[ViewVC] Diff of: radiance/ray/src/rt/rc3.c

Comparing ray/src/rt/rc3.c (file contents):
Revision 2.2 by greg, Sat Jun 9 16:47:27 2012 UTC vs.
Revision 2.21 by greg, Fri Mar 4 02:48:14 2016 UTC

#	Line 6 \| Line 6 \| static const char RCSid[] = "$Id$";
6		* Controlling process for multiple children
7		*/
8
9	+	#include <signal.h>
10		#include "rcontrib.h"
10	–	#include "platform.h"
11	–	#include "rtprocess.h"
11		#include "selcall.h"
12
13	+	#define MAXIQ (int)(PIPE_BUF/(sizeof(FVECT)*2))
14	+
15		/* Modifier contribution queue (results waiting to be output) */
16		typedef struct s_binq {
17	<	int ndx; /* index for this entry */
18	<	int n2add; /* number left to add */
17	>	RNUMBER ndx; /* index for this entry */
18	>	RNUMBER nadded; /* accumulated so far */
19		struct s_binq next; / next in queue */
20		MODCONT mca[1]; / contrib. array (extends struct) */
21		} BINQ;
#	Line 22 \| Line 23 \| typedef struct s_binq {
23		static BINQ out_bq = NULL; / output bin queue */
24		static BINQ free_bq = NULL; / free queue entries */
25
26	<	static SUBPROC kida[MAXPROCESS]; /* child processes */
26	<	static FILE inq_fp[MAXPROCESS]; / input streams */
26	>	static SUBPROC kidpr[MAXPROCESS]; /* our child processes */
27
28	+	static struct {
29	+	RNUMBER r1; /* assigned ray starting index */
30	+	FILE infp; / file pointer to read from process */
31	+	int nr; /* number of rays to sum (0 if free) */
32	+	} kida[MAXPROCESS]; /* our child process i/o */
33
34	<	/* Get new (empty) bin queue entry */
34	>
35	>	/* Get new bin queue entry */
36		static BINQ *
37		new_binq()
38		{
39	<	BINQ *bp = free_bq;
39	>	BINQ *bp;
40		int i;
41
42	<	if (bp != NULL) { /* something already available? */
42	>	if (free_bq != NULL) { /* something already available? */
43	>	bp = free_bq;
44		free_bq = bp->next;
45		bp->next = NULL;
46	<	bp->n2add = accumulate-1;
46	>	bp->nadded = 0;
47		return(bp);
48		}
49		/* else allocate fresh */
50	<	bp = (BINQ )malloc(sizeof(BINQ)+(nmods-1)sizeof(MODCONT *));
50	>	bp = (BINQ )malloc(sizeof(BINQ) + sizeof(MODCONT )*(nmods-1));
51		if (bp == NULL)
52		goto memerr;
53		for (i = nmods; i--; ) {
#	Line 53 \| Line 60 \| new_binq()
60		/* memset(bp->mca[i]->cbin, 0, sizeof(DCOLOR)mp->nbins); /
61		}
62		bp->ndx = 0;
63	<	bp->n2add = accumulate-1;
63	>	bp->nadded = 0;
64		bp->next = NULL;
65		return(bp);
66		memerr:
#	Line 89 \| Line 96 \| *free_binq(BINQ bp)**
96
97
98		/* Add modifier values to accumulation record in queue and clear */
99	<	void
99	>	static void
100		queue_modifiers()
101		{
102		MODCONT mpin, mpout;
#	Line 105 \| Line 112 \| queue_modifiers()
112		addcolor(mpout->cbin[j], mpin->cbin[j]);
113		memset(mpin->cbin, 0, sizeof(DCOLOR)*mpin->nbins);
114		}
115	+	out_bq->nadded++;
116		}
117
118
119	<	/* Sum one modifier record into another (doesn't update n2add) */
119	>	/* Sum one modifier record into another (updates nadded) */
120		static void
121		add_modbin(BINQ dst, BINQ src)
122		{
#	Line 120 \| Line 128 \| *add_modbin(BINQ dst, BINQ src)*
128		for (j = mpout->nbins; j--; )
129		addcolor(mpout->cbin[j], mpin->cbin[j]);
130		}
131	+	dst->nadded += src->nadded;
132		}
133
134
#	Line 139 \| Line 148 \| *queue_output(BINQ bp)**
148		}
149		return;
150		}
151	<	b_last = NULL; /* else insert in output queue */
151	>	b_last = NULL; /* insert in output queue */
152		for (b_cur = out_bq; b_cur != NULL && b_cur->ndx < bp->ndx;
153		b_cur = b_cur->next)
154		b_last = b_cur;
155	+
156		if (b_last != NULL) {
157		bp->next = b_cur;
