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phunix/minix/servers/vfs/open.c
David van Moolenbroek 27852ebe53 UDS: full rewrite 
This new implementation of the UDS service is built on top of the
libsockevent library.  It thereby inherits all the advantages that
libsockevent brings.  However, the fundamental restructuring
required for that change also paved the way for resolution of a
number of other important open issues with the old UDS code.  Most
importantly, the rewrite brings the behavior of the service much
closer to POSIX compliance and NetBSD compatibility.  These are the
most important changes:

- due to the use of libsockevent, UDS now supports multiple suspending
  calls per socket and a large number of standard socket flags and
  options;
- socket address matching is now based on <device,inode> lookups
  instead of canonized path names, and socket addresses are no longer
  altered either due to canonization or at connect time;
- the socket state machine is now well defined, most importantly
  resolving the erroneous reset-on-EOF semantics of the old UDS, but
  also allowing socket reuse;
- sockets are now connected before being accepted instead of being
  held in connecting state, unless the LOCAL_CONNWAIT option is set
  on either the connecting or the listening socket;
- connect(2) on datagram sockets is now supported (needed by syslog),
  and proper datagram socket disconnect notification is provided;
- the receive queue now supports segmentation, associating ancillary
  data (in-flight file descriptors and credentials) with each segment
  instead of being kept fully separately; this is a POSIX requirement
  (and needed by tmux);
- as part of the segmentation support, the receive queue can now hold
  as many packets as can fit, instead of one;
- in addition to the flags supported by libsockevent, the MSG_PEEK,
  MSG_WAITALL, MSG_CMSG_CLOEXEC, MSG_TRUNC, and MSG_CTRUNC send and
  receive flags are now supported;
- the SO_PASSCRED and SO_PEERCRED socket options are replaced by
  LOCAL_CREDS and LOCAL_PEEREID respectively, now following NetBSD
  semantics and allowing use of NetBSD libc's getpeereid(3);
- memory usage is reduced by about 250 KB due to centralized in-flight
  file descriptor tracking, with a limit of OPEN_MAX total rather than
  of OPEN_MAX per socket;
- memory usage is reduced by another ~50 KB due to removal of state
  redundancy, despite the fact that socket path names may now be up to
  253 bytes rather than the previous 104 bytes;
- compared to the old UDS, there is now very little direct indexing on
  the static array of sockets, thus allowing dynamic allocation of
  sockets more easily in the future;
- the UDS service now has RMIB support for the net.local sysctl tree,
  implementing preliminary support for NetBSD netstat(1).

Change-Id: I4a9b6fe4aaeef0edf2547eee894e6c14403fcb32
2017-03-09 23:39:56 +00:00

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/* This file contains the procedures for creating, opening, closing, and
* seeking on files.
*
* The entry points into this file are
* do_open: perform the OPEN system call
* do_mknod: perform the MKNOD system call
* do_mkdir: perform the MKDIR system call
* do_close: perform the CLOSE system call
* do_lseek: perform the LSEEK system call
*/
#include "fs.h"
#include <sys/stat.h>
#include <fcntl.h>
#include <string.h>
#include <unistd.h>
#include <minix/callnr.h>
#include <minix/com.h>
#include <minix/u64.h>
#include "file.h"
#include "lock.h"
#include <sys/dirent.h>
#include <assert.h>
#include <minix/vfsif.h>
#include "vnode.h"
#include "vmnt.h"
#include "path.h"
static char mode_map[] = {R_BIT, W_BIT, R_BIT|W_BIT, 0};
static struct vnode *new_node(struct lookup *resolve, int oflags,
mode_t bits);
static int pipe_open(int fd, struct vnode *vp, mode_t bits, int oflags);
/*===========================================================================*
* do_open *
*===========================================================================*/
int do_open(void)
{
/* Perform the open(name, flags) system call with O_CREAT *not* set. */
