[ViewVC] Diff of: radiance/ray/src/hd/holofile.c

Comparing ray/src/hd/holofile.c (file contents):
Revision 3.11 by gregl, Thu Dec 11 19:57:58 1997 UTC vs.
Revision 3.24 by gwlarson, Tue Sep 15 14:26:23 1998 UTC

#	Line 1 \| Line 1
1	<	/* Copyright (c) 1997 Silicon Graphics, Inc. */
1	>	/* Copyright (c) 1998 Silicon Graphics, Inc. */
2
3		#ifndef lint
4		static char SCCSid[] = "$SunId$ SGI";
#	Line 16 \| Line 16 \| static char SCCSid[] = "$SunId$ SGI";
16		#define CACHESIZE 16 /* default cache size (Mbytes, 0==inf) */
17		#endif
18		#ifndef FREEBEAMS
19	<	#define FREEBEAMS 512 /* maximum beams to free at a time */
19	>	#define FREEBEAMS 1024 /* maximum beams to free at a time */
20		#endif
21		#ifndef PCTFREE
22	<	#define PCTFREE 20 /* maximum fraction to free (%) */
22	>	#define PCTFREE 15 /* maximum fraction to free (%) */
23		#endif
24	+	#ifndef MAXFRAG
25	+	#define MAXFRAG 32767 /* maximum fragments/file to track (0==inf) */
26	+	#endif
27
25	–	/* define MAXFRAG if you want to limit fragment tracking memory */
26	–
28		#ifndef BSD
29		#define write writebuf /* safe i/o routines */
30		#define read readbuf
31		#endif
32
33	<	#define FRAGBLK 64 /* number of fragments to allocate at a time */
33	>	#define FRAGBLK 256 /* number of fragments to allocate at a time */
34
35	<	int hdcachesize = CACHESIZE10241024; /* target cache size (bytes) */
35	>	unsigned hdcachesize = CACHESIZE10241024; /* target cache size */
36		unsigned long hdclock; /* clock value */
37
38		HOLO hdlist[HDMAX+1]; / holodeck pointers (NULL term.) */
39
40	<	static struct fragment {
40	>	static struct fraglist {
41		short nlinks; /* number of holodeck sections using us */
42	<	short nfrags; /* number of known fragments */
42	>	short writerr; /* write error encountered */
43	>	int nfrags; /* number of known fragments */
44		BEAMI fi; / fragments, descending file position */
45		long flen; /* last known file length */
46	<	} hdfrag; / fragment lists, indexed by file descriptor */
46	>	} hdfragl; / fragment lists, indexed by file descriptor */
47
48	<	static int nhdfrags; /* size of hdfrag array */
48	>	static int nhdfragls; /* size of hdfragl array */
49
50
51		hdattach(fd) /* start tracking file fragments for some section */
52		register int fd;
53		{
54	<	if (fd >= nhdfrags) {
55	<	if (nhdfrags)
56	<	hdfrag = (struct fragment )realloc((char )hdfrag,
57	<	(fd+1)*sizeof(struct fragment));
54	>	if (fd >= nhdfragls) {
55	>	if (nhdfragls)
56	>	hdfragl = (struct fraglist )realloc((char )hdfragl,
57	>	(fd+1)*sizeof(struct fraglist));
58		else
59	<	hdfrag = (struct fragment *)malloc(
60	<	(fd+1)*sizeof(struct fragment));
61	<	if (hdfrag == NULL)
59	>	hdfragl = (struct fraglist *)malloc(
60	>	(fd+1)*sizeof(struct fraglist));
61	>	if (hdfragl == NULL)
62		error(SYSTEM, "out of memory in hdattach");
