freebsd-skq/sys/fs/nfs/nfs_commonsubs.c

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/*-
* Copyright (c) 1989, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Rick Macklem at The University of Guelph.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided 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.
* 3. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``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 REGENTS OR CONTRIBUTORS 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.
*
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* These functions support the macros and help fiddle mbuf chains for
* the nfs op functions. They do things like create the rpc header and
* copy data between mbuf chains and uio lists.
*/
#ifndef APPLEKEXT
#include "opt_inet6.h"
#include <fs/nfs/nfsport.h>
#include <security/mac/mac_framework.h>
/*
* Data items converted to xdr at startup, since they are constant
* This is kinda hokey, but may save a little time doing byte swaps
*/
u_int32_t newnfs_true, newnfs_false, newnfs_xdrneg1;
/* And other global data */
nfstype nfsv34_type[9] = { NFNON, NFREG, NFDIR, NFBLK, NFCHR, NFLNK, NFSOCK,
NFFIFO, NFNON };
enum vtype newnv2tov_type[8] = { VNON, VREG, VDIR, VBLK, VCHR, VLNK, VNON, VNON };
enum vtype nv34tov_type[8]={ VNON, VREG, VDIR, VBLK, VCHR, VLNK, VSOCK, VFIFO };
struct timeval nfsboottime; /* Copy boottime once, so it never changes */
int nfscl_ticks;
int nfsrv_useacl = 1;
struct nfssockreq nfsrv_nfsuserdsock;
int nfsrv_nfsuserd = 0;
struct nfsreqhead nfsd_reqq;
uid_t nfsrv_defaultuid;
gid_t nfsrv_defaultgid;
int nfsrv_lease = NFSRV_LEASE;
int ncl_mbuf_mlen = MLEN;
int nfsd_enable_stringtouid = 0;
NFSNAMEIDMUTEX;
NFSSOCKMUTEX;
extern int nfsrv_lughashsize;
/*
* This array of structures indicates, for V4:
* retfh - which of 3 types of calling args are used
* 0 - doesn't change cfh or use a sfh
* 1 - replaces cfh with a new one (unless it returns an error status)
* 2 - uses cfh and sfh
* needscfh - if the op wants a cfh and premtime
* 0 - doesn't use a cfh
* 1 - uses a cfh, but doesn't want pre-op attributes
* 2 - uses a cfh and wants pre-op attributes
* savereply - indicates a non-idempotent Op
* 0 - not non-idempotent
* 1 - non-idempotent
* Ops that are ordered via seqid# are handled separately from these
* non-idempotent Ops.
* Define it here, since it is used by both the client and server.
*/
struct nfsv4_opflag nfsv4_opflag[NFSV41_NOPS] = {
Fix NFSv4.1 client recovery from NFS4ERR_BAD_SESSION errors. For most NFSv4.1 servers, a NFS4ERR_BAD_SESSION error is a rare failure that indicates that the server has lost session/open/lock state. However, recent testing by cperciva@ against the AmazonEFS server found several problems with client recovery from this due to it generating this failure frequently. Briefly, the problems fixed are: - If all session slots were in use at the time of the failure, some processes would continue to loop waiting for a slot on the old session forever. - If an RPC that doesn't use open/lock state failed with NFS4ERR_BAD_SESSION, it would fail the RPC/syscall instead of initiating recovery and then looping to retry the RPC. - If a successful reply to an RPC for an old session wasn't processed until after a new session was created for a NFS4ERR_BAD_SESSION error, it would erroneously update the new session and corrupt it. - The use of the first element of the session list in the nfs mount structure (which is always the current metadata session) was slightly racey. With changes for the above problems it became more racey, so all uses of this head pointer was wrapped with a NFSLOCKMNT()/NFSUNLOCKMNT(). - Although the kernel malloc() usually allocates more bytes than requested and, as such, this wouldn't have caused problems, the allocation of a session structure was 1 byte smaller than it should have been. (Null termination byte for the string not included in byte count.) There are probably still problems with a pNFS data server that fails with NFS4ERR_BAD_SESSION, but I have no server that does this to test against (the AmazonEFS server doesn't do pNFS), so I can't fix these yet. Although this patch is fairly large, it should only affect the handling of NFS4ERR_BAD_SESSION error replies from an NFSv4.1 server. Thanks go to cperciva@ for the extension testing he did to help isolate/fix these problems. Reported by: cperciva Tested by: cperciva MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D8745
2016-12-23 23:14:53 +00:00
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* undef */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* undef */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* undef */
{ 0, 1, 0, 0, LK_SHARED, 1, 1 }, /* Access */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Close */
{ 0, 2, 0, 1, LK_EXCLUSIVE, 1, 1 }, /* Commit */
{ 1, 2, 1, 1, LK_EXCLUSIVE, 1, 1 }, /* Create */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Delegpurge */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Delegreturn */
{ 0, 1, 0, 0, LK_SHARED, 1, 1 }, /* Getattr */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* GetFH */
{ 2, 1, 1, 1, LK_EXCLUSIVE, 1, 1 }, /* Link */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Lock */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* LockT */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* LockU */
{ 1, 2, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Lookup */
{ 1, 2, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Lookupp */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* NVerify */
{ 1, 1, 0, 1, LK_EXCLUSIVE, 1, 0 }, /* Open */
{ 1, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* OpenAttr */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* OpenConfirm */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* OpenDowngrade */
{ 1, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* PutFH */
{ 1, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* PutPubFH */
{ 1, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* PutRootFH */
{ 0, 1, 0, 0, LK_SHARED, 1, 0 }, /* Read */
{ 0, 1, 0, 0, LK_SHARED, 1, 1 }, /* Readdir */
{ 0, 1, 0, 0, LK_SHARED, 1, 1 }, /* ReadLink */
{ 0, 2, 1, 1, LK_EXCLUSIVE, 1, 1 }, /* Remove */
{ 2, 1, 1, 1, LK_EXCLUSIVE, 1, 1 }, /* Rename */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Renew */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* RestoreFH */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* SaveFH */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* SecInfo */
{ 0, 2, 1, 1, LK_EXCLUSIVE, 1, 0 }, /* Setattr */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* SetClientID */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* SetClientIDConfirm */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Verify */
{ 0, 2, 1, 1, LK_EXCLUSIVE, 1, 0 }, /* Write */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* ReleaseLockOwner */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Backchannel Ctrl */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Bind Conn to Sess */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 0, 0 }, /* Exchange ID */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 0, 0 }, /* Create Session */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 0, 0 }, /* Destroy Session */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Free StateID */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Get Dir Deleg */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Get Device Info */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Get Device List */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Layout Commit */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Layout Get */
{ 0, 1, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Layout Return */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Secinfo No name */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Sequence */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Set SSV */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Test StateID */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 1 }, /* Want Delegation */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 0, 0 }, /* Destroy ClientID */
{ 0, 0, 0, 0, LK_EXCLUSIVE, 1, 0 }, /* Reclaim Complete */
};
#endif /* !APPLEKEXT */
static int ncl_mbuf_mhlen = MHLEN;
static int nfsrv_usercnt = 0;
static int nfsrv_dnsnamelen;
static u_char *nfsrv_dnsname = NULL;
static int nfsrv_usermax = 999999999;
struct nfsrv_lughash {
struct mtx mtx;
struct nfsuserhashhead lughead;
};
static struct nfsrv_lughash *nfsuserhash;
static struct nfsrv_lughash *nfsusernamehash;
static struct nfsrv_lughash *nfsgrouphash;
static struct nfsrv_lughash *nfsgroupnamehash;
/*
* This static array indicates whether or not the RPC generates a large
* reply. This is used by nfs_reply() to decide whether or not an mbuf
* cluster should be allocated. (If a cluster is required by an RPC
* marked 0 in this array, the code will still work, just not quite as
* efficiently.)
*/
int nfs_bigreply[NFSV41_NPROCS] = { 0, 0, 0, 1, 0, 1, 1, 0, 0, 0, 0,
0, 0, 0, 0, 0, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0 };
/* local functions */
static int nfsrv_skipace(struct nfsrv_descript *nd, int *acesizep);
static void nfsv4_wanted(struct nfsv4lock *lp);
static int nfsrv_cmpmixedcase(u_char *cp, u_char *cp2, int len);
static int nfsrv_getuser(int procnum, uid_t uid, gid_t gid, char *name,
NFSPROC_T *p);
static void nfsrv_removeuser(struct nfsusrgrp *usrp, int isuser);
static int nfsrv_getrefstr(struct nfsrv_descript *, u_char **, u_char **,
int *, int *);
static void nfsrv_refstrbigenough(int, u_char **, u_char **, int *);
#ifndef APPLE
/*
* copies mbuf chain to the uio scatter/gather list
*/
int
nfsm_mbufuio(struct nfsrv_descript *nd, struct uio *uiop, int siz)
{
char *mbufcp, *uiocp;
int xfer, left, len;
mbuf_t mp;
long uiosiz, rem;
int error = 0;
mp = nd->nd_md;
mbufcp = nd->nd_dpos;
len = NFSMTOD(mp, caddr_t) + mbuf_len(mp) - mbufcp;
rem = NFSM_RNDUP(siz) - siz;
while (siz > 0) {
if (uiop->uio_iovcnt <= 0 || uiop->uio_iov == NULL) {
error = EBADRPC;
goto out;
}
left = uiop->uio_iov->iov_len;
uiocp = uiop->uio_iov->iov_base;
if (left > siz)
left = siz;
uiosiz = left;
while (left > 0) {
while (len == 0) {
mp = mbuf_next(mp);
if (mp == NULL) {
error = EBADRPC;
goto out;
}
mbufcp = NFSMTOD(mp, caddr_t);
len = mbuf_len(mp);
KASSERT(len >= 0,
("len %d, corrupted mbuf?", len));
}
xfer = (left > len) ? len : left;
#ifdef notdef
/* Not Yet.. */
if (uiop->uio_iov->iov_op != NULL)
(*(uiop->uio_iov->iov_op))
(mbufcp, uiocp, xfer);
else
#endif
if (uiop->uio_segflg == UIO_SYSSPACE)
NFSBCOPY(mbufcp, uiocp, xfer);
else
copyout(mbufcp, CAST_USER_ADDR_T(uiocp), xfer);
left -= xfer;
len -= xfer;
mbufcp += xfer;
uiocp += xfer;
uiop->uio_offset += xfer;
uiop->uio_resid -= xfer;
}
if (uiop->uio_iov->iov_len <= siz) {
uiop->uio_iovcnt--;
uiop->uio_iov++;
} else {
uiop->uio_iov->iov_base = (void *)
((char *)uiop->uio_iov->iov_base + uiosiz);
uiop->uio_iov->iov_len -= uiosiz;
}
siz -= uiosiz;
}
nd->nd_dpos = mbufcp;
nd->nd_md = mp;
if (rem > 0) {
if (len < rem)
error = nfsm_advance(nd, rem, len);
else
nd->nd_dpos += rem;
}
out:
NFSEXITCODE2(error, nd);
return (error);
}
#endif /* !APPLE */
/*
* Help break down an mbuf chain by setting the first siz bytes contiguous
* pointed to by returned val.
* This is used by the macro NFSM_DISSECT for tough
* cases.
*/
APPLESTATIC void *
Revamp the old NFS server's File Handle Affinity (FHA) code so that it will work with either the old or new server. The FHA code keeps a cache of currently active file handles for NFSv2 and v3 requests, so that read and write requests for the same file are directed to the same group of threads (reads) or thread (writes). It does not currently work for NFSv4 requests. They are more complex, and will take more work to support. This improves read-ahead performance, especially with ZFS, if the FHA tuning parameters are configured appropriately. Without the FHA code, concurrent reads that are part of a sequential read from a file will be directed to separate NFS threads. This has the effect of confusing the ZFS zfetch (prefetch) code and makes sequential reads significantly slower with clients like Linux that do a lot of prefetching. The FHA code has also been updated to direct write requests to nearby file offsets to the same thread in the same way it batches reads, and the FHA code will now also send writes to multiple threads when needed. This improves sequential write performance in ZFS, because writes to a file are now more ordered. Since NFS writes (generally less than 64K) are smaller than the typical ZFS record size (usually 128K), out of order NFS writes to the same block can trigger a read in ZFS. Sending them down the same thread increases the odds of their being in order. In order for multiple write threads per file in the FHA code to be useful, writes in the NFS server have been changed to use a LK_SHARED vnode lock, and upgrade that to LK_EXCLUSIVE if the filesystem doesn't allow multiple writers to a file at once. ZFS is currently the only filesystem that allows multiple writers to a file, because it has internal file range locking. This change does not affect the NFSv4 code. This improves random write performance to a single file in ZFS, since we can now have multiple writers inside ZFS at one time. I have changed the default tuning parameters to a 22 bit (4MB) window size (from 256K) and unlimited commands per thread as a result of my benchmarking with ZFS. The FHA code has been updated to allow configuring the tuning parameters from loader tunable variables in addition to sysctl variables. The read offset window calculation has been slightly modified as well. Instead of having separate bins, each file handle has a rolling window of bin_shift size. This minimizes glitches in throughput when shifting from one bin to another. sys/conf/files: Add nfs_fha_new.c and nfs_fha_old.c. Compile nfs_fha.c when either the old or the new NFS server is built. sys/fs/nfs/nfsport.h, sys/fs/nfs/nfs_commonport.c: Bring in changes from Rick Macklem to newnfs_realign that allow it to operate in blocking (M_WAITOK) or non-blocking (M_NOWAIT) mode. sys/fs/nfs/nfs_commonsubs.c, sys/fs/nfs/nfs_var.h: Bring in a change from Rick Macklem to allow telling nfsm_dissect() whether or not to wait for mallocs. sys/fs/nfs/nfsm_subs.h: Bring in changes from Rick Macklem to create a new nfsm_dissect_nonblock() inline function and NFSM_DISSECT_NONBLOCK() macro. sys/fs/nfs/nfs_commonkrpc.c, sys/fs/nfsclient/nfs_clkrpc.c: Add the malloc wait flag to a newnfs_realign() call. sys/fs/nfsserver/nfs_nfsdkrpc.c: Setup the new NFS server's RPC thread pool so that it will call the FHA code. Add the malloc flag argument to newnfs_realign(). Unstaticize newnfs_nfsv3_procid[] so that we can use it in the FHA code. sys/fs/nfsserver/nfs_nfsdsocket.c: In nfsrvd_dorpc(), add NFSPROC_WRITE to the list of RPC types that use the LK_SHARED lock type. sys/fs/nfsserver/nfs_nfsdport.c: In nfsd_fhtovp(), if we're starting a write, check to see whether the underlying filesystem supports shared writes. If not, upgrade the lock type from LK_SHARED to LK_EXCLUSIVE. sys/nfsserver/nfs_fha.c: Remove all code that is specific to the NFS server implementation. Anything that is server-specific is now accessed through a callback supplied by that server's FHA shim in the new softc. There are now separate sysctls and tunables for the FHA implementations for