src/hd/holofile.c

/* Copyright (c) 1997 Silicon Graphics, Inc. */

#ifndef lint
static char SCCSid[] = "$SunId$ SGI";
#endif

/*
 * Routines for managing holodeck files
 *
 *      9/30/97 GWLarson
 */

#include "holo.h"

#ifndef CACHESIZE
#define CACHESIZE       16      /* default cache size (Mbytes, 0==inf) */
#endif
#ifndef FREEBEAMS
#define FREEBEAMS       512     /* maximum beams to free at a time */
#endif
#ifndef PCTFREE
#define PCTFREE         20      /* maximum fraction to free (%) */
#endif

/* define MAXFRAG if you want to limit fragment tracking memory */

#ifndef BSD
#define write   writebuf        /* safe i/o routines */
#define read    readbuf
#endif

#define FRAGBLK         64      /* number of fragments to allocate at a time */

int     hdcachesize = CACHESIZE*1024*1024;      /* target cache size (bytes) */
unsigned long   hdclock;        /* clock value */

HOLO    *hdlist[HDMAX+1];       /* holodeck pointers (NULL term.) */

static struct fragment {
        short   nlinks;         /* number of holodeck sections using us */
        short   nfrags;         /* number of known fragments */
        BEAMI   *fi;            /* fragments, descending file position */
        long    flen;           /* last known file length */
} *hdfrag;              /* fragment lists, indexed by file descriptor */

static int      nhdfrags;       /* size of hdfrag array */


hdattach(fd)            /* start tracking file fragments for some section */
register int    fd;
{
        if (fd >= nhdfrags) {
                if (nhdfrags)
                        hdfrag = (struct fragment *)realloc((char *)hdfrag,
                                        (fd+1)*sizeof(struct fragment));
                else
                        hdfrag = (struct fragment *)malloc(
                                        (fd+1)*sizeof(struct fragment));
                if (hdfrag == NULL)
                        error(SYSTEM, "out of memory in hdattach");
                bzero((char *)(hdfrag+nhdfrags),
                                (fd+1-nhdfrags)*sizeof(struct fragment));
                nhdfrags = fd+1;
        }
        hdfrag[fd].nlinks++;
        hdfrag[fd].flen = lseek(fd, 0L, 2);     /* get file length */
}


/* Do we need a routine to locate file fragments given known occupants? */


hdrelease(fd)           /* stop tracking file fragments for some section */
register int    fd;
{
        if (fd < 0 | fd >= nhdfrags || !hdfrag[fd].nlinks)
                return;
        if (!--hdfrag[fd].nlinks && hdfrag[fd].nfrags) {
                free((char *)hdfrag[fd].fi);
                hdfrag[fd].fi = NULL;
                hdfrag[fd].nfrags = 0;
        }
}


markdirty(hp)                   /* mark holodeck section directory dirty */
register HOLO   *hp;
{
        static BEAMI    smudge = {0, -1};

        if (hp->dirty)          /* already marked? */
                return;
        hp->dirty = 1;
        if (lseek(hp->fd, biglob(hp)->fo+(nbeams(hp)-1)*sizeof(BEAMI), 0) < 0
                        || write(hp->fd, (char *)&smudge,
                                        sizeof(BEAMI)) != sizeof(BEAMI))
                error(SYSTEM, "seek/write error in markdirty");
}


HOLO *
hdinit(fd, hproto)      /* initialize a holodeck section in a file */
int     fd;                     /* corresponding file descriptor */
HDGRID  *hproto;                /* holodeck section grid */
{
        long    fpos;
        register HOLO   *hp;
        register int    n;
                                        /* prepare for system errors */
        errno = 0;
        if ((fpos = lseek(fd, 0L, 1)) < 0)
                error(SYSTEM, "cannot determine holodeck file position");
        if (hproto == NULL) {           /* assume we're loading it */
                HDGRID  hpr;
                                                /* load header */
                if (read(fd, (char *)&hpr, sizeof(HDGRID)) != sizeof(HDGRID))
                        error(SYSTEM, "cannot load holodeck header");
                                                /* allocate grid */
                if ((hp = hdalloc(&hpr)) == NULL)
                        goto memerr;
                                                /* load beam directory */
                n = nbeams(hp)*sizeof(BEAMI);
                if (read(fd, (char *)(hp->bi+1), n) != n)
                        error(SYSTEM, "failure loading holodeck directory");
                                                /* check that it's clean */
                if (hp->bi[nbeams(hp)].fo < 0)
                        error(USER, "dirty holodeck section");
        } else {                        /* assume we're creating it */
                if ((hp = hdalloc(hproto)) == NULL)
                        goto memerr;
                                                /* write header and skeleton */
                n = nbeams(hp)*sizeof(BEAMI);
                if (write(fd, (char *)hproto, sizeof(HDGRID)) !=
                                        sizeof(HDGRID) ||
                                write(fd, (char *)(hp->bi+1), n) != n)
                        error(SYSTEM, "cannot write header to holodeck file");
        }
        hp->fd = fd;    
        hp->dirty = 0;
        biglob(hp)->fo = fpos + sizeof(HDGRID);
        biglob(hp)->nrd = 0;            /* count rays on disk */
        for (n = nbeams(hp); n > 0; n--)
                biglob(hp)->nrd += hp->bi[n].nrd;
                                        /* add to holodeck list */
        for (n = 0; n < HDMAX; n++)
                if (hdlist[n] == NULL) {
                        hdlist[n] = hp;
                        break;
                }
                                        /* start tracking fragments (last) */
        hdattach(fd);
                                        /* all done */
        return(hp);
memerr:
        error(SYSTEM, "cannot allocate holodeck grid");
}


