freebsd-nq/contrib/lib9p/pack.c
Jakub Wojciech Klama 134e17798c Import lib9p 7ddb1164407da19b9b1afb83df83ae65a71a9a66.
Approved by:	trasz
MFC after:	1 month
Sponsored by:	Conclusive Engineering (development), vStack.com (funding)
2020-05-14 19:57:52 +00:00

994 lines
23 KiB
C

/*
* Copyright 2016 Jakub Klama <jceel@FreeBSD.org>
* All rights reserved
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted providing that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
* IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*/
/*
* Based on libixp code: ©2007-2010 Kris Maglione <maglione.k at Gmail>
*/
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <sys/types.h>
#include <sys/param.h>
#ifdef __APPLE__
# include "apple_endian.h"
#else
# include <sys/endian.h>
#endif
#include <sys/uio.h>
#include "lib9p.h"
#include "lib9p_impl.h"
#include "log.h"
#define N(ary) (sizeof(ary) / sizeof(*ary))
#define STRING_SIZE(s) (L9P_WORD + (s != NULL ? (uint16_t)strlen(s) : 0))
#define QID_SIZE (L9P_BYTE + L9P_DWORD + L9P_QWORD)
static ssize_t l9p_iov_io(struct l9p_message *, void *, size_t);
static inline ssize_t l9p_pu8(struct l9p_message *, uint8_t *);
static inline ssize_t l9p_pu16(struct l9p_message *, uint16_t *);
static inline ssize_t l9p_pu32(struct l9p_message *, uint32_t *);
static inline ssize_t l9p_pu64(struct l9p_message *, uint64_t *);
static ssize_t l9p_pustring(struct l9p_message *, char **s);
static ssize_t l9p_pustrings(struct l9p_message *, uint16_t *, char **, size_t);
static ssize_t l9p_puqid(struct l9p_message *, struct l9p_qid *);
static ssize_t l9p_puqids(struct l9p_message *, uint16_t *, struct l9p_qid *q);
/*
* Transfer data from incoming request, or to outgoing response,
* using msg to track position and direction within request/response.
*
* Returns the number of bytes actually transferred (which is always
* just len itself, converted to signed), or -1 if we ran out of space.
*
* Note that if we return -1, subsequent l9p_iov_io() calls with
* the same (and not-reset) msg and len > 0 will also return -1.
* This means most users can just check the *last* call for failure.
*/
static ssize_t
l9p_iov_io(struct l9p_message *msg, void *buffer, size_t len)
{
size_t done = 0;
size_t left = len;
assert(msg != NULL);
if (len == 0)
return (0);
if (msg->lm_cursor_iov >= msg->lm_niov)
return (-1);
assert(buffer != NULL);
while (left > 0) {
size_t idx = msg->lm_cursor_iov;
size_t space = msg->lm_iov[idx].iov_len - msg->lm_cursor_offset;
size_t towrite = MIN(space, left);
if (msg->lm_mode == L9P_PACK) {
memcpy((char *)msg->lm_iov[idx].iov_base +
msg->lm_cursor_offset, (char *)buffer + done,
towrite);
}
if (msg->lm_mode == L9P_UNPACK) {
memcpy((char *)buffer + done,
(char *)msg->lm_iov[idx].iov_base +
msg->lm_cursor_offset, towrite);
}
msg->lm_cursor_offset += towrite;
done += towrite;
left -= towrite;
if (space - towrite == 0) {
/* Advance to next iov */
msg->lm_cursor_iov++;
msg->lm_cursor_offset = 0;
if (msg->lm_cursor_iov >= msg->lm_niov && left > 0)
return (-1);
}
}
msg->lm_size += done;
return ((ssize_t)done);
}
/*
* Pack or unpack a byte (8 bits).
*
* Returns 1 (success, 1 byte) or -1 (error).
*/
static inline ssize_t
l9p_pu8(struct l9p_message *msg, uint8_t *val)
{
return (l9p_iov_io(msg, val, sizeof (uint8_t)));
}
/*
* Pack or unpack 16-bit value.
*
* Returns 2 or -1.
