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root/radiance/ray/src/util/ranimove2.c
Revision: 3.1
Committed: Sat Feb 22 02:07:30 2003 UTC (21 years, 1 month ago) by greg
Content type: text/plain
Branch: MAIN
Log Message:
Changes and check-in for 3.5 release
Includes new source files and modifications not recorded for many years
See ray/doc/notes/ReleaseNotes for notes between 3.1 and 3.5 release

File Contents

# User Rev Content
1 greg 3.1 #ifndef lint
2     static const char RCSid[] = "$Id$";
3     #endif
4     /*
5     * ranimove2.c
6     *
7     * Frame refinement routines for ranimate(1).
8     *
9     * Created by Gregory Ward on Wed Jan 08 2003.
10     */
11    
12     /* ====================================================================
13     * The Radiance Software License, Version 1.0
14     *
15     * Copyright (c) 1990 - 2002 The Regents of the University of California,
16     * through Lawrence Berkeley National Laboratory. All rights reserved.
17     *
18     * Redistribution and use in source and binary forms, with or without
19     * modification, are permitted provided that the following conditions
20     * are met:
21     *
22     * 1. Redistributions of source code must retain the above copyright
23     * notice, this list of conditions and the following disclaimer.
24     *
25     * 2. Redistributions in binary form must reproduce the above copyright
26     * notice, this list of conditions and the following disclaimer in
27     * the documentation and/or other materials provided with the
28     * distribution.
29     *
30     * 3. The end-user documentation included with the redistribution,
31     * if any, must include the following acknowledgment:
32     * "This product includes Radiance software
33     * (http://radsite.lbl.gov/)
34     * developed by the Lawrence Berkeley National Laboratory
35     * (http://www.lbl.gov/)."
36     * Alternately, this acknowledgment may appear in the software itself,
37     * if and wherever such third-party acknowledgments normally appear.
38     *
39     * 4. The names "Radiance," "Lawrence Berkeley National Laboratory"
40     * and "The Regents of the University of California" must
41     * not be used to endorse or promote products derived from this
42     * software without prior written permission. For written
43     * permission, please contact [email protected].
44     *
45     * 5. Products derived from this software may not be called "Radiance",
46     * nor may "Radiance" appear in their name, without prior written
47     * permission of Lawrence Berkeley National Laboratory.
48     *
49     * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED
50     * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
51     * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
52     * DISCLAIMED. IN NO EVENT SHALL Lawrence Berkeley National Laboratory OR
53     * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
54     * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
55     * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
56     * USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
57     * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
58     * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
59     * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
60     * SUCH DAMAGE.
61     * ====================================================================
62     *
63     * This software consists of voluntary contributions made by many
64     * individuals on behalf of Lawrence Berkeley National Laboratory. For more
65     * information on Lawrence Berkeley National Laboratory, please see
66     * <http://www.lbl.gov/>.
67     */
68    
69     #include "ranimove.h"
70     #include "random.h"
71    
72    
73     #define HL_ERR 0.32 /* highlight error threshold */
74    
75     int cerrzero; /* is cerrmap all zeroes? */
76    
77    
78     int
79     refine_first() /* initial refinement pass */
80     {
81     int *esamp = (int *)zprev; /* OK to reuse */
82     int hl_erri = errori(HL_ERR);
83     int nextra = 0;
84     int x, y, xp, yp;
85     int neigh;
86     register int n, np;
87    
88     if (sizeof(int) < sizeof(*zprev))
89     error(CONSISTENCY, "code error in refine_first");
90     if (!silent) {
91     printf("\tFirst refinement pass...");
92     fflush(stdout);
93     }
94     bzero((void *)esamp, sizeof(int)*hres*vres);
95     /*
96     * In our initial pass, we look for lower error pixels from
97     * the same objects in the previous frame, and copy them here.