int
hdsync(hp)                      /* update directory on disk if necessary */
register HOLO   *hp;
{
        register int    j, n;

        if (hp == NULL) {               /* do all */
                n = 0;
                for (j = 0; hdlist[j] != NULL; j++)
                        n += hdsync(hdlist[j]);
                return(n);
        }
        if (!hp->dirty)                 /* check first */
                return(0);
        errno = 0;
        if (lseek(hp->fd, biglob(hp)->fo, 0) < 0)
                error(SYSTEM, "cannot seek on holodeck file");
        n = nbeams(hp)*sizeof(BEAMI);
        if (write(hp->fd, (char *)(hp->bi+1), n) != n)
                error(SYSTEM, "cannot update holodeck section directory");
        hp->dirty = 0;
        return(1);
}


long
hdmemuse(all)           /* return memory usage (in bytes) */
int     all;                    /* include overhead (painful) */
{
        long    total = 0;
        register int    i, j;

        for (j = 0; hdlist[j] != NULL; j++) {
                total += blglob(hdlist[j])->nrm * sizeof(RAYVAL);
                if (all) {
                        total += sizeof(HOLO) + sizeof(BEAM *) +
                                        nbeams(hdlist[j]) *
                                                (sizeof(BEAM *)+sizeof(BEAMI));
                        for (i = nbeams(hdlist[j]); i > 0; i--)
                                if (hdlist[j]->bl[i] != NULL)
                                        total += sizeof(BEAM);
                }
        }
        if (all)
                for (j = 0; j < nhdfrags; j++) {
                        total += sizeof(struct fragment);
                        if (hdfrag[j].nfrags)
                                total += FRAGBLK*sizeof(BEAMI) *
                                        ((hdfrag[j].nfrags-1)/FRAGBLK + 1) ;
                }
        return(total);
}


long
hdfilen(fd)             /* return file length for fd */
int     fd;
{
        long    fpos, flen;

        if (fd < 0)
                return(-1);
        if (fd >= nhdfrags || !hdfrag[fd].nlinks) {
                if ((fpos = lseek(fd, 0L, 1)) < 0)
                        return(-1);
                flen = lseek(fd, 0L, 2);
                lseek(fd, fpos, 0);
                return(flen);
        }
        return(hdfrag[fd].flen);
}


long
hdfiluse(fd, all)       /* compute file usage (in bytes) */
int     fd;                     /* open file descriptor to check */
int     all;                    /* include overhead and unflushed data */
{
        long    total = 0;
        register int    i, j;

        for (j = 0; hdlist[j] != NULL; j++) {
                if (hdlist[j]->fd != fd)
                        continue;
                total += biglob(hdlist[j])->nrd * sizeof(RAYVAL);
                if (all) {
                        for (i = nbeams(hdlist[j]); i > 0; i--)
                                if (hdlist[j]->bl[i] != NULL)
                                        total += sizeof(RAYVAL) *
                                                (hdlist[j]->bl[i]->nrm -
                                                hdlist[j]->bi[i].nrd);
                        total += sizeof(HDGRID) +
                                        nbeams(hdlist[j])*sizeof(BEAMI);
                }
        }
        return(total);          /* does not include fragments */
}


RAYVAL *
hdnewrays(hp, i, nr)    /* allocate space for add'l rays and return pointer */
register HOLO   *hp;
register int    i;
int     nr;                     /* number of new rays desired */
{
        RAYVAL  *p;
        int     n;

        if (nr <= 0)
                return(NULL);
        if (i < 1 | i > nbeams(hp))
                error(CONSISTENCY, "bad beam index given to hdnewrays");
        if (hp->bl[i] != NULL)
                hp->bl[i]->tick = hdclock;      /* preempt swap */
        if (hdcachesize > 0 && hdmemuse(0) >= hdcachesize)
                hdfreecache(PCTFREE, NULL);     /* free some space */
        errno = 0;
        if (hp->bl[i] == NULL) {                /* allocate (and load) */
                n = hp->bi[i].nrd + nr;
                if ((hp->bl[i] = (BEAM *)malloc(hdbsiz(n))) == NULL)
                        goto memerr;
                blglob(hp)->nrm += n;
                if (n = hp->bl[i]->nrm = hp->bi[i].nrd) {
                        if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
                                error(SYSTEM, "seek error on holodeck file");
                        n *= sizeof(RAYVAL);
                        if (read(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
                                error(SYSTEM,
                                "error reading beam from holodeck file");
                }
        } else {                                /* just grow in memory */
                hp->bl[i] = (BEAM *)realloc( (char *)hp->bl[i],
                                hdbsiz(hp->bl[i]->nrm + nr) );
                if (hp->bl[i] == NULL)
                        goto memerr;
                blglob(hp)->nrm += nr;
        }
        p = hdbray(hp->bl[i]) + hp->bl[i]->nrm;
        hp->bl[i]->nrm += nr;                   /* update in-core structure */
        bzero((char *)p, nr*sizeof(RAYVAL));
        hp->bl[i]->tick = ++hdclock;            /* update LRU clock */
        blglob(hp)->tick = hdclock;
        return(p);                              /* point to new rays */
memerr:
        error(SYSTEM, "out of memory in hdnewrays");
}