*/
static inline ssize_t
l9p_pu16(struct l9p_message *msg, uint16_t *val)
{
#if _BYTE_ORDER != _LITTLE_ENDIAN
/*
* The ifdefs are annoying, but there is no need
* for all of this foolery on little-endian hosts,
* and I don't expect the compiler to optimize it
* all away.
*/
uint16_t copy;
ssize_t ret;
if (msg->lm_mode == L9P_PACK) {
copy = htole16(*val);
return (l9p_iov_io(msg, &copy, sizeof (uint16_t)));
}
ret = l9p_iov_io(msg, val, sizeof (uint16_t));
*val = le16toh(*val);
return (ret);
#else
return (l9p_iov_io(msg, val, sizeof (uint16_t)));
#endif
}
/*
* Pack or unpack 32-bit value.
*
* Returns 4 or -1.
*/
static inline ssize_t
l9p_pu32(struct l9p_message *msg, uint32_t *val)
{
#if _BYTE_ORDER != _LITTLE_ENDIAN
uint32_t copy;
ssize_t ret;
if (msg->lm_mode == L9P_PACK) {
copy = htole32(*val);
return (l9p_iov_io(msg, &copy, sizeof (uint32_t)));
}
ret = l9p_iov_io(msg, val, sizeof (uint32_t));
*val = le32toh(*val);
return (ret);
#else
return (l9p_iov_io(msg, val, sizeof (uint32_t)));
#endif
}
/*
* Pack or unpack 64-bit value.
*
* Returns 8 or -1.
*/
static inline ssize_t
l9p_pu64(struct l9p_message *msg, uint64_t *val)
{
#if _BYTE_ORDER != _LITTLE_ENDIAN
uint64_t copy;
ssize_t ret;
if (msg->lm_mode == L9P_PACK) {
copy = htole64(*val);
return (l9p_iov_io(msg, &copy, sizeof (uint64_t)));
}
ret = l9p_iov_io(msg, val, sizeof (uint32_t));
*val = le64toh(*val);
return (ret);
#else
return (l9p_iov_io(msg, val, sizeof (uint64_t)));
#endif
}
/*
* Pack or unpack a string, encoded as 2-byte length followed by
* string bytes. The returned length is 2 greater than the
* length of the string itself.
*
* When unpacking, this allocates a new string (NUL-terminated).
*
* Return -1 on error (not space, or failed to allocate string,
* or illegal string).
*
* Note that pustring (and hence pustrings) can return an error
* even when l9p_iov_io succeeds.
*/
static ssize_t
l9p_pustring(struct l9p_message *msg, char **s)
{
uint16_t len;
if (msg->lm_mode == L9P_PACK)
len = *s != NULL ? (uint16_t)strlen(*s) : 0;
if (l9p_pu16(msg, &len) < 0)
return (-1);
if (msg->lm_mode == L9P_UNPACK) {
*s = l9p_calloc(1, len + 1);
if (*s == NULL)
return (-1);
}
if (l9p_iov_io(msg, *s, len) < 0)
return (-1);
if (msg->lm_mode == L9P_UNPACK) {
/*
* An embedded NUL byte in a string is illegal.
* We don't necessarily have to check (we'll just
* treat it as a shorter string), but checking
* seems like a good idea.
*/
if (memchr(*s, '\0', len) != NULL)
return (-1);
}
return ((ssize_t)len + 2);
}
/*
* Pack or unpack a number (*num) of strings (but at most max of
* them).
*
* Returns the number of bytes transferred, including the packed
* number of strings. If packing and the packed number of strings
* was reduced, the original *num value is unchanged; only the
* wire-format number is reduced. If unpacking and the input
* number of strings exceeds the max, the incoming *num is reduced
* to lim, if needed. (NOTE ASYMMETRY HERE!)
*
* Returns -1 on error.
