kernel-fxtec-pro1x/net/9p/conv.c

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/*
* net/9p/conv.c
*
* 9P protocol conversion functions
*
* Copyright (C) 2004, 2005 by Latchesar Ionkov <lucho@ionkov.net>
* Copyright (C) 2004 by Eric Van Hensbergen <ericvh@gmail.com>
* Copyright (C) 2002 by Ron Minnich <rminnich@lanl.gov>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2
* as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to:
* Free Software Foundation
* 51 Franklin Street, Fifth Floor
* Boston, MA 02111-1301 USA
*
*/
#include <linux/module.h>
#include <linux/errno.h>
#include <linux/fs.h>
#include <linux/sched.h>
#include <linux/idr.h>
#include <linux/uaccess.h>
#include <net/9p/9p.h>
/*
* Buffer to help with string parsing
*/
struct cbuf {
unsigned char *sp;
unsigned char *p;
unsigned char *ep;
};
static inline void buf_init(struct cbuf *buf, void *data, int datalen)
{
buf->sp = buf->p = data;
buf->ep = data + datalen;
}
static inline int buf_check_overflow(struct cbuf *buf)
{
return buf->p > buf->ep;
}
static int buf_check_size(struct cbuf *buf, int len)
{
if (buf->p + len > buf->ep) {
if (buf->p < buf->ep) {
P9_EPRINTK(KERN_ERR,
"buffer overflow: want %d has %d\n", len,
(int)(buf->ep - buf->p));
dump_stack();
buf->p = buf->ep + 1;
}
return 0;
}
return 1;
}
static void *buf_alloc(struct cbuf *buf, int len)
{
void *ret = NULL;
if (buf_check_size(buf, len)) {
ret = buf->p;
buf->p += len;
}
return ret;
}
static void buf_put_int8(struct cbuf *buf, u8 val)
{
if (buf_check_size(buf, 1)) {
buf->p[0] = val;
buf->p++;
}
}
static void buf_put_int16(struct cbuf *buf, u16 val)
{
if (buf_check_size(buf, 2)) {
*(__le16 *) buf->p = cpu_to_le16(val);
buf->p += 2;
}
}
static void buf_put_int32(struct cbuf *buf, u32 val)
{
if (buf_check_size(buf, 4)) {
*(__le32 *)buf->p = cpu_to_le32(val);
buf->p += 4;
}
}
static void buf_put_int64(struct cbuf *buf, u64 val)
{
if (buf_check_size(buf, 8)) {
*(__le64 *)buf->p = cpu_to_le64(val);
buf->p += 8;
}
}
static char *buf_put_stringn(struct cbuf *buf, const char *s, u16 slen)
{
char *ret;
ret = NULL;
if (buf_check_size(buf, slen + 2)) {
buf_put_int16(buf, slen);
ret = buf->p;
memcpy(buf->p, s, slen);
buf->p += slen;
}
return ret;
}
static u8 buf_get_int8(struct cbuf *buf)
{
u8 ret = 0;
if (buf_check_size(buf, 1)) {
ret = buf->p[0];
buf->p++;
}
return ret;
}
static u16 buf_get_int16(struct cbuf *buf)
{
u16 ret = 0;
if (buf_check_size(buf, 2)) {
ret = le16_to_cpu(*(__le16 *)buf->p);
buf->p += 2;
}
return ret;
}
static u32 buf_get_int32(struct cbuf *buf)
{
u32 ret = 0;
if (buf_check_size(buf, 4)) {
ret = le32_to_cpu(*(__le32 *)buf->p);
buf->p += 4;
}
return ret;
}
static u64 buf_get_int64(struct cbuf *buf)
{
u64 ret = 0;
if (buf_check_size(buf, 8)) {
ret = le64_to_cpu(*(__le64 *)buf->p);
buf->p += 8;
}
return ret;
}
static void buf_get_str(struct cbuf *buf, struct p9_str *vstr)
{
vstr->len = buf_get_int16(buf);
if (!buf_check_overflow(buf) && buf_check_size(buf, vstr->len)) {
vstr->str = buf->p;
buf->p += vstr->len;
} else {
vstr->len = 0;
vstr->str = NULL;
}
}
static void buf_get_qid(struct cbuf *bufp, struct p9_qid *qid)
{
qid->type = buf_get_int8(bufp);
qid->version = buf_get_int32(bufp);
qid->path = buf_get_int64(bufp);
}
/**
* p9_size_wstat - calculate the size of a variable length stat struct
* @wstat: metadata (stat) structure
* @dotu: non-zero if 9P2000.u
*
*/
static int p9_size_wstat(struct p9_wstat *wstat, int dotu)
{
int size = 0;
if (wstat == NULL) {
P9_EPRINTK(KERN_ERR, "p9_size_stat: got a NULL stat pointer\n");
return 0;
}
size = /* 2 + *//* size[2] */
2 + /* type[2] */
4 + /* dev[4] */
1 + /* qid.type[1] */
4 + /* qid.vers[4] */
8 + /* qid.path[8] */
4 + /* mode[4] */
4 + /* atime[4] */
4 + /* mtime[4] */
8 + /* length[8] */
8; /* minimum sum of string lengths */
if (wstat->name)
size += strlen(wstat->name);