63	<	bzero((char *)(hdfrag+nhdfrags),
64	<	(fd+1-nhdfrags)*sizeof(struct fragment));
65	<	nhdfrags = fd+1;
63	>	bzero((char *)(hdfragl+nhdfragls),
64	>	(fd+1-nhdfragls)*sizeof(struct fraglist));
65	>	nhdfragls = fd+1;
66		}
67	<	hdfrag[fd].nlinks++;
68	<	hdfrag[fd].flen = lseek(fd, 0L, 2); /* get file length */
67	>	hdfragl[fd].nlinks++;
68	>	hdfragl[fd].flen = lseek(fd, 0L, 2); /* get file length */
69		}
70
71
#	Line 73 \| Line 75 \| register int fd;
75		hdrelease(fd) /* stop tracking file fragments for some section */
76		register int fd;
77		{
78	<	if (fd < 0 \| fd >= nhdfrags \|\| !hdfrag[fd].nlinks)
78	>	if (fd < 0 \| fd >= nhdfragls \|\| !hdfragl[fd].nlinks)
79		return;
80	<	if (!--hdfrag[fd].nlinks && hdfrag[fd].nfrags) {
81	<	free((char *)hdfrag[fd].fi);
82	<	hdfrag[fd].fi = NULL;
83	<	hdfrag[fd].nfrags = 0;
80	>	if (!--hdfragl[fd].nlinks && hdfragl[fd].nfrags) {
81	>	free((char *)hdfragl[fd].fi);
82	>	hdfragl[fd].fi = NULL;
83	>	hdfragl[fd].nfrags = 0;
84		}
85		}
86
#	Line 103 \| Line 105 \| *hdinit(fd, hproto) / initialize a holodeck section in**
105		int fd; /* corresponding file descriptor */
106		HDGRID hproto; / holodeck section grid */
107		{
108	+	long rtrunc;
109		long fpos;
110		register HOLO *hp;
111		register int n;
#	Line 124 \| Line 127 \| *HDGRID hproto; /* holodeck section grid /*
127		error(SYSTEM, "failure loading holodeck directory");
128		/* check that it's clean */
129		if (hp->bi[nbeams(hp)].fo < 0)
130	<	error(USER, "dirty holodeck section");
130	>	error(WARNING, "dirty holodeck section");
131		} else { /* assume we're creating it */
132		if ((hp = hdalloc(hproto)) == NULL)
133		goto memerr;
#	Line 138 \| Line 141 \| *HDGRID hproto; /* holodeck section grid /*
141		hp->fd = fd;
142		hp->dirty = 0;
143		biglob(hp)->fo = fpos + sizeof(HDGRID);
144	<	biglob(hp)->nrd = 0; /* count rays on disk */
145	<	for (n = nbeams(hp); n > 0; n--)
146	<	biglob(hp)->nrd += hp->bi[n].nrd;
144	>	/* start tracking fragments */
145	>	hdattach(fd);
146	>	/* check rays on disk */
147	>	fpos = hdfilen(fd);
148	>	biglob(hp)->nrd = rtrunc = 0;
149	>	for (n = hproto == NULL ? nbeams(hp) : 0; n > 0; n--)
150	>	if (hp->bi[n].nrd)
151	>	if (hp->bi[n].fo + hp->bi[n].nrd > fpos) {
152	>	rtrunc += hp->bi[n].nrd;
153	>	hp->bi[n].nrd = 0;
154	>	} else
155	>	biglob(hp)->nrd += hp->bi[n].nrd;
156	>	if (rtrunc) {
157	>	sprintf(errmsg, "truncated section, %ld rays lost (%.1f%%)",
158	>	rtrunc, 100.*rtrunc/(rtrunc+biglob(hp)->nrd));
159	>	error(WARNING, errmsg);
160	>	}
161		/* add to holodeck list */
162		for (n = 0; n < HDMAX; n++)
163		if (hdlist[n] == NULL) {
164		hdlist[n] = hp;
165		break;
166		}
150	–	/* start tracking fragments (last) */
151	–	hdattach(fd);
167		/* all done */
168		return(hp);
169		memerr:
#	Line 157 \| Line 172 \| memerr:
172
173