int open_flags;
char fullpath[PATH_MAX];
open_flags = job_m_in.m_lc_vfs_path.flags;
if (open_flags & O_CREAT)
return EINVAL;
if (copy_path(fullpath, sizeof(fullpath)) != OK)
return(err_code);
return common_open(fullpath, open_flags, 0 /*omode*/, FALSE /*for_exec*/);
}
/*===========================================================================*
* do_creat *
*===========================================================================*/
int do_creat(void)
{
/* Perform the open(name, flags, mode) system call with O_CREAT set. */
int open_flags, create_mode;
char fullpath[PATH_MAX];
vir_bytes vname;
size_t vname_length;
vname = job_m_in.m_lc_vfs_creat.name;
vname_length = job_m_in.m_lc_vfs_creat.len;
open_flags = job_m_in.m_lc_vfs_creat.flags;
create_mode = job_m_in.m_lc_vfs_creat.mode;
if (!(open_flags & O_CREAT))
return(EINVAL);
if (fetch_name(vname, vname_length, fullpath) != OK)
return(err_code);
return common_open(fullpath, open_flags, create_mode, FALSE /*for_exec*/);
}
/*===========================================================================*
* common_open *
*===========================================================================*/
int common_open(char path[PATH_MAX], int oflags, mode_t omode, int for_exec)
{
/* Common code from do_creat and do_open. */
int b, r, exist = TRUE;
devmajor_t major_dev;
dev_t dev;
mode_t bits;
struct filp *filp, *filp2;
struct vnode *vp;
struct vmnt *vmp;
struct dmap *dp;
struct lookup resolve;
int fd, start = 0;
/* Remap the bottom two bits of oflags. */
bits = (mode_t) mode_map[oflags & O_ACCMODE];
if (!bits) return(EINVAL);
/* See if file descriptor and filp slots are available. */
if ((r = get_fd(fp, start, bits, &fd, &filp)) != OK)
return(r);
lookup_init(&resolve, path, PATH_NOFLAGS, &vmp, &vp);
/* If O_CREATE is set, try to make the file. */
if (oflags & O_CREAT) {
omode = I_REGULAR | (omode & ALLPERMS & fp->fp_umask);
vp = new_node(&resolve, oflags, omode);
r = err_code;
if (r == OK) exist = FALSE; /* We just created the file */
else if (r != EEXIST) { /* other error */
if (vp) unlock_vnode(vp);
unlock_filp(filp);
return(r);
}
else exist = !(oflags & O_EXCL);/* file exists, if the O_EXCL
flag is set this is an error */
} else {
/* Scan path name */
resolve.l_vmnt_lock = VMNT_READ;
resolve.l_vnode_lock = VNODE_OPCL;
if ((vp = eat_path(&resolve, fp)) == NULL) {
unlock_filp(filp);
return(err_code);
}
if (vmp != NULL) unlock_vmnt(vmp);
}
/* Claim the file descriptor and filp slot and fill them in. */
fp->fp_filp[fd] = filp;
filp->filp_count = 1;
filp->filp_vno = vp;
filp->filp_flags = oflags;
if (oflags & O_CLOEXEC)
FD_SET(fd, &fp->fp_cloexec_set);
/* Only do the normal open code if we didn't just create the file. */
if (exist) {
/* Check permissions based on the given open flags, except when we are
* opening an executable for the purpose of passing a file descriptor
* to its interpreter for execution, in which case we check the X bit.
*/
if ((r = forbidden(fp, vp, for_exec ? X_BIT : bits)) == OK) {
/* Opening reg. files, directories, and special files differ */
switch (vp->v_mode & S_IFMT) {
case S_IFREG:
/* Truncate regular file if O_TRUNC. */
if (oflags & O_TRUNC) {
if ((r = forbidden(fp, vp, W_BIT)) != OK)
break;
upgrade_vnode_lock(vp);
truncate_vnode(vp, 0);
}
break;
case S_IFDIR:
/* Directories may be read but not written. */
r = (bits & W_BIT ? EISDIR : OK);
break;
case S_IFCHR:
/* Invoke the driver for special processing. */
dev = vp->v_sdev;
/* TTY needs to know about the O_NOCTTY flag. */
r = cdev_open(fd, dev, bits | (oflags & O_NOCTTY));
vp = filp->filp_vno; /* Might be updated by
* cdev_open after cloning */
break;
case S_IFBLK:
lock_bsf();
/* Invoke the driver for special processing. */
dev = vp->v_sdev;
r = bdev_open(dev, bits);
if (r != OK) {
unlock_bsf();
break;
}
major_dev = major(vp->v_sdev);
dp = &dmap[major_dev];
if (dp->dmap_driver == NONE) {
printf("VFS: block driver disappeared!\n");
unlock_bsf();
r = ENXIO;
break;
}
/* Check whether the device is mounted or not. If so,
* then that FS is responsible for this device.