if (wstat->uid)
size += strlen(wstat->uid);
if (wstat->gid)
size += strlen(wstat->gid);
if (wstat->muid)
size += strlen(wstat->muid);
if (dotu) {
size += 4 + /* n_uid[4] */
4 + /* n_gid[4] */
4 + /* n_muid[4] */
2; /* string length of extension[4] */
if (wstat->extension)
size += strlen(wstat->extension);
}
return size;
}
/**
* buf_get_stat - safely decode a recieved metadata (stat) structure
* @bufp: buffer to deserialize
* @stat: metadata (stat) structure
* @dotu: non-zero if 9P2000.u
*
*/
static void
buf_get_stat(struct cbuf *bufp, struct p9_stat *stat, int dotu)
{
stat->size = buf_get_int16(bufp);
stat->type = buf_get_int16(bufp);
stat->dev = buf_get_int32(bufp);
stat->qid.type = buf_get_int8(bufp);
stat->qid.version = buf_get_int32(bufp);
stat->qid.path = buf_get_int64(bufp);
stat->mode = buf_get_int32(bufp);
stat->atime = buf_get_int32(bufp);
stat->mtime = buf_get_int32(bufp);
stat->length = buf_get_int64(bufp);
buf_get_str(bufp, &stat->name);
buf_get_str(bufp, &stat->uid);
buf_get_str(bufp, &stat->gid);
buf_get_str(bufp, &stat->muid);
if (dotu) {
buf_get_str(bufp, &stat->extension);
stat->n_uid = buf_get_int32(bufp);
stat->n_gid = buf_get_int32(bufp);
stat->n_muid = buf_get_int32(bufp);
}
}
/**
* p9_deserialize_stat - decode a received metadata structure
* @buf: buffer to deserialize
* @buflen: length of received buffer
* @stat: metadata structure to decode into
* @dotu: non-zero if 9P2000.u
*
* Note: stat will point to the buf region.
*/
int
p9_deserialize_stat(void *buf, u32 buflen, struct p9_stat *stat,
int dotu)
{
struct cbuf buffer;
struct cbuf *bufp = &buffer;
unsigned char *p;
buf_init(bufp, buf, buflen);
p = bufp->p;
buf_get_stat(bufp, stat, dotu);
if (buf_check_overflow(bufp))
return 0;
else
return bufp->p - p;
}
EXPORT_SYMBOL(p9_deserialize_stat);
/**
* deserialize_fcall - unmarshal a response
* @buf: recieved buffer
* @buflen: length of received buffer
* @rcall: fcall structure to populate
* @rcalllen: length of fcall structure to populate
* @dotu: non-zero if 9P2000.u
*
*/
int
p9_deserialize_fcall(void *buf, u32 buflen, struct p9_fcall *rcall,
int dotu)
{
struct cbuf buffer;
struct cbuf *bufp = &buffer;
int i = 0;
buf_init(bufp, buf, buflen);
rcall->size = buf_get_int32(bufp);
rcall->id = buf_get_int8(bufp);
rcall->tag = buf_get_int16(bufp);
P9_DPRINTK(P9_DEBUG_CONV, "size %d id %d tag %d\n", rcall->size,
rcall->id, rcall->tag);
switch (rcall->id) {
default:
P9_EPRINTK(KERN_ERR, "unknown message type: %d\n", rcall->id);
return -EPROTO;
case P9_RVERSION:
rcall->params.rversion.msize = buf_get_int32(bufp);
buf_get_str(bufp, &rcall->params.rversion.version);
break;
case P9_RFLUSH:
break;
case P9_RATTACH:
rcall->params.rattach.qid.type = buf_get_int8(bufp);
rcall->params.rattach.qid.version = buf_get_int32(bufp);
rcall->params.rattach.qid.path = buf_get_int64(bufp);
break;
case P9_RWALK:
rcall->params.rwalk.nwqid = buf_get_int16(bufp);
if (rcall->params.rwalk.nwqid > P9_MAXWELEM) {
P9_EPRINTK(KERN_ERR,
"Rwalk with more than %d qids: %d\n",
P9_MAXWELEM, rcall->params.rwalk.nwqid);
return -EPROTO;
}
for (i = 0; i < rcall->params.rwalk.nwqid; i++)
buf_get_qid(bufp, &rcall->params.rwalk.wqids[i]);
break;
case P9_ROPEN:
buf_get_qid(bufp, &rcall->params.ropen.qid);
rcall->params.ropen.iounit = buf_get_int32(bufp);
break;
case P9_RCREATE:
buf_get_qid(bufp, &rcall->params.rcreate.qid);
rcall->params.rcreate.iounit = buf_get_int32(bufp);
break;
case P9_RREAD:
rcall->params.rread.count = buf_get_int32(bufp);
rcall->params.rread.data = bufp->p;
buf_check_size(bufp, rcall->params.rread.count);
break;
case P9_RWRITE:
rcall->params.rwrite.count = buf_get_int32(bufp);
break;
case P9_RCLUNK:
break;
case P9_RREMOVE:
break;
case P9_RSTAT:
buf_get_int16(bufp);
buf_get_stat(bufp, &rcall->params.rstat.stat, dotu);
break;
case P9_RWSTAT:
break;
case P9_RERROR:
buf_get_str(bufp, &rcall->params.rerror.error);
if (dotu)
rcall->params.rerror.errno = buf_get_int16(bufp);
break;
}
if (buf_check_overflow(bufp)) {
P9_DPRINTK(P9_DEBUG_ERROR, "buffer overflow\n");
return -EIO;
}
return bufp->p - bufp->sp;
}
EXPORT_SYMBOL(p9_deserialize_fcall);
static inline void p9_put_int8(struct cbuf *bufp, u8 val, u8 * p)
{
*p = val;
buf_put_int8(bufp, val);
}
static inline void p9_put_int16(struct cbuf *bufp, u16 val, u16 * p)
{
*p = val;
buf_put_int16(bufp, val);
}
static inline void p9_put_int32(struct cbuf *bufp, u32 val, u32 * p)
{
*p = val;
buf_put_int32(bufp, val);
}
static inline void p9_put_int64(struct cbuf *bufp, u64 val, u64 * p)
{
*p = val;
buf_put_int64(bufp, val);
}
static void
p9_put_str(struct cbuf *bufp, char *data, struct p9_str *str)
{
int len;
char *s;
if (data)
len = strlen(data);
else
len = 0;
s = buf_put_stringn(bufp, data, len);
if (str) {
str->len = len;
str->str = s;
}
}
static int
p9_put_data(struct cbuf *bufp, const char *data, int count,
unsigned char **pdata)
{
*pdata = buf_alloc(bufp, count);
memmove(*pdata, data, count);
return count;
}
static int
p9_put_user_data(struct cbuf *bufp, const char __user *data, int count,
unsigned char **pdata)
{
*pdata = buf_alloc(bufp, count);
return copy_from_user(*pdata, data, count);
}
static void
p9_put_wstat(struct cbuf *bufp, struct p9_wstat *wstat,
struct p9_stat *stat, int statsz, int dotu)
{
p9_put_int16(bufp, statsz, &stat->size);
p9_put_int16(bufp, wstat->type, &stat->type);
p9_put_int32(bufp, wstat->dev, &stat->dev);
p9_put_int8(bufp, wstat->qid.type, &stat->qid.type);
p9_put_int32(bufp, wstat->qid.version, &stat->qid.version);
p9_put_int64(bufp, wstat->qid.path, &stat->qid.path);
p9_put_int32(bufp, wstat->mode, &stat->mode);
p9_put_int32(bufp, wstat->atime, &stat->atime);
p9_put_int32(bufp, wstat->mtime, &stat->mtime);
p9_put_int64(bufp, wstat->length, &stat->length);
p9_put_str(bufp, wstat->name, &stat->name);
p9_put_str(bufp, wstat->uid, &stat->uid);
p9_put_str(bufp, wstat->gid, &stat->gid);
p9_put_str(bufp, wstat->muid, &stat->muid);
if (dotu) {
p9_put_str(bufp, wstat->extension, &stat->extension);
p9_put_int32(bufp, wstat->n_uid, &stat->n_uid);
p9_put_int32(bufp, wstat->n_gid, &stat->n_gid);
p9_put_int32(bufp, wstat->n_muid, &stat->n_muid);
}
}
static struct p9_fcall *
p9_create_common(struct cbuf *bufp, u32 size, u8 id)
{
struct p9_fcall *fc;
size += 4 + 1 + 2; /* size[4] id[1] tag[2] */
fc = kmalloc(sizeof(struct p9_fcall) + size, GFP_KERNEL);
if (!fc)
return ERR_PTR(-ENOMEM);
fc->sdata = (char *)fc + sizeof(*fc);
buf_init(bufp, (char *)fc->sdata, size);
p9_put_int32(bufp, size, &fc->size);
p9_put_int8(bufp, id, &fc->id);
p9_put_int16(bufp, P9_NOTAG, &fc->tag);
return fc;
}
/**
* p9_set_tag - set the tag field of an &p9_fcall structure
* @fc: fcall structure to set tag within
* @tag: tag id to set
*/
void p9_set_tag(struct p9_fcall *fc, u16 tag)
{
fc->tag = tag;
*(__le16 *) (fc->sdata + 5) = cpu_to_le16(tag);
}
EXPORT_SYMBOL(p9_set_tag);
/**
* p9_create_tversion - allocates and creates a T_VERSION request
* @msize: requested maximum data size
* @version: version string to negotiate
*
*/
struct p9_fcall *p9_create_tversion(u32 msize, char *version)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4 + 2 + strlen(version); /* msize[4] version[s] */
fc = p9_create_common(bufp, size, P9_TVERSION);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, msize, &fc->params.tversion.msize);
p9_put_str(bufp, version, &fc->params.tversion.version);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tversion);
/**
* p9_create_tauth - allocates and creates a T_AUTH request
* @afid: handle to use for authentication protocol
* @uname: user name attempting to authenticate
* @aname: mount specifier for remote server
* @n_uname: numeric id for user attempting to authneticate
* @dotu: 9P2000.u extension flag