174		int
175	<	hdsync(hp) /* update directory on disk if necessary */
175	>	hdsync(hp, all) /* update beams and directory on disk */
176		register HOLO *hp;
177	+	int all;
178		{
179		register int j, n;
180
181	<	if (hp == NULL) { /* do all */
181	>	if (hp == NULL) { /* do all holodecks */
182		n = 0;
183		for (j = 0; hdlist[j] != NULL; j++)
184	<	n += hdsync(hdlist[j]);
184	>	n += hdsync(hdlist[j], all);
185		return(n);
186		}
187	<	if (!hp->dirty) /* check first */
187	>	/* sync the beams */
188	>	for (j = (all ? nbeams(hp) : 0); j > 0; j--)
189	>	if (hp->bl[j] != NULL)
190	>	hdsyncbeam(hp, j);
191	>	if (!hp->dirty) /* directory clean? */
192		return(0);
193		errno = 0;
194		if (lseek(hp->fd, biglob(hp)->fo, 0) < 0)
#	Line 181 \| Line 201 \| *register HOLO hp;**
201		}
202
203
204	<	long
204	>	unsigned
205		hdmemuse(all) /* return memory usage (in bytes) */
206		int all; /* include overhead (painful) */
207		{
#	Line 200 \| Line 220 \| *int all; / include overhead (painful) /*
220		}
221		}
222		if (all)
223	<	for (j = 0; j < nhdfrags; j++) {
224	<	total += sizeof(struct fragment);
225	<	if (hdfrag[j].nfrags)
223	>	for (j = 0; j < nhdfragls; j++) {
224	>	total += sizeof(struct fraglist);
225	>	if (hdfragl[j].nfrags)
226		total += FRAGBLKsizeof(BEAMI)
227	<	((hdfrag[j].nfrags-1)/FRAGBLK + 1) ;
227	>	((hdfragl[j].nfrags-1)/FRAGBLK + 1) ;
228		}
229		return(total);
230		}
#	Line 218 \| Line 238 \| int fd;
238
239		if (fd < 0)
240		return(-1);
241	<	if (fd >= nhdfrags \|\| !hdfrag[fd].nlinks) {
241	>	if (fd >= nhdfragls \|\| !hdfragl[fd].nlinks) {
242		if ((fpos = lseek(fd, 0L, 1)) < 0)
243		return(-1);
244		flen = lseek(fd, 0L, 2);
245		lseek(fd, fpos, 0);
246		return(flen);
247		}
248	<	return(hdfrag[fd].flen);
248	>	return(hdfragl[fd].flen);
249		}
250
251
#	Line 296 \| Line 316 \| *int nr; / number of new rays desired /*
316		p = hdbray(hp->bl[i]) + hp->bl[i]->nrm;
317		hp->bl[i]->nrm += nr; /* update in-core structure */
318		bzero((char )p, nrsizeof(RAYVAL));
319	<	hp->bl[i]->tick = ++hdclock; /* update LRU clock */
320	<	blglob(hp)->tick = hdclock;
319	>	hp->bl[i]->tick = hdclock; /* update LRU clock */
320	>	blglob(hp)->tick = hdclock++;
321		return(p); /* point to new rays */
322		memerr:
323		error(SYSTEM, "out of memory in hdnewrays");
#	Line 328 \| Line 348 \| register int i;
348		if (read(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
349		error(SYSTEM, "error reading beam from holodeck file");
350		}
351	<	hp->bl[i]->tick = ++hdclock; /* update LRU clock */
352	<	blglob(hp)->tick = hdclock;
351	>	hp->bl[i]->tick = hdclock; /* update LRU clock */
352	>	blglob(hp)->tick = hdclock++;
353		return(hp->bl[i]);
354		}
355
356
357		int
358	<	hdsyncbi(hp, i) /* sync beam in memory with beam on disk */
359	<	register HOLO *hp;
340	<	register int i;