98     */
99     for (y = vres; y--; )
100     for (x = hres; x--; ) {
101     n = fndx(x, y);
102     if (obuffer[n] == OVOID)
103     continue;
104     if (xmbuffer[n] == MO_UNK)
105     continue;
106     xp = x + xmbuffer[n];
107     if ((xp < 0 | xp >= hres))
108     continue;
109     yp = y + ymbuffer[n];
110     if ((yp < 0 | yp >= vres))
111     continue;
112     np = fndx(xp, yp);
113     /* make sure we hit same object */
114     if (oprev[np] != obuffer[n])
115     continue;
116     /* is previous frame error lower? */
117     if (aprev[np] < AMIN + ATIDIFF)
118     continue;
119     if (aprev[np] <= abuffer[n] + ATIDIFF)
120     continue;
121     /* shadow & highlight detection */
122     if (abuffer[n] > hl_erri &&
123     getclosest(&neigh, 1, x, y) &&
124     bigdiff(cbuffer[neigh], cprev[np],
125     HL_ERR*(.9+.2*frandom())))
126     continue;
127     abuffer[n] = aprev[np] - ATIDIFF;
128     copycolor(cbuffer[n], cprev[np]);
129     esamp[n] = 1; /* record extrapolated sample */
130     nextra++;
131     }
132     for (n = hres*vres; n--; ) /* update sample counts */
133     if (esamp[n])
134     sbuffer[n] = 1;
135     if (!silent)
136     printf("extrapolated %d pixels\n", nextra);
137     return(1);
138     }
139    
140    
141     /*
142     * We use a recursive computation of the conspicuity
143     * map to avoid associated memory costs and simplify
144     * coding. We create a virtual image pyramid, pooling
145     * variance calculations, etc. The top of the pyramid
146     * corresponds to the foveal resolution, as there should
147     * not be any interesting mechanisms above this level.
148     */
149    
150     #define CSF_C0 1.14
151     #define CSF_C1 0.67
152     #define CSF_C2 1.7
153     #define CSF_S1 6.1
154     #define CSF_S2 7.3
155     #define CSF_P1 45.9
156     #define CSF_PC (30./45.9*CSF_P1)
157     #define CSF_VR0 0.15
158     #define CSF_VRC 80.
159    
160     struct ConspSum {
161     COLOR vsum; /* value sum */
162     COLOR v2sum; /* value^2 sum */
163     long nsamp; /* number of samples */
164     long xmsum; /* x-motion sum */
165     long ymsum; /* y-motion sum */
166     int npix; /* number of pixels */
167     double hls; /* high-level saliency */
168     };
169    
170     static double pixel_deg; /* base pixel frequency */
171     static int fhsiz, fvsiz; /* foveal subimage size */
172    
173     static void
174     clr_consp(cs) /* initialize a conspicuity sum */
175     register struct ConspSum *cs;
176     {
177     if (cs == NULL)
178     return;
179     setcolor(cs->vsum, 0., 0., 0.);
180     setcolor(cs->v2sum, 0., 0., 0.);
181     cs->nsamp = 0;
182     cs->xmsum = cs->ymsum = 0;
183     cs->npix = 0;
184     cs->hls = 0;
185     }
186    
187     static void
188     sum_consp(cdest, cs) /* sum in conspicuity result */
189     register struct ConspSum *cdest, *cs;
190     {
191     if ((cdest == NULL | cs == NULL))
192     return;
193     addcolor(cdest->vsum, cs->vsum);
194     addcolor(cdest->v2sum, cs->v2sum);
195     cdest->nsamp += cs->nsamp;
196     cdest->xmsum += cs->xmsum;
197     cdest->ymsum += cs->ymsum;
198     cdest->npix += cs->npix;
199     if (cs->hls > cdest->hls)
200     cdest->hls = cs->hls;
201     }
202    
203     static void
204     est_consp(x0,y0,x1,y1, cs) /* estimate error conspicuity & update */
205     int x0, y0, x1, y1;
206     register struct ConspSum *cs;
207     {
208     double rad2, mtn2, cpd, vm, vr, csf, eest;
209     /* do we care? */
210     if (cs->hls <= FTINY)
211     return;
