src/rt/rcontrib.c

#ifndef lint
static const char RCSid[] = "$Id: rcontrib.c,v 2.43 2023/11/15 18:02:53 greg Exp $";
#endif
/*
 * Accumulate ray contributions for a set of materials
 * Initialization and calculation routines
 */

#include "copyright.h"

#include "rcontrib.h"
#include "otypes.h"
#include "source.h"

char    *shm_boundary = NULL;           /* boundary of shared memory */

CUBE    thescene;                       /* our scene */
OBJECT  nsceneobjs;                     /* number of objects in our scene */

int     dimlist[MAXDIM];                /* sampling dimensions */
int     ndims = 0;                      /* number of sampling dimensions */
int     samplendx = 0;                  /* index for this sample */

void    (*trace)() = NULL;              /* trace call (NULL before rcinit) */

int     do_irrad = 0;                   /* compute irradiance? */

int     rand_samp = 1;                  /* pure Monte Carlo sampling? */

double  dstrsrc = 0.9;                  /* square source distribution */
double  shadthresh = 0.;                /* shadow threshold */
double  shadcert = .75;                 /* shadow certainty */
int     directrelay = 3;                /* number of source relays */
int     vspretest = 512;                /* virtual source pretest density */
int     directvis = 1;                  /* sources visible? */
double  srcsizerat = .2;                /* maximum ratio source size/dist. */

COLOR   cextinction = BLKCOLOR;         /* global extinction coefficient */
COLOR   salbedo = BLKCOLOR;             /* global scattering albedo */
double  seccg = 0.;                     /* global scattering eccentricity */
double  ssampdist = 0.;                 /* scatter sampling distance */

double  specthresh = .02;               /* specular sampling threshold */
double  specjitter = 1.;                /* specular sampling jitter */

int     backvis = 1;                    /* back face visibility */

int     maxdepth = -10;                 /* maximum recursion depth */
double  minweight = 2e-3;               /* minimum ray weight */

char    *ambfile = NULL;                /* ambient file name */
COLOR   ambval = BLKCOLOR;              /* ambient value */
int     ambvwt = 0;                     /* initial weight for ambient value */
double  ambacc = 0.;                    /* ambient accuracy */
int     ambres = 256;                   /* ambient resolution */
int     ambdiv = 350;                   /* ambient divisions */
int     ambssamp = 0;                   /* ambient super-samples */
int     ambounce = 1;                   /* ambient bounces */
char    *amblist[AMBLLEN+1];            /* ambient include/exclude list */
int     ambincl = -1;                   /* include == 1, exclude == 0 */

int     account;                        /* current accumulation count */
RNUMBER raysleft;                       /* number of rays left to trace */
long    waitflush;                      /* how long until next flush */

RNUMBER lastray = 0;                    /* last ray number sent */
RNUMBER lastdone = 0;                   /* last ray output */

static void     trace_contrib(RAY *r);  /* our trace callback */

static void mcfree(void *p) { epfree((*(MODCONT *)p).binv,1); free(p); }

LUTAB   modconttab = LU_SINIT(NULL,mcfree);     /* modifier lookup table */

/************************** INITIALIZATION ROUTINES ***********************/

const char *
formstr(                                /* return format identifier */
        int  f
)
{
        switch (f) {
        case 'a': return("ascii");
        case 'f': return("float");
        case 'd': return("double");
        case 'c': return(NCSAMP==3 ? COLRFMT : SPECFMT);
        }
        return("unknown");
}


/* Add modifier to our list to track */
MODCONT *
addmodifier(char *modn, char *outf, char *prms, char *binv, int bincnt)
{
        LUENT   *lep = lu_find(&modconttab,modn);
        MODCONT *mp;
        EPNODE  *ebinv;
        int     i;
        