*
*/
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
struct p9_fcall *p9_create_tauth(u32 afid, char *uname, char *aname,
u32 n_uname, int dotu)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
/* afid[4] uname[s] aname[s] */
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
size = 4 + 2 + 2;
if (uname)
size += strlen(uname);
if (aname)
size += strlen(aname);
if (dotu)
size += 4; /* n_uname */
fc = p9_create_common(bufp, size, P9_TAUTH);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, afid, &fc->params.tauth.afid);
p9_put_str(bufp, uname, &fc->params.tauth.uname);
p9_put_str(bufp, aname, &fc->params.tauth.aname);
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
if (dotu)
p9_put_int32(bufp, n_uname, &fc->params.tauth.n_uname);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tauth);
/**
* p9_create_tattach - allocates and creates a T_ATTACH request
* @fid: handle to use for the new mount point
* @afid: handle to use for authentication protocol
* @uname: user name attempting to attach
* @aname: mount specifier for remote server
* @n_uname: numeric id for user attempting to attach
* @n_uname: numeric id for user attempting to attach
* @dotu: 9P2000.u extension flag
*
*/
struct p9_fcall *
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
p9_create_tattach(u32 fid, u32 afid, char *uname, char *aname,
u32 n_uname, int dotu)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
/* fid[4] afid[4] uname[s] aname[s] */
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
size = 4 + 4 + 2 + 2;
if (uname)
size += strlen(uname);
if (aname)
size += strlen(aname);
if (dotu)
size += 4; /* n_uname */
fc = p9_create_common(bufp, size, P9_TATTACH);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tattach.fid);
p9_put_int32(bufp, afid, &fc->params.tattach.afid);
p9_put_str(bufp, uname, &fc->params.tattach.uname);
p9_put_str(bufp, aname, &fc->params.tattach.aname);
9p: attach-per-user The 9P2000 protocol requires the authentication and permission checks to be done in the file server. For that reason every user that accesses the file server tree has to authenticate and attach to the server separately. Multiple users can share the same connection to the server. Currently v9fs does a single attach and executes all I/O operations as a single user. This makes using v9fs in multiuser environment unsafe as it depends on the client doing the permission checking. This patch improves the 9P2000 support by allowing every user to attach separately. The patch defines three modes of access (new mount option 'access'): - attach-per-user (access=user) (default mode for 9P2000.u) If a user tries to access a file served by v9fs for the first time, v9fs sends an attach command to the server (Tattach) specifying the user. If the attach succeeds, the user can access the v9fs tree. As there is no uname->uid (string->integer) mapping yet, this mode works only with the 9P2000.u dialect. - allow only one user to access the tree (access=<uid>) Only the user with uid can access the v9fs tree. Other users that attempt to access it will get EPERM error. - do all operations as a single user (access=any) (default for 9P2000) V9fs does a single attach and all operations are done as a single user. If this mode is selected, the v9fs behavior is identical with the current one. Signed-off-by: Latchesar Ionkov <lucho@ionkov.net> Signed-off-by: Eric Van Hensbergen <ericvh@gmail.com>
2007-10-17 13:31:07 -06:00
if (dotu)
p9_put_int32(bufp, n_uname, &fc->params.tattach.n_uname);
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tattach);
/**
* p9_create_tflush - allocates and creates a T_FLUSH request
* @oldtag: tag id for the transaction we are attempting to cancel
*
*/
struct p9_fcall *p9_create_tflush(u16 oldtag)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 2; /* oldtag[2] */