158		b_last->next = bp;
#	Line 150 \| Line 160 \| *queue_output(BINQ bp)**
160		bp->next = out_bq;
161		out_bq = bp;
162		}
163	<	if (accumulate <= 1) /* no accumulating? */
163	>	if (accumulate == 1) /* no accumulation? */
164		return;
165		b_cur = out_bq; /* else merge accumulation entries */
166		while (b_cur->next != NULL) {
167	<	if (b_cur->n2add <= 0 \|\|
167	>	if (b_cur->nadded >= accumulate \|\|
168		(b_cur->ndx-1)/accumulate !=
169		(b_cur->next->ndx-1)/accumulate) {
170		b_cur = b_cur->next;
171		continue;
172		}
173		add_modbin(b_cur, b_cur->next);
164	–	b_cur->n2add--;
174		b_last = b_cur->next;
175		b_cur->next = b_last->next;
176		b_last->next = NULL;
#	Line 170 \| Line 179 \| *queue_output(BINQ bp)**
179		}
180
181
182	<	/* Get current with output FIFO by producing ready results */
182	>	/* Count number of records ready for output */
183		static int
184	<	output_catchup()
184	>	queue_ready()
185		{
186	+	int nready = 0;
187	+	BINQ *bp;
188	+
189	+	for (bp = out_bq; bp != NULL && bp->nadded >= accumulate &&
190	+	bp->ndx == lastdone+nready*accumulate+1;
191	+	bp = bp->next)
192	+	++nready;
193	+
194	+	return(nready);
195	+	}
196	+
197	+
198	+	/* Catch up with output queue by producing ready results */
199	+	static int
200	+	output_catchup(int nmax)
201	+	{
202		int nout = 0;
203		BINQ *bp;
204		int i;
205	<
206	<	if (accumulate <= 0) /* just accumulating? */
207	<	return(0);
208	<	/* else output ready results */
209	<	while (out_bq != NULL && (out_bq->ndx == lastdone+1) & !out_bq->n2add) {
205	>	/* output ready results */
206	>	while (out_bq != NULL && out_bq->nadded >= accumulate
207	>	&& out_bq->ndx == lastdone+1) {
208	>	if ((nmax > 0) & (nout >= nmax))
209	>	break;
210		bp = out_bq; /* pop off first entry */
211		out_bq = bp->next;
212		bp->next = NULL;
#	Line 196 \| Line 221 \| output_catchup()
221		}
222
223
224	<	/* Put a zero record in results queue */
224	>	/* Put a zero record in results queue & output */
225		void
226	<	zero_record(int ndx)
226	>	put_zero_record(int ndx)
227		{
228		BINQ *bp = new_binq();
229		int i;
#	Line 206 \| Line 231 \| zero_record(int ndx)
231		for (i = nmods; i--; )
232		memset(bp->mca[i]->cbin, 0, sizeof(DCOLOR)*bp->mca[i]->nbins);
233		bp->ndx = ndx;
234	+	bp->nadded = 1;
235		queue_output(bp);
236	+	output_catchup(0);
237		}
238
239
240	+	/* Get results from child process and add to queue */
241	+	static void
242	+	queue_results(int k)
243	+	{
244	+	BINQ bq = new_binq(); / get results holder */
245	+	int j;
246	+
247	+	bq->ndx = kida[k].r1;
248	+	bq->nadded = kida[k].nr;
249	+	/* read from child */
250	+	for (j = 0; j < nmods; j++)
251	+	if (fread(bq->mca[j]->cbin, sizeof(DCOLOR), bq->mca[j]->nbins,
252	+	kida[k].infp) != bq->mca[j]->nbins)
253	+	error(SYSTEM, "read error from render process");
254	+
255	+	queue_output(bq); /* put results in output queue */
256	+	kida[k].nr = 0; /* mark child as available */
257	+	}
258	+
259	+
260		/* callback to set output spec to NULL (stdout) */
261		static int
262		set_stdout(const LUENT le, void p)
#	Line 219 \| Line 266 \| *set_stdout(const LUENT le, void p)*
266		}
267
268
269	<	/* Start child processes if we can */
269	>	/* Start child processes if we can (call only once in parent!) */
270		int
271		in_rchild()
272		{
273	<	#ifdef _WIN32
274	<	error(WARNING, "multiprocessing unsupported -- running solo");
275	<	nproc = 1;
276	<	return(1);
277	<	#else
278	<	/* try to fork ourselves */
279	<	while (nchild < nproc) {
280	<	int p0[2], p1[2];