BEAM *
hdgetbeam(hp, i)        /* get beam (from file if necessary) */
register HOLO   *hp;
register int    i;
{
        register int    n;

        if (i < 1 | i > nbeams(hp))
                error(CONSISTENCY, "bad beam index given to hdgetbeam");
        if (hp->bl[i] == NULL) {                /* load from disk */
                if (!(n = hp->bi[i].nrd))
                        return(NULL);
                if (hdcachesize > 0 && hdmemuse(0) >= hdcachesize)
                        hdfreecache(PCTFREE, NULL);     /* get free space */
                errno = 0;
                if ((hp->bl[i] = (BEAM *)malloc(hdbsiz(n))) == NULL)
                        error(SYSTEM, "cannot allocate memory for beam");
                blglob(hp)->nrm += hp->bl[i]->nrm = n;
                if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
                        error(SYSTEM, "seek error on holodeck file");
                n *= sizeof(RAYVAL);
                if (read(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
                        error(SYSTEM, "error reading beam from holodeck file");
        }
        hp->bl[i]->tick = ++hdclock;    /* update LRU clock */
        blglob(hp)->tick = hdclock;
        return(hp->bl[i]);
}


int
hdgetbi(hp, i)                  /* allocate a file fragment */
register HOLO   *hp;
register int    i;
{
        int     nrays = hp->bl[i]->nrm;

        if (hp->bi[i].nrd == nrays)     /* current one will do? */
                return(0);

        if (hp->fd >= nhdfrags || !hdfrag[hp->fd].nlinks) /* untracked */
                hp->bi[i].fo = lseek(hp->fd, 0L, 2);

        else if (hp->bi[i].fo + hp->bi[i].nrd*sizeof(RAYVAL) ==
                        hdfrag[hp->fd].flen)            /* EOF special case */
                hdfrag[hp->fd].flen = hp->bi[i].fo + nrays*sizeof(RAYVAL);

        else {                                          /* general case */
                register struct fragment        *f = &hdfrag[hp->fd];
                register int    j, k;
                                        /* relinquish old fragment */
                if (hp->bi[i].nrd) {
                        j = f->nfrags++;
#ifdef MAXFRAG
                        if (j >= MAXFRAG-1)
                                f->nfrags--;
#endif
                        if (j % FRAGBLK == 0) {         /* more frag. space */
                                if (f->fi == NULL)
                                        f->fi = (BEAMI *)malloc(
                                                        FRAGBLK*sizeof(BEAMI));
                                else
                                        f->fi = (BEAMI *)realloc((char *)f->fi,
                                                (j+FRAGBLK)*sizeof(BEAMI));
                                if (f->fi == NULL)
                                        error(SYSTEM,
                                                "out of memory in hdgetbi");
                        }
                        for ( ; ; j--) {        /* insert in descending list */
                                if (!j || hp->bi[i].fo < f->fi[j-1].fo) {
                                        f->fi[j].fo = hp->bi[i].fo;
                                        f->fi[j].nrd = hp->bi[i].nrd;
                                        break;
                                }
                                copystruct(f->fi+j, f->fi+j-1);
                        }
                                        /* coalesce adjacent fragments */
                        for (j = k = 0; k < f->nfrags; j++, k++) {
                                if (k > j)
                                        copystruct(f->fi+j, f->fi+k);
                                while (k+1 < f->nfrags && f->fi[k+1].fo +
                                                f->fi[k+1].nrd*sizeof(RAYVAL)
                                                        == f->fi[j].fo) {
                                        f->fi[j].fo -=
                                                f->fi[++k].nrd*sizeof(RAYVAL);
                                        f->fi[j].nrd += f->fi[k].nrd;
                                }
                        }
                        f->nfrags = j;
                }
                k = -1;                 /* find closest-sized fragment */
                for (j = f->nfrags; j-- > 0; )
                        if (f->fi[j].nrd >= nrays &&
                                        (k < 0 || f->fi[j].nrd < f->fi[k].nrd))
                                if (f->fi[k=j].nrd == nrays)
                                        break;
                if (k < 0) {            /* no fragment -- extend file */
                        hp->bi[i].fo = f->flen;
                        f->flen += nrays*sizeof(RAYVAL);
                } else {                /* else use fragment */
                        hp->bi[i].fo = f->fi[k].fo;
                        if (f->fi[k].nrd == nrays) {    /* delete fragment */
                                f->nfrags--;
                                for (j = k; j < f->nfrags; j++)
                                        copystruct(f->fi+j, f->fi+j+1);
                        } else {                        /* else shrink it */
                                f->fi[k].fo += nrays*sizeof(RAYVAL);
                                f->fi[k].nrd -= nrays;
                        }
                }
        }
        biglob(hp)->nrd += nrays - hp->bi[i].nrd;
        hp->bi[i].nrd = nrays;
        markdirty(hp);          /* section directory now out of date */
        return(1);
}


int
hdfreebeam(hp, i)               /* free beam, writing if dirty */
register HOLO   *hp;
register int    i;
{
        int     nchanged, n;