* Otherwise we default to ROOT_FS.
*/
vp->v_bfs_e = ROOT_FS_E; /* By default */
for (vmp = &vmnt[0]; vmp < &vmnt[NR_MNTS]; ++vmp)
if (vmp->m_dev == vp->v_sdev &&
!(vmp->m_flags & VMNT_FORCEROOTBSF)) {
vp->v_bfs_e = vmp->m_fs_e;
}
/* Send the driver label to the file system that will
* handle the block I/O requests (even when its label
* and endpoint are known already), but only when it is
* the root file system. Other file systems will
* already have it anyway.
*/
if (vp->v_bfs_e != ROOT_FS_E) {
unlock_bsf();
break;
}
if (req_newdriver(vp->v_bfs_e, vp->v_sdev,
dp->dmap_label) != OK) {
printf("VFS: error sending driver label\n");
bdev_close(dev);
r = ENXIO;
}
unlock_bsf();
break;
case S_IFIFO:
/* Create a mapped inode on PFS which handles reads
and writes to this named pipe. */
upgrade_vnode_lock(vp);
r = map_vnode(vp, PFS_PROC_NR);
if (r == OK) {
if (vp->v_ref_count == 1) {
if (vp->v_size != 0)
r = truncate_vnode(vp, 0);
}
oflags |= O_APPEND; /* force append mode */
filp->filp_flags = oflags;
}
if (r == OK) {
r = pipe_open(fd, vp, bits, oflags);
}
if (r != ENXIO) {
/* See if someone else is doing a rd or wt on
* the FIFO. If so, use its filp entry so the
* file position will be automatically shared.
*/
b = (bits & R_BIT ? R_BIT : W_BIT);
filp->filp_count = 0; /* don't find self */
if ((filp2 = find_filp(vp, b)) != NULL) {
/* Co-reader or writer found. Use it.*/
fp->fp_filp[fd] = filp2;
filp2->filp_count++;
filp2->filp_vno = vp;
filp2->filp_flags = oflags;
/* v_count was incremented after the vnode
* has been found. i_count was incremented
* incorrectly in FS, not knowing that we
* were going to use an existing filp
* entry. Correct this error.
*/
unlock_vnode(vp);
put_vnode(vp);
} else {
/* Nobody else found. Restore filp. */
filp->filp_count = 1;
}
}
break;
case S_IFSOCK:
r = EOPNOTSUPP;
break;
default:
printf("VFS: attempt to open file <%llu,%llu> of "
"type 0%o\n", vp->v_dev, vp->v_inode_nr,
vp->v_mode & S_IFMT);
r = EIO;
}
}
}
unlock_filp(filp);
/* If error, release inode. */
if (r != OK) {
if (r != SUSPEND) {
fp->fp_filp[fd] = NULL;
filp->filp_count = 0;
filp->filp_vno = NULL;
put_vnode(vp);
}
} else {
r = fd;
}
return(r);
}
/*===========================================================================*
* new_node *
*===========================================================================*/
static struct vnode *new_node(struct lookup *resolve, int oflags, mode_t bits)
{
/* Try to create a new inode and return a pointer to it. If the inode already
exists, return a pointer to it as well, but set err_code accordingly.
NULL is returned if the path cannot be resolved up to the last
directory, or when the inode cannot be created due to permissions or
otherwise. */
struct vnode *dirp, *vp;
struct vmnt *dir_vmp, *vp_vmp;
int r;
struct node_details res;
struct lookup findnode;
char *path;
path = resolve->l_path; /* For easy access */
lookup_init(&findnode, path, resolve->l_flags, &dir_vmp, &dirp);
findnode.l_vmnt_lock = VMNT_WRITE;
findnode.l_vnode_lock = VNODE_WRITE; /* dir node */
/* When O_CREAT and O_EXCL flags are set, the path may not be named by a
* symbolic link. */
if (oflags & O_EXCL) findnode.l_flags |= PATH_RET_SYMLINK;
/* See if the path can be opened down to the last directory. */
if ((dirp = last_dir(&findnode, fp)) == NULL) return(NULL);
/* The final directory is accessible. Get final component of the path. */
lookup_init(&findnode, findnode.l_path, findnode.l_flags, &vp_vmp, &vp);
findnode.l_vmnt_lock = VMNT_WRITE;
findnode.l_vnode_lock = (oflags & O_TRUNC) ? VNODE_WRITE : VNODE_OPCL;
vp = advance(dirp, &findnode, fp);
assert(vp_vmp == NULL); /* Lookup to last dir should have yielded lock
* on vmp or final component does not exist.