the old and new NFS servers. The new NFS server has its tunables under vfs.nfsd.fha, the old NFS server's tunables are under vfs.nfsrv.fha as before. In fha_extract_info(), use callouts for all server-specific code. Getting file handles and offsets is now done in the individual server's shim module. In fha_hash_entry_choose_thread(), change the way we decide whether two reads are in proximity to each other. Previously, the calculation was a simple shift operation to see whether the offsets were in the same power of 2 bucket. The issue was that there would be a bucket (and therefore thread) transition, even if the reads were in close proximity. When there is a thread transition, reads wind up going somewhat out of order, and ZFS gets confused. The new calculation simply tries to see whether the offsets are within 1 << bin_shift of each other. If they are, the reads will be sent to the same thread. The effect of this change is that for sequential reads, if the client doesn't exceed the max_reqs_per_nfsd parameter and the bin_shift is set to a reasonable value (22, or 4MB works well in my tests), the reads in any sequential stream will largely be confined to a single thread. Change fha_assign() so that it takes a softc argument. It is now called from the individual server's shim code, which will pass in the softc. Change fhe_stats_sysctl() so that it takes a softc parameter. It is now called from the individual server's shim code. Add the current offset to the list of things printed out about each active thread. Change the num_reads and num_writes counters in the fha_hash_entry structure to 32-bit values, and rename them num_rw and num_exclusive, respectively, to reflect their changed usage. Add an enable sysctl and tunable that allows the user to disable the FHA code (when vfs.XXX.fha.enable = 0). This is useful for before/after performance comparisons. nfs_fha.h: Move most structure definitions out of nfs_fha.c and into the header file, so that the individual server shims can see them. Change the default bin_shift to 22 (4MB) instead of 18 (256K). Allow unlimited commands per thread. sys/nfsserver/nfs_fha_old.c, sys/nfsserver/nfs_fha_old.h, sys/fs/nfsserver/nfs_fha_new.c, sys/fs/nfsserver/nfs_fha_new.h: Add shims for the old and new NFS servers to interface with the FHA code, and callbacks for the The shims contain all of the code and definitions that are specific to the NFS servers. They setup the server-specific callbacks and set the server name for the sysctl and loader tunable variables. sys/nfsserver/nfs_srvkrpc.c: Configure the RPC code to call fhaold_assign() instead of fha_assign(). sys/modules/nfsd/Makefile: Add nfs_fha.c and nfs_fha_new.c. sys/modules/nfsserver/Makefile: Add nfs_fha_old.c. Reviewed by: rmacklem Sponsored by: Spectra Logic MFC after: 2 weeks
2013-04-17 21:00:22 +00:00
nfsm_dissct(struct nfsrv_descript *nd, int siz, int how)
{
mbuf_t mp2;
int siz2, xfer;
caddr_t p;
int left;
caddr_t retp;
retp = NULL;
left = NFSMTOD(nd->nd_md, caddr_t) + mbuf_len(nd->nd_md) - nd->nd_dpos;
while (left == 0) {
nd->nd_md = mbuf_next(nd->nd_md);
if (nd->nd_md == NULL)
return (retp);
left = mbuf_len(nd->nd_md);
nd->nd_dpos = NFSMTOD(nd->nd_md, caddr_t);
}
if (left >= siz) {
retp = nd->nd_dpos;
nd->nd_dpos += siz;
} else if (mbuf_next(nd->nd_md) == NULL) {
return (retp);
} else if (siz > ncl_mbuf_mhlen) {
panic("nfs S too big");
} else {
Revamp the old NFS server's File Handle Affinity (FHA) code so that it will work with either the old or new server. The FHA code keeps a cache of currently active file handles for NFSv2 and v3 requests, so that read and write requests for the same file are directed to the same group of threads (reads) or thread (writes). It does not currently work for NFSv4 requests. They are more complex, and will take more work to support. This improves read-ahead performance, especially with ZFS, if the FHA tuning parameters are configured appropriately. Without the FHA code, concurrent reads that are part of a sequential read from a file will be directed to separate NFS threads. This has the effect of confusing the ZFS zfetch (prefetch) code and makes sequential reads significantly slower with clients like Linux that do a lot of prefetching. The FHA code has also been updated to direct write requests to nearby file offsets to the same thread in the same way it batches reads, and the FHA code will now also send writes to multiple threads when needed. This improves sequential write performance in ZFS, because writes to a file are now more ordered. Since NFS writes (generally less than 64K) are smaller than the typical ZFS record size (usually 128K), out of order NFS writes to the same block can trigger a read in ZFS. Sending them down the same thread increases the odds of their being in order. In order for multiple write threads per file in the FHA code to be useful, writes in the NFS server have been changed to use a LK_SHARED vnode lock, and upgrade that to LK_EXCLUSIVE if the filesystem doesn't allow multiple writers to a file at once. ZFS is currently the only filesystem that allows multiple writers to a file, because it has internal file range locking. This change does not affect the NFSv4 code. This improves random write performance to a single file in ZFS, since we can now have multiple writers inside ZFS at one time. I have changed the default tuning parameters to a 22 bit (4MB) window size (from 256K) and unlimited commands per thread as a result of my benchmarking with ZFS. The FHA code has been updated to allow configuring the tuning parameters from loader tunable variables in addition to sysctl variables. The read offset window calculation has been slightly modified as well. Instead of having separate bins, each file handle has a rolling window of bin_shift size. This minimizes glitches in throughput when shifting from one bin to another. sys/conf/files: Add nfs_fha_new.c and nfs_fha_old.c. Compile nfs_fha.c when either the old or the new NFS server is built. sys/fs/nfs/nfsport.h, sys/fs/nfs/nfs_commonport.c: Bring in changes from Rick Macklem to newnfs_realign that allow it to operate in blocking (M_WAITOK) or non-blocking (M_NOWAIT) mode. sys/fs/nfs/nfs_commonsubs.c, sys/fs/nfs/nfs_var.h: Bring in a change from Rick Macklem to allow telling nfsm_dissect() whether or not to wait for mallocs. sys/fs/nfs/nfsm_subs.h: Bring in changes from Rick Macklem to create a new nfsm_dissect_nonblock() inline function and NFSM_DISSECT_NONBLOCK() macro. sys/fs/nfs/nfs_commonkrpc.c, sys/fs/nfsclient/nfs_clkrpc.c: Add the malloc wait flag to a newnfs_realign() call. sys/fs/nfsserver/nfs_nfsdkrpc.c: Setup the new NFS server's RPC thread pool so that it will call the FHA code. Add the malloc flag argument to newnfs_realign(). Unstaticize newnfs_nfsv3_procid[] so that we can use it in the FHA code. sys/fs/nfsserver/nfs_nfsdsocket.c: In nfsrvd_dorpc(), add NFSPROC_WRITE to the list of RPC types that use the LK_SHARED lock type. sys/fs/nfsserver/nfs_nfsdport.c: In nfsd_fhtovp(), if we're starting a write, check to see whether the underlying filesystem supports shared writes. If not, upgrade the lock type from LK_SHARED to LK_EXCLUSIVE. sys/nfsserver/nfs_fha.c: Remove all code that is specific to the NFS server implementation. Anything that is server-specific is now accessed through a callback supplied by that server's FHA shim in the new softc. There are now separate sysctls and tunables for the FHA implementations for the old and new NFS servers. The new NFS server has its tunables under vfs.nfsd.fha, the old NFS server's tunables are under vfs.nfsrv.fha as before. In fha_extract_info(), use callouts for all server-specific code. Getting file handles and offsets is now done in the individual server's shim module. In fha_hash_entry_choose_thread(), change the way we decide whether two reads are in proximity to each other. Previously, the calculation was a simple shift operation to see whether the offsets were in the same power of 2 bucket. The issue was that there would be a bucket (and therefore thread) transition, even if the reads were in close proximity. When there is a thread transition, reads wind up going somewhat out of order, and ZFS gets confused. The new calculation simply tries to see whether the offsets are within 1 << bin_shift of each other. If they are, the reads will be sent to the same thread. The effect of this change is that for sequential reads, if the client doesn't exceed the max_reqs_per_nfsd parameter and the bin_shift is set to a reasonable value (22, or 4MB works well in my tests), the reads in any sequential stream will largely be confined to a single thread. Change fha_assign() so that it takes a softc argument. It is now called from the individual server's shim code, which will pass in the softc. Change fhe_stats_sysctl() so that it takes a softc parameter. It is now called from the individual server's shim code. Add the current offset to the list of things printed out about each active thread. Change the num_reads and num_writes counters in the fha_hash_entry structure to 32-bit values, and rename them num_rw and num_exclusive, respectively, to reflect their changed usage. Add an enable sysctl and tunable that allows the user to disable the FHA code (when vfs.XXX.fha.enable = 0). This is useful for before/after performance comparisons. nfs_fha.h: Move most structure definitions out of nfs_fha.c and into the header file, so that the individual server shims can see them. Change the default bin_shift to 22 (4MB) instead of 18 (256K). Allow unlimited commands per thread. sys/nfsserver/nfs_fha_old.c, sys/nfsserver/nfs_fha_old.h, sys/fs/nfsserver/nfs_fha_new.c, sys/fs/nfsserver/nfs_fha_new.h: Add shims for the old and new NFS servers to interface with the FHA code, and callbacks for the The shims contain all of the code and definitions that are specific to the NFS servers. They setup the server-specific callbacks and set the server name for the sysctl and loader tunable variables. sys/nfsserver/nfs_srvkrpc.c: Configure the RPC code to call fhaold_assign() instead of fha_assign(). sys/modules/nfsd/Makefile: Add nfs_fha.c and nfs_fha_new.c. sys/modules/nfsserver/Makefile: Add nfs_fha_old.c. Reviewed by: rmacklem Sponsored by: Spectra Logic MFC after: 2 weeks
2013-04-17 21:00:22 +00:00
MGET(mp2, MT_DATA, how);
if (mp2 == NULL)
return (NULL);
mbuf_setnext(mp2, mbuf_next(nd->nd_md));
mbuf_setnext(nd->nd_md, mp2);
mbuf_setlen(nd->nd_md, mbuf_len(nd->nd_md) - left);
nd->nd_md = mp2;
retp = p = NFSMTOD(mp2, caddr_t);
NFSBCOPY(nd->nd_dpos, p, left); /* Copy what was left */
siz2 = siz - left;
p += left;
mp2 = mbuf_next(mp2);
/* Loop around copying up the siz2 bytes */
while (siz2 > 0) {
if (mp2 == NULL)
return (NULL);
xfer = (siz2 > mbuf_len(mp2)) ? mbuf_len(mp2) : siz2;
if (xfer > 0) {
NFSBCOPY(NFSMTOD(mp2, caddr_t), p, xfer);
NFSM_DATAP(mp2, xfer);
mbuf_setlen(mp2, mbuf_len(mp2) - xfer);
p += xfer;
siz2 -= xfer;
}
if (siz2 > 0)
mp2 = mbuf_next(mp2);
}
mbuf_setlen(nd->nd_md, siz);
nd->nd_md = mp2;
nd->nd_dpos = NFSMTOD(mp2, caddr_t);
}
return (retp);
}
/*
* Advance the position in the mbuf chain.
* If offs == 0, this is a no-op, but it is simpler to just return from
* here than check for offs > 0 for all calls to nfsm_advance.
* If left == -1, it should be calculated here.
*/
APPLESTATIC int
nfsm_advance(struct nfsrv_descript *nd, int offs, int left)
{
int error = 0;
if (offs == 0)
goto out;
/*
* A negative offs should be considered a serious problem.
*/
if (offs < 0)
panic("nfsrv_advance");
/*
* If left == -1, calculate it here.
*/
if (left == -1)
left = NFSMTOD(nd->nd_md, caddr_t) + mbuf_len(nd->nd_md) -
nd->nd_dpos;
/*
* Loop around, advancing over the mbuf data.
*/
while (offs > left) {
offs -= left;
nd->nd_md = mbuf_next(nd->nd_md);
if (nd->nd_md == NULL) {
error = EBADRPC;
goto out;
}
left = mbuf_len(nd->nd_md);
nd->nd_dpos = NFSMTOD(nd->nd_md, caddr_t);
}
nd->nd_dpos += offs;
out:
NFSEXITCODE(error);
return (error);
}
/*
* Copy a string into mbuf(s).
* Return the number of bytes output, including XDR overheads.
*/
APPLESTATIC int
nfsm_strtom(struct nfsrv_descript *nd, const char *cp, int siz)
{
mbuf_t m2;
int xfer, left;
mbuf_t m1;
int rem, bytesize;
u_int32_t *tl;
char *cp2;
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(siz);
rem = NFSM_RNDUP(siz) - siz;
bytesize = NFSX_UNSIGNED + siz + rem;
m2 = nd->nd_mb;
cp2 = nd->nd_bpos;
left = M_TRAILINGSPACE(m2);
/*
* Loop around copying the string to mbuf(s).
*/
while (siz > 0) {
if (left == 0) {
if (siz > ncl_mbuf_mlen)
NFSMCLGET(m1, M_WAITOK);
else
NFSMGET(m1);
mbuf_setlen(m1, 0);
mbuf_setnext(m2, m1);
m2 = m1;
cp2 = NFSMTOD(m2, caddr_t);
left = M_TRAILINGSPACE(m2);
}
if (left >= siz)
xfer = siz;
else
xfer = left;
NFSBCOPY(cp, cp2, xfer);
cp += xfer;
mbuf_setlen(m2, mbuf_len(m2) + xfer);
siz -= xfer;
left -= xfer;
if (siz == 0 && rem) {
if (left < rem)
panic("nfsm_strtom");
NFSBZERO(cp2 + xfer, rem);
mbuf_setlen(m2, mbuf_len(m2) + rem);
}
}
nd->nd_mb = m2;
nd->nd_bpos = NFSMTOD(m2, caddr_t) + mbuf_len(m2);
return (bytesize);
}
/*
* Called once to initialize data structures...
*/
APPLESTATIC void
newnfs_init(void)
{
static int nfs_inited = 0;
if (nfs_inited)
return;
nfs_inited = 1;
newnfs_true = txdr_unsigned(TRUE);
newnfs_false = txdr_unsigned(FALSE);
newnfs_xdrneg1 = txdr_unsigned(-1);
nfscl_ticks = (hz * NFS_TICKINTVL + 500) / 1000;
if (nfscl_ticks < 1)
nfscl_ticks = 1;
NFSSETBOOTTIME(nfsboottime);
/*
* Initialize reply list and start timer
*/
TAILQ_INIT(&nfsd_reqq);
NFS_TIMERINIT;
}
/*
* Put a file handle in an mbuf list.
* If the size argument == 0, just use the default size.
* set_true == 1 if there should be an newnfs_true prepended on the file handle.
* Return the number of bytes output, including XDR overhead.
*/
APPLESTATIC int
nfsm_fhtom(struct nfsrv_descript *nd, u_int8_t *fhp, int size, int set_true)
{
u_int32_t *tl;
u_int8_t *cp;
int fullsiz, rem, bytesize = 0;
if (size == 0)
size = NFSX_MYFH;
switch (nd->nd_flag & (ND_NFSV2 | ND_NFSV3 | ND_NFSV4)) {
case ND_NFSV2:
if (size > NFSX_V2FH)
panic("fh size > NFSX_V2FH for NFSv2");
NFSM_BUILD(cp, u_int8_t *, NFSX_V2FH);
NFSBCOPY(fhp, cp, size);
if (size < NFSX_V2FH)
NFSBZERO(cp + size, NFSX_V2FH - size);
bytesize = NFSX_V2FH;
break;
case ND_NFSV3:
case ND_NFSV4:
fullsiz = NFSM_RNDUP(size);
rem = fullsiz - size;
if (set_true) {
bytesize = 2 * NFSX_UNSIGNED + fullsiz;
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_true;
} else {
bytesize = NFSX_UNSIGNED + fullsiz;
}
(void) nfsm_strtom(nd, fhp, size);
break;
}
return (bytesize);
}
/*
* This function compares two net addresses by family and returns TRUE
* if they are the same host.
* If there is any doubt, return FALSE.
* The AF_INET family is handled as a special case so that address mbufs
* don't need to be saved to store "struct in_addr", which is only 4 bytes.
*/
APPLESTATIC int
nfsaddr_match(int family, union nethostaddr *haddr, NFSSOCKADDR_T nam)
{
struct sockaddr_in *inetaddr;
switch (family) {
case AF_INET:
inetaddr = NFSSOCKADDR(nam, struct sockaddr_in *);
if (inetaddr->sin_family == AF_INET &&
inetaddr->sin_addr.s_addr == haddr->had_inet.s_addr)
return (1);
break;
#ifdef INET6
case AF_INET6:
{
struct sockaddr_in6 *inetaddr6;
inetaddr6 = NFSSOCKADDR(nam, struct sockaddr_in6 *);
/* XXX - should test sin6_scope_id ? */
if (inetaddr6->sin6_family == AF_INET6 &&
IN6_ARE_ADDR_EQUAL(&inetaddr6->sin6_addr,
&haddr->had_inet6))
return (1);
}
break;
#endif
}
return (0);
}
/*
* Similar to the above, but takes to NFSSOCKADDR_T args.