        if (hp == NULL) {               /* clear all holodecks */
                nchanged = 0;
                for (i = 0; hdlist[i] != NULL; i++)
                        nchanged += hdfreebeam(hdlist[i], 0);
                return(nchanged);
        }
        if (i == 0) {                   /* clear entire holodeck */
                nchanged = 0;
                for (i = 1; i <= nbeams(hp); i++)
                        nchanged += hdfreebeam(hp, i);
                return(nchanged);
        }
        if (i < 1 | i > nbeams(hp))
                error(CONSISTENCY, "bad beam index to hdfreebeam");
        if (hp->bl[i] == NULL)
                return(0);
                                        /* check for additions */
        nchanged = hp->bl[i]->nrm - hp->bi[i].nrd;
        if (nchanged) {
                hdgetbi(hp, i);                 /* allocate a file position */
                errno = 0;
                if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
                        error(SYSTEM, "cannot seek on holodeck file");
                n = hp->bl[i]->nrm * sizeof(RAYVAL);
                if (write(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
                        error(SYSTEM, "write error in hdfreebeam");
        }
        blglob(hp)->nrm -= hp->bl[i]->nrm;
        free((char *)hp->bl[i]);                /* free memory */
        hp->bl[i] = NULL;
        return(nchanged);
}


hdlrulist(ha, ba, n, hp)        /* add beams from holodeck to LRU list */
register HOLO   *ha[];                  /* section list (NULL terminated) */
register int    ba[];                   /* beam index to go with section */
int     n;                              /* length of arrays minus 1 */
register HOLO   *hp;                    /* section we're adding from */
{
        register int    i, j;
        int     nents;
                                        /* find last entry in LRU list */
        for (j = 0; ha[j] != NULL; j++)
                ;
        nents = j;
                                        /* insert each beam from hp */
        for (i = nbeams(hp); i > 0; i-- ) {
                if (hp->bl[i] == NULL)          /* check if loaded */
                        continue;
                if ((j = ++nents) > n)          /* grow list if we can */
                        nents--;
                for ( ; ; ) {                   /* bubble into place */
                        if (!--j || hp->bl[i]->tick >=
                                        ha[j-1]->bl[ba[j-1]]->tick) {
                                ha[j] = hp;
                                ba[j] = i;
                                break;
                        }
                        ha[j] = ha[j-1];
                        ba[j] = ba[j-1];
                }
        }
        ha[nents] = NULL;               /* all done */
        ba[nents] = 0;
}


hdfreecache(pct, honly)         /* free up cache space, writing changes */
int     pct;                            /* maximum percentage to free */
register HOLO   *honly;                 /* NULL means check all */
{
        HOLO    *hp[FREEBEAMS+1];
        int     bn[FREEBEAMS+1];
        int     freetarget;
        register int    i;
                                                /* compute free target */
        freetarget = (honly != NULL) ? blglob(honly)->nrm :
                        hdmemuse(0)/sizeof(RAYVAL) ;
        freetarget = freetarget*pct/100;
                                                /* find least recently used */
        hp[0] = NULL;
        bn[0] = 0;
        if (honly != NULL)
                hdlrulist(hp, bn, FREEBEAMS, honly);
        else
                for (i = 0; hdlist[i] != NULL; i++)
                        hdlrulist(hp, bn, FREEBEAMS, hdlist[i]);
                                                /* free LRU beams */
        for (i = 0; hp[i] != NULL; i++) {
                hdfreebeam(hp[i], bn[i]);
                if ((freetarget -= hp[i]->bi[bn[i]].nrd) <= 0)
                        break;
        }
        hdsync(honly);          /* synchronize directories as necessary */
}


hddone(hp)              /* clean up holodeck section and free */
register HOLO   *hp;            /* NULL means clean up all */
{
        register int    i;