fc = p9_create_common(bufp, size, P9_TFLUSH);
if (IS_ERR(fc))
goto error;
p9_put_int16(bufp, oldtag, &fc->params.tflush.oldtag);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tflush);
/**
* p9_create_twalk - allocates and creates a T_FLUSH request
* @fid: handle we are traversing from
* @newfid: a new handle for this transaction
* @nwname: number of path elements to traverse
* @wnames: array of path elements
*
*/
struct p9_fcall *p9_create_twalk(u32 fid, u32 newfid, u16 nwname,
char **wnames)
{
int i, size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
if (nwname > P9_MAXWELEM) {
P9_DPRINTK(P9_DEBUG_ERROR, "nwname > %d\n", P9_MAXWELEM);
return NULL;
}
size = 4 + 4 + 2; /* fid[4] newfid[4] nwname[2] ... */
for (i = 0; i < nwname; i++) {
size += 2 + strlen(wnames[i]); /* wname[s] */
}
fc = p9_create_common(bufp, size, P9_TWALK);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.twalk.fid);
p9_put_int32(bufp, newfid, &fc->params.twalk.newfid);
p9_put_int16(bufp, nwname, &fc->params.twalk.nwname);
for (i = 0; i < nwname; i++) {
p9_put_str(bufp, wnames[i], &fc->params.twalk.wnames[i]);
}
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_twalk);
/**
* p9_create_topen - allocates and creates a T_OPEN request
* @fid: handle we are trying to open
* @mode: what mode we are trying to open the file in
*
*/
struct p9_fcall *p9_create_topen(u32 fid, u8 mode)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4 + 1; /* fid[4] mode[1] */
fc = p9_create_common(bufp, size, P9_TOPEN);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.topen.fid);
p9_put_int8(bufp, mode, &fc->params.topen.mode);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_topen);
/**
* p9_create_tcreate - allocates and creates a T_CREATE request
* @fid: handle of directory we are trying to create in
* @name: name of the file we are trying to create
* @perm: permissions for the file we are trying to create
* @mode: what mode we are trying to open the file in
* @extension: 9p2000.u extension string (for special files)
* @dotu: 9p2000.u enabled flag
*
* Note: Plan 9 create semantics include opening the resulting file
* which is why mode is included.
*/
struct p9_fcall *p9_create_tcreate(u32 fid, char *name, u32 perm, u8 mode,
char *extension, int dotu)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
/* fid[4] name[s] perm[4] mode[1] */
size = 4 + 2 + strlen(name) + 4 + 1;
if (dotu) {
size += 2 + /* extension[s] */
(extension == NULL ? 0 : strlen(extension));
}
fc = p9_create_common(bufp, size, P9_TCREATE);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tcreate.fid);
p9_put_str(bufp, name, &fc->params.tcreate.name);
p9_put_int32(bufp, perm, &fc->params.tcreate.perm);
p9_put_int8(bufp, mode, &fc->params.tcreate.mode);
if (dotu)
p9_put_str(bufp, extension, &fc->params.tcreate.extension);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tcreate);
/**
* p9_create_tread - allocates and creates a T_READ request
* @fid: handle of the file we are trying to read
* @offset: offset to start reading from
* @count: how many bytes to read
*/
struct p9_fcall *p9_create_tread(u32 fid, u64 offset, u32 count)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4 + 8 + 4; /* fid[4] offset[8] count[4] */
fc = p9_create_common(bufp, size, P9_TREAD);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tread.fid);
p9_put_int64(bufp, offset, &fc->params.tread.offset);
p9_put_int32(bufp, count, &fc->params.tread.count);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tread);
/**
* p9_create_twrite - allocates and creates a T_WRITE request from the kernel
* @fid: handle of the file we are trying to write
* @offset: offset to start writing at
* @count: how many bytes to write
* @data: data to write
*
* This function will create a requst with data buffers from the kernel
* such as the page cache.