358	>	hdfilord(hb1, hb2) /* order beams for quick loading */
359	>	register HDBEAMI hb1, hb2;
360		{
361	<	unsigned int nrays = hp->bl[i]->nrm;
362	<	long nfo;
363	<	unsigned int n;
364	<	/* is current fragment OK? */
365	<	if (nrays == hp->bi[i].nrd)
347	<	return(0);
348	<	/* check file status */
349	<	if (hp->dirty < 0)
361	>	register long c;
362	>	/* residents go first */
363	>	if (hb2->h->bl[hb2->b] != NULL)
364	>	return(hb1->h->bl[hb1->b] == NULL);
365	>	if (hb1->h->bl[hb1->b] != NULL)
366		return(-1);
367	+	/* otherwise sort by file descriptor */
368	+	if ((c = hb1->h->fd - hb2->h->fd))
369	+	return(c);
370	+	/* then by position in file */
371	+	c = hb1->h->bi[hb1->b].fo - hb2->h->bi[hb2->b].fo;
372	+	return(c > 0 ? 1 : c < 0 ? -1 : 0);
373	+	}
374
352	–	if (hp->fd >= nhdfrags \|\| !hdfrag[hp->fd].nlinks) /* untracked */
353	–	hp->bi[i].fo = lseek(hp->fd, 0L, 2);
375
376	<	else if (hp->bi[i].fo + hp->bi[i].nrd*sizeof(RAYVAL) ==
377	<	hdfrag[hp->fd].flen) /* EOF special case */
378	<	hdfrag[hp->fd].flen = (nfo=hp->bi[i].fo) + nrays*sizeof(RAYVAL);
376	>	hdloadbeams(hb, n, bf) /* load a list of beams in optimal order */
377	>	register HDBEAMI hb; / list gets sorted by hdfilord() */
378	>	int n; /* list length */
379	>	int (bf)(); / callback function (optional) */
380	>	{
381	>	unsigned origcachesize, memuse;
382	>	int bytesloaded, needbytes, bytes2free;
383	>	register BEAM *bp;
384	>	register int i;
385	>	/* precheck consistency */
386	>	for (i = n; i--; )
387	>	if (hb[i].h == NULL \|\| hb[i].b < 1 \| hb[i].b > nbeams(hb[i].h))
388	>	error(CONSISTENCY, "bad beam in hdloadbeams");
389	>	/* sort list for optimal access */
390	>	qsort((char *)hb, n, sizeof(HDBEAMI), hdfilord);
391	>	bytesloaded = 0; /* run through loaded beams */
392	>	for ( ; n && (bp = hb->h->bl[hb->b]) != NULL; n--, hb++) {
393	>	bp->tick = hdclock; /* preempt swap */
394	>	bytesloaded += bp->nrm;
395	>	if (bf != NULL)
396	>	(*bf)(bp, hb);
397	>	}
398	>	bytesloaded *= sizeof(RAYVAL);
399	>	if ((origcachesize = hdcachesize) > 0) {
400	>	needbytes = 0; /* figure out memory needs */
401	>	for (i = n; i--; )
402	>	needbytes += hb[i].h->bi[hb[i].b].nrd;
403	>	needbytes *= sizeof(RAYVAL);
404	>	do { /* free enough memory */
405	>	memuse = hdmemuse(0);
406	>	bytes2free = needbytes - (int)(hdcachesize-memuse);
407	>	if (bytes2free > (int)(memuse - bytesloaded))
408	>	bytes2free = memuse - bytesloaded;
409	>	} while (bytes2free > 0 &&
410	>	hdfreecache(100*bytes2free/memuse, NULL) < 0);
411	>	hdcachesize = 0; /* load beams w/o swap */
412	>	}
413	>	for (i = 0; i < n; i++)
414	>	if ((bp = hdgetbeam(hb[i].h, hb[i].b)) != NULL && bf != NULL)
415	>	(*bf)(bp, hb+i);
416	>	hdcachesize = origcachesize; /* resume dynamic swapping */
417	>	}
418
419	<	else { /* general case */