212     /* get relative error */
213     if (cs->nsamp < NSAMPOK) {
214     int neigh[NSAMPOK]; /* gather neighbors */
215     eest = comperr(neigh,
216     getclosest(neigh, NSAMPOK, (x0+x1)>>1, (y0+y1)>>1),
217     cs->nsamp);
218     } else
219     eest = estimaterr(cs->vsum, cs->v2sum, cs->nsamp, cs->nsamp);
220    
221     if ((x0 == x1-1 & y0 == y1-1)) { /* update pixel error */
222     int n = fndx(x0, y0);
223     int ai;
224     int ne;
225     if (sbuffer[n] >= 255) {
226     abuffer[n] = ADISTANT;
227     } else {
228     ai = errori(eest);
229     if (ai < AMIN) ai = AMIN;
230     else if (ai >= ADISTANT) ai = ADISTANT-1;
231     abuffer[n] = ai;
232     /* can't improve on closest */
233     if (!cs->nsamp && getclosest(&ne, 1, x0, y0) &&
234     abuffer[ne] < ai &&
235     abuffer[ne] >= AMIN)
236     abuffer[n] = abuffer[ne];
237     }
238     }
239     /* compute radius^2 */
240     rad2 = 0.125*((x1-x0)*(x1-x0) + (y1-y0)*(y1-y0));
241    
242     /* average motion^2 */
243     mtn2 = (double)cs->xmsum*cs->xmsum + (double)cs->ymsum*cs->ymsum;
244     mtn2 /= (double)(cs->npix*cs->npix);
245     /* motion blur hides us? */
246     if (mblur*mblur*mtn2 >= 4.*rad2)
247     return;
248     /* too small to see? */
249     cpd = pixel_deg * pixel_deg / rad2;
250     if (cpd > CSF_PC*CSF_PC)
251     return;
252     cpd = sqrt(cpd);
253     /* compute CSF [Daley98] */
254     vm = rate * sqrt(mtn2) / pixel_deg;
255     vr = cs->hls/hlsmax*vm + CSF_VR0; /* use hls tracking eff. */
256     if (vr > CSF_VRC) vr = CSF_VRC;
257     vr = vm - vr;
258     if (vr < 0) vr = -vr;
259     csf = log(CSF_C2*(1./3.)*vr);
260     if (csf < 0) csf = -csf;
261     csf = CSF_S1 + CSF_S2*csf*csf*csf;
262     csf *= CSF_C0*CSF_C2*4.*PI*PI*CSF_C1*CSF_C1*cpd*cpd;
263     csf *= exp(-CSF_C1*4.*PI/CSF_P1*(CSF_C2*vr + 2.)*cpd);
264     /* compute visible error */
265     eest = eest*csf/ndthresh - 1.;
266     if (eest <= FTINY)
267     return;
268     /* scale by saleincy */
269     eest *= cs->hls;
270     /* worth the bother? */
271     if (eest <= .01)
272     return;
273     /* sum into map */
274     for ( ; y0 < y1; y0++) {
275     float *em0 = cerrmap + fndx(x0, y0);
276     register float *emp = em0 + (x1-x0);
277     while (emp-- > em0)
278     *emp += eest;
279     }
280     cerrzero = 0;
281     }
282    
283     static void
284     subconspicuity(x0,y0,x1,y1, cs) /* compute subportion of conspicuity */
285     int x0, y0, x1, y1;
286     struct ConspSum *cs;
287     {
288     struct ConspSum mysum;
289     int i;
290    
291     if ((x0 >= x1 | y0 >= y1))
292     error(CONSISTENCY, "bad call to subconspicuity");
293    
294     clr_consp(&mysum); /* prepare sum */
295    
296     if ((x0 == x1-1 & y0 == y1-1)) { /* single pixel */
297     double hls;
298     register int n = fndx(x0, y0);
299     if (sbuffer[n]) {
300     copycolor(mysum.vsum, cbuffer[n]);
301     copycolor(mysum.v2sum, val2map[n]);
302     mysum.nsamp = sbuffer[n];
303     }
304     if ((mysum.xmsum = xmbuffer[n]) == MO_UNK)
305     mysum.xmsum = 0;
306     else
307     mysum.ymsum = ymbuffer[n];
308     mysum.npix = 1;
309     /* max. hls in fovea */
310     mysum.hls = obj_prio(obuffer[n]);
311     if (x0 >= fhsiz) {
312     hls = obj_prio(obuffer[fndx(x0-fhsiz,y0)]);
313     if (hls > mysum.hls) mysum.hls = hls;
314     }
315     if (x0 < hres-fhsiz) {
316     hls = obj_prio(obuffer[fndx(x0+fhsiz,y0)]);
317     if (hls > mysum.hls) mysum.hls = hls;
318     }
319     if (y0 >= fvsiz) {
320     hls = obj_prio(obuffer[fndx(x0,y0-fvsiz)]);
