minix/servers/avfs/lock.c
Thomas Veerman de5a9a3e8b AVFS: Use scratchpad instead of m_in to pass around file descriptors
Some code relies on having the file descriptor in m_in.fd. Consequently,
m_in is not only used to provide syscall parameters from user space to
VFS, but also as a global variable to store temporary data within VFS.
This has the ugly side effect that m_in gets overwritten during core
dumping.*

To work around this problem VFS now uses a so called "scratchpad" to
store temporary data that has to be globally accessible. This is a simple
table indexed by process number, just like fproc. The scratchpad allows
us to store the buffer pointer and buffer size for suspended system calls
(i.e., read, write, open, lock) instead of using fproc. This makes fproc
a bit smaller and fproc iterators a bit faster. Moreover, suspension of
processes becomes simpler altogether and suspended operations on pipes
are now less of a special case.

* This patch fixes a bug where due to unexpected m_in overwriting a
coredump would fail, and consequently resources are leaked. The coredump
was triggered with:
$ a() { a; }
$ a
2011-12-21 10:52:51 +00:00

191 lines
5.9 KiB
C

/* This file handles advisory file locking as required by POSIX.
*
* The entry points into this file are
* lock_op: perform locking operations for FCNTL system call
* lock_revive: revive processes when a lock is released
*/
#include "fs.h"
#include <minix/com.h>
#include <minix/u64.h>
#include <fcntl.h>
#include <unistd.h>
#include "file.h"
#include "fproc.h"
#include "scratchpad.h"
#include "lock.h"
#include "vnode.h"
#include "param.h"
/*===========================================================================*
* lock_op *
*===========================================================================*/
PUBLIC int lock_op(f, req)
struct filp *f;
int req; /* either F_SETLK or F_SETLKW */
{
/* Perform the advisory locking required by POSIX. */
int r, ltype, i, conflict = 0, unlocking = 0;
mode_t mo;
off_t first, last;
struct flock flock;
struct file_lock *flp, *flp2, *empty;
/* Fetch the flock structure from user space. */
r = sys_datacopy(who_e, (vir_bytes) scratch(fp).io.io_buffer, VFS_PROC_NR,
(vir_bytes) &flock, sizeof(flock));
if (r != OK) return(EINVAL);
/* Make some error checks. */
ltype = flock.l_type;
mo = f->filp_mode;
if (ltype != F_UNLCK && ltype != F_RDLCK && ltype != F_WRLCK) return(EINVAL);
if (req == F_GETLK && ltype == F_UNLCK) return(EINVAL);
if ( (f->filp_vno->v_mode & I_TYPE) != I_REGULAR &&
(f->filp_vno->v_mode & I_TYPE) != I_BLOCK_SPECIAL) return(EINVAL);
if (req != F_GETLK && ltype == F_RDLCK && (mo & R_BIT) == 0) return(EBADF);
if (req != F_GETLK && ltype == F_WRLCK && (mo & W_BIT) == 0) return(EBADF);
/* Compute the first and last bytes in the lock region. */
switch (flock.l_whence) {
case SEEK_SET: first = 0; break;
case SEEK_CUR:
if (ex64hi(f->filp_pos) != 0)
panic("lock_op: position in file too high");
first = ex64lo(f->filp_pos);
break;
case SEEK_END: first = f->filp_vno->v_size; break;
default: return(EINVAL);
}
/* Check for overflow. */
if (((long) flock.l_start > 0) && ((first + flock.l_start) < first))
return(EINVAL);
if (((long) flock.l_start < 0) && ((first + flock.l_start) > first))
return(EINVAL);
first = first + flock.l_start;
last = first + flock.l_len - 1;
if (flock.l_len == 0) last = MAX_FILE_POS;
if (last < first) return(EINVAL);
/* Check if this region conflicts with any existing lock. */
empty = NULL;