*/
static ssize_t
l9p_pustrings(struct l9p_message *msg, uint16_t *num, char **strings,
size_t max)
{
size_t i, lim;
ssize_t r, ret;
uint16_t adjusted;
if (msg->lm_mode == L9P_PACK) {
lim = *num;
if (lim > max)
lim = max;
adjusted = (uint16_t)lim;
r = l9p_pu16(msg, &adjusted);
} else {
r = l9p_pu16(msg, num);
lim = *num;
if (lim > max)
*num = (uint16_t)(lim = max);
}
if (r < 0)
return (-1);
for (i = 0; i < lim; i++) {
ret = l9p_pustring(msg, &strings[i]);
if (ret < 1)
return (-1);
r += ret;
}
return (r);
}
/*
* Pack or unpack a qid.
*
* Returns 13 (success) or -1 (error).
*/
static ssize_t
l9p_puqid(struct l9p_message *msg, struct l9p_qid *qid)
{
ssize_t r;
uint8_t type;
if (msg->lm_mode == L9P_PACK) {
type = qid->type;
r = l9p_pu8(msg, &type);
} else {
r = l9p_pu8(msg, &type);
qid->type = type;
}
if (r > 0)
r = l9p_pu32(msg, &qid->version);
if (r > 0)
r = l9p_pu64(msg, &qid->path);
return (r > 0 ? QID_SIZE : r);
}
/*
* Pack or unpack *num qids.
*
* Returns 2 + 13 * *num (after possibly setting *num), or -1 on error.
*/
static ssize_t
l9p_puqids(struct l9p_message *msg, uint16_t *num, struct l9p_qid *qids)
{
size_t i, lim;
ssize_t ret, r;
r = l9p_pu16(msg, num);
if (r > 0) {
for (i = 0, lim = *num; i < lim; i++) {
ret = l9p_puqid(msg, &qids[i]);
if (ret < 0)
return (-1);
r += ret;
}
}
return (r);
}
/*
* Pack or unpack a l9p_stat.
*
* These have variable size, and the size further depends on
* the protocol version.
*
* Returns the number of bytes packed/unpacked, or -1 on error.
*/
ssize_t
l9p_pustat(struct l9p_message *msg, struct l9p_stat *stat,
enum l9p_version version)
{
ssize_t r = 0;
uint16_t size;
/* The on-wire size field excludes the size of the size field. */
if (msg->lm_mode == L9P_PACK)
size = l9p_sizeof_stat(stat, version) - 2;
r += l9p_pu16(msg, &size);
r += l9p_pu16(msg, &stat->type);
r += l9p_pu32(msg, &stat->dev);
r += l9p_puqid(msg, &stat->qid);
r += l9p_pu32(msg, &stat->mode);
r += l9p_pu32(msg, &stat->atime);
r += l9p_pu32(msg, &stat->mtime);
r += l9p_pu64(msg, &stat->length);
r += l9p_pustring(msg, &stat->name);
r += l9p_pustring(msg, &stat->uid);
r += l9p_pustring(msg, &stat->gid);
r += l9p_pustring(msg, &stat->muid);
if (version >= L9P_2000U) {
r += l9p_pustring(msg, &stat->extension);
r += l9p_pu32(msg, &stat->n_uid);
r += l9p_pu32(msg, &stat->n_gid);
r += l9p_pu32(msg, &stat->n_muid);
}
if (r < size + 2)
return (-1);
return (r);
}
/*
* Pack or unpack a variable-length dirent.
*
* If unpacking, the name field is malloc()ed and the caller must
* free it.
*
* Returns the wire-format length, or -1 if we ran out of room.
*/
ssize_t
l9p_pudirent(struct l9p_message *msg, struct l9p_dirent *de)
{
ssize_t r, s;
r = l9p_puqid(msg, &de->qid);
r += l9p_pu64(msg, &de->offset);
r += l9p_pu8(msg, &de->type);
s = l9p_pustring(msg, &de->name);
if (r < QID_SIZE + 8 + 1 || s < 0)
return (-1);
return (r + s);
}
/*
* Pack or unpack a request or response (fcall).
*
* Returns 0 on success, -1 on error. (It's up to the caller
* to call l9p_freefcall on our failure.)
