(0); /* should never happen */
multcolor(ar.rcol, ar.rcoef); /* apply coefficient */
if (zd*ap->d < 1.0) /* new/closer distance? */
ap->d = 1.0/zd;
if (!n) { /* record first vertex & value */
if (zd > 10.0*thescene.cusize + 1000.)
zd = 10.0*thescene.cusize + 1000.;
VSUM(ap->p, ar.rorg, ar.rdir, zd);
copycolor(ap->v, ar.rcol);
} else { /* else update recorded value */
hp->acol[RED] -= colval(ap->v,RED);
hp->acol[GRN] -= colval(ap->v,GRN);
hp->acol[BLU] -= colval(ap->v,BLU);
zd = 1.0/(double)(n+1);
scalecolor(ar.rcol, zd);
zd *= (double)n;
scalecolor(ap->v, zd);
addcolor(ap->v, ar.rcol);
}
addcolor(hp->acol, ap->v); /* add to our sum */
return(1);
}
char *
material(void) /* get (and print) current material */
{
char *mname = "mat";
COLOR radrgb, c2;
double d;
if (c_cmname != NULL)
mname = c_cmname;
if (!c_cmaterial->clock)
return(mname); /* already current */
/* else update output */
c_cmaterial->clock = 0;
if (c_cmaterial->ed > .1) { /* emitter */
cvtcolor(radrgb, &c_cmaterial->ed_c,
emult*c_cmaterial->ed/(PI*WHTEFFICACY));
if (glowdist < FHUGE) { /* do a glow */
fprintf(matfp, "\nvoid glow %s\n0\n0\n", mname);
fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN),
colval(radrgb,BLU), glowdist);
} else {
fprintf(matfp, "\nvoid light %s\n0\n0\n", mname);
fprintf(matfp, "3 %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN),
colval(radrgb,BLU));
}
return(mname);
}
d = c_cmaterial->rd + c_cmaterial->td +
c_cmaterial->rs + c_cmaterial->ts;
if ((d < 0.) | (d > 1.))
return(NULL);
/* check for glass/dielectric */
if (c_cmaterial->nr > 1.1 &&
c_cmaterial->ts > .25 && c_cmaterial->rs <= .125 &&
c_cmaterial->td <= .01 && c_cmaterial->rd <= .01 &&
c_cmaterial->rs_a <= .01 && c_cmaterial->ts_a <= .01) {
cvtcolor(radrgb, &c_cmaterial->ts_c,
c_cmaterial->ts + c_cmaterial->rs);
if (c_cmaterial->sided) { /* dielectric */
colval(radrgb,RED) = pow(colval(radrgb,RED),
1./C_1SIDEDTHICK);
colval(radrgb,GRN) = pow(colval(radrgb,GRN),
1./C_1SIDEDTHICK);
colval(radrgb,BLU) = pow(colval(radrgb,BLU),
1./C_1SIDEDTHICK);
fprintf(matfp, "\nvoid dielectric %s\n0\n0\n", mname);
fprintf(matfp, "5 %g %g %g %f 0\n", colval(radrgb,RED),
colval(radrgb,GRN), colval(radrgb,BLU),
c_cmaterial->nr);
return(mname);
}
/* glass */
fprintf(matfp, "\nvoid glass %s\n0\n0\n", mname);
fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN), colval(radrgb,BLU),
c_cmaterial->nr);
return(mname);
}
/* check for trans */
if (c_cmaterial->td > .01 || c_cmaterial->ts > .01) {
double ts, a5, a6;
if (c_cmaterial->sided) {
ts = sqrt(c_cmaterial->ts); /* approximate */
a5 = .5;
} else {
ts = c_cmaterial->ts;
a5 = 1.;
}
/* average colors */
d = c_cmaterial->rd + c_cmaterial->td + ts;
cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd/d);
cvtcolor(c2, &c_cmaterial->td_c, c_cmaterial->td/d);
addcolor(radrgb, c2);
cvtcolor(c2, &c_cmaterial->ts_c, ts/d);
addcolor(radrgb, c2);
if (c_cmaterial->rs + ts > .0001)
a5 = (c_cmaterial->rs*c_cmaterial->rs_a +