281	<	int pid;
282	<	/* prepare i/o pipes */
283	<	if (pipe(p0) < 0 \|\| pipe(p1) < 0)
284	<	error(SYSTEM, "pipe() call failed!");
285	<	pid = fork(); /* fork parent process */
286	<	if (pid == 0) { /* if in child, set up & return true */
240	<	close(p0[1]); close(p1[0]);
241	<	dup2(p0[0], 0); close(p0[0]);
242	<	dup2(p1[1], 1); close(p1[1]);
273	>	int rval;
274	>
275	>	while (nchild < nproc) { /* fork until target reached */
276	>	errno = 0;
277	>	rval = open_process(&kidpr[nchild], NULL);
278	>	if (rval < 0)
279	>	error(SYSTEM, "open_process() call failed");
280	>	if (rval == 0) { /* if in child, set up & return true */
281	>	lu_doall(&modconttab, &set_stdout, NULL);
282	>	lu_done(&ofiletab);
283	>	while (nchild--) { /* don't share other pipes */
284	>	close(kidpr[nchild].w);
285	>	fclose(kida[nchild].infp);
286	>	}
287		inpfmt = (sizeof(RREAL)==sizeof(double)) ? 'd' : 'f';
288		outfmt = 'd';
289		header = 0;
246	–	waitflush = xres = 1;
290		yres = 0;
291		raysleft = 0;
292	<	account = accumulate = 1;
293	<	lu_doall(&modconttab, set_stdout, NULL);
294	<	nchild = -1;
295	<	return(1); /* child return value */
292	>	if (accumulate == 1) {
293	>	waitflush = xres = 1;
294	>	account = accumulate = 1;
295	>	} else { /* parent controls accumulation */
296	>	waitflush = xres = 0;
297	>	account = accumulate = 0;
298	>	}
299	>	return(1); /* return "true" in child */
300		}
301	<	if (pid < 0)
302	<	error(SYSTEM, "fork() call failed!");
303	<	/* connect our pipes */
304	<	close(p0[0]); close(p1[1]);
305	<	kida[nchild].r = p1[0];
259	<	kida[nchild].w = p0[1];
260	<	kida[nchild].pid = pid;
261	<	kida[nchild].running = -1;
262	<	inq_fp[nchild] = fdopen(p1[0], "rb");
263	<	if (inq_fp[nchild] == NULL)
301	>	if (rval != PIPE_BUF)
302	>	error(CONSISTENCY, "bad value from open_process()");
303	>	/* connect to child's output */
304	>	kida[nchild].infp = fdopen(kidpr[nchild].r, "rb");
305	>	if (kida[nchild].infp == NULL)
306		error(SYSTEM, "out of memory in in_rchild()");
307	<	++nchild;
307	>	kida[nchild++].nr = 0; /* mark as available */
308		}
309	<	return(0); /* parent return value */
309	>	#ifdef getc_unlocked
310	>	for (rval = nchild; rval--; ) /* avoid mutex overhead */
311	>	flockfile(kida[rval].infp);
312		#endif
313	+	return(0); /* return "false" in parent */
314		}
315
316
317		/* Close child processes */
318		void
319	<	end_children()
319	>	end_children(int immed)
320		{
321	<	int status;
322	<
323	<	while (nchild-- > 0) {
324	<	kida[nchild].r = -1; /* close(-1) error is ignored */
325	<	if ((status = close_process(&kida[nchild])) > 0) {
326	<	sprintf(errmsg,
327	<	"rendering process returned bad status (%d)",
328	<	status);
321	>	int i;
322	>
323	>	#ifdef SIGKILL /* error mode -- quick exit */
324	>	for (i = nchild*immed; i-- > 0; )
325	>	kill(kidpr[nchild].pid, SIGKILL);
326	>	#endif
327	>	if ((i = close_processes(kidpr, nchild)) > 0 && !immed) {
328	>	sprintf(errmsg, "rendering process returned bad status (%d)",
329	>	i);
330		error(WARNING, errmsg);
285	–	}
286	–	fclose(inq_fp[nchild]); /* performs actual close() */
331		}
332	+	while (nchild-- > 0)
333	+	fclose(kida[nchild].infp);
334		}
335
336
337	<	/* Wait for the next available child, managing output queue as well */
337	>	/* Wait for the next available child, managing output queue simultaneously */
338		static int
339	<	next_child_nq(int force_wait)
339	>	next_child_nq(int flushing)
340		{
341		static struct timeval polling;
342	<	struct timeval *pmode = force_wait \| (accumulate <= 0) ?