for (flp = &file_lock[0]; flp < &file_lock[NR_LOCKS]; flp++) {
if (flp->lock_type == 0) {
if (empty == NULL) empty = flp;
continue; /* 0 means unused slot */
}
if (flp->lock_vnode != f->filp_vno) continue; /* different file */
if (last < flp->lock_first) continue; /* new one is in front */
if (first > flp->lock_last) continue; /* new one is afterwards */
if (ltype == F_RDLCK && flp->lock_type == F_RDLCK) continue;
if (ltype != F_UNLCK && flp->lock_pid == fp->fp_pid) continue;
/* There might be a conflict. Process it. */
conflict = 1;
if (req == F_GETLK) break;
/* If we are trying to set a lock, it just failed. */
if (ltype == F_RDLCK || ltype == F_WRLCK) {
if (req == F_SETLK) {
/* For F_SETLK, just report back failure. */
return(EAGAIN);
} else {
/* For F_SETLKW, suspend the process. */
suspend(FP_BLOCKED_ON_LOCK);
return(SUSPEND);
}
}
/* We are clearing a lock and we found something that overlaps. */
unlocking = 1;
if (first <= flp->lock_first && last >= flp->lock_last) {
flp->lock_type = 0; /* mark slot as unused */
nr_locks--; /* number of locks is now 1 less */
continue;
}
/* Part of a locked region has been unlocked. */
if (first <= flp->lock_first) {
flp->lock_first = last + 1;
continue;
}
if (last >= flp->lock_last) {
flp->lock_last = first - 1;
continue;
}
/* Bad luck. A lock has been split in two by unlocking the middle. */
if (nr_locks == NR_LOCKS) return(ENOLCK);
for (i = 0; i < NR_LOCKS; i++)
if (file_lock[i].lock_type == 0) break;
flp2 = &file_lock[i];
flp2->lock_type = flp->lock_type;
flp2->lock_pid = flp->lock_pid;
flp2->lock_vnode = flp->lock_vnode;
flp2->lock_first = last + 1;
flp2->lock_last = flp->lock_last;
flp->lock_last = first - 1;
nr_locks++;
}
if (unlocking) lock_revive();
if (req == F_GETLK) {
if (conflict) {
/* GETLK and conflict. Report on the conflicting lock. */
flock.l_type = flp->lock_type;
flock.l_whence = SEEK_SET;
flock.l_start = flp->lock_first;
flock.l_len = flp->lock_last - flp->lock_first + 1;
flock.l_pid = flp->lock_pid;
} else {
/* It is GETLK and there is no conflict. */
flock.l_type = F_UNLCK;
}
/* Copy the flock structure back to the caller. */
r = sys_datacopy(VFS_PROC_NR, (vir_bytes) &flock,
who_e, (vir_bytes) scratch(fp).io.io_buffer, sizeof(flock));
return(r);
}
if (ltype == F_UNLCK) return(OK); /* unlocked a region with no locks */
/* There is no conflict. If space exists, store new lock in the table. */
if (empty == NULL) return(ENOLCK); /* table full */
empty->lock_type = ltype;
empty->lock_pid = fp->fp_pid;
empty->lock_vnode = f->filp_vno;
empty->lock_first = first;
empty->lock_last = last;
nr_locks++;
return(OK);
}
/*===========================================================================*
* lock_revive *
*===========================================================================*/
PUBLIC void lock_revive()
{
/* Go find all the processes that are waiting for any kind of lock and
* revive them all. The ones that are still blocked will block again when
* they run. The others will complete. This strategy is a space-time
* tradeoff. Figuring out exactly which ones to unblock now would take
* extra code, and the only thing it would win would be some performance in
* extremely rare circumstances (namely, that somebody actually used
* locking).
*/
struct fproc *fptr;
for (fptr = &fproc[0]; fptr < &fproc[NR_PROCS]; fptr++){
if (fptr->fp_pid == PID_FREE) continue;
if (fptr->fp_blocked_on == FP_BLOCKED_ON_LOCK) {
revive(fptr->fp_endpoint, 0);
}
}
}