ts*a5*c_cmaterial->ts_a) /
(c_cmaterial->rs + ts);
a6 = (c_cmaterial->td + ts) /
(c_cmaterial->rd + c_cmaterial->td + ts);
if (a6 < .999)
d = c_cmaterial->rd/(1. - c_cmaterial->rs)/(1. - a6);
else
d = c_cmaterial->td + ts;
scalecolor(radrgb, d);
fprintf(matfp, "\nvoid trans %s\n0\n0\n", mname);
fprintf(matfp, "7 %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN), colval(radrgb,BLU));
fprintf(matfp, "\t%f %f %f %f\n", c_cmaterial->rs, a5, a6,
ts/(ts + c_cmaterial->td));
return(mname);
}
/* check for plastic */
if (c_cmaterial->rs < .1) {
cvtcolor(radrgb, &c_cmaterial->rd_c,
c_cmaterial->rd/(1.-c_cmaterial->rs));
fprintf(matfp, "\nvoid plastic %s\n0\n0\n", mname);
fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN), colval(radrgb,BLU),
c_cmaterial->rs, c_cmaterial->rs_a);
return(mname);
}
/* else it's metal */
/* average colors */
cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd);
cvtcolor(c2, &c_cmaterial->rs_c, c_cmaterial->rs);
addcolor(radrgb, c2);
fprintf(matfp, "\nvoid metal %s\n0\n0\n", mname);
fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
colval(radrgb,GRN), colval(radrgb,BLU),
c_cmaterial->rs/(c_cmaterial->rd + c_cmaterial->rs),
c_cmaterial->rs_a);
return(mname);
}
int
m_dielectric( /* color a ray which hit a dielectric interface */
OBJREC *m,
RAY *r
)
{
double cos1, cos2, nratio;
COLOR ctrans;
COLOR talb;
int hastexture;
int flatsurface;
double refl, trans;
FVECT dnorm;
double d1, d2;
RAY p;
int i;
/* PMAP: skip refracted shadow or ambient ray if accounted for in
photon map */
if (shadowRayInPmap(r) || ambRayInPmap(r))
return(1);
if (m->oargs.nfargs != (m->otype==MAT_DIELECTRIC ? 5 : 8))
objerror(m, USER, "bad arguments");
raytexture(r, m->omod); /* get modifiers */
if ( (hastexture = DOT(r->pert,r->pert) > FTINY*FTINY) )
cos1 = raynormal(dnorm, r); /* perturb normal */
else {
VCOPY(dnorm, r->ron);
cos1 = r->rod;
}
flatsurface = r->ro != NULL && isflat(r->ro->otype) &&
!hastexture | (r->crtype & AMBIENT);
/* index of refraction */
if (m->otype == MAT_DIELECTRIC)
nratio = m->oargs.farg[3] + m->oargs.farg[4]/MLAMBDA;
else
nratio = m->oargs.farg[3] / m->oargs.farg[7];
if (cos1 < 0.0) { /* inside */
hastexture = -hastexture;
cos1 = -cos1;
dnorm[0] = -dnorm[0];
dnorm[1] = -dnorm[1];
dnorm[2] = -dnorm[2];
setcolor(r->cext, -mylog(m->oargs.farg[0]*colval(r->pcol,RED)),
-mylog(m->oargs.farg[1]*colval(r->pcol,GRN)),
-mylog(m->oargs.farg[2]*colval(r->pcol,BLU)));
setcolor(r->albedo, 0., 0., 0.);
r->gecc = 0.;
if (m->otype == MAT_INTERFACE) {
setcolor(ctrans,
-mylog(m->oargs.farg[4]*colval(r->pcol,RED)),
-mylog(m->oargs.farg[5]*colval(r->pcol,GRN)),
-mylog(m->oargs.farg[6]*colval(r->pcol,BLU)));
setcolor(talb, 0., 0., 0.);
} else {
copycolor(ctrans, cextinction);
copycolor(talb, salbedo);
}
} else { /* outside */
nratio = 1.0 / nratio;
setcolor(ctrans, -mylog(m->oargs.farg[0]*colval(r->pcol,RED)),
-mylog(m->oargs.farg[1]*colval(r->pcol,GRN)),
-mylog(m->oargs.farg[2]*colval(r->pcol,BLU)));