        if (hp == NULL) {               /* NULL means clean up everything */
                while (hdlist[0] != NULL)
                        hddone(hdlist[0]);
                return;
        }
                                        /* flush all data and free memory */
        hdflush(hp);
                                        /* release fragment resources */
        hdrelease(hp->fd);
                                        /* remove hp from active list */
        for (i = 0; hdlist[i] != NULL; i++)
                if (hdlist[i] == hp) {
                        while ((hdlist[i] = hdlist[i+1]) != NULL)
                                i++;
                        break;
                }
        free((char *)hp->bl);           /* free beam list */
        free((char *)hp);               /* free holodeck struct */
}
Revision:	3.8
Committed:	Tue Nov 11 11:31:54 1997 UTC (27 years, 11 months ago) by gregl
Content type:	text/plain
Branch:	MAIN
Changes since 3.7:	+20 -1 lines
Log Message:	made file length testing more efficient
#	User	Rev	Content
1	gregl	3.1	/* Copyright (c) 1997 Silicon Graphics, Inc. */
2
3			#ifndef lint
4			static char SCCSid[] = "$SunId$ SGI";
5			#endif
6
7			/*
8			* Routines for managing holodeck files
9			*
10			* 9/30/97 GWLarson
11			*/
12
13			#include "holo.h"
14
15			#ifndef CACHESIZE
16			#define CACHESIZE 16 /* default cache size (Mbytes, 0==inf) */
17			#endif
18			#ifndef FREEBEAMS
19	gregl	3.5	#define FREEBEAMS 512 /* maximum beams to free at a time */
20	gregl	3.1	#endif
21			#ifndef PCTFREE
22	gregl	3.5	#define PCTFREE 20 /* maximum fraction to free (%) */
23	gregl	3.1	#endif
24
25	gregl	3.7	/* define MAXFRAG if you want to limit fragment tracking memory */
26
27	gregl	3.6	#ifndef BSD
28			#define write writebuf /* safe i/o routines */
29			#define read readbuf
30			#endif
31	gregl	3.4
32			#define FRAGBLK 64 /* number of fragments to allocate at a time */
33
34	gregl	3.1	int hdcachesize = CACHESIZE10241024; /* target cache size (bytes) */
35			unsigned long hdclock; /* clock value */
36
37			HOLO hdlist[HDMAX+1]; / holodeck pointers (NULL term.) */
38
39			static struct fragment {
40			short nlinks; /* number of holodeck sections using us */
41			short nfrags; /* number of known fragments */
42	gregl	3.4	BEAMI fi; / fragments, descending file position */
43	gregl	3.1	long flen; /* last known file length */
44	gregl	3.4	} hdfrag; / fragment lists, indexed by file descriptor */
45	gregl	3.1
46	gregl	3.4	static int nhdfrags; /* size of hdfrag array */
47	gregl	3.1
48	gregl	3.4
49	gregl	3.1	hdattach(fd) /* start tracking file fragments for some section */
50			register int fd;
51			{
52	gregl	3.4	if (fd >= nhdfrags) {
53			if (nhdfrags)
54			hdfrag = (struct fragment )realloc((char )hdfrag,
55			(fd+1)*sizeof(struct fragment));
56			else
57			hdfrag = (struct fragment *)malloc(
58			(fd+1)*sizeof(struct fragment));
59			if (hdfrag == NULL)
60			error(SYSTEM, "out of memory in hdattach");
61			bzero((char *)(hdfrag+nhdfrags),
62			(fd+1-nhdfrags)*sizeof(struct fragment));
63			nhdfrags = fd+1;
64	gregl	3.1	}
65	gregl	3.4	hdfrag[fd].nlinks++;
66			hdfrag[fd].flen = lseek(fd, 0L, 2); /* get file length */
67	gregl	3.1	}
68
69
70			/* Do we need a routine to locate file fragments given known occupants? */
71
72
73			hdrelease(fd) /* stop tracking file fragments for some section */
74			register int fd;
75			{
76	gregl	3.8	if (fd < 0 \| fd >= nhdfrags \|\| !hdfrag[fd].nlinks)
77	gregl	3.1	return;
78	gregl	3.4	if (!--hdfrag[fd].nlinks && hdfrag[fd].nfrags) {
79			free((char *)hdfrag[fd].fi);
80			hdfrag[fd].fi = NULL;
81			hdfrag[fd].nfrags = 0;
82	gregl	3.1	}
83			}
84
85
86	gregl	3.6	markdirty(hp) /* mark holodeck section directory dirty */
87			register HOLO *hp;
88			{
89			static BEAMI smudge = {0, -1};
90
91			if (hp->dirty) /* already marked? */
92			return;
93			hp->dirty = 1;
94			if (lseek(hp->fd, biglob(hp)->fo+(nbeams(hp)-1)*sizeof(BEAMI), 0) < 0
95			\|\| write(hp->fd, (char *)&smudge,
96			sizeof(BEAMI)) != sizeof(BEAMI))
97			error(SYSTEM, "seek/write error in markdirty");
98			}
99
100
101	gregl	3.1	HOLO *
102			hdinit(fd, hproto) /* initialize a holodeck section in a file */
103			int fd; /* corresponding file descriptor */
104			HDGRID hproto; / holodeck section grid */
105			{
106			long fpos;
107			register HOLO *hp;
108			register int n;
109			/* prepare for system errors */
110			errno = 0;
111			if ((fpos = lseek(fd, 0L, 1)) < 0)
112			error(SYSTEM, "cannot determine holodeck file position");