*/
int
l9p_pufcall(struct l9p_message *msg, union l9p_fcall *fcall,
enum l9p_version version)
{
uint32_t length = 0;
ssize_t r;
/*
* Get overall length, type, and tag, which should appear
* in all messages. If not even that works, abort immediately.
*/
l9p_pu32(msg, &length);
l9p_pu8(msg, &fcall->hdr.type);
r = l9p_pu16(msg, &fcall->hdr.tag);
if (r < 0)
return (-1);
/*
* Decode remainder of message. When unpacking, this may
* allocate memory, even if we fail during the decode.
* Note that the initial fcall is zeroed out, though, so
* we can just freefcall() to release whatever might have
* gotten allocated, if the unpack fails due to a short
* packet.
*/
switch (fcall->hdr.type) {
case L9P_TVERSION:
case L9P_RVERSION:
l9p_pu32(msg, &fcall->version.msize);
r = l9p_pustring(msg, &fcall->version.version);
break;
case L9P_TAUTH:
l9p_pu32(msg, &fcall->tauth.afid);
r = l9p_pustring(msg, &fcall->tauth.uname);
if (r < 0)
break;
r = l9p_pustring(msg, &fcall->tauth.aname);
if (r < 0)
break;
if (version >= L9P_2000U)
r = l9p_pu32(msg, &fcall->tauth.n_uname);
break;
case L9P_RAUTH:
r = l9p_puqid(msg, &fcall->rauth.aqid);
break;
case L9P_TATTACH:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu32(msg, &fcall->tattach.afid);
r = l9p_pustring(msg, &fcall->tattach.uname);
if (r < 0)
break;
r = l9p_pustring(msg, &fcall->tattach.aname);
if (r < 0)
break;
if (version >= L9P_2000U)
r = l9p_pu32(msg, &fcall->tattach.n_uname);
break;
case L9P_RATTACH:
r = l9p_puqid(msg, &fcall->rattach.qid);
break;
case L9P_RERROR:
r = l9p_pustring(msg, &fcall->error.ename);
if (r < 0)
break;
if (version >= L9P_2000U)
r = l9p_pu32(msg, &fcall->error.errnum);
break;
case L9P_RLERROR:
r = l9p_pu32(msg, &fcall->error.errnum);
break;
case L9P_TFLUSH:
r = l9p_pu16(msg, &fcall->tflush.oldtag);
break;
case L9P_RFLUSH:
break;
case L9P_TWALK:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu32(msg, &fcall->twalk.newfid);
r = l9p_pustrings(msg, &fcall->twalk.nwname,
fcall->twalk.wname, N(fcall->twalk.wname));
break;
case L9P_RWALK:
r = l9p_puqids(msg, &fcall->rwalk.nwqid, fcall->rwalk.wqid);
break;
case L9P_TOPEN:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pu8(msg, &fcall->topen.mode);
break;
case L9P_ROPEN:
l9p_puqid(msg, &fcall->ropen.qid);
r = l9p_pu32(msg, &fcall->ropen.iounit);
break;
case L9P_TCREATE:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tcreate.name);
if (r < 0)
break;
l9p_pu32(msg, &fcall->tcreate.perm);
r = l9p_pu8(msg, &fcall->tcreate.mode);
if (version >= L9P_2000U)
r = l9p_pustring(msg, &fcall->tcreate.extension);
break;
case L9P_RCREATE:
l9p_puqid(msg, &fcall->rcreate.qid);
r = l9p_pu32(msg, &fcall->rcreate.iounit);
break;
case L9P_TREAD:
case L9P_TREADDIR:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu64(msg, &fcall->io.offset);
r = l9p_pu32(msg, &fcall->io.count);
break;
case L9P_RREAD:
case L9P_RREADDIR:
r = l9p_pu32(msg, &fcall->io.count);
break;
case L9P_TWRITE:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu64(msg, &fcall->io.offset);
r = l9p_pu32(msg, &fcall->io.count);
break;
case L9P_RWRITE:
r = l9p_pu32(msg, &fcall->io.count);
break;
case L9P_TCLUNK:
case L9P_TSTAT:
case L9P_TREMOVE:
case L9P_TSTATFS:
r = l9p_pu32(msg, &fcall->hdr.fid);
break;
case L9P_RCLUNK:
case L9P_RREMOVE:
break;
case L9P_RSTAT:
{
uint16_t size = l9p_sizeof_stat(&fcall->rstat.stat,
version);
l9p_pu16(msg, &size);
r = l9p_pustat(msg, &fcall->rstat.stat, version);
}
break;
case L9P_TWSTAT:
{
uint16_t size;
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu16(msg, &size);
r = l9p_pustat(msg, &fcall->twstat.stat, version);
}
break;
case L9P_RWSTAT:
break;
case L9P_RSTATFS:
l9p_pu32(msg, &fcall->rstatfs.statfs.type);
l9p_pu32(msg, &fcall->rstatfs.statfs.bsize);
l9p_pu64(msg, &fcall->rstatfs.statfs.blocks);
l9p_pu64(msg, &fcall->rstatfs.statfs.bfree);
l9p_pu64(msg, &fcall->rstatfs.statfs.bavail);
l9p_pu64(msg, &fcall->rstatfs.statfs.files);
l9p_pu64(msg, &fcall->rstatfs.statfs.ffree);
l9p_pu64(msg, &fcall->rstatfs.statfs.fsid);
r = l9p_pu32(msg, &fcall->rstatfs.statfs.namelen);
break;
case L9P_TLOPEN:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pu32(msg, &fcall->tlopen.flags);
break;
case L9P_RLOPEN:
l9p_puqid(msg, &fcall->rlopen.qid);
r = l9p_pu32(msg, &fcall->rlopen.iounit);
break;
case L9P_TLCREATE:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tlcreate.name);
if (r < 0)
break;
l9p_pu32(msg, &fcall->tlcreate.flags);
l9p_pu32(msg, &fcall->tlcreate.mode);
r = l9p_pu32(msg, &fcall->tlcreate.gid);
break;
case L9P_RLCREATE:
l9p_puqid(msg, &fcall->rlcreate.qid);
r = l9p_pu32(msg, &fcall->rlcreate.iounit);
break;
case L9P_TSYMLINK:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tsymlink.name);
if (r < 0)
break;
r = l9p_pustring(msg, &fcall->tsymlink.symtgt);
if (r < 0)
break;
r = l9p_pu32(msg, &fcall->tlcreate.gid);
break;
case L9P_RSYMLINK:
r = l9p_puqid(msg, &fcall->rsymlink.qid);
break;
case L9P_TMKNOD:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tmknod.name);
if (r < 0)
break;
l9p_pu32(msg, &fcall->tmknod.mode);
l9p_pu32(msg, &fcall->tmknod.major);
l9p_pu32(msg, &fcall->tmknod.minor);
r = l9p_pu32(msg, &fcall->tmknod.gid);
break;
case L9P_RMKNOD:
r = l9p_puqid(msg, &fcall->rmknod.qid);
break;
case L9P_TRENAME:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu32(msg, &fcall->trename.dfid);
r = l9p_pustring(msg, &fcall->trename.name);
break;
case L9P_RRENAME:
break;
case L9P_TREADLINK:
r = l9p_pu32(msg, &fcall->hdr.fid);
break;
case L9P_RREADLINK:
r = l9p_pustring(msg, &fcall->rreadlink.target);
break;
case L9P_TGETATTR:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pu64(msg, &fcall->tgetattr.request_mask);
break;
case L9P_RGETATTR:
l9p_pu64(msg, &fcall->rgetattr.valid);
l9p_puqid(msg, &fcall->rgetattr.qid);
l9p_pu32(msg, &fcall->rgetattr.mode);
l9p_pu32(msg, &fcall->rgetattr.uid);
l9p_pu32(msg, &fcall->rgetattr.gid);
l9p_pu64(msg, &fcall->rgetattr.nlink);
l9p_pu64(msg, &fcall->rgetattr.rdev);
l9p_pu64(msg, &fcall->rgetattr.size);
l9p_pu64(msg, &fcall->rgetattr.blksize);
l9p_pu64(msg, &fcall->rgetattr.blocks);
l9p_pu64(msg, &fcall->rgetattr.atime_sec);
l9p_pu64(msg, &fcall->rgetattr.atime_nsec);
l9p_pu64(msg, &fcall->rgetattr.mtime_sec);
l9p_pu64(msg, &fcall->rgetattr.mtime_nsec);
l9p_pu64(msg, &fcall->rgetattr.ctime_sec);
l9p_pu64(msg, &fcall->rgetattr.ctime_nsec);
l9p_pu64(msg, &fcall->rgetattr.btime_sec);