* Either way, vp_vmp ought to be not set.
*/
/* The combination of a symlink with absolute path followed by a danglink
* symlink results in a new path that needs to be re-resolved entirely. */
if (path[0] == '/') {
unlock_vnode(dirp);
unlock_vmnt(dir_vmp);
put_vnode(dirp);
if (vp != NULL) {
unlock_vnode(vp);
put_vnode(vp);
}
return new_node(resolve, oflags, bits);
}
if (vp == NULL && err_code == ENOENT) {
/* Last path component does not exist. Make a new directory entry. */
if ((vp = get_free_vnode()) == NULL) {
/* Can't create new entry: out of vnodes. */
unlock_vnode(dirp);
unlock_vmnt(dir_vmp);
put_vnode(dirp);
return(NULL);
}
lock_vnode(vp, VNODE_OPCL);
upgrade_vmnt_lock(dir_vmp); /* Creating file, need exclusive access */
if ((r = forbidden(fp, dirp, W_BIT|X_BIT)) != OK ||
(r = req_create(dirp->v_fs_e, dirp->v_inode_nr,bits, fp->fp_effuid,
fp->fp_effgid, path, &res)) != OK ) {
/* Can't create inode either due to permissions or some other
* problem. In case r is EEXIST, we might be dealing with a
* dangling symlink.*/
/* Downgrade lock to prevent deadlock during symlink resolving*/
downgrade_vmnt_lock(dir_vmp);
if (r == EEXIST) {
struct vnode *slp, *old_wd;
/* Resolve path up to symlink */
findnode.l_flags = PATH_RET_SYMLINK;
findnode.l_vnode_lock = VNODE_READ;
findnode.l_vnode = &slp;
slp = advance(dirp, &findnode, fp);
if (slp != NULL) {
if (S_ISLNK(slp->v_mode)) {
/* Get contents of link */
r = req_rdlink(slp->v_fs_e,
slp->v_inode_nr,
VFS_PROC_NR,
(vir_bytes) path,
PATH_MAX - 1, 0);
if (r < 0) {
/* Failed to read link */
unlock_vnode(slp);
unlock_vnode(dirp);
unlock_vmnt(dir_vmp);
put_vnode(slp);
put_vnode(dirp);
err_code = r;
return(NULL);
}
path[r] = '\0'; /* Terminate path */
}
unlock_vnode(slp);
put_vnode(slp);
}
/* Try to create the inode the dangling symlink was
* pointing to. We have to use dirp as starting point
* as there might be multiple successive symlinks
* crossing multiple mountpoints.
* Unlock vnodes and vmnts as we're going to recurse.
*/
unlock_vnode(dirp);
unlock_vnode(vp);
unlock_vmnt(dir_vmp);
old_wd = fp->fp_wd; /* Save orig. working dirp */
fp->fp_wd = dirp;
vp = new_node(resolve, oflags, bits);
fp->fp_wd = old_wd; /* Restore */
if (vp != NULL) {
put_vnode(dirp);
*(resolve->l_vnode) = vp;
return(vp);
}
r = err_code;
}
if (r == EEXIST)
err_code = EIO; /* Impossible, we have verified that
* the last component doesn't exist and
* is not a dangling symlink. */
else
err_code = r;
unlock_vmnt(dir_vmp);
unlock_vnode(dirp);
unlock_vnode(vp);
put_vnode(dirp);
return(NULL);
}
/* Store results and mark vnode in use */
vp->v_fs_e = res.fs_e;
vp->v_inode_nr = res.inode_nr;
vp->v_mode = res.fmode;
vp->v_size = res.fsize;
vp->v_uid = res.uid;
vp->v_gid = res.gid;
vp->v_sdev = res.dev;
vp->v_vmnt = dirp->v_vmnt;
vp->v_dev = vp->v_vmnt->m_dev;
vp->v_fs_count = 1;
vp->v_ref_count = 1;
} else {
/* Either last component exists, or there is some other problem. */
if (vp != NULL) {
r = EEXIST; /* File exists or a symlink names a file while
* O_EXCL is set. */
} else
r = err_code; /* Other problem. */
}
err_code = r;
/* When dirp equals vp, we shouldn't release the lock as a vp is locked only
* once. Releasing the lock would cause the resulting vp not be locked and
* cause mayhem later on. */
if (dirp != vp) {
unlock_vnode(dirp);
}
unlock_vmnt(dir_vmp);
put_vnode(dirp);
*(resolve->l_vnode) = vp;
return(vp);
}
/*===========================================================================*
* pipe_open *
*===========================================================================*/
static int pipe_open(int fd, struct vnode *vp, mode_t bits, int oflags)
{
/* This function is called from common_open. It checks if
* there is at least one reader/writer pair for the pipe, if not
* it suspends the caller, otherwise it revives all other blocked
* processes hanging on the pipe.
