V7M/sys/sys/alloc.c
#include "../h/param.h"
#include "../h/systm.h"
#include "../h/mount.h"
#include "../h/filsys.h"
#include "../h/fblk.h"
#include "../h/conf.h"
#include "../h/buf.h"
#include "../h/inode.h"
#include "../h/ino.h"
#include "../h/dir.h"
#include "../h/user.h"
typedef struct fblk *FBLKP;
/*
* alloc will obtain the next available
* free disk block from the free list of
* the specified device.
* The super block has up to NICFREE remembered
* free blocks; the last of these is read to
* obtain NICFREE more . . .
*
* no space on dev x/y -- when
* the free list is exhausted.
*/
struct buf *
alloc(dev)
dev_t dev;
{
daddr_t bno;
register struct filsys *fp;
register struct buf *bp;
fp = getfs(dev);
while(fp->s_flock)
sleep((caddr_t)&fp->s_flock, PINOD);
do {
if(fp->s_nfree <= 0)
goto nospace;
if (fp->s_nfree > NICFREE) {
prdev("Bad free count", dev);
goto nospace;
}
bno = fp->s_free[--fp->s_nfree];
if(bno == 0)
goto nospace;
} while (badblock(fp, bno, dev));
if(fp->s_nfree <= 0) {
fp->s_flock++;
bp = bread(dev, bno);
if ((bp->b_flags&B_ERROR) == 0) {
fp->s_nfree = ((FBLKP)(bp->b_un.b_addr))->df_nfree;
bcopy((caddr_t)((FBLKP)(bp->b_un.b_addr))->df_free,
(caddr_t)fp->s_free, sizeof(fp->s_free));
}
brelse(bp);
fp->s_flock = 0;
wakeup((caddr_t)&fp->s_flock);
if (fp->s_nfree <=0)
goto nospace;
}
bp = getblk(dev, bno);
clrbuf(bp);
fp->s_fmod = 1;
return(bp);
nospace:
fp->s_nfree = 0;
prdev("no space", dev);
u.u_error = ENOSPC;
return(NULL);
}
/*
* place the specified disk block
* back on the free list of the
* specified device.
*/
free(dev, bno)
dev_t dev;
daddr_t bno;
{
register struct filsys *fp;
register struct buf *bp;
fp = getfs(dev);
fp->s_fmod = 1;
while(fp->s_flock)
sleep((caddr_t)&fp->s_flock, PINOD);
if (badblock(fp, bno, dev))
return;
if(fp->s_nfree <= 0) {
fp->s_nfree = 1;
fp->s_free[0] = 0;
}
if(fp->s_nfree >= NICFREE) {
fp->s_flock++;
bp = getblk(dev, bno);
((FBLKP)(bp->b_un.b_addr))->df_nfree = fp->s_nfree;
bcopy((caddr_t)fp->s_free,
(caddr_t)((FBLKP)(bp->b_un.b_addr))->df_free,
sizeof(fp->s_free));
fp->s_nfree = 0;
bwrite(bp);
fp->s_flock = 0;
wakeup((caddr_t)&fp->s_flock);
}
fp->s_free[fp->s_nfree++] = bno;
fp->s_fmod = 1;
}
/*
* Check that a block number is in the
* range between the I list and the size
* of the device.
* This is used mainly to check that a
* garbage file system has not been mounted.
*
* bad block on dev x/y -- not in range
*/
badblock(fp, bn, dev)
register struct filsys *fp;
daddr_t bn;
dev_t dev;
{
if (bn < fp->s_isize || bn >= fp->s_fsize) {
prdev("bad block", dev);
return(1);
}
return(0);
}
/*
* Allocate an unused I node
* on the specified device.
* Used with file creation.
* The algorithm keeps up to
* NICINOD spare I nodes in the
* super block. When this runs out,
* a linear search through the
* I list is instituted to pick
* up NICINOD more.