l9p_pu64(msg, &fcall->rgetattr.btime_nsec);
l9p_pu64(msg, &fcall->rgetattr.gen);
r = l9p_pu64(msg, &fcall->rgetattr.data_version);
break;
case L9P_TSETATTR:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu32(msg, &fcall->tsetattr.valid);
l9p_pu32(msg, &fcall->tsetattr.mode);
l9p_pu32(msg, &fcall->tsetattr.uid);
l9p_pu32(msg, &fcall->tsetattr.gid);
l9p_pu64(msg, &fcall->tsetattr.size);
l9p_pu64(msg, &fcall->tsetattr.atime_sec);
l9p_pu64(msg, &fcall->tsetattr.atime_nsec);
l9p_pu64(msg, &fcall->tsetattr.mtime_sec);
r = l9p_pu64(msg, &fcall->tsetattr.mtime_nsec);
break;
case L9P_RSETATTR:
break;
case L9P_TXATTRWALK:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu32(msg, &fcall->txattrwalk.newfid);
r = l9p_pustring(msg, &fcall->txattrwalk.name);
break;
case L9P_RXATTRWALK:
r = l9p_pu64(msg, &fcall->rxattrwalk.size);
break;
case L9P_TXATTRCREATE:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->txattrcreate.name);
if (r < 0)
break;
l9p_pu64(msg, &fcall->txattrcreate.attr_size);
r = l9p_pu32(msg, &fcall->txattrcreate.flags);
break;
case L9P_RXATTRCREATE:
break;
case L9P_TFSYNC:
r = l9p_pu32(msg, &fcall->hdr.fid);
break;
case L9P_RFSYNC:
break;
case L9P_TLOCK:
l9p_pu32(msg, &fcall->hdr.fid);
l9p_pu8(msg, &fcall->tlock.type);
l9p_pu32(msg, &fcall->tlock.flags);
l9p_pu64(msg, &fcall->tlock.start);
l9p_pu64(msg, &fcall->tlock.length);
l9p_pu32(msg, &fcall->tlock.proc_id);
r = l9p_pustring(msg, &fcall->tlock.client_id);
break;
case L9P_RLOCK:
r = l9p_pu8(msg, &fcall->rlock.status);
break;
case L9P_TGETLOCK:
l9p_pu32(msg, &fcall->hdr.fid);
/* FALLTHROUGH */
case L9P_RGETLOCK:
l9p_pu8(msg, &fcall->getlock.type);
l9p_pu64(msg, &fcall->getlock.start);
l9p_pu64(msg, &fcall->getlock.length);
l9p_pu32(msg, &fcall->getlock.proc_id);
r = l9p_pustring(msg, &fcall->getlock.client_id);
break;
case L9P_TLINK:
l9p_pu32(msg, &fcall->tlink.dfid);
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tlink.name);
break;
case L9P_RLINK:
break;
case L9P_TMKDIR:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tmkdir.name);
if (r < 0)
break;
l9p_pu32(msg, &fcall->tmkdir.mode);
r = l9p_pu32(msg, &fcall->tmkdir.gid);
break;
case L9P_RMKDIR:
r = l9p_puqid(msg, &fcall->rmkdir.qid);
break;
case L9P_TRENAMEAT:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->trenameat.oldname);
if (r < 0)
break;
l9p_pu32(msg, &fcall->trenameat.newdirfid);
r = l9p_pustring(msg, &fcall->trenameat.newname);
break;
case L9P_RRENAMEAT:
break;
case L9P_TUNLINKAT:
l9p_pu32(msg, &fcall->hdr.fid);
r = l9p_pustring(msg, &fcall->tunlinkat.name);
if (r < 0)
break;
r = l9p_pu32(msg, &fcall->tunlinkat.flags);
break;
case L9P_RUNLINKAT:
break;
default:
L9P_LOG(L9P_ERROR, "%s(): missing case for type %d",
__func__, fcall->hdr.type);
break;
}
/* Check for over- or under-run, or pustring error. */
if (r < 0)
return (-1);
if (msg->lm_mode == L9P_PACK) {
/* Rewind to the beginning and install size at front. */
uint32_t len = (uint32_t)msg->lm_size;
msg->lm_cursor_offset = 0;
msg->lm_cursor_iov = 0;
/*
* Subtract 4 bytes from current size, becase we're
* overwriting size (rewinding message to the beginning)
* and writing again, which will increase it 4 more.