420	<	register struct fragment *f = &hdfrag[hp->fd];
421	<	register int j, k;
422	<	/* relinquish old fragment */
423	<	if (hp->bi[i].nrd) {
424	<	j = f->nfrags++;
425	<	#ifdef MAXFRAG
426	<	if (j >= MAXFRAG-1)
427	<	f->nfrags--;
419	>
420	>	hdfreefrag(fd, bi) /* free a file fragment */
421	>	int fd;
422	>	register BEAMI *bi;
423	>	{
424	>	register struct fraglist *f;
425	>	register int j, k;
426	>
427	>	if (bi->nrd == 0)
428	>	return;
429	>	#ifdef DEBUG
430	>	if (fd < 0 \| fd >= nhdfragls \|\| !hdfragl[fd].nlinks)
431	>	error(CONSISTENCY, "bad file descriptor in hdfreefrag");
432		#endif
433	<	if (j % FRAGBLK == 0) { /* more frag. space */
434	<	if (f->fi == NULL)
435	<	f->fi = (BEAMI *)malloc(
436	<	FRAGBLK*sizeof(BEAMI));
437	<	else
438	<	f->fi = (BEAMI )realloc((char )f->fi,
439	<	(j+FRAGBLK)*sizeof(BEAMI));
440	<	if (f->fi == NULL)
441	<	error(SYSTEM,
442	<	"out of memory in hdsyncbi");
443	<	}
444	<	for ( ; ; j--) { /* insert in descending list */
445	<	if (!j \|\| hp->bi[i].fo < f->fi[j-1].fo) {
446	<	f->fi[j].fo = hp->bi[i].fo;
447	<	f->fi[j].nrd = hp->bi[i].nrd;
448	<	break;
449	<	}
450	<	copystruct(f->fi+j, f->fi+j-1);
451	<	}
433	>	f = &hdfragl[fd];
434	>	if (f->nfrags % FRAGBLK == 0) { /* delete empty remnants */
435	>	for (j = k = 0; k < f->nfrags; j++, k++) {
436	>	while (f->fi[k].nrd == 0)
437	>	if (++k >= f->nfrags)
438	>	goto endloop;
439	>	if (k > j)
440	>	copystruct(f->fi+j, f->fi+k);
441	>	}
442	>	endloop:
443	>	f->nfrags = j;
444	>	}
445	>	j = f->nfrags++; /* allocate a slot in free list */
446	>	#if MAXFRAG
447	>	if (j >= MAXFRAG-1)
448	>	f->nfrags--;
449	>	#endif
450	>	if (j % FRAGBLK == 0) { /* more free list space */
451	>	if (f->fi == NULL)
452	>	f->fi = (BEAMI )malloc(FRAGBLKsizeof(BEAMI));
453	>	else
454	>	f->fi = (BEAMI )realloc((char )f->fi,
455	>	(j+FRAGBLK)*sizeof(BEAMI));
456	>	if (f->fi == NULL)
457	>	error(SYSTEM, "out of memory in hdfreefrag");
458	>	}
459	>	for ( ; ; j--) { /* insert in descending list */
460	>	if (!j \|\| bi->fo < f->fi[j-1].fo) {
461	>	f->fi[j].fo = bi->fo;
462	>	f->fi[j].nrd = bi->nrd;
463	>	break;
464	>	}
465	>	copystruct(f->fi+j, f->fi+(j-1));
466	>	}
467		/* coalesce adjacent fragments */
468	<	for (j = k = 0; k < f->nfrags; j++, k++) {
469	<	if (k > j)
470	<	copystruct(f->fi+j, f->fi+k);
471	<	while (k+1 < f->nfrags && f->fi[k+1].fo +
472	<	f->fi[k+1].nrd*sizeof(RAYVAL)
473	<	== f->fi[j].fo) {
474	<	f->fi[j].fo -=
475	<	f->fi[++k].nrd*sizeof(RAYVAL);
476	<	f->fi[j].nrd += f->fi[k].nrd;
477	<	}
468	>	/* successors never empty */
469	>	if (j && f->fi[j-1].fo == f->fi[j].fo + f->fi[j].nrd*sizeof(RAYVAL)) {
470	>	f->fi[j].nrd += f->fi[j-1].nrd;
471	>	f->fi[j-1].nrd = 0;
472	>	}
473	>	for (k = j+1; k < f->nfrags; k++) /* get non-empty predecessor */
474	>	if (f->fi[k].nrd) {
475	>	if (f->fi[j].fo == f->fi[k].fo +