*/
struct p9_fcall *p9_create_twrite(u32 fid, u64 offset, u32 count,
const char *data)
{
int size, err;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
/* fid[4] offset[8] count[4] data[count] */
size = 4 + 8 + 4 + count;
fc = p9_create_common(bufp, size, P9_TWRITE);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.twrite.fid);
p9_put_int64(bufp, offset, &fc->params.twrite.offset);
p9_put_int32(bufp, count, &fc->params.twrite.count);
err = p9_put_data(bufp, data, count, &fc->params.twrite.data);
if (err) {
kfree(fc);
fc = ERR_PTR(err);
goto error;
}
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_twrite);
/**
* p9_create_twrite_u - allocates and creates a T_WRITE request from userspace
* @fid: handle of the file we are trying to write
* @offset: offset to start writing at
* @count: how many bytes to write
* @data: data to write
*
* This function will create a request with data buffers from userspace
*/
struct p9_fcall *p9_create_twrite_u(u32 fid, u64 offset, u32 count,
const char __user *data)
{
int size, err;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
/* fid[4] offset[8] count[4] data[count] */
size = 4 + 8 + 4 + count;
fc = p9_create_common(bufp, size, P9_TWRITE);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.twrite.fid);
p9_put_int64(bufp, offset, &fc->params.twrite.offset);
p9_put_int32(bufp, count, &fc->params.twrite.count);
err = p9_put_user_data(bufp, data, count, &fc->params.twrite.data);
if (err) {
kfree(fc);
fc = ERR_PTR(err);
goto error;
}
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_twrite_u);
/**
* p9_create_tclunk - allocate a request to forget about a file handle
* @fid: handle of the file we closing or forgetting about
*
* clunk is used both to close open files and to discard transient handles
* which may be created during meta-data operations and hierarchy traversal.
*/
struct p9_fcall *p9_create_tclunk(u32 fid)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4; /* fid[4] */
fc = p9_create_common(bufp, size, P9_TCLUNK);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tclunk.fid);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tclunk);
/**
* p9_create_tremove - allocate and create a request to remove a file
* @fid: handle of the file or directory we are removing
*
*/
struct p9_fcall *p9_create_tremove(u32 fid)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4; /* fid[4] */
fc = p9_create_common(bufp, size, P9_TREMOVE);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tremove.fid);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tremove);
/**
* p9_create_tstat - allocate and populate a request for attributes
* @fid: handle of the file or directory we are trying to get the attributes of
*
*/
struct p9_fcall *p9_create_tstat(u32 fid)
{
int size;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
size = 4; /* fid[4] */
fc = p9_create_common(bufp, size, P9_TSTAT);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.tstat.fid);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_tstat);
/**
* p9_create_tstat - allocate and populate a request to change attributes
* @fid: handle of the file or directory we are trying to change
* @wstat: &p9_stat structure with attributes we wish to set
* @dotu: 9p2000.u enabled flag
*
*/
struct p9_fcall *p9_create_twstat(u32 fid, struct p9_wstat *wstat,
int dotu)
{
int size, statsz;
struct p9_fcall *fc;
struct cbuf buffer;
struct cbuf *bufp = &buffer;
statsz = p9_size_wstat(wstat, dotu);
size = 4 + 2 + 2 + statsz; /* fid[4] stat[n] */
fc = p9_create_common(bufp, size, P9_TWSTAT);
if (IS_ERR(fc))
goto error;
p9_put_int32(bufp, fid, &fc->params.twstat.fid);
buf_put_int16(bufp, statsz + 2);
p9_put_wstat(bufp, wstat, &fc->params.twstat.stat, statsz, dotu);
if (buf_check_overflow(bufp)) {
kfree(fc);
fc = ERR_PTR(-ENOMEM);
}
error:
return fc;
}
EXPORT_SYMBOL(p9_create_twstat);