*/
msg->lm_size -= sizeof(uint32_t);
if (fcall->hdr.type == L9P_RREAD ||
fcall->hdr.type == L9P_RREADDIR)
len += fcall->io.count;
l9p_pu32(msg, &len);
}
return (0);
}
/*
* Free any strings or other data malloc'ed in the process of
* packing or unpacking an fcall.
*/
void
l9p_freefcall(union l9p_fcall *fcall)
{
uint16_t i;
switch (fcall->hdr.type) {
case L9P_TVERSION:
case L9P_RVERSION:
free(fcall->version.version);
return;
case L9P_TATTACH:
free(fcall->tattach.aname);
free(fcall->tattach.uname);
return;
case L9P_TWALK:
for (i = 0; i < fcall->twalk.nwname; i++)
free(fcall->twalk.wname[i]);
return;
case L9P_TCREATE:
case L9P_TOPEN:
free(fcall->tcreate.name);
free(fcall->tcreate.extension);
return;
case L9P_RSTAT:
l9p_freestat(&fcall->rstat.stat);
return;
case L9P_TWSTAT:
l9p_freestat(&fcall->twstat.stat);
return;
case L9P_TLCREATE:
free(fcall->tlcreate.name);
return;
case L9P_TSYMLINK:
free(fcall->tsymlink.name);
free(fcall->tsymlink.symtgt);
return;
case L9P_TMKNOD:
free(fcall->tmknod.name);
return;
case L9P_TRENAME:
free(fcall->trename.name);
return;
case L9P_RREADLINK:
free(fcall->rreadlink.target);
return;
case L9P_TXATTRWALK:
free(fcall->txattrwalk.name);
return;
case L9P_TXATTRCREATE:
free(fcall->txattrcreate.name);
return;
case L9P_TLOCK:
free(fcall->tlock.client_id);
return;
case L9P_TGETLOCK:
case L9P_RGETLOCK:
free(fcall->getlock.client_id);
return;
case L9P_TLINK:
free(fcall->tlink.name);
return;
case L9P_TMKDIR:
free(fcall->tmkdir.name);
return;
case L9P_TRENAMEAT:
free(fcall->trenameat.oldname);
free(fcall->trenameat.newname);
return;
case L9P_TUNLINKAT:
free(fcall->tunlinkat.name);
return;
}
}
void
l9p_freestat(struct l9p_stat *stat)
{
free(stat->name);
free(stat->extension);
free(stat->uid);
free(stat->gid);
free(stat->muid);
}
uint16_t
l9p_sizeof_stat(struct l9p_stat *stat, enum l9p_version version)
{
uint16_t size = L9P_WORD /* size */
+ L9P_WORD /* type */
+ L9P_DWORD /* dev */
+ QID_SIZE /* qid */
+ 3 * L9P_DWORD /* mode, atime, mtime */
+ L9P_QWORD /* length */
+ STRING_SIZE(stat->name)
+ STRING_SIZE(stat->uid)
+ STRING_SIZE(stat->gid)
+ STRING_SIZE(stat->muid);
if (version >= L9P_2000U) {
size += STRING_SIZE(stat->extension)
+ 3 * L9P_DWORD;
}
return (size);
}