*/
if ((bits & (R_BIT|W_BIT)) == (R_BIT|W_BIT)) return(ENXIO);
/* Find the reader/writer at the other end of the pipe */
if (find_filp(vp, bits & W_BIT ? R_BIT : W_BIT) == NULL) {
/* Not found */
if (oflags & O_NONBLOCK) {
if (bits & W_BIT) return(ENXIO);
} else {
/* Let's wait for the other side to show up */
fp->fp_popen.fd = fd;
suspend(FP_BLOCKED_ON_POPEN);
return(SUSPEND);
}
} else if (susp_count > 0) { /* revive blocked processes */
release(vp, VFS_OPEN, susp_count);
}
return(OK);
}
/*===========================================================================*
* do_mknod *
*===========================================================================*/
int do_mknod(void)
{
/* Perform the mknod(name, mode, addr) system call. */
register mode_t bits, mode_bits;
int r;
struct vnode *vp;
struct vmnt *vmp;
char fullpath[PATH_MAX];
struct lookup resolve;
vir_bytes vname1;
size_t vname1_length;
dev_t dev;
vname1 = job_m_in.m_lc_vfs_mknod.name;
vname1_length = job_m_in.m_lc_vfs_mknod.len;
mode_bits = job_m_in.m_lc_vfs_mknod.mode;
dev = job_m_in.m_lc_vfs_mknod.device;
/* If the path names a symbolic link, mknod() shall fail with EEXIST. */
lookup_init(&resolve, fullpath, PATH_RET_SYMLINK, &vmp, &vp);
resolve.l_vmnt_lock = VMNT_WRITE;
resolve.l_vnode_lock = VNODE_WRITE;
/* Only the super_user may make nodes other than fifos. */
if (!super_user && !S_ISFIFO(mode_bits))
return(EPERM);
bits = (mode_bits & S_IFMT) | (mode_bits & ACCESSPERMS & fp->fp_umask);
/* Open directory that's going to hold the new node. */
if (fetch_name(vname1, vname1_length, fullpath) != OK) return(err_code);
if ((vp = last_dir(&resolve, fp)) == NULL) return(err_code);
/* Make sure that the object is a directory */
if (!S_ISDIR(vp->v_mode)) {
r = ENOTDIR;
} else if ((r = forbidden(fp, vp, W_BIT|X_BIT)) == OK) {
r = req_mknod(vp->v_fs_e, vp->v_inode_nr, fullpath, fp->fp_effuid,
fp->fp_effgid, bits, dev);
}
unlock_vnode(vp);
unlock_vmnt(vmp);
put_vnode(vp);
return(r);
}
/*===========================================================================*
* do_mkdir *
*===========================================================================*/
int do_mkdir(void)
{
/* Perform the mkdir(name, mode) system call. */
mode_t bits; /* mode bits for the new inode */
int r;
struct vnode *vp;
struct vmnt *vmp;
char fullpath[PATH_MAX];
struct lookup resolve;
mode_t dirmode;
if (copy_path(fullpath, sizeof(fullpath)) != OK)
return(err_code);
dirmode = job_m_in.m_lc_vfs_path.mode;
lookup_init(&resolve, fullpath, PATH_NOFLAGS, &vmp, &vp);
resolve.l_vmnt_lock = VMNT_WRITE;
resolve.l_vnode_lock = VNODE_WRITE;
bits = I_DIRECTORY | (dirmode & RWX_MODES & fp->fp_umask);
if ((vp = last_dir(&resolve, fp)) == NULL) return(err_code);
/* Make sure that the object is a directory */
if (!S_ISDIR(vp->v_mode)) {
r = ENOTDIR;
} else if ((r = forbidden(fp, vp, W_BIT|X_BIT)) == OK) {
r = req_mkdir(vp->v_fs_e, vp->v_inode_nr, fullpath, fp->fp_effuid,
fp->fp_effgid, bits);
}
unlock_vnode(vp);
unlock_vmnt(vmp);
put_vnode(vp);
return(r);
}
/*===========================================================================*
* actual_lseek *
*===========================================================================*/