*/
APPLESTATIC int
nfsaddr2_match(NFSSOCKADDR_T nam1, NFSSOCKADDR_T nam2)
{
struct sockaddr_in *addr1, *addr2;
struct sockaddr *inaddr;
inaddr = NFSSOCKADDR(nam1, struct sockaddr *);
switch (inaddr->sa_family) {
case AF_INET:
addr1 = NFSSOCKADDR(nam1, struct sockaddr_in *);
addr2 = NFSSOCKADDR(nam2, struct sockaddr_in *);
if (addr2->sin_family == AF_INET &&
addr1->sin_addr.s_addr == addr2->sin_addr.s_addr)
return (1);
break;
#ifdef INET6
case AF_INET6:
{
struct sockaddr_in6 *inet6addr1, *inet6addr2;
inet6addr1 = NFSSOCKADDR(nam1, struct sockaddr_in6 *);
inet6addr2 = NFSSOCKADDR(nam2, struct sockaddr_in6 *);
/* XXX - should test sin6_scope_id ? */
if (inet6addr2->sin6_family == AF_INET6 &&
IN6_ARE_ADDR_EQUAL(&inet6addr1->sin6_addr,
&inet6addr2->sin6_addr))
return (1);
}
break;
#endif
}
return (0);
}
/*
* Trim the stuff already dissected off the mbuf list.
*/
APPLESTATIC void
newnfs_trimleading(nd)
struct nfsrv_descript *nd;
{
mbuf_t m, n;
int offs;
/*
* First, free up leading mbufs.
*/
if (nd->nd_mrep != nd->nd_md) {
m = nd->nd_mrep;
while (mbuf_next(m) != nd->nd_md) {
if (mbuf_next(m) == NULL)
panic("nfsm trim leading");
m = mbuf_next(m);
}
mbuf_setnext(m, NULL);
mbuf_freem(nd->nd_mrep);
}
m = nd->nd_md;
/*
* Now, adjust this mbuf, based on nd_dpos.
*/
offs = nd->nd_dpos - NFSMTOD(m, caddr_t);
if (offs == mbuf_len(m)) {
n = m;
m = mbuf_next(m);
if (m == NULL)
panic("nfsm trim leading2");
mbuf_setnext(n, NULL);
mbuf_freem(n);
} else if (offs > 0) {
mbuf_setlen(m, mbuf_len(m) - offs);
NFSM_DATAP(m, offs);
} else if (offs < 0)
panic("nfsm trimleading offs");
nd->nd_mrep = m;
nd->nd_md = m;
nd->nd_dpos = NFSMTOD(m, caddr_t);
}
/*
* Trim trailing data off the mbuf list being built.
*/
APPLESTATIC void
newnfs_trimtrailing(nd, mb, bpos)
struct nfsrv_descript *nd;
mbuf_t mb;
caddr_t bpos;
{
if (mbuf_next(mb)) {
mbuf_freem(mbuf_next(mb));
mbuf_setnext(mb, NULL);
}
mbuf_setlen(mb, bpos - NFSMTOD(mb, caddr_t));
nd->nd_mb = mb;
nd->nd_bpos = bpos;
}
/*
* Dissect a file handle on the client.
*/
APPLESTATIC int
nfsm_getfh(struct nfsrv_descript *nd, struct nfsfh **nfhpp)
{
u_int32_t *tl;
struct nfsfh *nfhp;
int error, len;
*nfhpp = NULL;
if (nd->nd_flag & (ND_NFSV3 | ND_NFSV4)) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if ((len = fxdr_unsigned(int, *tl)) <= 0 ||
len > NFSX_FHMAX) {
error = EBADRPC;
goto nfsmout;
}
} else
len = NFSX_V2FH;
MALLOC(nfhp, struct nfsfh *, sizeof (struct nfsfh) + len,
M_NFSFH, M_WAITOK);
error = nfsrv_mtostr(nd, nfhp->nfh_fh, len);
if (error) {
FREE((caddr_t)nfhp, M_NFSFH);
goto nfsmout;
}
nfhp->nfh_len = len;
*nfhpp = nfhp;
nfsmout:
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Break down the nfsv4 acl.
* If the aclp == NULL or won't fit in an acl, just discard the acl info.
*/
APPLESTATIC int
nfsrv_dissectacl(struct nfsrv_descript *nd, NFSACL_T *aclp, int *aclerrp,
int *aclsizep, __unused NFSPROC_T *p)
{
u_int32_t *tl;
int i, aclsize;
int acecnt, error = 0, aceerr = 0, acesize;
*aclerrp = 0;
if (aclp)
aclp->acl_cnt = 0;
/*
* Parse out the ace entries and expect them to conform to
* what can be supported by R/W/X bits.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
aclsize = NFSX_UNSIGNED;
acecnt = fxdr_unsigned(int, *tl);
if (acecnt > ACL_MAX_ENTRIES)
aceerr = NFSERR_ATTRNOTSUPP;
if (nfsrv_useacl == 0)
aceerr = NFSERR_ATTRNOTSUPP;
for (i = 0; i < acecnt; i++) {
if (aclp && !aceerr)
error = nfsrv_dissectace(nd, &aclp->acl_entry[i],
&aceerr, &acesize, p);
else
error = nfsrv_skipace(nd, &acesize);
if (error)
goto nfsmout;
aclsize += acesize;
}
if (aclp && !aceerr)
aclp->acl_cnt = acecnt;
if (aceerr)
*aclerrp = aceerr;
if (aclsizep)
*aclsizep = aclsize;
nfsmout:
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Skip over an NFSv4 ace entry. Just dissect the xdr and discard it.
*/
static int
nfsrv_skipace(struct nfsrv_descript *nd, int *acesizep)
{
u_int32_t *tl;
int error, len = 0;
NFSM_DISSECT(tl, u_int32_t *, 4 * NFSX_UNSIGNED);
len = fxdr_unsigned(int, *(tl + 3));
error = nfsm_advance(nd, NFSM_RNDUP(len), -1);
nfsmout:
*acesizep = NFSM_RNDUP(len) + (4 * NFSX_UNSIGNED);
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Get attribute bits from an mbuf list.
* Returns EBADRPC for a parsing error, 0 otherwise.
* If the clearinvalid flag is set, clear the bits not supported.
*/
APPLESTATIC int
nfsrv_getattrbits(struct nfsrv_descript *nd, nfsattrbit_t *attrbitp, int *cntp,
int *retnotsupp)
{
u_int32_t *tl;
int cnt, i, outcnt;
int error = 0;
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
cnt = fxdr_unsigned(int, *tl);
if (cnt < 0) {
error = NFSERR_BADXDR;
goto nfsmout;
}
if (cnt > NFSATTRBIT_MAXWORDS)
outcnt = NFSATTRBIT_MAXWORDS;
else
outcnt = cnt;
NFSZERO_ATTRBIT(attrbitp);
if (outcnt > 0) {
NFSM_DISSECT(tl, u_int32_t *, outcnt * NFSX_UNSIGNED);
for (i = 0; i < outcnt; i++)
attrbitp->bits[i] = fxdr_unsigned(u_int32_t, *tl++);
}
for (i = 0; i < (cnt - outcnt); i++) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (retnotsupp != NULL && *tl != 0)
*retnotsupp = NFSERR_ATTRNOTSUPP;
}
if (cntp)
*cntp = NFSX_UNSIGNED + (cnt * NFSX_UNSIGNED);
nfsmout:
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Get the attributes for V4.
* If the compare flag is true, test for any attribute changes,
* otherwise return the attribute values.
* These attributes cover fields in "struct vattr", "struct statfs",
* "struct nfsfsinfo", the file handle and the lease duration.
* The value of retcmpp is set to 1 if all attributes are the same,
* and 0 otherwise.
* Returns EBADRPC if it can't be parsed, 0 otherwise.
*/
APPLESTATIC int
nfsv4_loadattr(struct nfsrv_descript *nd, vnode_t vp,
struct nfsvattr *nap, struct nfsfh **nfhpp, fhandle_t *fhp, int fhsize,
struct nfsv3_pathconf *pc, struct statfs *sbp, struct nfsstatfs *sfp,
struct nfsfsinfo *fsp, NFSACL_T *aclp, int compare, int *retcmpp,
u_int32_t *leasep, u_int32_t *rderrp, NFSPROC_T *p, struct ucred *cred)
{
u_int32_t *tl;
int i = 0, j, k, l = 0, m, bitpos, attrsum = 0;
int error, tfhsize, aceerr, attrsize, cnt, retnotsup;
u_char *cp, *cp2, namestr[NFSV4_SMALLSTR + 1];
nfsattrbit_t attrbits, retattrbits, checkattrbits;
struct nfsfh *tnfhp;
struct nfsreferral *refp;
u_quad_t tquad;
nfsquad_t tnfsquad;
struct timespec temptime;
uid_t uid;
gid_t gid;
long fid;
u_int32_t freenum = 0, tuint;
u_int64_t uquad = 0, thyp, thyp2;
#ifdef QUOTA
struct dqblk dqb;
uid_t savuid;
#endif
static struct timeval last64fileid;
static size_t count64fileid;
static struct timeval last64mountfileid;
static size_t count64mountfileid;
static struct timeval warninterval = { 60, 0 };
if (compare) {
retnotsup = 0;
error = nfsrv_getattrbits(nd, &attrbits, NULL, &retnotsup);
} else {
error = nfsrv_getattrbits(nd, &attrbits, NULL, NULL);
}
if (error)
goto nfsmout;
if (compare) {
*retcmpp = retnotsup;
} else {
/*
* Just set default values to some of the important ones.
*/
if (nap != NULL) {
nap->na_type = VREG;
nap->na_mode = 0;
nap->na_rdev = (NFSDEV_T)0;
nap->na_mtime.tv_sec = 0;
nap->na_mtime.tv_nsec = 0;
nap->na_gen = 0;
nap->na_flags = 0;
nap->na_blocksize = NFS_FABLKSIZE;
}
if (sbp != NULL) {
sbp->f_bsize = NFS_FABLKSIZE;
sbp->f_blocks = 0;
sbp->f_bfree = 0;
sbp->f_bavail = 0;
sbp->f_files = 0;
sbp->f_ffree = 0;
}
if (fsp != NULL) {
fsp->fs_rtmax = 8192;
fsp->fs_rtpref = 8192;
fsp->fs_maxname = NFS_MAXNAMLEN;
fsp->fs_wtmax = 8192;
fsp->fs_wtpref = 8192;
fsp->fs_wtmult = NFS_FABLKSIZE;
fsp->fs_dtpref = 8192;
fsp->fs_maxfilesize = 0xffffffffffffffffull;
fsp->fs_timedelta.tv_sec = 0;
fsp->fs_timedelta.tv_nsec = 1;
fsp->fs_properties = (NFSV3_FSFLINK | NFSV3_FSFSYMLINK |
NFSV3_FSFHOMOGENEOUS | NFSV3_FSFCANSETTIME);
}
if (pc != NULL) {
pc->pc_linkmax = LINK_MAX;
pc->pc_namemax = NAME_MAX;
pc->pc_notrunc = 0;
pc->pc_chownrestricted = 0;
pc->pc_caseinsensitive = 0;
pc->pc_casepreserving = 1;
}
if (sfp != NULL) {
sfp->sf_ffiles = UINT64_MAX;
sfp->sf_tfiles = UINT64_MAX;
sfp->sf_afiles = UINT64_MAX;
sfp->sf_fbytes = UINT64_MAX;
sfp->sf_tbytes = UINT64_MAX;
sfp->sf_abytes = UINT64_MAX;
}
}
/*
* Loop around getting the attributes.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
attrsize = fxdr_unsigned(int, *tl);
for (bitpos = 0; bitpos < NFSATTRBIT_MAX; bitpos++) {
if (attrsum > attrsize) {
error = NFSERR_BADXDR;
goto nfsmout;
}
if (NFSISSET_ATTRBIT(&attrbits, bitpos))
switch (bitpos) {
case NFSATTRBIT_SUPPORTEDATTRS:
retnotsup = 0;
if (compare || nap == NULL)
error = nfsrv_getattrbits(nd, &retattrbits,
&cnt, &retnotsup);
else
error = nfsrv_getattrbits(nd, &nap->na_suppattr,
&cnt, &retnotsup);
if (error)
goto nfsmout;
if (compare && !(*retcmpp)) {
NFSSETSUPP_ATTRBIT(&checkattrbits);
/* Some filesystem do not support NFSv4ACL */
if (nfsrv_useacl == 0 || nfs_supportsnfsv4acls(vp) == 0) {
NFSCLRBIT_ATTRBIT(&checkattrbits, NFSATTRBIT_ACL);
NFSCLRBIT_ATTRBIT(&checkattrbits, NFSATTRBIT_ACLSUPPORT);
}
if (!NFSEQUAL_ATTRBIT(&retattrbits, &checkattrbits)
|| retnotsup)
*retcmpp = NFSERR_NOTSAME;
}
attrsum += cnt;
break;
case NFSATTRBIT_TYPE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (nap->na_type != nfsv34tov_type(*tl))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_type = nfsv34tov_type(*tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FHEXPIRETYPE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp)) {
if (fxdr_unsigned(int, *tl) !=
NFSV4FHTYPE_PERSISTENT)
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CHANGE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp)) {
if (nap->na_filerev != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_filerev = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SIZE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp)) {
if (nap->na_size != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_size = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_LINKSUPPORT:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_properties & NFSV3_FSFLINK) {
if (*tl == newnfs_false)
*retcmpp = NFSERR_NOTSAME;
} else {
if (*tl == newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
}
} else if (fsp != NULL) {
if (*tl == newnfs_true)
fsp->fs_properties |= NFSV3_FSFLINK;
else
fsp->fs_properties &= ~NFSV3_FSFLINK;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_SYMLINKSUPPORT:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_properties & NFSV3_FSFSYMLINK) {
if (*tl == newnfs_false)
*retcmpp = NFSERR_NOTSAME;
} else {
if (*tl == newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
}
} else if (fsp != NULL) {
if (*tl == newnfs_true)
fsp->fs_properties |= NFSV3_FSFSYMLINK;
else
fsp->fs_properties &= ~NFSV3_FSFSYMLINK;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NAMEDATTR:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp)) {
if (*tl != newnfs_false)
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FSID:
NFSM_DISSECT(tl, u_int32_t *, 4 * NFSX_UNSIGNED);
thyp = fxdr_hyper(tl);
tl += 2;
thyp2 = fxdr_hyper(tl);
if (compare) {
if (*retcmpp == 0) {
if (thyp != (u_int64_t)
vfs_statfs(vnode_mount(vp))->f_fsid.val[0] ||
thyp2 != (u_int64_t)
vfs_statfs(vnode_mount(vp))->f_fsid.val[1])
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_filesid[0] = thyp;
nap->na_filesid[1] = thyp2;
}
attrsum += (4 * NFSX_UNSIGNED);
break;
case NFSATTRBIT_UNIQUEHANDLES:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp)) {
if (*tl != newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_LEASETIME:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (fxdr_unsigned(int, *tl) != nfsrv_lease &&
!(*retcmpp))
*retcmpp = NFSERR_NOTSAME;
} else if (leasep != NULL) {
*leasep = fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_RDATTRERROR:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp))
*retcmpp = NFSERR_INVAL;
} else if (rderrp != NULL) {
*rderrp = fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_ACL:
if (compare) {
if (!(*retcmpp)) {
if (nfsrv_useacl && nfs_supportsnfsv4acls(vp)) {
NFSACL_T *naclp;
naclp = acl_alloc(M_WAITOK);
error = nfsrv_dissectacl(nd, naclp, &aceerr,
&cnt, p);
if (error) {
acl_free(naclp);
goto nfsmout;
}
if (aceerr || aclp == NULL ||
nfsrv_compareacl(aclp, naclp))
*retcmpp = NFSERR_NOTSAME;
acl_free(naclp);
} else {
error = nfsrv_dissectacl(nd, NULL, &aceerr,
&cnt, p);
*retcmpp = NFSERR_ATTRNOTSUPP;
}
}
} else {
if (vp != NULL && aclp != NULL)
error = nfsrv_dissectacl(nd, aclp, &aceerr,
&cnt, p);
else
error = nfsrv_dissectacl(nd, NULL, &aceerr,
&cnt, p);
if (error)
goto nfsmout;
}
attrsum += cnt;
break;
case NFSATTRBIT_ACLSUPPORT:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp)) {
if (nfsrv_useacl && nfs_supportsnfsv4acls(vp)) {
if (fxdr_unsigned(u_int32_t, *tl) !=
NFSV4ACE_SUPTYPES)
*retcmpp = NFSERR_NOTSAME;
} else {
*retcmpp = NFSERR_ATTRNOTSUPP;
}
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_ARCHIVE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CANSETTIME:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_properties & NFSV3_FSFCANSETTIME) {
if (*tl == newnfs_false)
*retcmpp = NFSERR_NOTSAME;
} else {
if (*tl == newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
}
} else if (fsp != NULL) {
if (*tl == newnfs_true)
fsp->fs_properties |= NFSV3_FSFCANSETTIME;
else
fsp->fs_properties &= ~NFSV3_FSFCANSETTIME;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CASEINSENSITIVE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (*tl != newnfs_false)
*retcmpp = NFSERR_NOTSAME;
}
} else if (pc != NULL) {
pc->pc_caseinsensitive =
fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CASEPRESERVING:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (*tl != newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
} else if (pc != NULL) {
pc->pc_casepreserving =
fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CHOWNRESTRICTED:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (*tl != newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
} else if (pc != NULL) {
pc->pc_chownrestricted =
fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FILEHANDLE:
error = nfsm_getfh(nd, &tnfhp);
if (error)
goto nfsmout;
tfhsize = tnfhp->nfh_len;
if (compare) {
if (!(*retcmpp) &&
!NFSRV_CMPFH(tnfhp->nfh_fh, tfhsize,
fhp, fhsize))
*retcmpp = NFSERR_NOTSAME;
FREE((caddr_t)tnfhp, M_NFSFH);
} else if (nfhpp != NULL) {
*nfhpp = tnfhp;
} else {
FREE((caddr_t)tnfhp, M_NFSFH);
}
attrsum += (NFSX_UNSIGNED + NFSM_RNDUP(tfhsize));
break;
case NFSATTRBIT_FILEID:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
thyp = fxdr_hyper(tl);
if (compare) {
if (!(*retcmpp)) {
if ((u_int64_t)nap->na_fileid != thyp)
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
if (*tl++) {
count64fileid++;
if (ratecheck(&last64fileid, &warninterval)) {
printf("NFSv4 fileid > 32bits (%zu occurrences)\n",
count64fileid);
count64fileid = 0;
}
}
nap->na_fileid = thyp;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESAVAIL:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_afiles != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_afiles = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESFREE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_ffiles != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_ffiles = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESTOTAL:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_tfiles != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_tfiles = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_FSLOCATIONS:
error = nfsrv_getrefstr(nd, &cp, &cp2, &l, &m);
if (error)
goto nfsmout;
attrsum += l;
if (compare && !(*retcmpp)) {
refp = nfsv4root_getreferral(vp, NULL, 0);
if (refp != NULL) {
if (cp == NULL || cp2 == NULL ||
strcmp(cp, "/") ||
strcmp(cp2, refp->nfr_srvlist))
*retcmpp = NFSERR_NOTSAME;
} else if (m == 0) {
*retcmpp = NFSERR_NOTSAME;
}
}
if (cp != NULL)
free(cp, M_NFSSTRING);
if (cp2 != NULL)
free(cp2, M_NFSSTRING);
break;
case NFSATTRBIT_HIDDEN:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_HOMOGENEOUS:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_properties &
NFSV3_FSFHOMOGENEOUS) {
if (*tl == newnfs_false)
*retcmpp = NFSERR_NOTSAME;
} else {
if (*tl == newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
}
} else if (fsp != NULL) {
if (*tl == newnfs_true)
fsp->fs_properties |= NFSV3_FSFHOMOGENEOUS;
else
fsp->fs_properties &= ~NFSV3_FSFHOMOGENEOUS;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXFILESIZE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
tnfsquad.qval = fxdr_hyper(tl);
if (compare) {
if (!(*retcmpp)) {
tquad = NFSRV_MAXFILESIZE;
if (tquad != tnfsquad.qval)
*retcmpp = NFSERR_NOTSAME;
}
} else if (fsp != NULL) {
fsp->fs_maxfilesize = tnfsquad.qval;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_MAXLINK:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fxdr_unsigned(int, *tl) != LINK_MAX)
*retcmpp = NFSERR_NOTSAME;
}
} else if (pc != NULL) {
pc->pc_linkmax = fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXNAME:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_maxname !=
fxdr_unsigned(u_int32_t, *tl))
*retcmpp = NFSERR_NOTSAME;
}
} else {
tuint = fxdr_unsigned(u_int32_t, *tl);
/*
* Some Linux NFSv4 servers report this
* as 0 or 4billion, so I'll set it to
* NFS_MAXNAMLEN. If a server actually creates
* a name longer than NFS_MAXNAMLEN, it will
* get an error back.
*/
if (tuint == 0 || tuint > NFS_MAXNAMLEN)
tuint = NFS_MAXNAMLEN;
if (fsp != NULL)
fsp->fs_maxname = tuint;
if (pc != NULL)
pc->pc_namemax = tuint;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXREAD:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_rtmax != fxdr_unsigned(u_int32_t,
*(tl + 1)) || *tl != 0)
*retcmpp = NFSERR_NOTSAME;
}
} else if (fsp != NULL) {
fsp->fs_rtmax = fxdr_unsigned(u_int32_t, *++tl);
fsp->fs_rtpref = fsp->fs_rtmax;
fsp->fs_dtpref = fsp->fs_rtpref;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_MAXWRITE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp)) {
if (fsp->fs_wtmax != fxdr_unsigned(u_int32_t,
*(tl + 1)) || *tl != 0)
*retcmpp = NFSERR_NOTSAME;
}
} else if (fsp != NULL) {
fsp->fs_wtmax = fxdr_unsigned(int, *++tl);
fsp->fs_wtpref = fsp->fs_wtmax;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_MIMETYPE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
i = fxdr_unsigned(int, *tl);
attrsum += (NFSX_UNSIGNED + NFSM_RNDUP(i));
error = nfsm_advance(nd, NFSM_RNDUP(i), -1);
if (error)
goto nfsmout;
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
break;
case NFSATTRBIT_MODE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (nap->na_mode != nfstov_mode(*tl))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_mode = nfstov_mode(*tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NOTRUNC:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare) {
if (!(*retcmpp)) {
if (*tl != newnfs_true)
*retcmpp = NFSERR_NOTSAME;
}
} else if (pc != NULL) {
pc->pc_notrunc = fxdr_unsigned(u_int32_t, *tl);
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NUMLINKS:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
tuint = fxdr_unsigned(u_int32_t, *tl);
if (compare) {
if (!(*retcmpp)) {
if ((u_int32_t)nap->na_nlink != tuint)
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_nlink = tuint;
}
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_OWNER:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
j = fxdr_unsigned(int, *tl);
if (j < 0) {
error = NFSERR_BADXDR;
goto nfsmout;
}
attrsum += (NFSX_UNSIGNED + NFSM_RNDUP(j));
if (j > NFSV4_SMALLSTR)
cp = malloc(j + 1, M_NFSSTRING, M_WAITOK);
else
cp = namestr;
error = nfsrv_mtostr(nd, cp, j);
if (error) {
if (j > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
goto nfsmout;
}
if (compare) {
if (!(*retcmpp)) {
if (nfsv4_strtouid(nd, cp, j, &uid, p) ||
nap->na_uid != uid)
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
if (nfsv4_strtouid(nd, cp, j, &uid, p))
nap->na_uid = nfsrv_defaultuid;
else
nap->na_uid = uid;
}
if (j > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
break;
case NFSATTRBIT_OWNERGROUP:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
j = fxdr_unsigned(int, *tl);
if (j < 0) {
error = NFSERR_BADXDR;
goto nfsmout;
}
attrsum += (NFSX_UNSIGNED + NFSM_RNDUP(j));
if (j > NFSV4_SMALLSTR)
cp = malloc(j + 1, M_NFSSTRING, M_WAITOK);
else
cp = namestr;
error = nfsrv_mtostr(nd, cp, j);
if (error) {
if (j > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
goto nfsmout;
}
if (compare) {
if (!(*retcmpp)) {
if (nfsv4_strtogid(nd, cp, j, &gid, p) ||
nap->na_gid != gid)
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
if (nfsv4_strtogid(nd, cp, j, &gid, p))
nap->na_gid = nfsrv_defaultgid;
else
nap->na_gid = gid;
}
if (j > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
break;
case NFSATTRBIT_QUOTAHARD:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (sbp != NULL) {
if (priv_check_cred(cred, PRIV_VFS_EXCEEDQUOTA, 0))
freenum = sbp->f_bfree;
else
freenum = sbp->f_bavail;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(vnode_mount(vp),QCMD(Q_GETQUOTA,
USRQUOTA), cred->cr_uid, (caddr_t)&dqb))
freenum = min(dqb.dqb_bhardlimit, freenum);
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, sbp->f_bsize);
}
if (compare && !(*retcmpp)) {
if (uquad != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_QUOTASOFT:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (sbp != NULL) {
if (priv_check_cred(cred, PRIV_VFS_EXCEEDQUOTA, 0))
freenum = sbp->f_bfree;
else
freenum = sbp->f_bavail;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(vnode_mount(vp),QCMD(Q_GETQUOTA,
USRQUOTA), cred->cr_uid, (caddr_t)&dqb))
freenum = min(dqb.dqb_bsoftlimit, freenum);
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, sbp->f_bsize);
}
if (compare && !(*retcmpp)) {
if (uquad != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_QUOTAUSED:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (sbp != NULL) {
freenum = 0;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(vnode_mount(vp),QCMD(Q_GETQUOTA,
USRQUOTA), cred->cr_uid, (caddr_t)&dqb))
freenum = dqb.dqb_curblocks;
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, sbp->f_bsize);
}
if (compare && !(*retcmpp)) {
if (uquad != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_RAWDEV:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4SPECDATA);
j = fxdr_unsigned(int, *tl++);
k = fxdr_unsigned(int, *tl);
if (compare) {
if (!(*retcmpp)) {
if (nap->na_rdev != NFSMAKEDEV(j, k))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_rdev = NFSMAKEDEV(j, k);
}
attrsum += NFSX_V4SPECDATA;
break;
case NFSATTRBIT_SPACEAVAIL:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_abytes != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_abytes = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACEFREE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_fbytes != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_fbytes = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACETOTAL:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
if (compare) {
if (!(*retcmpp) &&
sfp->sf_tbytes != fxdr_hyper(tl))
*retcmpp = NFSERR_NOTSAME;
} else if (sfp != NULL) {
sfp->sf_tbytes = fxdr_hyper(tl);
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACEUSED:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
thyp = fxdr_hyper(tl);
if (compare) {
if (!(*retcmpp)) {
if ((u_int64_t)nap->na_bytes != thyp)
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_bytes = thyp;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SYSTEM:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
attrsum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_TIMEACCESS:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
fxdr_nfsv4time(tl, &temptime);
if (compare) {
if (!(*retcmpp)) {
if (!NFS_CMPTIME(temptime, nap->na_atime))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_atime = temptime;
}
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEACCESSSET:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
attrsum += NFSX_UNSIGNED;
i = fxdr_unsigned(int, *tl);
if (i == NFSV4SATTRTIME_TOCLIENT) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
attrsum += NFSX_V4TIME;
}
if (compare && !(*retcmpp))
*retcmpp = NFSERR_INVAL;
break;
case NFSATTRBIT_TIMEBACKUP:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMECREATE:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEDELTA:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
if (fsp != NULL) {
if (compare) {
if (!(*retcmpp)) {
if ((u_int32_t)fsp->fs_timedelta.tv_sec !=
fxdr_unsigned(u_int32_t, *(tl + 1)) ||
(u_int32_t)fsp->fs_timedelta.tv_nsec !=
(fxdr_unsigned(u_int32_t, *(tl + 2)) %
1000000000) ||
*tl != 0)
*retcmpp = NFSERR_NOTSAME;
}
} else {
fxdr_nfsv4time(tl, &fsp->fs_timedelta);
}
}
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMETADATA:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
fxdr_nfsv4time(tl, &temptime);
if (compare) {
if (!(*retcmpp)) {
if (!NFS_CMPTIME(temptime, nap->na_ctime))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_ctime = temptime;
}
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMODIFY:
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
fxdr_nfsv4time(tl, &temptime);
if (compare) {
if (!(*retcmpp)) {
if (!NFS_CMPTIME(temptime, nap->na_mtime))
*retcmpp = NFSERR_NOTSAME;
}
} else if (nap != NULL) {
nap->na_mtime = temptime;
}
attrsum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMODIFYSET:
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
attrsum += NFSX_UNSIGNED;
i = fxdr_unsigned(int, *tl);
if (i == NFSV4SATTRTIME_TOCLIENT) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_V4TIME);
attrsum += NFSX_V4TIME;
}
if (compare && !(*retcmpp))
*retcmpp = NFSERR_INVAL;
break;
case NFSATTRBIT_MOUNTEDONFILEID:
NFSM_DISSECT(tl, u_int32_t *, NFSX_HYPER);
thyp = fxdr_hyper(tl);
if (compare) {
if (!(*retcmpp)) {
if (*tl++) {
*retcmpp = NFSERR_NOTSAME;
} else {
if (!vp || !nfsrv_atroot(vp, &fid))
fid = nap->na_fileid;
if ((u_int64_t)fid != thyp)
*retcmpp = NFSERR_NOTSAME;
}
}
} else if (nap != NULL) {
if (*tl++) {
count64mountfileid++;
if (ratecheck(&last64mountfileid, &warninterval)) {
printf("NFSv4 mounted on fileid > 32bits (%zu occurrences)\n",
count64mountfileid);
count64mountfileid = 0;
}
}
nap->na_mntonfileno = thyp;
}
attrsum += NFSX_HYPER;
break;
case NFSATTRBIT_SUPPATTREXCLCREAT:
retnotsup = 0;
error = nfsrv_getattrbits(nd, &retattrbits,
&cnt, &retnotsup);
if (error)
goto nfsmout;
if (compare && !(*retcmpp)) {
NFSSETSUPP_ATTRBIT(&checkattrbits);
NFSCLRNOTSETABLE_ATTRBIT(&checkattrbits);
NFSCLRBIT_ATTRBIT(&checkattrbits,
NFSATTRBIT_TIMEACCESSSET);
if (!NFSEQUAL_ATTRBIT(&retattrbits, &checkattrbits)
|| retnotsup)
*retcmpp = NFSERR_NOTSAME;
}
attrsum += cnt;
break;
default:
printf("EEK! nfsv4_loadattr unknown attr=%d\n",
bitpos);
if (compare && !(*retcmpp))
*retcmpp = NFSERR_ATTRNOTSUPP;
/*
* and get out of the loop, since we can't parse
* the unknown attrbute data.
*/
bitpos = NFSATTRBIT_MAX;
break;
}
}
/*
* some clients pad the attrlist, so we need to skip over the
* padding.
*/
if (attrsum > attrsize) {
error = NFSERR_BADXDR;
} else {
attrsize = NFSM_RNDUP(attrsize);
if (attrsum < attrsize)
error = nfsm_advance(nd, attrsize - attrsum, -1);
}
nfsmout:
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Implement sleep locks for newnfs. The nfslock_usecnt allows for a
* shared lock and the NFSXXX_LOCK flag permits an exclusive lock.