476	>	f->fi[k].nrd*sizeof(RAYVAL)) {
477	>	f->fi[k].nrd += f->fi[j].nrd;
478	>	f->fi[j].nrd = 0;
479		}
480	<	f->nfrags = j;
480	>	break;
481		}
482	<	k = -1; /* find closest-sized fragment */
483	<	for (j = nrays ? f->nfrags : 0; j-- > 0; )
484	<	if (f->fi[j].nrd >= nrays &&
485	<	(k < 0 \|\| f->fi[j].nrd < f->fi[k].nrd))
486	<	if (f->fi[k=j].nrd == nrays)
487	<	break;
488	<	if (k < 0) { /* no fragment -- extend file */
489	<	nfo = f->flen;
490	<	f->flen += nrays*sizeof(RAYVAL);
491	<	} else { /* else use fragment */
492	<	nfo = f->fi[k].fo;
493	<	if (f->fi[k].nrd == nrays) { /* delete fragment */
494	<	f->nfrags--;
495	<	for (j = k; j < f->nfrags; j++)
496	<	copystruct(f->fi+j, f->fi+j+1);
497	<	} else { /* else shrink it */
498	<	f->fi[k].fo += nrays*sizeof(RAYVAL);
499	<	f->fi[k].nrd -= nrays;
500	<	}
501	<	}
482	>	}
483	>
484	>
485	>	long
486	>	hdallocfrag(fd, nrays) /* allocate a file fragment */
487	>	int fd;
488	>	unsigned int4 nrays;
489	>	{
490	>	register struct fraglist *f;
491	>	register int j, k;
492	>	long nfo;
493	>
494	>	if (nrays == 0)
495	>	return(-1L);
496	>	#ifdef DEBUG
497	>	if (fd < 0 \| fd >= nhdfragls \|\| !hdfragl[fd].nlinks)
498	>	error(CONSISTENCY, "bad file descriptor in hdallocfrag");
499	>	#endif
500	>	f = &hdfragl[fd];
501	>	k = -1; /* find closest-sized fragment */
502	>	for (j = f->nfrags; j-- > 0; )
503	>	if (f->fi[j].nrd >= nrays &&
504	>	(k < 0 \|\| f->fi[j].nrd < f->fi[k].nrd))
505	>	if (f->fi[k=j].nrd == nrays)
506	>	break;
507	>	if (k < 0) { /* no fragment -- extend file */
508	>	nfo = f->flen;
509	>	f->flen += nrays*sizeof(RAYVAL);
510	>	} else { /* else use fragment */
511	>	nfo = f->fi[k].fo;
512	>	f->fi[k].fo += nrays*sizeof(RAYVAL);
513	>	f->fi[k].nrd -= nrays;
514		}
515	<	if (nrays) { /* write the new fragment */
515	>	return(nfo);
516	>	}
517	>
518	>
519	>	int
520	>	hdsyncbeam(hp, i) /* sync beam in memory with beam on disk */
521	>	register HOLO *hp;
522	>	register int i;
523	>	{
524	>	unsigned int4 nrays;
525	>	unsigned int n;
526	>	long nfo;
527	>	/* check file status */
528	>	if (hdfragl[hp->fd].writerr)
529	>	return(-1);
530	>	#ifdef DEBUG
531	>	if (i < 1 \| i > nbeams(hp))
532	>	error(CONSISTENCY, "bad beam index in hdsyncbeam");
533	>	#endif
534	>	/* is current fragment OK? */
535	>	if (hp->bl[i] == NULL \|\| (nrays = hp->bl[i]->nrm) == hp->bi[i].nrd)
536	>	return(0);
537	>	if (hp->bi[i].nrd) /* relinquish old fragment */
538	>	hdfreefrag(hp->fd, &hp->bi[i]);
539	>	if (nrays) { /* get and write new fragment */
540	>	nfo = hdallocfrag(hp->fd, nrays);
541		errno = 0;
542		if (lseek(hp->fd, nfo, 0) < 0)
543		error(SYSTEM, "cannot seek on holodeck file");
544		n = hp->bl[i]->nrm * sizeof(RAYVAL);
545		if (write(hp->fd, (char *)hdbray(hp->bl[i]), n) != n) {
546	<	hp->dirty = -1; /* avoid recursive error */