321     if (hls > mysum.hls) mysum.hls = hls;
322     }
323     if (y0 < vres-fvsiz) {
324     hls = obj_prio(obuffer[fndx(x0,y0+fvsiz)]);
325     if (hls > mysum.hls) mysum.hls = hls;
326     }
327     } else if (x0 == x1-1) { /* vertical pair */
328     for (i = y0 ; i < y1; i++)
329     subconspicuity(x0, i, x1, i+1, &mysum);
330     } else if (y0 == y1-1) { /* horizontal pair */
331     for (i = x0 ; i < x1; i++)
332     subconspicuity(i, y0, i+1, y1, &mysum);
333     } else { /* rectangle */
334     subconspicuity(x0, y0, (x0+x1)>>1, (y0+y1)>>1, &mysum);
335     subconspicuity((x0+x1)>>1, y0, x1, (y0+y1)>>1, &mysum);
336     subconspicuity(x0, (y0+y1)>>1, (x0+x1)>>1, y1, &mysum);
337     subconspicuity((x0+x1)>>1, (y0+y1)>>1, x1, y1, &mysum);
338     }
339     /* update conspicuity */
340     est_consp(x0, y0, x1, y1, &mysum);
341     /* sum into return value */
342     sum_consp(cs, &mysum);
343     }
344    
345     void
346     conspicuity() /* compute conspicuous error map */
347     {
348     int fhres, fvres;
349     int fx, fy;
350     /* reuse previous z-buffer */
351     cerrmap = (float *)zprev;
352     bzero((void *)cerrmap, sizeof(float)*hres*vres);
353     cerrzero = 1;
354     /* compute base pixel frequency */
355     pixel_deg = .5*(hres/vw.horiz + vres/vw.vert);
356     /* compute foveal resolution */
357     fhres = vw.horiz/FOV_DEG + 0.5;
358     if (fhres <= 0) fhres = 1;
359     else if (fhres > hres) fhres = hres;
360     fvres = vw.vert/FOV_DEG + 0.5;
361     if (fvres <= 0) fvres = 1;
362     else if (fvres > vres) fvres = vres;
363     fhsiz = hres/fhres;
364     fvsiz = vres/fvres;
365     /* call our foveal subroutine */
366     for (fy = fvres; fy--; )
367     for (fx = fhres; fx--; )
368     subconspicuity(hres*fx/fhres, vres*fy/fvres,
369     hres*(fx+1)/fhres, vres*(fy+1)/fvres,
370     NULL);
371     }
372    
373    
374     /*
375     * The following structure is used to collect data on the
376     * initial error in the ambient value estimate, in order
377     * to correct for it in the subsequent frames.
378     */
379     static struct AmbSum {
380     double diffsum[3]; /* sum of (correct - ambval) */
381     long nsamps; /* number of values in sum */
382     } *asump = NULL;
383    
384    
385     static int
386     ppri_cmp(pp1, pp2) /* pixel priority comparison */
387     const void *pp1, *pp2;
388     {
389     double se1 = cerrmap[*(const int *)pp1];
390     double se2 = cerrmap[*(const int *)pp2];
391     int adiff;
392     /* higher conspicuity to front */
393     if (se1 < se2) return(1);
394     if (se1 > se2) return(-1);
395     /* else higher error to front */
396     adiff = (int)abuffer[*(const int *)pp1] -
397     (int)abuffer[*(const int *)pp2];
398     if (adiff)
399     return(adiff);
400     /* else fewer samples to front */
401     return((int)sbuffer[*(const int *)pp1] -
402     (int)sbuffer[*(const int *)pp2]);
403     }
404    
405    
406     static int
407     ray_refine(n) /* refine the given pixel by tracing a ray */
408     register int n;
409     {
410     RAY ir;
411     int neigh[NSAMPOK];
412     int nc;
413     COLOR ctmp;
414     int i;
415    
416     if (n < 0) { /* fetching stragglers */
417     if (nprocs <= 1 || !ray_presult(&ir, 0))
418     return(-1);
419     n = ir.rno;
420     } else { /* else tracing a new ray */
421     double hv[2];
422     if (sbuffer[n] >= 255) /* reached limit? */
423     return(-1);
424     sample_pos(hv, n%hres, n/hres, sbuffer[n]);
425     ir.rmax = viewray(ir.rorg, ir.rdir, &vw, hv[0], hv[1]);