* The first argument is a pointer to an nfsv4lock structure.
* The second argument is 1 iff a blocking lock is wanted.
* If this argument is 0, the call waits until no thread either wants nor
* holds an exclusive lock.
* It returns 1 if the lock was acquired, 0 otherwise.
* If several processes call this function concurrently wanting the exclusive
* lock, one will get the lock and the rest will return without getting the
* lock. (If the caller must have the lock, it simply calls this function in a
* loop until the function returns 1 to indicate the lock was acquired.)
* Any usecnt must be decremented by calling nfsv4_relref() before
* calling nfsv4_lock(). It was done this way, so nfsv4_lock() could
* be called in a loop.
* The isleptp argument is set to indicate if the call slept, iff not NULL
* and the mp argument indicates to check for a forced dismount, iff not
* NULL.
*/
APPLESTATIC int
nfsv4_lock(struct nfsv4lock *lp, int iwantlock, int *isleptp,
void *mutex, struct mount *mp)
{
if (isleptp)
*isleptp = 0;
/*
* If a lock is wanted, loop around until the lock is acquired by
* someone and then released. If I want the lock, try to acquire it.
* For a lock to be issued, no lock must be in force and the usecnt
* must be zero.
*/
if (iwantlock) {
if (!(lp->nfslock_lock & NFSV4LOCK_LOCK) &&
lp->nfslock_usecnt == 0) {
lp->nfslock_lock &= ~NFSV4LOCK_LOCKWANTED;
lp->nfslock_lock |= NFSV4LOCK_LOCK;
return (1);
}
lp->nfslock_lock |= NFSV4LOCK_LOCKWANTED;
}
while (lp->nfslock_lock & (NFSV4LOCK_LOCK | NFSV4LOCK_LOCKWANTED)) {
if (mp != NULL && (mp->mnt_kern_flag & MNTK_UNMOUNTF) != 0) {
lp->nfslock_lock &= ~NFSV4LOCK_LOCKWANTED;
return (0);
}
lp->nfslock_lock |= NFSV4LOCK_WANTED;
if (isleptp)
*isleptp = 1;
(void) nfsmsleep(&lp->nfslock_lock, mutex,
PZERO - 1, "nfsv4lck", NULL);
if (iwantlock && !(lp->nfslock_lock & NFSV4LOCK_LOCK) &&
lp->nfslock_usecnt == 0) {
lp->nfslock_lock &= ~NFSV4LOCK_LOCKWANTED;
lp->nfslock_lock |= NFSV4LOCK_LOCK;
return (1);
}
}
return (0);
}
/*
* Release the lock acquired by nfsv4_lock().
* The second argument is set to 1 to indicate the nfslock_usecnt should be
* incremented, as well.
*/
APPLESTATIC void
nfsv4_unlock(struct nfsv4lock *lp, int incref)
{
lp->nfslock_lock &= ~NFSV4LOCK_LOCK;
if (incref)
lp->nfslock_usecnt++;
nfsv4_wanted(lp);
}
/*
* Release a reference cnt.
*/
APPLESTATIC void
nfsv4_relref(struct nfsv4lock *lp)
{
if (lp->nfslock_usecnt <= 0)
panic("nfsv4root ref cnt");
lp->nfslock_usecnt--;
if (lp->nfslock_usecnt == 0)
nfsv4_wanted(lp);
}
/*
* Get a reference cnt.
* This function will wait for any exclusive lock to be released, but will
* not wait for threads that want the exclusive lock. If priority needs
* to be given to threads that need the exclusive lock, a call to nfsv4_lock()
* with the 2nd argument == 0 should be done before calling nfsv4_getref().
* If the mp argument is not NULL, check for MNTK_UNMOUNTF being set and
* return without getting a refcnt for that case.
*/
APPLESTATIC void
nfsv4_getref(struct nfsv4lock *lp, int *isleptp, void *mutex,
struct mount *mp)
{
if (isleptp)
*isleptp = 0;
/*
* Wait for a lock held.
*/
while (lp->nfslock_lock & NFSV4LOCK_LOCK) {
if (mp != NULL && (mp->mnt_kern_flag & MNTK_UNMOUNTF) != 0)
return;
lp->nfslock_lock |= NFSV4LOCK_WANTED;
if (isleptp)
*isleptp = 1;
(void) nfsmsleep(&lp->nfslock_lock, mutex,
PZERO - 1, "nfsv4gr", NULL);
}
if (mp != NULL && (mp->mnt_kern_flag & MNTK_UNMOUNTF) != 0)
return;
lp->nfslock_usecnt++;
}
/*
* Get a reference as above, but return failure instead of sleeping if
* an exclusive lock is held.
*/
APPLESTATIC int
nfsv4_getref_nonblock(struct nfsv4lock *lp)
{
if ((lp->nfslock_lock & NFSV4LOCK_LOCK) != 0)
return (0);
lp->nfslock_usecnt++;
return (1);
}
/*
* Test for a lock. Return 1 if locked, 0 otherwise.
*/
APPLESTATIC int
nfsv4_testlock(struct nfsv4lock *lp)
{
if ((lp->nfslock_lock & NFSV4LOCK_LOCK) == 0 &&
lp->nfslock_usecnt == 0)
return (0);
return (1);
}
/*
* Wake up anyone sleeping, waiting for this lock.
*/
static void
nfsv4_wanted(struct nfsv4lock *lp)
{
if (lp->nfslock_lock & NFSV4LOCK_WANTED) {
lp->nfslock_lock &= ~NFSV4LOCK_WANTED;
wakeup((caddr_t)&lp->nfslock_lock);
}
}
/*
* Copy a string from an mbuf list into a character array.
* Return EBADRPC if there is an mbuf error,
* 0 otherwise.
*/
APPLESTATIC int
nfsrv_mtostr(struct nfsrv_descript *nd, char *str, int siz)
{
char *cp;
int xfer, len;
mbuf_t mp;
int rem, error = 0;
mp = nd->nd_md;
cp = nd->nd_dpos;
len = NFSMTOD(mp, caddr_t) + mbuf_len(mp) - cp;
rem = NFSM_RNDUP(siz) - siz;
while (siz > 0) {
if (len > siz)
xfer = siz;
else
xfer = len;
NFSBCOPY(cp, str, xfer);
str += xfer;
siz -= xfer;
if (siz > 0) {
mp = mbuf_next(mp);
if (mp == NULL) {
error = EBADRPC;
goto out;
}
cp = NFSMTOD(mp, caddr_t);
len = mbuf_len(mp);
} else {
cp += xfer;
len -= xfer;
}
}
*str = '\0';
nd->nd_dpos = cp;
nd->nd_md = mp;
if (rem > 0) {
if (len < rem)
error = nfsm_advance(nd, rem, len);
else
nd->nd_dpos += rem;
}
out:
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Fill in the attributes as marked by the bitmap (V4).
*/
APPLESTATIC int
nfsv4_fillattr(struct nfsrv_descript *nd, struct mount *mp, vnode_t vp,
NFSACL_T *saclp, struct vattr *vap, fhandle_t *fhp, int rderror,
nfsattrbit_t *attrbitp, struct ucred *cred, NFSPROC_T *p, int isdgram,
int reterr, int supports_nfsv4acls, int at_root, uint64_t mounted_on_fileno)
{
int bitpos, retnum = 0;
u_int32_t *tl;
int siz, prefixnum, error;
u_char *cp, namestr[NFSV4_SMALLSTR];
nfsattrbit_t attrbits, retbits;
nfsattrbit_t *retbitp = &retbits;
u_int32_t freenum, *retnump;
u_int64_t uquad;
struct statfs *fs;
struct nfsfsinfo fsinf;
struct timespec temptime;
NFSACL_T *aclp, *naclp = NULL;
#ifdef QUOTA
struct dqblk dqb;
uid_t savuid;
#endif
/*
* First, set the bits that can be filled and get fsinfo.
*/
NFSSET_ATTRBIT(retbitp, attrbitp);
/*
* If both p and cred are NULL, it is a client side setattr call.
* If both p and cred are not NULL, it is a server side reply call.
* If p is not NULL and cred is NULL, it is a client side callback
* reply call.
*/
if (p == NULL && cred == NULL) {
NFSCLRNOTSETABLE_ATTRBIT(retbitp);
aclp = saclp;
} else {
NFSCLRNOTFILLABLE_ATTRBIT(retbitp);
naclp = acl_alloc(M_WAITOK);
aclp = naclp;
}
nfsvno_getfs(&fsinf, isdgram);
#ifndef APPLE
/*
* Get the VFS_STATFS(), since some attributes need them.
*/
fs = malloc(sizeof(struct statfs), M_STATFS, M_WAITOK);
if (NFSISSETSTATFS_ATTRBIT(retbitp)) {
error = VFS_STATFS(mp, fs);
if (error != 0) {
if (reterr) {
nd->nd_repstat = NFSERR_ACCES;
free(fs, M_STATFS);
return (0);
}
NFSCLRSTATFS_ATTRBIT(retbitp);
}
}
#endif
/*
* And the NFSv4 ACL...
*/
if (NFSISSET_ATTRBIT(retbitp, NFSATTRBIT_ACLSUPPORT) &&
(nfsrv_useacl == 0 || ((cred != NULL || p != NULL) &&
supports_nfsv4acls == 0))) {
NFSCLRBIT_ATTRBIT(retbitp, NFSATTRBIT_ACLSUPPORT);
}
if (NFSISSET_ATTRBIT(retbitp, NFSATTRBIT_ACL)) {
if (nfsrv_useacl == 0 || ((cred != NULL || p != NULL) &&
supports_nfsv4acls == 0)) {
NFSCLRBIT_ATTRBIT(retbitp, NFSATTRBIT_ACL);
} else if (naclp != NULL) {
if (NFSVOPLOCK(vp, LK_SHARED) == 0) {
error = VOP_ACCESSX(vp, VREAD_ACL, cred, p);
if (error == 0)
error = VOP_GETACL(vp, ACL_TYPE_NFS4,
naclp, cred, p);
NFSVOPUNLOCK(vp, 0);
} else
error = NFSERR_PERM;
if (error != 0) {
if (reterr) {
nd->nd_repstat = NFSERR_ACCES;
free(fs, M_STATFS);
return (0);
}
NFSCLRBIT_ATTRBIT(retbitp, NFSATTRBIT_ACL);
}
}
}
/*
* Put out the attribute bitmap for the ones being filled in
* and get the field for the number of attributes returned.
*/
prefixnum = nfsrv_putattrbit(nd, retbitp);
NFSM_BUILD(retnump, u_int32_t *, NFSX_UNSIGNED);
prefixnum += NFSX_UNSIGNED;
/*
* Now, loop around filling in the attributes for each bit set.
*/
for (bitpos = 0; bitpos < NFSATTRBIT_MAX; bitpos++) {
if (NFSISSET_ATTRBIT(retbitp, bitpos)) {
switch (bitpos) {
case NFSATTRBIT_SUPPORTEDATTRS:
NFSSETSUPP_ATTRBIT(&attrbits);
if (nfsrv_useacl == 0 || ((cred != NULL || p != NULL)
&& supports_nfsv4acls == 0)) {
NFSCLRBIT_ATTRBIT(&attrbits,NFSATTRBIT_ACLSUPPORT);
NFSCLRBIT_ATTRBIT(&attrbits,NFSATTRBIT_ACL);
}
retnum += nfsrv_putattrbit(nd, &attrbits);
break;
case NFSATTRBIT_TYPE:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = vtonfsv34_type(vap->va_type);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FHEXPIRETYPE:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(NFSV4FHTYPE_PERSISTENT);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CHANGE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
txdr_hyper(vap->va_filerev, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_SIZE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
txdr_hyper(vap->va_size, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_LINKSUPPORT:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
if (fsinf.fs_properties & NFSV3FSINFO_LINK)
*tl = newnfs_true;
else
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_SYMLINKSUPPORT:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
if (fsinf.fs_properties & NFSV3FSINFO_SYMLINK)
*tl = newnfs_true;
else
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NAMEDATTR:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FSID:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4FSID);
*tl++ = 0;
*tl++ = txdr_unsigned(mp->mnt_stat.f_fsid.val[0]);
*tl++ = 0;
*tl = txdr_unsigned(mp->mnt_stat.f_fsid.val[1]);
retnum += NFSX_V4FSID;
break;
case NFSATTRBIT_UNIQUEHANDLES:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_true;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_LEASETIME:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(nfsrv_lease);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_RDATTRERROR:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(rderror);
retnum += NFSX_UNSIGNED;
break;
/*
* Recommended Attributes. (Only the supported ones.)
*/
case NFSATTRBIT_ACL:
retnum += nfsrv_buildacl(nd, aclp, vnode_vtype(vp), p);
break;
case NFSATTRBIT_ACLSUPPORT:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(NFSV4ACE_SUPTYPES);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CANSETTIME:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
if (fsinf.fs_properties & NFSV3FSINFO_CANSETTIME)
*tl = newnfs_true;
else
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CASEINSENSITIVE:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CASEPRESERVING:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_true;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_CHOWNRESTRICTED:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_true;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_FILEHANDLE:
retnum += nfsm_fhtom(nd, (u_int8_t *)fhp, 0, 0);
break;
case NFSATTRBIT_FILEID:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(vap->va_fileid);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESAVAIL:
/*
* Check quota and use min(quota, f_ffree).
*/
freenum = fs->f_ffree;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(mp, QCMD(Q_GETQUOTA,USRQUOTA),
cred->cr_uid, (caddr_t)&dqb))
freenum = min(dqb.dqb_isoftlimit-dqb.dqb_curinodes,
freenum);
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(freenum);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESFREE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(fs->f_ffree);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_FILESTOTAL:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(fs->f_files);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_FSLOCATIONS:
NFSM_BUILD(tl, u_int32_t *, 2 * NFSX_UNSIGNED);
*tl++ = 0;
*tl = 0;
retnum += 2 * NFSX_UNSIGNED;
break;
case NFSATTRBIT_HOMOGENEOUS:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
if (fsinf.fs_properties & NFSV3FSINFO_HOMOGENEOUS)
*tl = newnfs_true;
else
*tl = newnfs_false;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXFILESIZE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = NFSRV_MAXFILESIZE;
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_MAXLINK:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(LINK_MAX);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXNAME:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(NFS_MAXNAMLEN);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_MAXREAD:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(fsinf.fs_rtmax);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_MAXWRITE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
*tl++ = 0;
*tl = txdr_unsigned(fsinf.fs_wtmax);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_MODE:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = vtonfsv34_mode(vap->va_mode);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NOTRUNC:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = newnfs_true;
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_NUMLINKS:
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(vap->va_nlink);
retnum += NFSX_UNSIGNED;
break;
case NFSATTRBIT_OWNER:
cp = namestr;
nfsv4_uidtostr(vap->va_uid, &cp, &siz, p);
retnum += nfsm_strtom(nd, cp, siz);
if (cp != namestr)
free(cp, M_NFSSTRING);
break;
case NFSATTRBIT_OWNERGROUP:
cp = namestr;
nfsv4_gidtostr(vap->va_gid, &cp, &siz, p);
retnum += nfsm_strtom(nd, cp, siz);
if (cp != namestr)
free(cp, M_NFSSTRING);
break;
case NFSATTRBIT_QUOTAHARD:
if (priv_check_cred(cred, PRIV_VFS_EXCEEDQUOTA, 0))
freenum = fs->f_bfree;
else
freenum = fs->f_bavail;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(mp, QCMD(Q_GETQUOTA,USRQUOTA),
cred->cr_uid, (caddr_t)&dqb))
freenum = min(dqb.dqb_bhardlimit, freenum);
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, fs->f_bsize);
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_QUOTASOFT:
if (priv_check_cred(cred, PRIV_VFS_EXCEEDQUOTA, 0))
freenum = fs->f_bfree;
else
freenum = fs->f_bavail;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(mp, QCMD(Q_GETQUOTA,USRQUOTA),
cred->cr_uid, (caddr_t)&dqb))
freenum = min(dqb.dqb_bsoftlimit, freenum);
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, fs->f_bsize);
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_QUOTAUSED:
freenum = 0;
#ifdef QUOTA
/*
* ufs_quotactl() insists that the uid argument
* equal p_ruid for non-root quota access, so
* we'll just make sure that's the case.