setcolor(talb, 0., 0., 0.);
if (m->otype == MAT_INTERFACE) {
setcolor(r->cext,
-mylog(m->oargs.farg[4]*colval(r->pcol,RED)),
-mylog(m->oargs.farg[5]*colval(r->pcol,GRN)),
-mylog(m->oargs.farg[6]*colval(r->pcol,BLU)));
setcolor(r->albedo, 0., 0., 0.);
r->gecc = 0.;
}
}
d2 = 1.0 - nratio*nratio*(1.0 - cos1*cos1); /* compute cos theta2 */
if (d2 < FTINY) /* total reflection */
refl = 1.0;
else { /* refraction occurs */
/* compute Fresnel's equations */
cos2 = sqrt(d2);
d1 = cos1;
d2 = nratio*cos2;
d1 = (d1 - d2) / (d1 + d2);
refl = d1 * d1;
d1 = 1.0 / cos1;
d2 = nratio / cos2;
d1 = (d1 - d2) / (d1 + d2);
refl += d1 * d1;
refl *= 0.5;
trans = 1.0 - refl;
trans *= nratio*nratio; /* solid angle ratio */
setcolor(p.rcoef, trans, trans, trans);
if (rayorigin(&p, REFRACTED, r, p.rcoef) == 0) {
/* compute refracted ray */
d1 = nratio*cos1 - cos2;
for (i = 0; i < 3; i++)
p.rdir[i] = nratio*r->rdir[i] + d1*dnorm[i];
/* accidental reflection? */
if (hastexture &&
DOT(p.rdir,r->ron)*hastexture >= -FTINY) {
d1 *= (double)hastexture;
for (i = 0; i < 3; i++) /* ignore texture */
p.rdir[i] = nratio*r->rdir[i] +
d1*r->ron[i];
normalize(p.rdir); /* not exact */
} else
checknorm(p.rdir);
#ifdef DISPERSE
if (m->otype != MAT_DIELECTRIC
|| r->rod > 0.0
|| r->crtype & SHADOW
|| !directvis
|| m->oargs.farg[4] == 0.0
|| !disperse(m, r, p.rdir,
trans, ctrans, talb))
#endif
{
copycolor(p.cext, ctrans);
copycolor(p.albedo, talb);
rayvalue(&p);
multcolor(p.rcol, p.rcoef);
addcolor(r->rcol, p.rcol);
/* virtual distance */
if (flatsurface ||
(1.-FTINY <= nratio) &
(nratio <= 1.+FTINY))
r->rxt = r->rot + raydistance(&p);
}
}
}
setcolor(p.rcoef, refl, refl, refl);
if (!(r->crtype & SHADOW) &&
rayorigin(&p, REFLECTED, r, p.rcoef) == 0) {
/* compute reflected ray */
VSUM(p.rdir, r->rdir, dnorm, 2.*cos1);
/* accidental penetration? */
if (hastexture && DOT(p.rdir,r->ron)*hastexture <= FTINY)
VSUM(p.rdir, r->rdir, r->ron, 2.*r->rod);
checknorm(p.rdir);
rayvalue(&p); /* reflected ray value */
multcolor(p.rcol, p.rcoef); /* color contribution */
copycolor(r->mcol, p.rcol);
addcolor(r->rcol, p.rcol);
/* virtual distance */
r->rmt = r->rot;
if (flatsurface)
r->rmt += raydistance(&p);
}
/* rayvalue() computes absorption */
return(1);
}
static void
dirbrdf( /* compute source contribution */
COLOR cval, /* returned coefficient */
void *nnp, /* material data */
FVECT ldir, /* light source direction */
double omega /* light source size */
)
{
BRDFDAT *np = nnp;
double ldot;
double dtmp;
COLOR ctmp;
FVECT ldx;
static double vldx[5], pt[MAXDIM];
char **sa;
int i;
#define lddx (vldx+1)
setcolor(cval, 0.0, 0.0, 0.0);
ldot = DOT(np->pnorm, ldir);
if (ldot <= FTINY && ldot >= -FTINY)
return; /* too close to grazing */
if (ldot < 0.0 ? np->trans <= FTINY : np->trans >= 1.0-FTINY)
return; /* wrong side */
if (ldot > 0.0) {
/*
* Compute and add diffuse reflected component to returned
* color. The diffuse reflected component will always be
* modified by the color of the material.