426     if (ir.rmax < -FTINY)
427     return(-1);
428     if (nprocs > 1) {
429     int rval;
430     rayorigin(&ir, NULL, PRIMARY, 1.0);
431     ir.rno = n;
432     rval = ray_pqueue(&ir);
433     if (!rval)
434     return(-1);
435     if (rval < 0)
436     quit(1);
437     n = ir.rno;
438     } else
439     ray_trace(&ir);
440     }
441     if (abuffer[n] == ALOWQ && asump != NULL) {
442     if (sbuffer[n] != 1)
443     error(CONSISTENCY, "bad code in ray_refine");
444     if (getambcolor(ctmp, obuffer[n]) &&
445     (colval(ctmp,RED) > 0.01 &
446     colval(ctmp,GRN) > 0.01 &
447     colval(ctmp,BLU) > 0.01)) {
448     for (i = 0; i < 3; i++)
449     asump->diffsum[i] +=
450     (colval(ir.rcol,i) - colval(cbuffer[n],i))
451     / colval(ctmp,i);
452     asump->nsamps++;
453     }
454     sbuffer[n] = 0;
455     }
456     setcolor(ctmp,
457     colval(ir.rcol,RED)*colval(ir.rcol,RED),
458     colval(ir.rcol,GRN)*colval(ir.rcol,GRN),
459     colval(ir.rcol,BLU)*colval(ir.rcol,BLU));
460     if (!sbuffer[n]) { /* first sample */
461     copycolor(cbuffer[n], ir.rcol);
462     copycolor(val2map[n], ctmp);
463     abuffer[n] = AHIGHQ;
464     sbuffer[n] = 1;
465     } else { /* else sum in sample */
466     addcolor(cbuffer[n], ir.rcol);
467     addcolor(val2map[n], ctmp);
468     sbuffer[n]++;
469     }
470     return(n);
471     }
472    
473    
474     static long
475     refine_rays(nrays) /* compute refinement rays */
476     long nrays;
477     {
478     int *pord;
479     int ntodo;
480     long rdone;
481     int i;
482     /* skip if nothing significant */
483     if (ndtset && cerrzero)
484     return;
485     /* initialize priority list */
486     pord = (int *)malloc(sizeof(int)*hres*vres);
487     for (i = hres*vres; i--; )
488     pord[i] = i;
489     /* sort our priorities */
490     ntodo = hres*vres;
491     if (nrays < ntodo)
492     qsort((void *)pord, hres*vres, sizeof(int), ppri_cmp);
493     i = 0;
494     /* trace rays in list */
495     for (rdone = 0; rdone < nrays; rdone++) {
496     if (ndtset && i >= 1000 && cerrmap[pord[i]] <= FTINY)
497     ntodo = i;
498     if (i >= ntodo) { /* redo conspicuity & priority */
499     while (ray_refine(-1) >= 0)
500     ;
501     conspicuity();
502     if (ndtset && cerrzero)
503     break;
504     qsort((void *)pord, hres*vres, sizeof(int), ppri_cmp);
505     ntodo = hres*vres/8;
506     i = 0;
507     }
508     /* sample next pixel */
509     ray_refine(pord[i++]);
510     }
511     /* clean up and return */
512     while (ray_refine(-1) >= 0)
513     ;
514     free((void *)pord);
515     return(rdone);
516     }
517    
518    
519     int
520     refine_frame(pass) /* refine current frame */
521     int pass;
522     {
523     static double rtime_used = 0;
524     static long ray_cnt = 0;
525     static double ctime_used = 0;
526     static int csp_cnt = 0;
527     int timed = (fcur > fbeg | pass > 0 | quickstart);
528     double time_start, rtime_start, time_done;
529     struct AmbSum myAmbSum;
530     long rays_todo, nr;
531     register int n;
532     /* IBR refinement? */
533     if ((pass == 0 & fcur > fbeg))
534     return(refine_first());
535     /* any time left? */
536     time_start = getTime();
537     if (timed) {
538     if (time_start >= frm_stop)
539     goto nomore;
540     if (csp_cnt > 0 && time_start + ctime_used/csp_cnt >= frm_stop)
541     goto nomore;
542     }
543     asump = NULL; /* use resampling to update ambval? */
544     if (!curparams->ambounce && hirendparams.ambounce) {