547	<	error(SYSTEM, "write error in hdsyncbi");
546	>	hdfragl[hp->fd].writerr++;
547	>	hdsync(NULL, 0); /* sync directories */
548	>	error(SYSTEM, "write error in hdsyncbeam");
549		}
550	<	}
550	>	hp->bi[i].fo = nfo;
551	>	} else
552	>	hp->bi[i].fo = 0L;
553		biglob(hp)->nrd += nrays - hp->bi[i].nrd;
554		hp->bi[i].nrd = nrays;
555	<	hp->bi[i].fo = nfo;
436	<	markdirty(hp); /* section directory now out of date */
555	>	markdirty(hp); /* section directory now out of date */
556		return(1);
557		}
558
#	Line 451 \| Line 570 \| register int i;
570		nchanged += hdfreebeam(hdlist[i], 0);
571		return(nchanged);
572		}
573	+	if (hdfragl[hp->fd].writerr) /* check for file error */
574	+	return(0);
575		if (i == 0) { /* clear entire holodeck */
576		nchanged = 0;
577		for (i = nbeams(hp); i > 0; i--)
#	Line 458 \| Line 579 \| register int i;
579		nchanged += hdfreebeam(hp, i);
580		return(nchanged);
581		}
582	+	#ifdef DEBUG
583		if (i < 1 \| i > nbeams(hp))
584		error(CONSISTENCY, "bad beam index to hdfreebeam");
585	+	#endif
586		if (hp->bl[i] == NULL)
587		return(0);
588		/* check for additions */
589		nchanged = hp->bl[i]->nrm - hp->bi[i].nrd;
590		if (nchanged)
591	<	hdsyncbi(hp, i); /* write new fragment */
591	>	hdsyncbeam(hp, i); /* write new fragment */
592		blglob(hp)->nrm -= hp->bl[i]->nrm;
593		free((char )hp->bl[i]); / free memory */
594		hp->bl[i] = NULL;
#	Line 498 \| Line 621 \| register int i;
621		#endif
622		return(nchanged);
623		}
624	+	#ifdef DEBUG
625		if (i < 1 \| i > nbeams(hp))
626		error(CONSISTENCY, "bad beam index to hdkillbeam");
627	+	#endif
628		if (hp->bl[i] != NULL) { /* free memory */
629		blglob(hp)->nrm -= nchanged = hp->bl[i]->nrm;
630		free((char *)hp->bl[i]);
#	Line 507 \| Line 632 \| register int i;
632		nchanged = hp->bi[i].nrd;
633		if (hp->bi[i].nrd) { /* free file fragment */
634		hp->bl[i] = &emptybeam;
635	<	hdsyncbi(hp, i);
635	>	hdsyncbeam(hp, i);
636		}
637		hp->bl[i] = NULL;
638		return(nchanged);
639		}
640
641
642	<	hdlrulist(ha, ba, n, hp) /* add beams from holodeck to LRU list */
643	<	register HOLO ha[]; / section list (NULL terminated) */
644	<	register int ba[]; /* beam index to go with section */
645	<	int n; /* length of arrays minus 1 */
642	>	int
643	>	hdlrulist(hb, nents, n, hp) /* add beams from holodeck to LRU list */
644	>	register HDBEAMI hb; / beam list */
645	>	int nents; /* current list length */
646	>	int n; /* maximum list length */
647		register HOLO hp; / section we're adding from */
648		{
649		register int i, j;
524	–	int nents;
525	–	/* find last entry in LRU list */
526	–	for (j = 0; ha[j] != NULL; j++)
527	–	;
528	–	nents = j;
650		/* insert each beam from hp */
651	<	for (i = nbeams(hp); i > 0; i--) {
651	>	for (i = 1; i <= nbeams(hp); i++) {
652		if (hp->bl[i] == NULL) /* check if loaded */