        if (lep->data != NULL) {
                sprintf(errmsg, "duplicate modifier '%s'", modn);
                error(USER, errmsg);
        }
        if (!strcmp(modn, VOIDID)) {
                sprintf(errmsg, "cannot track '%s' modifier", VOIDID);
                error(USER, errmsg);
        }
        if (nmods >= modasiz) {         /* need bigger modifier array */
                modasiz += modasiz/2 + 64;
                if (modname == NULL)
                        modname = (char **)malloc(modasiz*sizeof(char *));
                else
                        modname = (char **)realloc(modname, modasiz*sizeof(char *));
                if (modname == NULL)
                        error(SYSTEM, "Out of memory in addmodifier()");
        }
        modname[nmods++] = modn;        /* XXX assumes static string */
        lep->key = modn;                /* XXX assumes static string */
        if (binv == NULL)
                binv = "0";             /* use single bin if unspecified */
        ebinv = eparse(binv);
        if (ebinv->type == NUM) {       /* check value if constant */
                bincnt = (int)(evalue(ebinv) + 1.5);
                if (bincnt != 1) {
                        sprintf(errmsg, "illegal non-zero constant for bin (%s)",
                                        binv);
                        error(USER, errmsg);
                }
        } else if (bincnt <= 0) {
                sprintf(errmsg,
                        "unspecified or illegal bin count for modifier '%s'",
                                modn);
                error(USER, errmsg);
        }
                                        /* initialize results holder */
        mp = (MODCONT *)malloc(mcsize(bincnt));
        if (mp == NULL)
                error(SYSTEM, "out of memory in addmodifier");
        mp->outspec = outf;             /* XXX assumes static string */
        mp->modname = modn;             /* XXX assumes static string */
        mp->params = prms;              /* XXX assumes static string */
        mp->binv = ebinv;
        mp->bin0 = 0;
        mp->nbins = bincnt;
        memset(mp->cbin, 0, DCOLORSIZ*bincnt);
                                        /* figure out starting bin */
        while (!getostream(mp->outspec, mp->modname, mp->bin0, 1))
                mp->bin0++;
                                        /* allocate other output streams */
        for (i = 0; ++i < mp->nbins; )
                getostream(mp->outspec, mp->modname, mp->bin0+i, 1);
        lep->data = (char *)mp;
        return(mp);
}


/* Add modifiers from a file list */
void
addmodfile(char *fname, char *outf, char *prms, char *binv, int bincnt)
{
        char    *path = getpath(fname, getrlibpath(), R_OK);
        char    mod[MAXSTR];
        FILE    *fp;

        if (path == NULL || (fp = fopen(path, "r")) == NULL) {
                if (path == NULL)
                        sprintf(errmsg, "cannot find modifier file '%s'", fname);
                else
                        sprintf(errmsg, "cannot load modifier file '%s'", path);
                error(SYSTEM, errmsg);
        }
        while (fgetword(mod, sizeof(mod), fp) != NULL)
                addmodifier(savqstr(mod), outf, prms, binv, bincnt);
        fclose(fp);
}


/* Check if we have any more rays left (and report progress) */
int
morays(void)
{
        static RNUMBER  total_rays;
        static time_t   tstart, last_report;
        time_t          tnow;

        if (!raysleft)
                return(1);      /* unknown total, so nothing to do or say */

        if (report_intvl > 0 && (tnow = time(0)) >= last_report+report_intvl) {
                if (!total_rays) {
                        total_rays = raysleft;
                        tstart = tnow;
                } else {
                        sprintf(errmsg, "%.2f%% done after %.3f hours\n",
                                        100.-100.*raysleft/total_rays,
                                        (1./3600.)*(tnow - tstart));
                        eputs(errmsg);
                }
                last_report = tnow;
        }
        return(--raysleft);
}


/* Quit program */
void
quit(
        int  code
)
{
        if (nchild > 0)         /* close children if any */
                end_children(code != 0);
        else if (nchild < 0)
                _exit(code);    /* avoid flush() in child */
        exit(code);
}


/* Initialize our process(es) */
static void
rcinit(void)
{
        int     i;

        if (nproc > MAXPROCESS)
                sprintf(errmsg, "too many processes requested -- reducing to %d",
                                nproc = MAXPROCESS);
        if (nproc > 1) {
                preload_objs();         /* preload auxiliary data */
                                        /* set shared memory boundary */
                shm_boundary = strcpy((char *)malloc(16), "SHM_BOUNDARY");
        }
        trace = trace_contrib;          /* set up trace call-back */
        for (i = 0; i < nsources; i++)  /* tracing to sources as well */
                source[i].sflags |= SFOLLOW;
        if (yres > 0) {                 /* set up flushing & ray counts */
                if (xres > 0)
                        raysleft = (RNUMBER)xres*yres;
                else
                        raysleft = yres;
        } else
                raysleft = 0;
        if ((account = accumulate) > 1)
                raysleft *= accumulate;
        waitflush = (yres > 0) & (xres > 1) ? 0 : xres;