113			if (hproto == NULL) { /* assume we're loading it */
114			HDGRID hpr;
115			/* load header */
116			if (read(fd, (char *)&hpr, sizeof(HDGRID)) != sizeof(HDGRID))
117			error(SYSTEM, "cannot load holodeck header");
118			/* allocate grid */
119			if ((hp = hdalloc(&hpr)) == NULL)
120			goto memerr;
121			/* load beam directory */
122			n = nbeams(hp)*sizeof(BEAMI);
123			if (read(fd, (char *)(hp->bi+1), n) != n)
124			error(SYSTEM, "failure loading holodeck directory");
125	gregl	3.6	/* check that it's clean */
126			if (hp->bi[nbeams(hp)].fo < 0)
127			error(USER, "dirty holodeck section");
128	gregl	3.1	} else { /* assume we're creating it */
129			if ((hp = hdalloc(hproto)) == NULL)
130			goto memerr;
131			/* write header and skeleton */
132			n = nbeams(hp)*sizeof(BEAMI);
133			if (write(fd, (char *)hproto, sizeof(HDGRID)) !=
134			sizeof(HDGRID) \|\|
135			write(fd, (char *)(hp->bi+1), n) != n)
136			error(SYSTEM, "cannot write header to holodeck file");
137			}
138			hp->fd = fd;
139			hp->dirty = 0;
140			biglob(hp)->fo = fpos + sizeof(HDGRID);
141			biglob(hp)->nrd = 0; /* count rays on disk */
142			for (n = nbeams(hp); n > 0; n--)
143			biglob(hp)->nrd += hp->bi[n].nrd;
144			/* add to holodeck list */
145			for (n = 0; n < HDMAX; n++)
146			if (hdlist[n] == NULL) {
147			hdlist[n] = hp;
148			break;
149			}
150			/* start tracking fragments (last) */
151			hdattach(fd);
152			/* all done */
153			return(hp);
154			memerr:
155			error(SYSTEM, "cannot allocate holodeck grid");
156			}
157
158
159			int
160			hdsync(hp) /* update directory on disk if necessary */
161			register HOLO *hp;
162			{
163			register int j, n;
164
165			if (hp == NULL) { /* do all */
166			n = 0;
167			for (j = 0; hdlist[j] != NULL; j++)
168			n += hdsync(hdlist[j]);
169			return(n);
170			}
171			if (!hp->dirty) /* check first */
172			return(0);
173	gregl	3.3	errno = 0;
174	gregl	3.1	if (lseek(hp->fd, biglob(hp)->fo, 0) < 0)
175			error(SYSTEM, "cannot seek on holodeck file");
176			n = nbeams(hp)*sizeof(BEAMI);
177			if (write(hp->fd, (char *)(hp->bi+1), n) != n)
178			error(SYSTEM, "cannot update holodeck section directory");
179			hp->dirty = 0;
180			return(1);
181			}
182
183
184			long
185			hdmemuse(all) /* return memory usage (in bytes) */
186			int all; /* include overhead (painful) */
187			{
188			long total = 0;
189			register int i, j;
190
191			for (j = 0; hdlist[j] != NULL; j++) {
192			total += blglob(hdlist[j])->nrm * sizeof(RAYVAL);
193			if (all) {
194			total += sizeof(HOLO) + sizeof(BEAM *) +
195			nbeams(hdlist[j]) *
196			(sizeof(BEAM *)+sizeof(BEAMI));
197			for (i = nbeams(hdlist[j]); i > 0; i--)
198			if (hdlist[j]->bl[i] != NULL)
199			total += sizeof(BEAM);
200			}
201			}
202			if (all)
203	gregl	3.4	for (j = 0; j < nhdfrags; j++) {
204			total += sizeof(struct fragment);
205			if (hdfrag[j].nfrags)
206			total += FRAGBLKsizeof(BEAMI)
207			((hdfrag[j].nfrags-1)/FRAGBLK + 1) ;
208			}
209	gregl	3.1	return(total);
210	gregl	3.8	}
211
212
213			long
214			hdfilen(fd) /* return file length for fd */
215			int fd;
216			{
217			long fpos, flen;
218
219			if (fd < 0)
220			return(-1);
221			if (fd >= nhdfrags \|\| !hdfrag[fd].nlinks) {
222			if ((fpos = lseek(fd, 0L, 1)) < 0)
223			return(-1);
224			flen = lseek(fd, 0L, 2);
225			lseek(fd, fpos, 0);
226			return(flen);
227			}
228			return(hdfrag[fd].flen);
229	gregl	3.1	}
230
231
232			long
233			hdfiluse(fd, all) /* compute file usage (in bytes) */
234			int fd; /* open file descriptor to check */
235			int all; /* include overhead and unflushed data */
236			{
237			long total = 0;
238			register int i, j;
239
240			for (j = 0; hdlist[j] != NULL; j++) {
241			if (hdlist[j]->fd != fd)
242			continue;
243			total += biglob(hdlist[j])->nrd * sizeof(RAYVAL);
244			if (all) {
245			for (i = nbeams(hdlist[j]); i > 0; i--)
246			if (hdlist[j]->bl[i] != NULL)
247			total += sizeof(RAYVAL) *
248			(hdlist[j]->bl[i]->nrm -
249			hdlist[j]->bi[i].nrd);
250			total += sizeof(HDGRID) +
251			nbeams(hdlist[j])*sizeof(BEAMI);
252			}
253			}
254			return(total); /* does not include fragments */
255			}
256
257
258			RAYVAL *
259			hdnewrays(hp, i, nr) /* allocate space for add'l rays and return pointer */
260			register HOLO *hp;
261			register int i;
262			int nr; /* number of new rays desired */
263			{
264			RAYVAL *p;
265			int n;
266
267			if (nr <= 0)
268			return(NULL);
269			if (i < 1 \| i > nbeams(hp))
270			error(CONSISTENCY, "bad beam index given to hdnewrays");
271			if (hp->bl[i] != NULL)