*/
savuid = p->p_cred->p_ruid;
p->p_cred->p_ruid = cred->cr_uid;
if (!VFS_QUOTACTL(mp, QCMD(Q_GETQUOTA,USRQUOTA),
cred->cr_uid, (caddr_t)&dqb))
freenum = dqb.dqb_curblocks;
p->p_cred->p_ruid = savuid;
#endif /* QUOTA */
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = (u_int64_t)freenum;
NFSQUOTABLKTOBYTE(uquad, fs->f_bsize);
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_RAWDEV:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4SPECDATA);
*tl++ = txdr_unsigned(NFSMAJOR(vap->va_rdev));
*tl = txdr_unsigned(NFSMINOR(vap->va_rdev));
retnum += NFSX_V4SPECDATA;
break;
case NFSATTRBIT_SPACEAVAIL:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
if (priv_check_cred(cred, PRIV_VFS_BLOCKRESERVE, 0))
uquad = (u_int64_t)fs->f_bfree;
else
uquad = (u_int64_t)fs->f_bavail;
uquad *= fs->f_bsize;
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACEFREE:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = (u_int64_t)fs->f_bfree;
uquad *= fs->f_bsize;
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACETOTAL:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
uquad = (u_int64_t)fs->f_blocks;
uquad *= fs->f_bsize;
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_SPACEUSED:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
txdr_hyper(vap->va_bytes, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_TIMEACCESS:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4TIME);
txdr_nfsv4time(&vap->va_atime, tl);
retnum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEACCESSSET:
if ((vap->va_vaflags & VA_UTIMES_NULL) == 0) {
NFSM_BUILD(tl, u_int32_t *, NFSX_V4SETTIME);
*tl++ = txdr_unsigned(NFSV4SATTRTIME_TOCLIENT);
txdr_nfsv4time(&vap->va_atime, tl);
retnum += NFSX_V4SETTIME;
} else {
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(NFSV4SATTRTIME_TOSERVER);
retnum += NFSX_UNSIGNED;
}
break;
case NFSATTRBIT_TIMEDELTA:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4TIME);
temptime.tv_sec = 0;
temptime.tv_nsec = 1000000000 / hz;
txdr_nfsv4time(&temptime, tl);
retnum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMETADATA:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4TIME);
txdr_nfsv4time(&vap->va_ctime, tl);
retnum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMODIFY:
NFSM_BUILD(tl, u_int32_t *, NFSX_V4TIME);
txdr_nfsv4time(&vap->va_mtime, tl);
retnum += NFSX_V4TIME;
break;
case NFSATTRBIT_TIMEMODIFYSET:
if ((vap->va_vaflags & VA_UTIMES_NULL) == 0) {
NFSM_BUILD(tl, u_int32_t *, NFSX_V4SETTIME);
*tl++ = txdr_unsigned(NFSV4SATTRTIME_TOCLIENT);
txdr_nfsv4time(&vap->va_mtime, tl);
retnum += NFSX_V4SETTIME;
} else {
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
*tl = txdr_unsigned(NFSV4SATTRTIME_TOSERVER);
retnum += NFSX_UNSIGNED;
}
break;
case NFSATTRBIT_MOUNTEDONFILEID:
NFSM_BUILD(tl, u_int32_t *, NFSX_HYPER);
if (at_root != 0)
uquad = mounted_on_fileno;
else
uquad = (u_int64_t)vap->va_fileid;
txdr_hyper(uquad, tl);
retnum += NFSX_HYPER;
break;
case NFSATTRBIT_SUPPATTREXCLCREAT:
NFSSETSUPP_ATTRBIT(&attrbits);
NFSCLRNOTSETABLE_ATTRBIT(&attrbits);
NFSCLRBIT_ATTRBIT(&attrbits, NFSATTRBIT_TIMEACCESSSET);
retnum += nfsrv_putattrbit(nd, &attrbits);
break;
default:
printf("EEK! Bad V4 attribute bitpos=%d\n", bitpos);
}
}
}
if (naclp != NULL)
acl_free(naclp);
free(fs, M_STATFS);
*retnump = txdr_unsigned(retnum);
return (retnum + prefixnum);
}
/*
* Put the attribute bits onto an mbuf list.
* Return the number of bytes of output generated.
*/
APPLESTATIC int
nfsrv_putattrbit(struct nfsrv_descript *nd, nfsattrbit_t *attrbitp)
{
u_int32_t *tl;
int cnt, i, bytesize;
for (cnt = NFSATTRBIT_MAXWORDS; cnt > 0; cnt--)
if (attrbitp->bits[cnt - 1])
break;
bytesize = (cnt + 1) * NFSX_UNSIGNED;
NFSM_BUILD(tl, u_int32_t *, bytesize);
*tl++ = txdr_unsigned(cnt);
for (i = 0; i < cnt; i++)
*tl++ = txdr_unsigned(attrbitp->bits[i]);
return (bytesize);
}
/*
* Convert a uid to a string.
* If the lookup fails, just output the digits.
* uid - the user id
* cpp - points to a buffer of size NFSV4_SMALLSTR
* (malloc a larger one, as required)
* retlenp - pointer to length to be returned
*/
APPLESTATIC void
nfsv4_uidtostr(uid_t uid, u_char **cpp, int *retlenp, NFSPROC_T *p)
{
int i;
struct nfsusrgrp *usrp;
u_char *cp = *cpp;
uid_t tmp;
int cnt, hasampersand, len = NFSV4_SMALLSTR, ret;
struct nfsrv_lughash *hp;
cnt = 0;
tryagain:
if (nfsrv_dnsnamelen > 0) {
/*
* Always map nfsrv_defaultuid to "nobody".
*/
if (uid == nfsrv_defaultuid) {
i = nfsrv_dnsnamelen + 7;
if (i > len) {
if (len > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
cp = malloc(i, M_NFSSTRING, M_WAITOK);
*cpp = cp;
len = i;
goto tryagain;
}
*retlenp = i;
NFSBCOPY("nobody@", cp, 7);
cp += 7;
NFSBCOPY(nfsrv_dnsname, cp, nfsrv_dnsnamelen);
return;
}
hasampersand = 0;
hp = NFSUSERHASH(uid);
mtx_lock(&hp->mtx);
TAILQ_FOREACH(usrp, &hp->lughead, lug_numhash) {
if (usrp->lug_uid == uid) {
if (usrp->lug_expiry < NFSD_MONOSEC)
break;
/*
* If the name doesn't already have an '@'
* in it, append @domainname to it.
*/
for (i = 0; i < usrp->lug_namelen; i++) {
if (usrp->lug_name[i] == '@') {
hasampersand = 1;
break;
}
}
if (hasampersand)
i = usrp->lug_namelen;
else
i = usrp->lug_namelen +
nfsrv_dnsnamelen + 1;
if (i > len) {
mtx_unlock(&hp->mtx);
if (len > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
cp = malloc(i, M_NFSSTRING, M_WAITOK);
*cpp = cp;
len = i;
goto tryagain;
}
*retlenp = i;
NFSBCOPY(usrp->lug_name, cp, usrp->lug_namelen);
if (!hasampersand) {
cp += usrp->lug_namelen;
*cp++ = '@';
NFSBCOPY(nfsrv_dnsname, cp, nfsrv_dnsnamelen);
}
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
TAILQ_INSERT_TAIL(&hp->lughead, usrp,
lug_numhash);
mtx_unlock(&hp->mtx);
return;
}
}
mtx_unlock(&hp->mtx);
cnt++;
ret = nfsrv_getuser(RPCNFSUSERD_GETUID, uid, (gid_t)0,
NULL, p);
if (ret == 0 && cnt < 2)
goto tryagain;
}
/*
* No match, just return a string of digits.
*/
tmp = uid;
i = 0;
while (tmp || i == 0) {
tmp /= 10;
i++;
}
len = (i > len) ? len : i;
*retlenp = len;
cp += (len - 1);
tmp = uid;
for (i = 0; i < len; i++) {
*cp-- = '0' + (tmp % 10);
tmp /= 10;
}
return;
}
/*
* Get a credential for the uid with the server's group list.
* If none is found, just return the credential passed in after
* logging a warning message.
*/
struct ucred *
nfsrv_getgrpscred(struct ucred *oldcred)
{
struct nfsusrgrp *usrp;
struct ucred *newcred;
int cnt, ret;
uid_t uid;
struct nfsrv_lughash *hp;
cnt = 0;
uid = oldcred->cr_uid;
tryagain:
if (nfsrv_dnsnamelen > 0) {
hp = NFSUSERHASH(uid);
mtx_lock(&hp->mtx);
TAILQ_FOREACH(usrp, &hp->lughead, lug_numhash) {
if (usrp->lug_uid == uid) {
if (usrp->lug_expiry < NFSD_MONOSEC)
break;
if (usrp->lug_cred != NULL) {
newcred = crhold(usrp->lug_cred);
crfree(oldcred);
} else
newcred = oldcred;
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
TAILQ_INSERT_TAIL(&hp->lughead, usrp,
lug_numhash);
mtx_unlock(&hp->mtx);
return (newcred);
}
}
mtx_unlock(&hp->mtx);
cnt++;
ret = nfsrv_getuser(RPCNFSUSERD_GETUID, uid, (gid_t)0,
NULL, curthread);
if (ret == 0 && cnt < 2)
goto tryagain;
}
return (oldcred);
}
/*
* Convert a string to a uid.
* If no conversion is possible return NFSERR_BADOWNER, otherwise
* return 0.
* If this is called from a client side mount using AUTH_SYS and the
* string is made up entirely of digits, just convert the string to
* a number.
*/
APPLESTATIC int
nfsv4_strtouid(struct nfsrv_descript *nd, u_char *str, int len, uid_t *uidp,
NFSPROC_T *p)
{
int i;
char *cp, *endstr, *str0;
struct nfsusrgrp *usrp;
int cnt, ret;
int error = 0;
uid_t tuid;
struct nfsrv_lughash *hp, *hp2;
if (len == 0) {
error = NFSERR_BADOWNER;
goto out;
}
/* If a string of digits and an AUTH_SYS mount, just convert it. */
str0 = str;
tuid = (uid_t)strtoul(str0, &endstr, 10);
if ((endstr - str0) == len) {
/* A numeric string. */
if ((nd->nd_flag & ND_KERBV) == 0 &&
((nd->nd_flag & ND_NFSCL) != 0 ||
nfsd_enable_stringtouid != 0))
*uidp = tuid;
else
error = NFSERR_BADOWNER;
goto out;
}
/*
* Look for an '@'.
*/
cp = strchr(str0, '@');
if (cp != NULL)
i = (int)(cp++ - str0);
else
i = len;
cnt = 0;
tryagain:
if (nfsrv_dnsnamelen > 0) {
/*
* If an '@' is found and the domain name matches, search for
* the name with dns stripped off.
* Mixed case alpahbetics will match for the domain name, but
* all upper case will not.
*/
if (cnt == 0 && i < len && i > 0 &&
(len - 1 - i) == nfsrv_dnsnamelen &&
!nfsrv_cmpmixedcase(cp, nfsrv_dnsname, nfsrv_dnsnamelen)) {
len -= (nfsrv_dnsnamelen + 1);
*(cp - 1) = '\0';
}
/*
* Check for the special case of "nobody".
*/
if (len == 6 && !NFSBCMP(str, "nobody", 6)) {
*uidp = nfsrv_defaultuid;
error = 0;
goto out;
}
hp = NFSUSERNAMEHASH(str, len);
mtx_lock(&hp->mtx);
TAILQ_FOREACH(usrp, &hp->lughead, lug_namehash) {
if (usrp->lug_namelen == len &&
!NFSBCMP(usrp->lug_name, str, len)) {
if (usrp->lug_expiry < NFSD_MONOSEC)
break;
hp2 = NFSUSERHASH(usrp->lug_uid);
mtx_lock(&hp2->mtx);
TAILQ_REMOVE(&hp2->lughead, usrp, lug_numhash);
TAILQ_INSERT_TAIL(&hp2->lughead, usrp,
lug_numhash);
*uidp = usrp->lug_uid;
mtx_unlock(&hp2->mtx);
mtx_unlock(&hp->mtx);
error = 0;
goto out;
}
}
mtx_unlock(&hp->mtx);
cnt++;
ret = nfsrv_getuser(RPCNFSUSERD_GETUSER, (uid_t)0, (gid_t)0,
str, p);
if (ret == 0 && cnt < 2)
goto tryagain;
}
error = NFSERR_BADOWNER;
out:
NFSEXITCODE(error);
return (error);
}
/*
* Convert a gid to a string.
* gid - the group id
* cpp - points to a buffer of size NFSV4_SMALLSTR
* (malloc a larger one, as required)
* retlenp - pointer to length to be returned
*/
APPLESTATIC void
nfsv4_gidtostr(gid_t gid, u_char **cpp, int *retlenp, NFSPROC_T *p)
{
int i;
struct nfsusrgrp *usrp;
u_char *cp = *cpp;
gid_t tmp;
int cnt, hasampersand, len = NFSV4_SMALLSTR, ret;
struct nfsrv_lughash *hp;
cnt = 0;
tryagain:
if (nfsrv_dnsnamelen > 0) {
/*
* Always map nfsrv_defaultgid to "nogroup".
*/
if (gid == nfsrv_defaultgid) {
i = nfsrv_dnsnamelen + 8;
if (i > len) {
if (len > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
cp = malloc(i, M_NFSSTRING, M_WAITOK);
*cpp = cp;
len = i;
goto tryagain;
}
*retlenp = i;
NFSBCOPY("nogroup@", cp, 8);
cp += 8;
NFSBCOPY(nfsrv_dnsname, cp, nfsrv_dnsnamelen);
return;
}
hasampersand = 0;
hp = NFSGROUPHASH(gid);
mtx_lock(&hp->mtx);
TAILQ_FOREACH(usrp, &hp->lughead, lug_numhash) {
if (usrp->lug_gid == gid) {
if (usrp->lug_expiry < NFSD_MONOSEC)
break;
/*
* If the name doesn't already have an '@'
* in it, append @domainname to it.
*/
for (i = 0; i < usrp->lug_namelen; i++) {
if (usrp->lug_name[i] == '@') {
hasampersand = 1;
break;
}
}
if (hasampersand)
i = usrp->lug_namelen;
else
i = usrp->lug_namelen +
nfsrv_dnsnamelen + 1;
if (i > len) {
mtx_unlock(&hp->mtx);
if (len > NFSV4_SMALLSTR)
free(cp, M_NFSSTRING);
cp = malloc(i, M_NFSSTRING, M_WAITOK);
*cpp = cp;
len = i;
goto tryagain;
}
*retlenp = i;
NFSBCOPY(usrp->lug_name, cp, usrp->lug_namelen);
if (!hasampersand) {
cp += usrp->lug_namelen;
*cp++ = '@';
NFSBCOPY(nfsrv_dnsname, cp, nfsrv_dnsnamelen);
}
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
TAILQ_INSERT_TAIL(&hp->lughead, usrp,
lug_numhash);
mtx_unlock(&hp->mtx);
return;
}
}
mtx_unlock(&hp->mtx);
cnt++;
ret = nfsrv_getuser(RPCNFSUSERD_GETGID, (uid_t)0, gid,
NULL, p);
if (ret == 0 && cnt < 2)
goto tryagain;
}
/*
* No match, just return a string of digits.