545     myAmbSum.diffsum[RED] =
546     myAmbSum.diffsum[GRN] =
547     myAmbSum.diffsum[BLU] = 0;
548     myAmbSum.nsamps = 0;
549     asump = &myAmbSum;
550     }
551     /* initialize value-squared map */
552     if (val2map == NULL) {
553     val2map = cprev; /* OK to reuse at this point */
554     n = (asump == NULL) ? hres*vres : 0;
555     while (n--)
556     if (sbuffer[n])
557     setcolor(val2map[n],
558     colval(cbuffer[n],RED)*colval(cbuffer[n],RED),
559     colval(cbuffer[n],GRN)*colval(cbuffer[n],GRN),
560     colval(cbuffer[n],BLU)*colval(cbuffer[n],BLU));
561     else
562     setcolor(val2map[n], 0., 0., 0.);
563     }
564     /* compute conspicuity */
565     if (!silent) {
566     printf("\tComputing conspicuity map\n");
567     fflush(stdout);
568     }
569     conspicuity();
570     csp_cnt++;
571     #if 0
572     if (pass == 1) {
573     char fnm[256];
574     sprintf(fnm, vval(BASENAME), fcur);
575     strcat(fnm, "_incmap.pic");
576     write_map(cerrmap, fnm);
577     }
578     #endif
579     /* get ray start time */
580     rtime_start = getTime();
581     ctime_used += rtime_start - time_start;
582     if (timed && rtime_start >= frm_stop)
583     return(0); /* error done but out of time */
584     if (rtime_used <= FTINY) {
585     if (quickstart)
586     rays_todo = 1000;
587     else
588     rays_todo = hres*vres;
589     } else {
590     rays_todo = (long)((frm_stop - rtime_start) *
591     ray_cnt / rtime_used);
592     if (rays_todo < 1000)
593     return(0); /* let's call it a frame */
594     }
595     /* set higher rendering quality */
596     if (twolevels && curparams != &hirendparams) {
597     ray_restore(curparams = &hirendparams);
598     if (nprocs > 1) { /* need to update children */
599     if (!silent) {
600     printf("\tRestarting %d processes\n", nprocs);
601     fflush(stdout);
602     }
603     ray_pclose(0);
604     ray_popen(nprocs);
605     }
606     }
607     /* compute refinement rays */
608     if (!silent) {
609     printf("\tRefinement pass %d...",
610     pass+1, rays_todo);
611     fflush(stdout);
612     }
613     if (asump != NULL) /* flag low-quality samples */
614     for (n = hres*vres; n--; )
615     if (sbuffer[n])
616     abuffer[n] = ALOWQ;
617     /* trace those rays */
618     nr = refine_rays(rays_todo);
619     if (!silent)
620     printf("traced %d HQ rays\n", nr);
621     if (nr <= 0)
622     return(0);
623     /* update timing stats */
624     while (ray_cnt >= 1L<<20) {
625     ray_cnt >>= 1;
626     rtime_used *= .5;
627     }
628     ray_cnt += nr;
629     time_done = getTime();
630     rtime_used += time_done - rtime_start;
631     if (!timed && time_done > frm_stop)
632     frm_stop = time_done;
633     /* update ambient value */
634     if (asump != NULL && asump->nsamps >= 1000) {
635     double sf = 1./(double)asump->nsamps;
636     for (n = 3; n--; ) {
637     asump->diffsum[n] *= sf;
638     asump->diffsum[n] += colval(lorendparams.ambval,n);
639     if (asump->diffsum[n] < 0) asump->diffsum[n] = 0;
640     }
641     setcolor(lorendparams.ambval,
642     asump->diffsum[RED],
643     asump->diffsum[GRN],
644     asump->diffsum[BLU]);
645     if (!silent)
646     printf("\tUpdated parameter: -av %f %f %f\n",
647     asump->diffsum[RED],
648     asump->diffsum[GRN],
649     asump->diffsum[BLU]);
650     asump = NULL;
651     }
652     return(1);
653     nomore:
654     /* make sure error map is updated */
655     if ((fcur == fbeg | pass > 1))
656     comp_frame_error();
657     return(0);
658     }