297	<	(struct timeval *)NULL : &polling;
342	>	struct timeval *pmode;
343		fd_set readset, errset;
344	<	int i, j, n, nr;
344	>	int i, n, nr, nqr;
345
346	<	if (!force_wait) /* see if there's one free */
346	>	if (!flushing) /* see if there's one free */
347		for (i = nchild; i--; )
348	<	if (kida[i].running < 0)
348	>	if (!kida[i].nr)
349		return(i);
350	+
351	+	nqr = queue_ready(); /* choose blocking mode or polling */
352	+	if ((nqr > 0) & !flushing)
353	+	pmode = &polling;
354	+	else
355	+	pmode = NULL;
356	+	tryagain: /* catch up with output? */
357	+	if (pmode == &polling) {
358	+	if (nqr > nchild) /* don't get too far behind */
359	+	nqr -= output_catchup(nqr-nchild);
360	+	} else if (nqr > 0) /* clear output before blocking */
361	+	nqr -= output_catchup(0);
362		/* prepare select() call */
363		FD_ZERO(&readset); FD_ZERO(&errset);
364		n = nr = 0;
365		for (i = nchild; i--; ) {
366	<	if (kida[i].running > 0) {
367	<	FD_SET(kida[i].r, &readset);
366	>	if (kida[i].nr) {
367	>	FD_SET(kidpr[i].r, &readset);
368		++nr;
369		}
370	<	FD_SET(kida[i].r, &errset);
371	<	if (kida[i].r >= n)
372	<	n = kida[i].r + 1;
370	>	FD_SET(kidpr[i].r, &errset);
371	>	if (kidpr[i].r >= n)
372	>	n = kidpr[i].r + 1;
373		}
374	<	if (!nr) /* nothing going on */
374	>	if (!nr) /* nothing to wait for? */
375		return(-1);
319	–	tryagain:
320	–	if (pmode == NULL) /* about to block, so catch up */
321	–	output_catchup();
376		if ((nr > 1) \| (pmode == &polling)) {
377		errno = 0;
378		nr = select(n, &readset, NULL, &errset, pmode);
379	<	if (!nr & (pmode == &polling)) {
379	>	if (!nr) {
380		pmode = NULL; /* try again, blocking this time */
381		goto tryagain;
382		}
383	<	if (nr <= 0)
384	<	error(SYSTEM, "select call error in next_child_nq()");
383	>	if (nr < 0)
384	>	error(SYSTEM, "select() error in next_child_nq()");
385		} else
386		FD_ZERO(&errset);
387		n = -1; /* read results from child(ren) */
388		for (i = nchild; i--; ) {
389	<	BINQ *bq;
336	<	if (FD_ISSET(kida[i].r, &errset))
389	>	if (FD_ISSET(kidpr[i].r, &errset))
390		error(USER, "rendering process died");
391	<	if (!FD_ISSET(kida[i].r, &readset))
392	<	continue;
340	<	bq = new_binq(); /* get results holder */
341	<	bq->ndx = kida[i].running;
342	<	/* read from child */
343	<	for (j = 0; j < nmods; j++) {
344	<	n = bq->mca[j]->nbins;
345	<	nr = fread(bq->mca[j]->cbin,sizeof(DCOLOR),n,inq_fp[i]);
346	<	if (nr != n)
347	<	error(SYSTEM, "read error from render process");
348	<	}
349	<	queue_output(bq); /* put results in output queue */
350	<	kida[i].running = -1; /* mark child as available */
351	<	n = i;
391	>	if (FD_ISSET(kidpr[i].r, &readset))
392	>	queue_results(n = i);
393		}
394	<	return(n); /* last available child */
394	>	return(n); /* first available child */
395		}
396
397
#	Line 358 \| Line 399 \| tryagain:
399		void
400		parental_loop()
401		{
402	+	const int qlimit = (accumulate == 1) ? 1 : MAXIQ-1;
403	+	int ninq = 0;
404	+	FVECT orgdir[2*MAXIQ];
405	+	int i, n;
406	+	/* load rays from stdin & process */
407	+	#ifdef getc_unlocked
408	+	flockfile(stdin); /* avoid lock/unlock overhead */
409	+	#endif
410	+	while (getvec(orgdir[2ninq]) == 0 && getvec(orgdir[2ninq+1]) == 0) {