*/
copycolor(ctmp, np->rdiff);
dtmp = ldot * omega / PI;
scalecolor(ctmp, dtmp);
addcolor(cval, ctmp);
} else {
/*
* Diffuse transmitted component.
*/
copycolor(ctmp, np->tdiff);
dtmp = -ldot * omega / PI;
scalecolor(ctmp, dtmp);
addcolor(cval, ctmp);
}
if (ldot > 0.0 ? np->rspec <= FTINY : np->tspec <= FTINY)
return; /* diffuse only */
/* set up function */
setbrdfunc(np);
sa = np->mp->oargs.sarg;
errno = 0;
/* transform light vector */
multv3(ldx, ldir, funcxf.xfm);
for (i = 0; i < 3; i++)
lddx[i] = ldx[i]/funcxf.sca;
lddx[3] = omega;
/* compute BRTDF */
if (np->mp->otype == MAT_BRTDF) {
if (sa[6][0] == '0') /* special case */
colval(ctmp,RED) = 0.0;
else
colval(ctmp,RED) = funvalue(sa[6], 4, lddx);
if (sa[7][0] == '0')
colval(ctmp,GRN) = 0.0;
else if (!strcmp(sa[7],sa[6]))
colval(ctmp,GRN) = colval(ctmp,RED);
else
colval(ctmp,GRN) = funvalue(sa[7], 4, lddx);
if (!strcmp(sa[8],sa[6]))
colval(ctmp,BLU) = colval(ctmp,RED);
else if (!strcmp(sa[8],sa[7]))
colval(ctmp,BLU) = colval(ctmp,GRN);
else
colval(ctmp,BLU) = funvalue(sa[8], 4, lddx);
dtmp = bright(ctmp);
} else if (np->dp == NULL) {
dtmp = funvalue(sa[0], 4, lddx);
setcolor(ctmp, dtmp, dtmp, dtmp);
} else {
for (i = 0; i < np->dp->nd; i++)
pt[i] = funvalue(sa[3+i], 4, lddx);
vldx[0] = datavalue(np->dp, pt);
dtmp = funvalue(sa[0], 5, vldx);
setcolor(ctmp, dtmp, dtmp, dtmp);
}
if ((errno == EDOM) | (errno == ERANGE)) {
objerror(np->mp, WARNING, "compute error");
return;
}
if (dtmp <= FTINY)
return;
if (ldot > 0.0) {
/*
* Compute reflected non-diffuse component.
*/
if ((np->mp->otype == MAT_MFUNC) | (np->mp->otype == MAT_MDATA))
multcolor(ctmp, np->mcolor);
dtmp = ldot * omega * np->rspec;
scalecolor(ctmp, dtmp);
addcolor(cval, ctmp);
} else {
/*
* Compute transmitted non-diffuse component.