        if (nproc > 1 && in_rchild())   /* forked child? */
                return;                 /* return to main processing loop */

        if (recover) {                  /* recover previous output? */
                if (accumulate <= 0)
                        reload_output();
                else
                        recover_output();
        }
        if (nproc == 1)                 /* single process? */
                return;
                                        /* else run appropriate controller */
        if (accumulate <= 0)
                feeder_loop();
        else
                parental_loop();
        quit(0);                        /* parent musn't return! */
}

/************************** MAIN CALCULATION PROCESS ***********************/

/* Our trace call to sum contributions */
static void
trace_contrib(RAY *r)
{
        MODCONT *mp;
        double  bval;
        int     bn;
        SCOLOR  contr;
        DCOLORV *dvp;
        int     i;

        if (r->ro == NULL || r->ro->omod == OVOID)
                return;
                                                /* shadow ray not on source? */
        if (r->rsrc >= 0 && source[r->rsrc].so != r->ro)
                return;

        mp = (MODCONT *)lu_find(&modconttab,objptr(r->ro->omod)->oname)->data;

        if (mp == NULL)                         /* not in our list? */
                return;

        worldfunc(RCCONTEXT, r);                /* else set context */
        set_eparams((char *)mp->params);
        if ((bval = evalue(mp->binv)) <= -.5)   /* and get bin number */
                return;                         /* silently ignore negatives */
        if ((bn = (int)(bval + .5)) >= mp->nbins) {
                sprintf(errmsg, "bad bin number (%d ignored)", bn);
                error(WARNING, errmsg);
                return;
        }
        raycontrib(contr, r, PRIMARY);          /* compute coefficient */
        if (contrib)
                smultscolor(contr, r->rcol);    /* -> contribution */
        dvp = mcbin(mp, bn);
        for (i = 0; i < NCSAMP; i++)            /* add it in */
                *dvp++ += contr[i];
}


/* Evaluate irradiance contributions */
static void
eval_irrad(FVECT org, FVECT dir)
{
        RAY     thisray;

        VSUM(thisray.rorg, org, dir, 1.1e-4);
        thisray.rdir[0] = -dir[0];
        thisray.rdir[1] = -dir[1];
        thisray.rdir[2] = -dir[2];
        thisray.rmax = 0.0;
        rayorigin(&thisray, PRIMARY, NULL, NULL);
                                        /* pretend we hit surface */
        thisray.rxt = thisray.rot = 1e-5;
        thisray.rod = 1.0;
        VCOPY(thisray.ron, dir);
        VSUM(thisray.rop, org, dir, 1e-4);
        samplendx++;                    /* compute result */
        (*ofun[Lamb.otype].funp)(&Lamb, &thisray);
}


/* Evaluate radiance contributions */
static void
eval_rad(FVECT org, FVECT dir, double dmax)
{
        RAY     thisray;
                                        /* set up ray */
        VCOPY(thisray.rorg, org);
        VCOPY(thisray.rdir, dir);
        thisray.rmax = dmax;
        rayorigin(&thisray, PRIMARY, NULL, NULL);
        samplendx++;                    /* call ray evaluation */
        rayvalue(&thisray);
}


/* Accumulate and/or output ray contributions (child or only process) */
static void
done_contrib(void)
{
        MODCONT *mp;
        int     i;

        if (account <= 0 || --account)
                return;                 /* not time yet */

        for (i = 0; i < nmods; i++) {   /* output records & clear */
                mp = (MODCONT *)lu_find(&modconttab,modname[i])->data;
                mod_output(mp);
                memset(mp->cbin, 0, DCOLORSIZ*mp->nbins);
        }
        end_record();                   /* end lines & flush if time */