int actual_lseek(struct fproc *rfp, int seekfd, int seekwhence, off_t offset,
off_t *newposp)
{
register struct filp *rfilp;
int r = OK;
off_t pos, newpos;
/* Check to see if the file descriptor is valid. */
if ( (rfilp = get_filp2(rfp, seekfd, VNODE_READ)) == NULL) {
return(err_code);
}
/* No lseek on pipes. */
if (S_ISFIFO(rfilp->filp_vno->v_mode)) {
unlock_filp(rfilp);
return(ESPIPE);
}
/* The value of 'whence' determines the start position to use. */
switch(seekwhence) {
case SEEK_SET: pos = 0; break;
case SEEK_CUR: pos = rfilp->filp_pos; break;
case SEEK_END: pos = rfilp->filp_vno->v_size; break;
default: unlock_filp(rfilp); return(EINVAL);
}
newpos = pos + offset;
/* Check for overflow. */
if ((offset > 0) && (newpos <= pos)) {
r = EOVERFLOW;
} else if ((offset < 0) && (newpos >= pos)) {
r = EOVERFLOW;
} else {
if (newposp != NULL) *newposp = newpos;
if (newpos != rfilp->filp_pos) {
rfilp->filp_pos = newpos;
/* Inhibit read ahead request */
r = req_inhibread(rfilp->filp_vno->v_fs_e,
rfilp->filp_vno->v_inode_nr);
}
}
unlock_filp(rfilp);
return(r);
}
/*===========================================================================*
* do_lseek *
*===========================================================================*/
int do_lseek(void)
{
/* Perform the lseek(2) system call. */
off_t newpos = 0;
int r;
if ((r = actual_lseek(fp, job_m_in.m_lc_vfs_lseek.fd,
job_m_in.m_lc_vfs_lseek.whence, job_m_in.m_lc_vfs_lseek.offset,
&newpos)) != OK)
return r;
/* insert the new position into the output message */
job_m_out.m_vfs_lc_lseek.offset = newpos;
return OK;
}
/*===========================================================================*
* do_close *
*===========================================================================*/
int do_close(void)
{
/* Perform the close(fd) or closenb(fd) system call. */
int fd, nblock;
fd = job_m_in.m_lc_vfs_close.fd;
nblock = job_m_in.m_lc_vfs_close.nblock;
return close_fd(fp, fd, !nblock /*may_suspend*/);
}
/*===========================================================================*
* close_fd *
*===========================================================================*/
int
close_fd(struct fproc * rfp, int fd_nr, int may_suspend)
{
/* Perform the close(fd) system call. */
register struct filp *rfilp;
register struct vnode *vp;
struct file_lock *flp;
int r, lock_count;
/* First locate the vnode that belongs to the file descriptor. */
if ( (rfilp = get_filp2(rfp, fd_nr, VNODE_OPCL)) == NULL) return(err_code);
vp = rfilp->filp_vno;
/* first, make all future get_filp2()'s fail; otherwise
* we might try to close the same fd in different threads
*/
rfp->fp_filp[fd_nr] = NULL;
r = close_filp(rfilp, may_suspend);
FD_CLR(fd_nr, &rfp->fp_cloexec_set);
/* Check to see if the file is locked. If so, release all locks. */
if (nr_locks > 0) {
lock_count = nr_locks; /* save count of locks */
for (flp = &file_lock[0]; flp < &file_lock[NR_LOCKS]; flp++) {
if (flp->lock_type == 0) continue; /* slot not in use */
if (flp->lock_vnode == vp && flp->lock_pid == rfp->fp_pid) {
flp->lock_type = 0;
nr_locks--;
}
}
if (nr_locks < lock_count)
lock_revive(); /* one or more locks released */
}
return(r);
}
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