*/
tmp = gid;
i = 0;
while (tmp || i == 0) {
tmp /= 10;
i++;
}
len = (i > len) ? len : i;
*retlenp = len;
cp += (len - 1);
tmp = gid;
for (i = 0; i < len; i++) {
*cp-- = '0' + (tmp % 10);
tmp /= 10;
}
return;
}
/*
* Convert a string to a gid.
* If no conversion is possible return NFSERR_BADOWNER, otherwise
* return 0.
* If this is called from a client side mount using AUTH_SYS and the
* string is made up entirely of digits, just convert the string to
* a number.
*/
APPLESTATIC int
nfsv4_strtogid(struct nfsrv_descript *nd, u_char *str, int len, gid_t *gidp,
NFSPROC_T *p)
{
int i;
char *cp, *endstr, *str0;
struct nfsusrgrp *usrp;
int cnt, ret;
int error = 0;
gid_t tgid;
struct nfsrv_lughash *hp, *hp2;
if (len == 0) {
error = NFSERR_BADOWNER;
goto out;
}
/* If a string of digits and an AUTH_SYS mount, just convert it. */
str0 = str;
tgid = (gid_t)strtoul(str0, &endstr, 10);
if ((endstr - str0) == len) {
/* A numeric string. */
if ((nd->nd_flag & ND_KERBV) == 0 &&
((nd->nd_flag & ND_NFSCL) != 0 ||
nfsd_enable_stringtouid != 0))
*gidp = tgid;
else
error = NFSERR_BADOWNER;
goto out;
}
/*
* Look for an '@'.
*/
cp = strchr(str0, '@');
if (cp != NULL)
i = (int)(cp++ - str0);
else
i = len;
cnt = 0;
tryagain:
if (nfsrv_dnsnamelen > 0) {
/*
* If an '@' is found and the dns name matches, search for the
* name with the dns stripped off.
*/
if (cnt == 0 && i < len && i > 0 &&
(len - 1 - i) == nfsrv_dnsnamelen &&
!nfsrv_cmpmixedcase(cp, nfsrv_dnsname, nfsrv_dnsnamelen)) {
len -= (nfsrv_dnsnamelen + 1);
*(cp - 1) = '\0';
}
/*
* Check for the special case of "nogroup".
*/
if (len == 7 && !NFSBCMP(str, "nogroup", 7)) {
*gidp = nfsrv_defaultgid;
error = 0;
goto out;
}
hp = NFSGROUPNAMEHASH(str, len);
mtx_lock(&hp->mtx);
TAILQ_FOREACH(usrp, &hp->lughead, lug_namehash) {
if (usrp->lug_namelen == len &&
!NFSBCMP(usrp->lug_name, str, len)) {
if (usrp->lug_expiry < NFSD_MONOSEC)
break;
hp2 = NFSGROUPHASH(usrp->lug_gid);
mtx_lock(&hp2->mtx);
TAILQ_REMOVE(&hp2->lughead, usrp, lug_numhash);
TAILQ_INSERT_TAIL(&hp2->lughead, usrp,
lug_numhash);
*gidp = usrp->lug_gid;
mtx_unlock(&hp2->mtx);
mtx_unlock(&hp->mtx);
error = 0;
goto out;
}
}
mtx_unlock(&hp->mtx);
cnt++;
ret = nfsrv_getuser(RPCNFSUSERD_GETGROUP, (uid_t)0, (gid_t)0,
str, p);
if (ret == 0 && cnt < 2)
goto tryagain;
}
error = NFSERR_BADOWNER;
out:
NFSEXITCODE(error);
return (error);
}
/*
* Cmp len chars, allowing mixed case in the first argument to match lower
* case in the second, but not if the first argument is all upper case.
* Return 0 for a match, 1 otherwise.
*/
static int
nfsrv_cmpmixedcase(u_char *cp, u_char *cp2, int len)
{
int i;
u_char tmp;
int fndlower = 0;
for (i = 0; i < len; i++) {
if (*cp >= 'A' && *cp <= 'Z') {
tmp = *cp++ + ('a' - 'A');
} else {
tmp = *cp++;
if (tmp >= 'a' && tmp <= 'z')
fndlower = 1;
}
if (tmp != *cp2++)
return (1);
}
if (fndlower)
return (0);
else
return (1);
}
/*
* Set the port for the nfsuserd.
*/
APPLESTATIC int
nfsrv_nfsuserdport(u_short port, NFSPROC_T *p)
{
struct nfssockreq *rp;
struct sockaddr_in *ad;
int error;
NFSLOCKNAMEID();
if (nfsrv_nfsuserd) {
NFSUNLOCKNAMEID();
error = EPERM;
goto out;
}
nfsrv_nfsuserd = 1;
NFSUNLOCKNAMEID();
/*
* Set up the socket record and connect.
*/
rp = &nfsrv_nfsuserdsock;
rp->nr_client = NULL;
rp->nr_sotype = SOCK_DGRAM;
rp->nr_soproto = IPPROTO_UDP;
rp->nr_lock = (NFSR_RESERVEDPORT | NFSR_LOCALHOST);
rp->nr_cred = NULL;
NFSSOCKADDRALLOC(rp->nr_nam);
NFSSOCKADDRSIZE(rp->nr_nam, sizeof (struct sockaddr_in));
ad = NFSSOCKADDR(rp->nr_nam, struct sockaddr_in *);
ad->sin_family = AF_INET;
ad->sin_addr.s_addr = htonl((u_int32_t)0x7f000001); /* 127.0.0.1 */
ad->sin_port = port;
rp->nr_prog = RPCPROG_NFSUSERD;
rp->nr_vers = RPCNFSUSERD_VERS;
error = newnfs_connect(NULL, rp, NFSPROCCRED(p), p, 0);
if (error) {
NFSSOCKADDRFREE(rp->nr_nam);
nfsrv_nfsuserd = 0;
}
out:
NFSEXITCODE(error);
return (error);
}
/*
* Delete the nfsuserd port.
*/
APPLESTATIC void
nfsrv_nfsuserddelport(void)
{
NFSLOCKNAMEID();
if (nfsrv_nfsuserd == 0) {
NFSUNLOCKNAMEID();
return;
}
nfsrv_nfsuserd = 0;
NFSUNLOCKNAMEID();
newnfs_disconnect(&nfsrv_nfsuserdsock);
NFSSOCKADDRFREE(nfsrv_nfsuserdsock.nr_nam);
}
/*
* Do upcalls to the nfsuserd, for cache misses of the owner/ownergroup
* name<-->id cache.
* Returns 0 upon success, non-zero otherwise.
*/
static int
nfsrv_getuser(int procnum, uid_t uid, gid_t gid, char *name, NFSPROC_T *p)
{
u_int32_t *tl;
struct nfsrv_descript *nd;
int len;
struct nfsrv_descript nfsd;
struct ucred *cred;
int error;
NFSLOCKNAMEID();
if (nfsrv_nfsuserd == 0) {
NFSUNLOCKNAMEID();
error = EPERM;
goto out;
}
NFSUNLOCKNAMEID();
nd = &nfsd;
cred = newnfs_getcred();
nd->nd_flag = ND_GSSINITREPLY;
nfsrvd_rephead(nd);
nd->nd_procnum = procnum;
if (procnum == RPCNFSUSERD_GETUID || procnum == RPCNFSUSERD_GETGID) {
NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
if (procnum == RPCNFSUSERD_GETUID)
*tl = txdr_unsigned(uid);
else
*tl = txdr_unsigned(gid);
} else {
len = strlen(name);
(void) nfsm_strtom(nd, name, len);
}
error = newnfs_request(nd, NULL, NULL, &nfsrv_nfsuserdsock, NULL, NULL,
cred, RPCPROG_NFSUSERD, RPCNFSUSERD_VERS, NULL, 0, NULL, NULL);
NFSFREECRED(cred);
if (!error) {
mbuf_freem(nd->nd_mrep);
error = nd->nd_repstat;
}
out:
NFSEXITCODE(error);
return (error);
}
/*
* This function is called from the nfssvc(2) system call, to update the
* kernel user/group name list(s) for the V4 owner and ownergroup attributes.
*/
APPLESTATIC int
nfssvc_idname(struct nfsd_idargs *nidp)
{
struct nfsusrgrp *nusrp, *usrp, *newusrp;
struct nfsrv_lughash *hp_name, *hp_idnum, *thp;
int i, group_locked, groupname_locked, user_locked, username_locked;
int error = 0;
u_char *cp;
gid_t *grps;
struct ucred *cr;
static int onethread = 0;
static time_t lasttime = 0;
if (nidp->nid_namelen <= 0 || nidp->nid_namelen > MAXHOSTNAMELEN) {
error = EINVAL;
goto out;
}
if (nidp->nid_flag & NFSID_INITIALIZE) {
cp = malloc(nidp->nid_namelen + 1, M_NFSSTRING, M_WAITOK);
error = copyin(CAST_USER_ADDR_T(nidp->nid_name), cp,
nidp->nid_namelen);
if (error != 0) {
free(cp, M_NFSSTRING);
goto out;
}
if (atomic_cmpset_acq_int(&nfsrv_dnsnamelen, 0, 0) == 0) {
/*
* Free up all the old stuff and reinitialize hash
* lists. All mutexes for both lists must be locked,
* with the user/group name ones before the uid/gid
* ones, to avoid a LOR.
*/
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsusernamehash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsuserhash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_FOREACH_SAFE(usrp,
&nfsuserhash[i].lughead, lug_numhash, nusrp)
nfsrv_removeuser(usrp, 1);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsuserhash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsusernamehash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsgroupnamehash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsgrouphash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_FOREACH_SAFE(usrp,
&nfsgrouphash[i].lughead, lug_numhash,
nusrp)
nfsrv_removeuser(usrp, 0);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsgrouphash[i].mtx);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsgroupnamehash[i].mtx);
free(nfsrv_dnsname, M_NFSSTRING);
nfsrv_dnsname = NULL;
}
if (nfsuserhash == NULL) {
/* Allocate the hash tables. */
nfsuserhash = malloc(sizeof(struct nfsrv_lughash) *
nfsrv_lughashsize, M_NFSUSERGROUP, M_WAITOK |
M_ZERO);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_init(&nfsuserhash[i].mtx, "nfsuidhash",
NULL, MTX_DEF | MTX_DUPOK);
nfsusernamehash = malloc(sizeof(struct nfsrv_lughash) *
nfsrv_lughashsize, M_NFSUSERGROUP, M_WAITOK |
M_ZERO);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_init(&nfsusernamehash[i].mtx,
"nfsusrhash", NULL, MTX_DEF |
MTX_DUPOK);
nfsgrouphash = malloc(sizeof(struct nfsrv_lughash) *
nfsrv_lughashsize, M_NFSUSERGROUP, M_WAITOK |
M_ZERO);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_init(&nfsgrouphash[i].mtx, "nfsgidhash",
NULL, MTX_DEF | MTX_DUPOK);
nfsgroupnamehash = malloc(sizeof(struct nfsrv_lughash) *
nfsrv_lughashsize, M_NFSUSERGROUP, M_WAITOK |
M_ZERO);
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_init(&nfsgroupnamehash[i].mtx,
"nfsgrphash", NULL, MTX_DEF | MTX_DUPOK);
}
/* (Re)initialize the list heads. */
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_INIT(&nfsuserhash[i].lughead);
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_INIT(&nfsusernamehash[i].lughead);
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_INIT(&nfsgrouphash[i].lughead);
for (i = 0; i < nfsrv_lughashsize; i++)
TAILQ_INIT(&nfsgroupnamehash[i].lughead);
/*
* Put name in "DNS" string.
*/
nfsrv_dnsname = cp;
nfsrv_defaultuid = nidp->nid_uid;
nfsrv_defaultgid = nidp->nid_gid;
nfsrv_usercnt = 0;
nfsrv_usermax = nidp->nid_usermax;
atomic_store_rel_int(&nfsrv_dnsnamelen, nidp->nid_namelen);
goto out;
}
/*
* malloc the new one now, so any potential sleep occurs before
* manipulation of the lists.
*/
newusrp = malloc(sizeof(struct nfsusrgrp) + nidp->nid_namelen,
M_NFSUSERGROUP, M_WAITOK | M_ZERO);
error = copyin(CAST_USER_ADDR_T(nidp->nid_name), newusrp->lug_name,
nidp->nid_namelen);
if (error == 0 && nidp->nid_ngroup > 0 &&
(nidp->nid_flag & NFSID_ADDUID) != 0) {
grps = malloc(sizeof(gid_t) * nidp->nid_ngroup, M_TEMP,
M_WAITOK);
error = copyin(CAST_USER_ADDR_T(nidp->nid_grps), grps,
sizeof(gid_t) * nidp->nid_ngroup);
if (error == 0) {
/*
* Create a credential just like svc_getcred(),
* but using the group list provided.
*/
cr = crget();
cr->cr_uid = cr->cr_ruid = cr->cr_svuid = nidp->nid_uid;
crsetgroups(cr, nidp->nid_ngroup, grps);
cr->cr_rgid = cr->cr_svgid = cr->cr_groups[0];
cr->cr_prison = &prison0;
prison_hold(cr->cr_prison);
#ifdef MAC
mac_cred_associate_nfsd(cr);
#endif
newusrp->lug_cred = cr;
}
free(grps, M_TEMP);
}
if (error) {
free(newusrp, M_NFSUSERGROUP);
goto out;
}
newusrp->lug_namelen = nidp->nid_namelen;
/*
* The lock order is username[0]->[nfsrv_lughashsize - 1] followed
* by uid[0]->[nfsrv_lughashsize - 1], with the same for group.
* The flags user_locked, username_locked, group_locked and
* groupname_locked are set to indicate all of those hash lists are
* locked. hp_name != NULL and hp_idnum != NULL indicates that
* the respective one mutex is locked.
*/
user_locked = username_locked = group_locked = groupname_locked = 0;
hp_name = hp_idnum = NULL;
/*
* Delete old entries, as required.
*/
if (nidp->nid_flag & (NFSID_DELUID | NFSID_ADDUID)) {
/* Must lock all username hash lists first, to avoid a LOR. */
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsusernamehash[i].mtx);
username_locked = 1;
hp_idnum = NFSUSERHASH(nidp->nid_uid);
mtx_lock(&hp_idnum->mtx);
TAILQ_FOREACH_SAFE(usrp, &hp_idnum->lughead, lug_numhash,
nusrp) {
if (usrp->lug_uid == nidp->nid_uid)
nfsrv_removeuser(usrp, 1);
}
} else if (nidp->nid_flag & (NFSID_DELUSERNAME | NFSID_ADDUSERNAME)) {
hp_name = NFSUSERNAMEHASH(newusrp->lug_name,
newusrp->lug_namelen);
mtx_lock(&hp_name->mtx);
TAILQ_FOREACH_SAFE(usrp, &hp_name->lughead, lug_namehash,
nusrp) {
if (usrp->lug_namelen == newusrp->lug_namelen &&
!NFSBCMP(usrp->lug_name, newusrp->lug_name,
usrp->lug_namelen)) {
thp = NFSUSERHASH(usrp->lug_uid);
mtx_lock(&thp->mtx);
nfsrv_removeuser(usrp, 1);
mtx_unlock(&thp->mtx);
}
}
hp_idnum = NFSUSERHASH(nidp->nid_uid);
mtx_lock(&hp_idnum->mtx);
} else if (nidp->nid_flag & (NFSID_DELGID | NFSID_ADDGID)) {
/* Must lock all groupname hash lists first, to avoid a LOR. */
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsgroupnamehash[i].mtx);
groupname_locked = 1;
hp_idnum = NFSGROUPHASH(nidp->nid_gid);
mtx_lock(&hp_idnum->mtx);
TAILQ_FOREACH_SAFE(usrp, &hp_idnum->lughead, lug_numhash,
nusrp) {
if (usrp->lug_gid == nidp->nid_gid)
nfsrv_removeuser(usrp, 0);
}
} else if (nidp->nid_flag & (NFSID_DELGROUPNAME | NFSID_ADDGROUPNAME)) {
hp_name = NFSGROUPNAMEHASH(newusrp->lug_name,
newusrp->lug_namelen);
mtx_lock(&hp_name->mtx);
TAILQ_FOREACH_SAFE(usrp, &hp_name->lughead, lug_namehash,
nusrp) {
if (usrp->lug_namelen == newusrp->lug_namelen &&
!NFSBCMP(usrp->lug_name, newusrp->lug_name,
usrp->lug_namelen)) {
thp = NFSGROUPHASH(usrp->lug_gid);
mtx_lock(&thp->mtx);
nfsrv_removeuser(usrp, 0);
mtx_unlock(&thp->mtx);
}
}
hp_idnum = NFSGROUPHASH(nidp->nid_gid);
mtx_lock(&hp_idnum->mtx);
}
/*
* Now, we can add the new one.