        account = accumulate;           /* reset accumulation counter */
}


/* Principal calculation loop (called by main) */
void
rcontrib(void)
{
        static int      ignore_warning_given = 0;
        FVECT           orig, direc;
        double          d;
                                        /* initialize (& fork more of us) */
        rcinit();
                                        /* load rays from stdin & process */
#ifdef getc_unlocked
        flockfile(stdin);               /* avoid mutex overhead */
#endif
        while (getvec(orig) == 0 && getvec(direc) == 0) {
                d = normalize(direc);
                if (nchild != -1 && (d == 0.0) & (accumulate == 0)) {
                        if (!ignore_warning_given++)
                                error(WARNING,
                                "dummy ray(s) ignored during accumulation\n");
                        continue;
                }
                if (lastray+1 < lastray)
                        lastray = lastdone = 0;
                ++lastray;
                if (d == 0.0) {                         /* zero ==> flush */
                        if ((yres <= 0) | (xres <= 1))
                                waitflush = 1;          /* flush after */
                        if (nchild == -1)
                                account = 1;
                } else if (imm_irrad) {                 /* else compute */
                        eval_irrad(orig, direc);
                } else {
                        eval_rad(orig, direc, lim_dist ? d : 0.0);
                }
                done_contrib();         /* accumulate/output */
                ++lastdone;
                if (!morays())
                        break;          /* preemptive EOI */
        }
        if (nchild != -1 && (accumulate <= 0) | (account < accumulate)) {
                if (account < accumulate) {
                        error(WARNING, "partial accumulation in final record");
                        accumulate -= account;
                }
                account = 1;            /* output accumulated totals */
                done_contrib();
        }
        lu_done(&ofiletab);             /* close output files */
        if (raysleft)
                error(USER, "unexpected EOF on input");
}
Revision:	2.44
Committed:	Fri Feb 23 03:45:52 2024 UTC (2 months, 3 weeks ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	HEAD
Changes since 2.43:	+2 -2 lines
Log Message:	perf: Added some list optimization to calcomp routines
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: rcontrib.c,v 2.43 2023/11/15 18:02:53 greg Exp $";
3	#endif
4	/*
5	* Accumulate ray contributions for a set of materials
6	* Initialization and calculation routines
7	*/
8
9	#include "copyright.h"
10
11	#include "rcontrib.h"
12	#include "otypes.h"
13	#include "source.h"
14
15	char shm_boundary = NULL; / boundary of shared memory */
16
17	CUBE thescene; /* our scene */
18	OBJECT nsceneobjs; /* number of objects in our scene */
19
20	int dimlist[MAXDIM]; /* sampling dimensions */
21	int ndims = 0; /* number of sampling dimensions */
22	int samplendx = 0; /* index for this sample */
23
24	void (trace)() = NULL; / trace call (NULL before rcinit) */
25
26	int do_irrad = 0; /* compute irradiance? */
27
28	int rand_samp = 1; /* pure Monte Carlo sampling? */
29
30	double dstrsrc = 0.9; /* square source distribution */
31	double shadthresh = 0.; /* shadow threshold */
32	double shadcert = .75; /* shadow certainty */
33	int directrelay = 3; /* number of source relays */
34	int vspretest = 512; /* virtual source pretest density */
35	int directvis = 1; /* sources visible? */