*/
if ((np->mp->otype == MAT_TFUNC) | (np->mp->otype == MAT_TDATA))
multcolor(ctmp, np->mcolor);
dtmp = -ldot * omega * np->tspec;
scalecolor(ctmp, dtmp);
addcolor(cval, ctmp);
}
#undef lddx
}
static void
pixtoval(void) /* convert picture to values */
{
register COLOR *scanln;
int dogamma;
COLOR lastc;
RREAL hv[2];
int startprim, endprim;
long startpos;
int y;
register int x;
scanln = (COLOR *)malloc(scanlen(&picres)*sizeof(COLOR));
if (scanln == NULL) {
fprintf(stderr, "%s: out of memory\n", progname);
quit(1);
}
dogamma = gamcor < .95 || gamcor > 1.05;
if (putprim == ALL && !interleave) {
startprim = RED; endprim = BLU;
startpos = ftell(fin);
} else {
startprim = putprim; endprim = putprim;
}
for (putprim = startprim; putprim <= endprim; putprim++) {
if (putprim != startprim && fseek(fin, startpos, 0)) {
fprintf(stderr, "%s: seek error on input file\n",
progname);
quit(1);
}
set_io();
setcolor(lastc, 0.0, 0.0, 0.0);
for (y = 0; y < numscans(&picres); y++) {
if (freadscan(scanln, scanlen(&picres), fin) < 0) {
fprintf(stderr, "%s: read error\n", progname);
quit(1);
}
for (x = 0; x < scanlen(&picres); x++) {
if (uniq) {
if ( colval(scanln[x],RED) ==
colval(lastc,RED) &&
colval(scanln[x],GRN) ==
colval(lastc,GRN) &&
colval(scanln[x],BLU) ==
colval(lastc,BLU) )
continue;
else
copycolor(lastc, scanln[x]);
}
if (doexposure)
multcolor(scanln[x], exposure);
if (dogamma)
setcolor(scanln[x],
pow(colval(scanln[x],RED), 1.0/gamcor),
pow(colval(scanln[x],GRN), 1.0/gamcor),
pow(colval(scanln[x],BLU), 1.0/gamcor));
if (!dataonly) {
pix2loc(hv, &picres, x, y);
printf("%7d %7d ",
(int)(hv[0]*picres.xr),
(int)(hv[1]*picres.yr));
}
if ((*putval)(scanln[x]) < 0) {
fprintf(stderr, "%s: write error\n",
progname);
quit(1);
}
}
}
}
free((void *)scanln);
}
int
getparam( /* get variable from user */
char *str,
char *dsc,
int typ,
void *p
)
{
MyUptr ptr = (MyUptr)p;
int i0;
double d0, d1, d2;
char buf[48];
switch (typ) {
case 'i': /* integer */
if (sscanf(str, "%d", &i0) != 1) {
(*dev->comout)(dsc);
sprintf(buf, " (%d): ", ptr->i);
(*dev->comout)(buf);
(*dev->comin)(buf, NULL);
if (sscanf(buf, "%d", &i0) != 1)
return(0);
}
if (ptr->i == i0)
return(0);
ptr->i = i0;
break;
case 'r': /* real */
if (sscanf(str, "%lf", &d0) != 1) {
(*dev->comout)(dsc);
sprintf(buf, " (%.6g): ", ptr->d);
(*dev->comout)(buf);
(*dev->comin)(buf, NULL);
if (sscanf(buf, "%lf", &d0) != 1)
return(0);
}
if (FEQ(ptr->d, d0))
return(0);
ptr->d = d0;
break;
case 'b': /* boolean */
if (sscanf(str, "%1s", buf) != 1) {
(*dev->comout)(dsc);
sprintf(buf, "? (%c): ", ptr->i ? 'y' : 'n');
(*dev->comout)(buf);
(*dev->comin)(buf, NULL);
if (buf[0] == '\0')
return(0);
}
if (strchr("yY+1tTnN-0fF", buf[0]) == NULL)
return(0);
i0 = strchr("yY+1tT", buf[0]) != NULL;
if (ptr->i == i0)
return(0);
ptr->i = i0;
break;
case 'C': /* color */
if (sscanf(str, "%lf %lf %lf", &d0, &d1, &d2) != 3) {
(*dev->comout)(dsc);
sprintf(buf, " (%.6g %.6g %.6g): ",
colval(ptr->C,RED),
colval(ptr->C,GRN),
colval(ptr->C,BLU));
(*dev->comout)(buf);
(*dev->comin)(buf, NULL);
if (sscanf(buf, "%lf %lf %lf", &d0, &d1, &d2) != 3)
return(0);
}
if (FEQ(colval(ptr->C,RED), d0) &&
FEQ(colval(ptr->C,GRN), d1) &&
FEQ(colval(ptr->C,BLU), d2))
return(0);
setcolor(ptr->C, d0, d1, d2);
break;
default:
return(0); /* shouldn't happen */
}
newparam++;
return(1);
}