653		continue;
654	<	if ((j = ++nents) > n) /* grow list if we can */
654	>	#if 0
655	>	if (hp->bl[i]->tick == hdclock) /* preempt swap? */
656	>	continue;
657	>	#endif
658	>	if ((j = ++nents) >= n) /* grow list if we can */
659		nents--;
660		for ( ; ; ) { /* bubble into place */
661		if (!--j \|\| hp->bl[i]->tick >=
662	<	ha[j-1]->bl[ba[j-1]]->tick) {
663	<	ha[j] = hp;
664	<	ba[j] = i;
662	>	hb[j-1].h->bl[hb[j-1].b]->tick) {
663	>	hb[j].h = hp;
664	>	hb[j].b = i;
665		break;
666		}
667	<	ha[j] = ha[j-1];
543	<	ba[j] = ba[j-1];
667	>	copystruct(hb+j, hb+(j-1));
668		}
669		}
670	<	ha[nents] = NULL; /* all done */
547	<	ba[nents] = 0;
670	>	return(nents); /* return new list length */
671		}
672
673
674	+	int
675		hdfreecache(pct, honly) /* free up cache space, writing changes */
676		int pct; /* maximum percentage to free */
677		register HOLO honly; / NULL means check all */
678		{
679	<	HOLO *hp[FREEBEAMS+1];
556	<	int bn[FREEBEAMS+1];
679	>	HDBEAMI hb[FREEBEAMS];
680		int freetarget;
681	+	int n;
682		register int i;
683		/* compute free target */
684		freetarget = (honly != NULL) ? blglob(honly)->nrm :
685		hdmemuse(0)/sizeof(RAYVAL) ;
686		freetarget = freetarget*pct/100;
687	+	if (freetarget <= 0)
688	+	return(0);
689		/* find least recently used */
690	<	hp[0] = NULL;
565	<	bn[0] = 0;
690	>	n = 0;
691		if (honly != NULL)
692	<	hdlrulist(hp, bn, FREEBEAMS, honly);
692	>	n = hdlrulist(hb, n, FREEBEAMS, honly);
693		else
694		for (i = 0; hdlist[i] != NULL; i++)
695	<	hdlrulist(hp, bn, FREEBEAMS, hdlist[i]);
695	>	n = hdlrulist(hb, n, FREEBEAMS, hdlist[i]);
696		/* free LRU beams */
697	<	for (i = 0; hp[i] != NULL; i++) {
698	<	hdfreebeam(hp[i], bn[i]);
699	<	if ((freetarget -= hp[i]->bi[bn[i]].nrd) <= 0)
697	>	for (i = 0; i < n; i++) {
698	>	hdfreebeam(hb[i].h, hb[i].b);
699	>	if ((freetarget -= hb[i].h->bi[hb[i].b].nrd) <= 0)
700		break;
701		}
702	<	hdsync(honly); /* synchronize directories as necessary */
702	>	hdsync(honly, 0); /* synchronize directories as necessary */
703	>	return(-freetarget); /* return how far past goal we went */
704		}
705
706
#	Line 586 \| Line 712 \| *register HOLO hp; /* NULL means clean up all /*
712		if (hp == NULL) { /* NULL means clean up everything */
713		while (hdlist[0] != NULL)
714		hddone(hdlist[0]);
715	+	free((char *)hdfragl);
716	+	hdfragl = NULL; nhdfragls = 0;
717		return;
718		}
719		/* flush all data and free memory */

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Comparing ray/src/hd/holofile.c (file contents): Revision 3.11 by gregl, Thu Dec 11 19:57:58 1997 UTC vs. Revision 3.24 by gwlarson, Tue Sep 15 14:26:23 1998 UTC

Diff Legend

Comparing ray/src/hd/holofile.c (file contents):
Revision 3.11 by gregl, Thu Dec 11 19:57:58 1997 UTC vs.
Revision 3.24 by gwlarson, Tue Sep 15 14:26:23 1998 UTC