411	+	const int zero_ray = orgdir[2*ninq+1][0] == 0.0 &&
412	+	(orgdir[2*ninq+1][1] == 0.0) &
413	+	(orgdir[2*ninq+1][2] == 0.0);
414	+	ninq += !zero_ray;
415	+	/* Zero ray cannot go in input queue */
416	+	if (zero_ray ? ninq : ninq >= qlimit \|\|
417	+	lastray/accumulate != (lastray+ninq)/accumulate) {
418	+	i = next_child_nq(0); /* manages output */
419	+	n = ninq;
420	+	if (accumulate > 1) /* need terminator? */
421	+	memset(orgdir[2n++], 0, sizeof(FVECT)2);
422	+	n = sizeof(FVECT)2; /* send assignment */
423	+	if (writebuf(kidpr[i].w, (char *)orgdir, n) != n)
424	+	error(SYSTEM, "pipe write error");
425	+	kida[i].r1 = lastray+1;
426	+	lastray += kida[i].nr = ninq; /* mark as busy */
427	+	if (lastray < lastdone) { /* RNUMBER wrapped? */
428	+	while (next_child_nq(1) >= 0)
429	+	;
430	+	lastray -= ninq;
431	+	lastdone = lastray %= accumulate;
432	+	}
433	+	ninq = 0;
434	+	}
435	+	if (zero_ray) { /* put bogus record? */
436	+	if ((yres <= 0) \| (xres <= 1) &&
437	+	(lastray+1) % accumulate == 0) {
438	+	while (next_child_nq(1) >= 0)
439	+	; /* clear the queue */
440	+	lastdone = lastray = accumulate-1;
441	+	waitflush = 1; /* flush next */
442	+	}
443	+	put_zero_record(++lastray);
444	+	}
445	+	if (raysleft && !--raysleft)
446	+	break; /* preemptive EOI */
447	+	}
448	+	while (next_child_nq(1) >= 0) /* empty results queue */
449	+	;
450	+	if (account < accumulate) {
451	+	error(WARNING, "partial accumulation in final record");
452	+	free_binq(out_bq); /* XXX just ignore it */
453	+	out_bq = NULL;
454	+	}
455	+	free_binq(NULL); /* clean up */
456	+	lu_done(&ofiletab);
457	+	if (raysleft)
458	+	error(USER, "unexpected EOF on input");
459	+	}
460	+
461	+
462	+	/* Wait for the next available child by monitoring "to" pipes */
463	+	static int
464	+	next_child_ready()
465	+	{
466	+	fd_set writeset, errset;
467	+	int i, n;
468	+
469	+	for (i = nchild; i--; ) /* see if there's one free first */
470	+	if (!kida[i].nr)
471	+	return(i);
472	+	/* prepare select() call */
473	+	FD_ZERO(&writeset); FD_ZERO(&errset);
474	+	n = 0;
475	+	for (i = nchild; i--; ) {
476	+	FD_SET(kidpr[i].w, &writeset);
477	+	FD_SET(kidpr[i].r, &errset);
478	+	if (kidpr[i].w >= n)
479	+	n = kidpr[i].w + 1;
480	+	if (kidpr[i].r >= n)
481	+	n = kidpr[i].r + 1;
482	+	}
483	+	errno = 0;
484	+	n = select(n, NULL, &writeset, &errset, NULL);
485	+	if (n < 0)
486	+	error(SYSTEM, "select() error in next_child_ready()");
487	+	n = -1; /* identify waiting child */
488	+	for (i = nchild; i--; ) {
489	+	if (FD_ISSET(kidpr[i].r, &errset))
490	+	error(USER, "rendering process died");
491	+	if (FD_ISSET(kidpr[i].w, &writeset))
492	+	kida[n = i].nr = 0;
493	+	}
494	+	return(n); /* first available child */
495	+	}
496	+
497	+
498	+	/* Modified parental loop for full accumulation mode (-c 0) */
499	+	void
500	+	feeder_loop()
501	+	{
502		static int ignore_warning_given = 0;
503	<	FVECT orgdir[2];
504	<	double d;
503	>	int ninq = 0;
504	>	FVECT orgdir[2*MAXIQ];
505	>	int i, n;
506		/* load rays from stdin & process */
507		#ifdef getc_unlocked
508		flockfile(stdin); /* avoid lock/unlock overhead */
509		#endif
510	<	while (getvec(orgdir[0]) == 0 && getvec(orgdir[1]) == 0) {