272			hp->bl[i]->tick = hdclock; /* preempt swap */
273			if (hdcachesize > 0 && hdmemuse(0) >= hdcachesize)
274			hdfreecache(PCTFREE, NULL); /* free some space */
275	gregl	3.3	errno = 0;
276	gregl	3.1	if (hp->bl[i] == NULL) { /* allocate (and load) */
277			n = hp->bi[i].nrd + nr;
278			if ((hp->bl[i] = (BEAM *)malloc(hdbsiz(n))) == NULL)
279			goto memerr;
280			blglob(hp)->nrm += n;
281			if (n = hp->bl[i]->nrm = hp->bi[i].nrd) {
282			if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
283			error(SYSTEM, "seek error on holodeck file");
284			n *= sizeof(RAYVAL);
285			if (read(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
286			error(SYSTEM,
287			"error reading beam from holodeck file");
288			}
289			} else { /* just grow in memory */
290			hp->bl[i] = (BEAM )realloc( (char )hp->bl[i],
291			hdbsiz(hp->bl[i]->nrm + nr) );
292			if (hp->bl[i] == NULL)
293			goto memerr;
294			blglob(hp)->nrm += nr;
295			}
296			p = hdbray(hp->bl[i]) + hp->bl[i]->nrm;
297			hp->bl[i]->nrm += nr; /* update in-core structure */
298			bzero((char )p, nrsizeof(RAYVAL));
299			hp->bl[i]->tick = ++hdclock; /* update LRU clock */
300			blglob(hp)->tick = hdclock;
301			return(p); /* point to new rays */
302			memerr:
303			error(SYSTEM, "out of memory in hdnewrays");
304			}
305
306
307			BEAM *
308			hdgetbeam(hp, i) /* get beam (from file if necessary) */
309			register HOLO *hp;
310			register int i;
311			{
312			register int n;
313
314			if (i < 1 \| i > nbeams(hp))
315			error(CONSISTENCY, "bad beam index given to hdgetbeam");
316			if (hp->bl[i] == NULL) { /* load from disk */
317			if (!(n = hp->bi[i].nrd))
318			return(NULL);
319			if (hdcachesize > 0 && hdmemuse(0) >= hdcachesize)
320			hdfreecache(PCTFREE, NULL); /* get free space */
321			errno = 0;
322			if ((hp->bl[i] = (BEAM *)malloc(hdbsiz(n))) == NULL)
323			error(SYSTEM, "cannot allocate memory for beam");
324			blglob(hp)->nrm += hp->bl[i]->nrm = n;
325			if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
326			error(SYSTEM, "seek error on holodeck file");
327			n *= sizeof(RAYVAL);
328			if (read(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
329			error(SYSTEM, "error reading beam from holodeck file");
330			}
331			hp->bl[i]->tick = ++hdclock; /* update LRU clock */
332			blglob(hp)->tick = hdclock;
333			return(hp->bl[i]);
334			}
335
336
337			int
338			hdgetbi(hp, i) /* allocate a file fragment */
339			register HOLO *hp;
340			register int i;
341			{
342			int nrays = hp->bl[i]->nrm;
343
344			if (hp->bi[i].nrd == nrays) /* current one will do? */
345			return(0);
346
347	gregl	3.4	if (hp->fd >= nhdfrags \|\| !hdfrag[hp->fd].nlinks) /* untracked */
348	gregl	3.1	hp->bi[i].fo = lseek(hp->fd, 0L, 2);
349
350			else if (hp->bi[i].fo + hp->bi[i].nrd*sizeof(RAYVAL) ==
351	gregl	3.4	hdfrag[hp->fd].flen) /* EOF special case */
352			hdfrag[hp->fd].flen = hp->bi[i].fo + nrays*sizeof(RAYVAL);
353	gregl	3.1
354			else { /* general case */
355	gregl	3.4	register struct fragment *f = &hdfrag[hp->fd];
356	gregl	3.1	register int j, k;
357			/* relinquish old fragment */
358	gregl	3.2	if (hp->bi[i].nrd) {
359	gregl	3.5	j = f->nfrags++;
360	gregl	3.4	#ifdef MAXFRAG
361	gregl	3.5	if (j >= MAXFRAG-1)
362	gregl	3.2	f->nfrags--;
363	gregl	3.4	#endif
364	gregl	3.5	if (j % FRAGBLK == 0) { /* more frag. space */
365	gregl	3.4	if (f->fi == NULL)
366			f->fi = (BEAMI *)malloc(
367			FRAGBLK*sizeof(BEAMI));
368			else
369			f->fi = (BEAMI )realloc((char )f->fi,
370	gregl	3.5	(j+FRAGBLK)*sizeof(BEAMI));
371	gregl	3.4	if (f->fi == NULL)
372			error(SYSTEM,
373			"out of memory in hdgetbi");
374			}
375	gregl	3.5	for ( ; ; j--) { /* insert in descending list */
376			if (!j \|\| hp->bi[i].fo < f->fi[j-1].fo) {
377	gregl	3.2	f->fi[j].fo = hp->bi[i].fo;
378			f->fi[j].nrd = hp->bi[i].nrd;
379			break;
380			}
381			copystruct(f->fi+j, f->fi+j-1);
382	gregl	3.1	}
383			/* coalesce adjacent fragments */
384	gregl	3.2	for (j = k = 0; k < f->nfrags; j++, k++) {
385	gregl	3.3	if (k > j)
386	gregl	3.2	copystruct(f->fi+j, f->fi+k);
387	gregl	3.3	while (k+1 < f->nfrags && f->fi[k+1].fo +
388			f->fi[k+1].nrd*sizeof(RAYVAL)
389			== f->fi[j].fo) {
390	gregl	3.2	f->fi[j].fo -=
391			f->fi[++k].nrd*sizeof(RAYVAL);
392	gregl	3.3	f->fi[j].nrd += f->fi[k].nrd;
393			}
394	gregl	3.2	}
395			f->nfrags = j;
396	gregl	3.1	}
397			k = -1; /* find closest-sized fragment */
398			for (j = f->nfrags; j-- > 0; )
399			if (f->fi[j].nrd >= nrays &&
400	gregl	3.3	(k < 0 \|\| f->fi[j].nrd < f->fi[k].nrd))
401			if (f->fi[k=j].nrd == nrays)