36	double srcsizerat = .2; /* maximum ratio source size/dist. */
37
38	COLOR cextinction = BLKCOLOR; /* global extinction coefficient */
39	COLOR salbedo = BLKCOLOR; /* global scattering albedo */
40	double seccg = 0.; /* global scattering eccentricity */
41	double ssampdist = 0.; /* scatter sampling distance */
42
43	double specthresh = .02; /* specular sampling threshold */
44	double specjitter = 1.; /* specular sampling jitter */
45
46	int backvis = 1; /* back face visibility */
47
48	int maxdepth = -10; /* maximum recursion depth */
49	double minweight = 2e-3; /* minimum ray weight */
50
51	char ambfile = NULL; / ambient file name */
52	COLOR ambval = BLKCOLOR; /* ambient value */
53	int ambvwt = 0; /* initial weight for ambient value */
54	double ambacc = 0.; /* ambient accuracy */
55	int ambres = 256; /* ambient resolution */
56	int ambdiv = 350; /* ambient divisions */
57	int ambssamp = 0; /* ambient super-samples */
58	int ambounce = 1; /* ambient bounces */
59	char amblist[AMBLLEN+1]; / ambient include/exclude list */
60	int ambincl = -1; /* include == 1, exclude == 0 */
61
62	int account; /* current accumulation count */
63	RNUMBER raysleft; /* number of rays left to trace */
64	long waitflush; /* how long until next flush */
65
66	RNUMBER lastray = 0; /* last ray number sent */
67	RNUMBER lastdone = 0; /* last ray output */
68
69	static void trace_contrib(RAY r); / our trace callback */
70
71	static void mcfree(void p) { epfree(((MODCONT *)p).binv,1); free(p); }
72
73	LUTAB modconttab = LU_SINIT(NULL,mcfree); /* modifier lookup table */
74
75	/************************ INITIALIZATION ROUTINES *********************/
76
77	const char *
78	formstr( /* return format identifier */
79	int f
80	)
81	{
82	switch (f) {
83	case 'a': return("ascii");
84	case 'f': return("float");
85	case 'd': return("double");
86	case 'c': return(NCSAMP==3 ? COLRFMT : SPECFMT);
87	}
88	return("unknown");
89	}
90
91
92	/* Add modifier to our list to track */
93	MODCONT *
94	addmodifier(char modn, char outf, char prms, char binv, int bincnt)
95	{
96	LUENT *lep = lu_find(&modconttab,modn);
97	MODCONT *mp;
98	EPNODE *ebinv;
99	int i;
100
101	if (lep->data != NULL) {
102	sprintf(errmsg, "duplicate modifier '%s'", modn);
103	error(USER, errmsg);
104	}
105	if (!strcmp(modn, VOIDID)) {
106	sprintf(errmsg, "cannot track '%s' modifier", VOIDID);
107	error(USER, errmsg);
108	}
109	if (nmods >= modasiz) { /* need bigger modifier array */
110	modasiz += modasiz/2 + 64;
111	if (modname == NULL)
112	modname = (char *)malloc(modasizsizeof(char *));
113	else
114	modname = (char *)realloc(modname, modasizsizeof(char *));
115	if (modname == NULL)
116	error(SYSTEM, "Out of memory in addmodifier()");
117	}
118	modname[nmods++] = modn; /* XXX assumes static string */
119	lep->key = modn; /* XXX assumes static string */
120	if (binv == NULL)
121	binv = "0"; /* use single bin if unspecified */
122	ebinv = eparse(binv);
123	if (ebinv->type == NUM) { /* check value if constant */
124	bincnt = (int)(evalue(ebinv) + 1.5);
125	if (bincnt != 1) {
126	sprintf(errmsg, "illegal non-zero constant for bin (%s)",
127	binv);
128	error(USER, errmsg);
129	}
130	} else if (bincnt <= 0) {
131	sprintf(errmsg,
132	"unspecified or illegal bin count for modifier '%s'",
133	modn);
134	error(USER, errmsg);
135	}
136	/* initialize results holder */
137	mp = (MODCONT *)malloc(mcsize(bincnt));
138	if (mp == NULL)
139	error(SYSTEM, "out of memory in addmodifier");
140	mp->outspec = outf; /* XXX assumes static string */
141	mp->modname = modn; /* XXX assumes static string */
142	mp->params = prms; /* XXX assumes static string */
143	mp->binv = ebinv;
144	mp->bin0 = 0;