511	<	d = normalize(orgdir[1]);
512	<	/* asking for flush? */
513	<	if ((d == 0.0) & (accumulate != 1)) {
510	>	while (getvec(orgdir[2ninq]) == 0 && getvec(orgdir[2ninq+1]) == 0) {
511	>	if (orgdir[2ninq+1][0] == 0.0 && / asking for flush? */
512	>	(orgdir[2*ninq+1][1] == 0.0) &
513	>	(orgdir[2*ninq+1][2] == 0.0)) {
514		if (!ignore_warning_given++)
515		error(WARNING,
516		"dummy ray(s) ignored during accumulation\n");
517		continue;
518	<	}
519	<	if ((d == 0.0) \| (lastray+1 < lastray)) {
520	<	while (next_child_nq(1) >= 0)
521	<	;
522	<	lastdone = lastray = 0;
381	<	}
382	<	if (d == 0.0) {
383	<	if ((yres <= 0) \| (xres <= 0))
384	<	waitflush = 1; /* flush right after */
385	<	zero_record(++lastray);
386	<	} else { /* else assign */
387	<	int avail = next_child_nq(0);
388	<	if (writebuf(kida[avail].w, (char *)orgdir,
389	<	sizeof(FVECT)2) != sizeof(FVECT)2)
518	>	}
519	>	if (++ninq >= MAXIQ) {
520	>	i = next_child_ready(); /* get eager child */
521	>	n = sizeof(FVECT)2 ninq; /* give assignment */
522	>	if (writebuf(kidpr[i].w, (char *)orgdir, n) != n)
523		error(SYSTEM, "pipe write error");
524	<	kida[avail].running = ++lastray;
524	>	kida[i].r1 = lastray+1;
525	>	lastray += kida[i].nr = ninq;
526	>	if (lastray < lastdone) /* RNUMBER wrapped? */
527	>	lastdone = lastray = 0;
528	>	ninq = 0;
529		}
530		if (raysleft && !--raysleft)
531		break; /* preemptive EOI */
532		}
533	<	while (next_child_nq(1) >= 0) /* empty results queue */
534	<	;
535	<	/* output accumulated record */
536	<	if (accumulate <= 0 \|\| account < accumulate) {
537	<	int i;
538	<	if (account < accumulate) {
539	<	error(WARNING, "partial accumulation in final record");
540	<	accumulate -= account;
404	<	}
405	<	for (i = 0; i < nmods; i++)
406	<	mod_output(out_bq->mca[i]);
407	<	end_record();
533	>	if (ninq) { /* polish off input */
534	>	i = next_child_ready();
535	>	n = sizeof(FVECT)2 ninq;
536	>	if (writebuf(kidpr[i].w, (char *)orgdir, n) != n)
537	>	error(SYSTEM, "pipe write error");
538	>	kida[i].r1 = lastray+1;
539	>	lastray += kida[i].nr = ninq;
540	>	ninq = 0;
541		}
542	+	memset(orgdir, 0, sizeof(FVECT)2); / get results */
543	+	for (i = nchild; i--; ) {
544	+	writebuf(kidpr[i].w, (char )orgdir, sizeof(FVECT)2);
545	+	queue_results(i);
546	+	}
547	+	if (recover) /* and from before? */
548	+	queue_modifiers();
549	+	end_children(0); /* free up file descriptors */
550	+	for (i = 0; i < nmods; i++)
551	+	mod_output(out_bq->mca[i]); /* output accumulated record */
552	+	end_record();
553	+	free_binq(out_bq); /* clean up */
554	+	out_bq = NULL;
555	+	free_binq(NULL);
556	+	lu_done(&ofiletab);
557		if (raysleft)
558		error(USER, "unexpected EOF on input");
411	–	free_binq(NULL); /* clean up */
412	–	lu_done(&ofiletab);
559		}

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Comparing ray/src/rt/rc3.c (file contents): Revision 2.2 by greg, Sat Jun 9 16:47:27 2012 UTC vs. Revision 2.21 by greg, Fri Mar 4 02:48:14 2016 UTC

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Comparing ray/src/rt/rc3.c (file contents):
Revision 2.2 by greg, Sat Jun 9 16:47:27 2012 UTC vs.
Revision 2.21 by greg, Fri Mar 4 02:48:14 2016 UTC