402			break;
403	gregl	3.1	if (k < 0) { /* no fragment -- extend file */
404			hp->bi[i].fo = f->flen;
405			f->flen += nrays*sizeof(RAYVAL);
406			} else { /* else use fragment */
407			hp->bi[i].fo = f->fi[k].fo;
408			if (f->fi[k].nrd == nrays) { /* delete fragment */
409			f->nfrags--;
410			for (j = k; j < f->nfrags; j++)
411			copystruct(f->fi+j, f->fi+j+1);
412			} else { /* else shrink it */
413			f->fi[k].fo += nrays*sizeof(RAYVAL);
414			f->fi[k].nrd -= nrays;
415			}
416			}
417			}
418			biglob(hp)->nrd += nrays - hp->bi[i].nrd;
419			hp->bi[i].nrd = nrays;
420	gregl	3.6	markdirty(hp); /* section directory now out of date */
421	gregl	3.1	return(1);
422			}
423
424
425			int
426			hdfreebeam(hp, i) /* free beam, writing if dirty */
427			register HOLO *hp;
428			register int i;
429			{
430			int nchanged, n;
431
432			if (hp == NULL) { /* clear all holodecks */
433			nchanged = 0;
434			for (i = 0; hdlist[i] != NULL; i++)
435			nchanged += hdfreebeam(hdlist[i], 0);
436			return(nchanged);
437			}
438			if (i == 0) { /* clear entire holodeck */
439			nchanged = 0;
440			for (i = 1; i <= nbeams(hp); i++)
441			nchanged += hdfreebeam(hp, i);
442			return(nchanged);
443			}
444			if (i < 1 \| i > nbeams(hp))
445			error(CONSISTENCY, "bad beam index to hdfreebeam");
446			if (hp->bl[i] == NULL)
447			return(0);
448			/* check for additions */
449			nchanged = hp->bl[i]->nrm - hp->bi[i].nrd;
450			if (nchanged) {
451			hdgetbi(hp, i); /* allocate a file position */
452			errno = 0;
453			if (lseek(hp->fd, hp->bi[i].fo, 0) < 0)
454			error(SYSTEM, "cannot seek on holodeck file");
455			n = hp->bl[i]->nrm * sizeof(RAYVAL);
456			if (write(hp->fd, (char *)hdbray(hp->bl[i]), n) != n)
457			error(SYSTEM, "write error in hdfreebeam");
458			}
459			blglob(hp)->nrm -= hp->bl[i]->nrm;
460			free((char )hp->bl[i]); / free memory */
461			hp->bl[i] = NULL;
462			return(nchanged);
463			}
464
465
466			hdlrulist(ha, ba, n, hp) /* add beams from holodeck to LRU list */
467			register HOLO ha[]; / section list (NULL terminated) */
468			register int ba[]; /* beam index to go with section */
469			int n; /* length of arrays minus 1 */
470			register HOLO hp; / section we're adding from */
471			{
472			register int i, j;
473			int nents;
474			/* find last entry in LRU list */
475			for (j = 0; ha[j] != NULL; j++)
476			;
477			nents = j;
478			/* insert each beam from hp */
479			for (i = nbeams(hp); i > 0; i-- ) {
480			if (hp->bl[i] == NULL) /* check if loaded */
481			continue;
482			if ((j = ++nents) > n) /* grow list if we can */
483			nents--;
484			for ( ; ; ) { /* bubble into place */
485			if (!--j \|\| hp->bl[i]->tick >=
486			ha[j-1]->bl[ba[j-1]]->tick) {
487			ha[j] = hp;
488			ba[j] = i;
489			break;
490			}
491			ha[j] = ha[j-1];
492			ba[j] = ba[j-1];
493			}
494			}
495			ha[nents] = NULL; /* all done */
496			ba[nents] = 0;
497			}
498
499
500			hdfreecache(pct, honly) /* free up cache space, writing changes */
501			int pct; /* maximum percentage to free */
502			register HOLO honly; / NULL means check all */
503			{
504			HOLO *hp[FREEBEAMS+1];
505			int bn[FREEBEAMS+1];
506			int freetarget;
507			register int i;
508			/* compute free target */
509			freetarget = (honly != NULL) ? blglob(honly)->nrm :
510			hdmemuse(0)/sizeof(RAYVAL) ;
511			freetarget = freetarget*pct/100;
512			/* find least recently used */
513			hp[0] = NULL;
514			bn[0] = 0;
515			if (honly != NULL)
516			hdlrulist(hp, bn, FREEBEAMS, honly);
517			else
518			for (i = 0; hdlist[i] != NULL; i++)
519			hdlrulist(hp, bn, FREEBEAMS, hdlist[i]);
520			/* free LRU beams */
521			for (i = 0; hp[i] != NULL; i++) {
522			hdfreebeam(hp[i], bn[i]);
523			if ((freetarget -= hp[i]->bi[bn[i]].nrd) <= 0)
524			break;
525			}
526			hdsync(honly); /* synchronize directories as necessary */
527			}
528
529
530			hddone(hp) /* clean up holodeck section and free */
531			register HOLO hp; / NULL means clean up all */
532			{
533			register int i;
534
535			if (hp == NULL) { /* NULL means clean up everything */
536			while (hdlist[0] != NULL)
537			hddone(hdlist[0]);
538			return;
539			}
540			/* flush all data and free memory */
541			hdflush(hp);
542			/* release fragment resources */
543			hdrelease(hp->fd);
544			/* remove hp from active list */
545			for (i = 0; hdlist[i] != NULL; i++)
546			if (hdlist[i] == hp) {
547			while ((hdlist[i] = hdlist[i+1]) != NULL)
548			i++;
549			break;
550			}
551			free((char )hp->bl); / free beam list */
552			free((char )hp); / free holodeck struct */
553			}