*/
struct inode *
ialloc(dev)
dev_t dev;
{
register struct filsys *fp;
register struct buf *bp;
register struct inode *ip;
int i;
struct dinode *dp;
ino_t ino;
daddr_t adr;
fp = getfs(dev);
while(fp->s_ilock)
sleep((caddr_t)&fp->s_ilock, PINOD);
loop:
if(fp->s_ninode > 0) {
ino = fp->s_inode[--fp->s_ninode];
if (ino < ROOTINO)
goto loop;
ip = iget(dev, ino);
if(ip == NULL)
return(NULL);
if(ip->i_mode == 0) {
for (i=0; i<NADDR; i++)
ip->i_un.i_addr[i] = 0;
fp->s_fmod = 1;
return(ip);
}
/*
* Inode was allocated after all.
* Look some more.
*/
iput(ip);
goto loop;
}
fp->s_ilock++;
ino = 1;
for(adr = SUPERB+1; adr < fp->s_isize; adr++) {
bp = bread(dev, adr);
if (bp->b_flags & B_ERROR) {
brelse(bp);
ino += INOPB;
continue;
}
dp = bp->b_un.b_dino;
for(i=0; i<INOPB; i++) {
if(dp->di_mode != 0)
goto cont;
for(ip = &inode[0]; ip < &inode[NINODE]; ip++)
if(dev==ip->i_dev && ino==ip->i_number)
goto cont;
fp->s_inode[fp->s_ninode++] = ino;
if(fp->s_ninode >= NICINOD)
break;
cont:
ino++;
dp++;
}
brelse(bp);
if(fp->s_ninode >= NICINOD)
break;
}
fp->s_ilock = 0;
wakeup((caddr_t)&fp->s_ilock);
if(fp->s_ninode > 0)
goto loop;
prdev("Out of inodes", dev);
u.u_error = ENOSPC;
return(NULL);
}
/*
* Free the specified I node
* on the specified device.
* The algorithm stores up
* to NICINOD I nodes in the super
* block and throws away any more.
*/
ifree(dev, ino)
dev_t dev;
ino_t ino;
{
register struct filsys *fp;
fp = getfs(dev);
if(fp->s_ilock)
return;
if(fp->s_ninode >= NICINOD)
return;
fp->s_inode[fp->s_ninode++] = ino;
fp->s_fmod = 1;
}
/*
* getfs maps a device number into
* a pointer to the incore super
* block.
* The algorithm is a linear
* search through the mount table.
* A consistency check of the
* in core free-block and i-node
* counts.
*
* bad count on dev x/y -- the count
* check failed. At this point, all
* the counts are zeroed which will
* almost certainly lead to "no space"
* diagnostic
* panic: no fs -- the device is not mounted.
* this "cannot happen"
*/
struct filsys *
getfs(dev)
dev_t dev;
{
register struct mount *mp;
register struct filsys *fp;
for(mp = &mount[0]; mp < &mount[NMOUNT]; mp++)
if(mp->m_bufp != NULL && mp->m_dev == dev) {
fp = mp->m_bufp->b_un.b_filsys;
if(fp->s_nfree > NICFREE || fp->s_ninode > NICINOD) {
prdev("bad count", dev);
fp->s_nfree = 0;
fp->s_ninode = 0;
}
return(fp);
}
panic("no fs");
return(NULL);
}
/*
* update is the internal name of
* 'sync'. It goes through the disk
* queues to initiate sandbagged IO;
* goes through the I nodes to write
* modified nodes; and it goes through
* the mount table to initiate modified
* super blocks.
*/
update()
{
register struct inode *ip;
register struct mount *mp;
register struct buf *bp;
struct filsys *fp;
if(updlock)
return;
updlock++;
for(mp = &mount[0]; mp < &mount[NMOUNT]; mp++)
if(mp->m_bufp != NULL) {
fp = mp->m_bufp->b_un.b_filsys;
if(fp->s_fmod==0 || fp->s_ilock!=0 ||
fp->s_flock!=0 || fp->s_ronly!=0)
continue;
bp = getblk(mp->m_dev, SUPERB);
if (bp->b_flags & B_ERROR)
continue;
fp->s_fmod = 0;
fp->s_time = time;
bcopy((caddr_t)fp, bp->b_un.b_addr, BSIZE);
bwrite(bp);
}
for(ip = &inode[0]; ip < &inode[NINODE]; ip++)
if((ip->i_flag&ILOCK)==0 && ip->i_count) {
ip->i_flag |= ILOCK;
ip->i_count++;
iupdat(ip, &time, &time);
iput(ip);
}
updlock = 0;
bflush(NODEV);
}