145	mp->nbins = bincnt;
146	memset(mp->cbin, 0, DCOLORSIZ*bincnt);
147	/* figure out starting bin */
148	while (!getostream(mp->outspec, mp->modname, mp->bin0, 1))
149	mp->bin0++;
150	/* allocate other output streams */
151	for (i = 0; ++i < mp->nbins; )
152	getostream(mp->outspec, mp->modname, mp->bin0+i, 1);
153	lep->data = (char *)mp;
154	return(mp);
155	}
156
157
158	/* Add modifiers from a file list */
159	void
160	addmodfile(char fname, char outf, char prms, char binv, int bincnt)
161	{
162	char *path = getpath(fname, getrlibpath(), R_OK);
163	char mod[MAXSTR];
164	FILE *fp;
165
166	if (path == NULL \|\| (fp = fopen(path, "r")) == NULL) {
167	if (path == NULL)
168	sprintf(errmsg, "cannot find modifier file '%s'", fname);
169	else
170	sprintf(errmsg, "cannot load modifier file '%s'", path);
171	error(SYSTEM, errmsg);
172	}
173	while (fgetword(mod, sizeof(mod), fp) != NULL)
174	addmodifier(savqstr(mod), outf, prms, binv, bincnt);
175	fclose(fp);
176	}
177
178
179	/* Check if we have any more rays left (and report progress) */
180	int
181	morays(void)
182	{
183	static RNUMBER total_rays;
184	static time_t tstart, last_report;
185	time_t tnow;
186
187	if (!raysleft)
188	return(1); /* unknown total, so nothing to do or say */
189
190	if (report_intvl > 0 && (tnow = time(0)) >= last_report+report_intvl) {
191	if (!total_rays) {
192	total_rays = raysleft;
193	tstart = tnow;
194	} else {
195	sprintf(errmsg, "%.2f%% done after %.3f hours\n",
196	100.-100.*raysleft/total_rays,
197	(1./3600.)*(tnow - tstart));
198	eputs(errmsg);
199	}
200	last_report = tnow;
201	}
202	return(--raysleft);
203	}
204
205
206	/* Quit program */
207	void
208	quit(
209	int code
210	)
211	{
212	if (nchild > 0) /* close children if any */
213	end_children(code != 0);
214	else if (nchild < 0)
215	_exit(code); /* avoid flush() in child */
216	exit(code);
217	}
218
219
220	/* Initialize our process(es) */
221	static void
222	rcinit(void)
223	{
224	int i;
225
226	if (nproc > MAXPROCESS)
227	sprintf(errmsg, "too many processes requested -- reducing to %d",
228	nproc = MAXPROCESS);
229	if (nproc > 1) {
230	preload_objs(); /* preload auxiliary data */
231	/* set shared memory boundary */
232	shm_boundary = strcpy((char *)malloc(16), "SHM_BOUNDARY");
233	}
234	trace = trace_contrib; /* set up trace call-back */
235	for (i = 0; i < nsources; i++) /* tracing to sources as well */
236	source[i].sflags \|= SFOLLOW;
237	if (yres > 0) { /* set up flushing & ray counts */
238	if (xres > 0)
239	raysleft = (RNUMBER)xres*yres;
240	else
241	raysleft = yres;
242	} else
243	raysleft = 0;
244	if ((account = accumulate) > 1)
245	raysleft *= accumulate;
246	waitflush = (yres > 0) & (xres > 1) ? 0 : xres;
247
248	if (nproc > 1 && in_rchild()) /* forked child? */
249	return; /* return to main processing loop */
250
251	if (recover) { /* recover previous output? */
252	if (accumulate <= 0)
253	reload_output();
254	else
255	recover_output();
256	}
257	if (nproc == 1) /* single process? */
258	return;
259	/* else run appropriate controller */
260	if (accumulate <= 0)
261	feeder_loop();
262	else
263	parental_loop();
264	quit(0); /* parent musn't return! */
265	}
266
267	/************************ MAIN CALCULATION PROCESS *********************/
268
269	/* Our trace call to sum contributions */
270	static void
271	trace_contrib(RAY *r)
272	{
273	MODCONT *mp;
274	double bval;
275	int bn;
276	SCOLOR contr;
277	DCOLORV *dvp;
278	int i;
279
280	if (r->ro == NULL \|\| r->ro->omod == OVOID)
281	return;
282	/* shadow ray not on source? */
283	if (r->rsrc >= 0 && source[r->rsrc].so != r->ro)
284	return;
285
286	mp = (MODCONT *)lu_find(&modconttab,objptr(r->ro->omod)->oname)->data;
287
288	if (mp == NULL) /* not in our list? */
289	return;
290
291	worldfunc(RCCONTEXT, r); /* else set context */
292	set_eparams((char *)mp->params);
293	if ((bval = evalue(mp->binv)) <= -.5) /* and get bin number */
294	return; /* silently ignore negatives */
295	if ((bn = (int)(bval + .5)) >= mp->nbins) {
296	sprintf(errmsg, "bad bin number (%d ignored)", bn);
297	error(WARNING, errmsg);
298	return;
299	}
300	raycontrib(contr, r, PRIMARY); /* compute coefficient */
301	if (contrib)
302	smultscolor(contr, r->rcol); /* -> contribution */
303	dvp = mcbin(mp, bn);
304	for (i = 0; i < NCSAMP; i++) /* add it in */
305	*dvp++ += contr[i];
306	}
307
308
309	/* Evaluate irradiance contributions */
310	static void
311	eval_irrad(FVECT org, FVECT dir)
312	{
313	RAY thisray;
314
315	VSUM(thisray.rorg, org, dir, 1.1e-4);
316	thisray.rdir[0] = -dir[0];
317	thisray.rdir[1] = -dir[1];
318	thisray.rdir[2] = -dir[2];
319	thisray.rmax = 0.0;
320	rayorigin(&thisray, PRIMARY, NULL, NULL);
321	/* pretend we hit surface */
322	thisray.rxt = thisray.rot = 1e-5;
323	thisray.rod = 1.0;
324	VCOPY(thisray.ron, dir);
325	VSUM(thisray.rop, org, dir, 1e-4);
326	samplendx++; /* compute result */
327	(*ofun[Lamb.otype].funp)(&Lamb, &thisray);
328	}
329
330
331	/* Evaluate radiance contributions */
332	static void
333	eval_rad(FVECT org, FVECT dir, double dmax)
334	{
335	RAY thisray;
336	/* set up ray */
337	VCOPY(thisray.rorg, org);
338	VCOPY(thisray.rdir, dir);
339	thisray.rmax = dmax;
340	rayorigin(&thisray, PRIMARY, NULL, NULL);
341	samplendx++; /* call ray evaluation */
342	rayvalue(&thisray);
343	}
344
345
346	/* Accumulate and/or output ray contributions (child or only process) */
347	static void
348	done_contrib(void)
349	{
350	MODCONT *mp;
351	int i;
352
353	if (account <= 0 \|\| --account)
354	return; /* not time yet */
355
356	for (i = 0; i < nmods; i++) { /* output records & clear */
357	mp = (MODCONT *)lu_find(&modconttab,modname[i])->data;
358	mod_output(mp);
359	memset(mp->cbin, 0, DCOLORSIZ*mp->nbins);
360	}
361	end_record(); /* end lines & flush if time */
362
363	account = accumulate; /* reset accumulation counter */
364	}
365
366
367	/* Principal calculation loop (called by main) */
368	void
369	rcontrib(void)
370	{
371	static int ignore_warning_given = 0;
372	FVECT orig, direc;
373	double d;
374	/* initialize (& fork more of us) */
375	rcinit();
376	/* load rays from stdin & process */
377	#ifdef getc_unlocked
378	flockfile(stdin); /* avoid mutex overhead */
379	#endif
380	while (getvec(orig) == 0 && getvec(direc) == 0) {
381	d = normalize(direc);
382	if (nchild != -1 && (d == 0.0) & (accumulate == 0)) {
383	if (!ignore_warning_given++)
384	error(WARNING,
385	"dummy ray(s) ignored during accumulation\n");
386	continue;
387	}
388	if (lastray+1 < lastray)
389	lastray = lastdone = 0;
390	++lastray;
391	if (d == 0.0) { /* zero ==> flush */
392	if ((yres <= 0) \| (xres <= 1))
393	waitflush = 1; /* flush after */
394	if (nchild == -1)
395	account = 1;
396	} else if (imm_irrad) { /* else compute */
397	eval_irrad(orig, direc);
398	} else {
399	eval_rad(orig, direc, lim_dist ? d : 0.0);
400	}
401	done_contrib(); /* accumulate/output */
402	++lastdone;
403	if (!morays())
404	break; /* preemptive EOI */
405	}
406	if (nchild != -1 && (accumulate <= 0) \| (account < accumulate)) {
407	if (account < accumulate) {
408	error(WARNING, "partial accumulation in final record");
409	accumulate -= account;
410	}
411	account = 1; /* output accumulated totals */
412	done_contrib();
413	}
414	lu_done(&ofiletab); /* close output files */
415	if (raysleft)
416	error(USER, "unexpected EOF on input");
417	}