*/
if (nidp->nid_usertimeout)
newusrp->lug_expiry = NFSD_MONOSEC + nidp->nid_usertimeout;
else
newusrp->lug_expiry = NFSD_MONOSEC + 5;
if (nidp->nid_flag & (NFSID_ADDUID | NFSID_ADDUSERNAME)) {
newusrp->lug_uid = nidp->nid_uid;
thp = NFSUSERHASH(newusrp->lug_uid);
mtx_assert(&thp->mtx, MA_OWNED);
TAILQ_INSERT_TAIL(&thp->lughead, newusrp, lug_numhash);
thp = NFSUSERNAMEHASH(newusrp->lug_name, newusrp->lug_namelen);
mtx_assert(&thp->mtx, MA_OWNED);
TAILQ_INSERT_TAIL(&thp->lughead, newusrp, lug_namehash);
atomic_add_int(&nfsrv_usercnt, 1);
} else if (nidp->nid_flag & (NFSID_ADDGID | NFSID_ADDGROUPNAME)) {
newusrp->lug_gid = nidp->nid_gid;
thp = NFSGROUPHASH(newusrp->lug_gid);
mtx_assert(&thp->mtx, MA_OWNED);
TAILQ_INSERT_TAIL(&thp->lughead, newusrp, lug_numhash);
thp = NFSGROUPNAMEHASH(newusrp->lug_name, newusrp->lug_namelen);
mtx_assert(&thp->mtx, MA_OWNED);
TAILQ_INSERT_TAIL(&thp->lughead, newusrp, lug_namehash);
atomic_add_int(&nfsrv_usercnt, 1);
} else {
if (newusrp->lug_cred != NULL)
crfree(newusrp->lug_cred);
free(newusrp, M_NFSUSERGROUP);
}
/*
* Once per second, allow one thread to trim the cache.
*/
if (lasttime < NFSD_MONOSEC &&
atomic_cmpset_acq_int(&onethread, 0, 1) != 0) {
/*
* First, unlock the single mutexes, so that all entries
* can be locked and any LOR is avoided.
*/
if (hp_name != NULL) {
mtx_unlock(&hp_name->mtx);
hp_name = NULL;
}
if (hp_idnum != NULL) {
mtx_unlock(&hp_idnum->mtx);
hp_idnum = NULL;
}
if ((nidp->nid_flag & (NFSID_DELUID | NFSID_ADDUID |
NFSID_DELUSERNAME | NFSID_ADDUSERNAME)) != 0) {
if (username_locked == 0) {
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsusernamehash[i].mtx);
username_locked = 1;
}
KASSERT(user_locked == 0,
("nfssvc_idname: user_locked"));
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsuserhash[i].mtx);
user_locked = 1;
for (i = 0; i < nfsrv_lughashsize; i++) {
TAILQ_FOREACH_SAFE(usrp,
&nfsuserhash[i].lughead, lug_numhash,
nusrp)
if (usrp->lug_expiry < NFSD_MONOSEC)
nfsrv_removeuser(usrp, 1);
}
for (i = 0; i < nfsrv_lughashsize; i++) {
/*
* Trim the cache using an approximate LRU
* algorithm. This code deletes the least
* recently used entry on each hash list.
*/
if (nfsrv_usercnt <= nfsrv_usermax)
break;
usrp = TAILQ_FIRST(&nfsuserhash[i].lughead);
if (usrp != NULL)
nfsrv_removeuser(usrp, 1);
}
} else {
if (groupname_locked == 0) {
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsgroupnamehash[i].mtx);
groupname_locked = 1;
}
KASSERT(group_locked == 0,
("nfssvc_idname: group_locked"));
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_lock(&nfsgrouphash[i].mtx);
group_locked = 1;
for (i = 0; i < nfsrv_lughashsize; i++) {
TAILQ_FOREACH_SAFE(usrp,
&nfsgrouphash[i].lughead, lug_numhash,
nusrp)
if (usrp->lug_expiry < NFSD_MONOSEC)
nfsrv_removeuser(usrp, 0);
}
for (i = 0; i < nfsrv_lughashsize; i++) {
/*
* Trim the cache using an approximate LRU
* algorithm. This code deletes the least
* recently user entry on each hash list.
*/
if (nfsrv_usercnt <= nfsrv_usermax)
break;
usrp = TAILQ_FIRST(&nfsgrouphash[i].lughead);
if (usrp != NULL)
nfsrv_removeuser(usrp, 0);
}
}
lasttime = NFSD_MONOSEC;
atomic_store_rel_int(&onethread, 0);
}
/* Now, unlock all locked mutexes. */
if (hp_idnum != NULL)
mtx_unlock(&hp_idnum->mtx);
if (hp_name != NULL)
mtx_unlock(&hp_name->mtx);
if (user_locked != 0)
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsuserhash[i].mtx);
if (username_locked != 0)
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsusernamehash[i].mtx);
if (group_locked != 0)
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsgrouphash[i].mtx);
if (groupname_locked != 0)
for (i = 0; i < nfsrv_lughashsize; i++)
mtx_unlock(&nfsgroupnamehash[i].mtx);
out:
NFSEXITCODE(error);
return (error);
}
/*
* Remove a user/group name element.
*/
static void
nfsrv_removeuser(struct nfsusrgrp *usrp, int isuser)
{
struct nfsrv_lughash *hp;
if (isuser != 0) {
hp = NFSUSERHASH(usrp->lug_uid);
mtx_assert(&hp->mtx, MA_OWNED);
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
hp = NFSUSERNAMEHASH(usrp->lug_name, usrp->lug_namelen);
mtx_assert(&hp->mtx, MA_OWNED);
TAILQ_REMOVE(&hp->lughead, usrp, lug_namehash);
} else {
hp = NFSGROUPHASH(usrp->lug_gid);
mtx_assert(&hp->mtx, MA_OWNED);
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
hp = NFSGROUPNAMEHASH(usrp->lug_name, usrp->lug_namelen);
mtx_assert(&hp->mtx, MA_OWNED);
TAILQ_REMOVE(&hp->lughead, usrp, lug_namehash);
}
atomic_add_int(&nfsrv_usercnt, -1);
if (usrp->lug_cred != NULL)
crfree(usrp->lug_cred);
free(usrp, M_NFSUSERGROUP);
}
/*
* Free up all the allocations related to the name<-->id cache.
* This function should only be called when the nfsuserd daemon isn't
* running, since it doesn't do any locking.
* This function is meant to be used when the nfscommon module is unloaded.
*/
APPLESTATIC void
nfsrv_cleanusergroup(void)
{
struct nfsrv_lughash *hp, *hp2;
struct nfsusrgrp *nusrp, *usrp;
int i;
if (nfsuserhash == NULL)
return;
for (i = 0; i < nfsrv_lughashsize; i++) {
hp = &nfsuserhash[i];
TAILQ_FOREACH_SAFE(usrp, &hp->lughead, lug_numhash, nusrp) {
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
hp2 = NFSUSERNAMEHASH(usrp->lug_name,
usrp->lug_namelen);
TAILQ_REMOVE(&hp2->lughead, usrp, lug_namehash);
if (usrp->lug_cred != NULL)
crfree(usrp->lug_cred);
free(usrp, M_NFSUSERGROUP);
}
hp = &nfsgrouphash[i];
TAILQ_FOREACH_SAFE(usrp, &hp->lughead, lug_numhash, nusrp) {
TAILQ_REMOVE(&hp->lughead, usrp, lug_numhash);
hp2 = NFSGROUPNAMEHASH(usrp->lug_name,
usrp->lug_namelen);
TAILQ_REMOVE(&hp2->lughead, usrp, lug_namehash);
if (usrp->lug_cred != NULL)
crfree(usrp->lug_cred);
free(usrp, M_NFSUSERGROUP);
}
mtx_destroy(&nfsuserhash[i].mtx);
mtx_destroy(&nfsusernamehash[i].mtx);
mtx_destroy(&nfsgroupnamehash[i].mtx);
mtx_destroy(&nfsgrouphash[i].mtx);
}
free(nfsuserhash, M_NFSUSERGROUP);
free(nfsusernamehash, M_NFSUSERGROUP);
free(nfsgrouphash, M_NFSUSERGROUP);
free(nfsgroupnamehash, M_NFSUSERGROUP);
free(nfsrv_dnsname, M_NFSSTRING);
}
/*
* This function scans a byte string and checks for UTF-8 compliance.
* It returns 0 if it conforms and NFSERR_INVAL if not.
*/
APPLESTATIC int
nfsrv_checkutf8(u_int8_t *cp, int len)
{
u_int32_t val = 0x0;
int cnt = 0, gotd = 0, shift = 0;
u_int8_t byte;
static int utf8_shift[5] = { 7, 11, 16, 21, 26 };
int error = 0;
/*
* Here are what the variables are used for:
* val - the calculated value of a multibyte char, used to check
* that it was coded with the correct range
* cnt - the number of 10xxxxxx bytes to follow
* gotd - set for a char of Dxxx, so D800<->DFFF can be checked for
* shift - lower order bits of range (ie. "val >> shift" should
* not be 0, in other words, dividing by the lower bound
* of the range should get a non-zero value)
* byte - used to calculate cnt
*/
while (len > 0) {
if (cnt > 0) {
/* This handles the 10xxxxxx bytes */
if ((*cp & 0xc0) != 0x80 ||
(gotd && (*cp & 0x20))) {
error = NFSERR_INVAL;
goto out;
}
gotd = 0;
val <<= 6;
val |= (*cp & 0x3f);
cnt--;
if (cnt == 0 && (val >> shift) == 0x0) {
error = NFSERR_INVAL;
goto out;
}
} else if (*cp & 0x80) {
/* first byte of multi byte char */
byte = *cp;
while ((byte & 0x40) && cnt < 6) {
cnt++;
byte <<= 1;
}
if (cnt == 0 || cnt == 6) {
error = NFSERR_INVAL;
goto out;
}
val = (*cp & (0x3f >> cnt));
shift = utf8_shift[cnt - 1];
if (cnt == 2 && val == 0xd)
/* Check for the 0xd800-0xdfff case */
gotd = 1;
}
cp++;
len--;
}
if (cnt > 0)
error = NFSERR_INVAL;
out:
NFSEXITCODE(error);
return (error);
}
/*
* Parse the xdr for an NFSv4 FsLocations attribute. Return two malloc'd
* strings, one with the root path in it and the other with the list of
* locations. The list is in the same format as is found in nfr_refs.
* It is a "," separated list of entries, where each of them is of the
* form <server>:<rootpath>. For example
* "nfsv4-test:/sub2,nfsv4-test2:/user/mnt,nfsv4-test2:/user/mnt2"
* The nilp argument is set to 1 for the special case of a null fs_root
* and an empty server list.
* It returns NFSERR_BADXDR, if the xdr can't be parsed and returns the
* number of xdr bytes parsed in sump.
*/
static int
nfsrv_getrefstr(struct nfsrv_descript *nd, u_char **fsrootp, u_char **srvp,
int *sump, int *nilp)
{
u_int32_t *tl;
u_char *cp = NULL, *cp2 = NULL, *cp3, *str;
int i, j, len, stringlen, cnt, slen, siz, xdrsum, error = 0, nsrv;
struct list {
SLIST_ENTRY(list) next;
int len;
u_char host[1];
} *lsp, *nlsp;
SLIST_HEAD(, list) head;
*fsrootp = NULL;
*srvp = NULL;
*nilp = 0;
/*
* Get the fs_root path and check for the special case of null path
* and 0 length server list.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
len = fxdr_unsigned(int, *tl);
if (len < 0 || len > 10240) {
error = NFSERR_BADXDR;
goto nfsmout;
}
if (len == 0) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
if (*tl != 0) {
error = NFSERR_BADXDR;
goto nfsmout;
}
*nilp = 1;
*sump = 2 * NFSX_UNSIGNED;
error = 0;
goto nfsmout;
}
cp = malloc(len + 1, M_NFSSTRING, M_WAITOK);
error = nfsrv_mtostr(nd, cp, len);
if (!error) {
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
cnt = fxdr_unsigned(int, *tl);
if (cnt <= 0)
error = NFSERR_BADXDR;
}
if (error)
goto nfsmout;
/*
* Now, loop through the location list and make up the srvlist.
*/
xdrsum = (2 * NFSX_UNSIGNED) + NFSM_RNDUP(len);
cp2 = cp3 = malloc(1024, M_NFSSTRING, M_WAITOK);
slen = 1024;
siz = 0;
for (i = 0; i < cnt; i++) {
SLIST_INIT(&head);
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
nsrv = fxdr_unsigned(int, *tl);
if (nsrv <= 0) {
error = NFSERR_BADXDR;
goto nfsmout;
}
/*
* Handle the first server by putting it in the srvstr.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
len = fxdr_unsigned(int, *tl);
if (len <= 0 || len > 1024) {
error = NFSERR_BADXDR;
goto nfsmout;
}
nfsrv_refstrbigenough(siz + len + 3, &cp2, &cp3, &slen);
if (cp3 != cp2) {
*cp3++ = ',';
siz++;
}
error = nfsrv_mtostr(nd, cp3, len);
if (error)
goto nfsmout;
cp3 += len;
*cp3++ = ':';
siz += (len + 1);
xdrsum += (2 * NFSX_UNSIGNED) + NFSM_RNDUP(len);
for (j = 1; j < nsrv; j++) {
/*
* Yuck, put them in an slist and process them later.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
len = fxdr_unsigned(int, *tl);
if (len <= 0 || len > 1024) {
error = NFSERR_BADXDR;
goto nfsmout;
}
lsp = (struct list *)malloc(sizeof (struct list)
+ len, M_TEMP, M_WAITOK);
error = nfsrv_mtostr(nd, lsp->host, len);
if (error)
goto nfsmout;
xdrsum += NFSX_UNSIGNED + NFSM_RNDUP(len);
lsp->len = len;
SLIST_INSERT_HEAD(&head, lsp, next);
}
/*
* Finally, we can get the path.
*/
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
len = fxdr_unsigned(int, *tl);
if (len <= 0 || len > 1024) {
error = NFSERR_BADXDR;
goto nfsmout;
}
nfsrv_refstrbigenough(siz + len + 1, &cp2, &cp3, &slen);
error = nfsrv_mtostr(nd, cp3, len);
if (error)
goto nfsmout;
xdrsum += NFSX_UNSIGNED + NFSM_RNDUP(len);
str = cp3;
stringlen = len;
cp3 += len;
siz += len;
SLIST_FOREACH_SAFE(lsp, &head, next, nlsp) {
nfsrv_refstrbigenough(siz + lsp->len + stringlen + 3,
&cp2, &cp3, &slen);
*cp3++ = ',';
NFSBCOPY(lsp->host, cp3, lsp->len);
cp3 += lsp->len;
*cp3++ = ':';
NFSBCOPY(str, cp3, stringlen);
cp3 += stringlen;
*cp3 = '\0';
siz += (lsp->len + stringlen + 2);
free((caddr_t)lsp, M_TEMP);
}
}
*fsrootp = cp;
*srvp = cp2;
*sump = xdrsum;
NFSEXITCODE2(0, nd);
return (0);
nfsmout:
if (cp != NULL)
free(cp, M_NFSSTRING);
if (cp2 != NULL)
free(cp2, M_NFSSTRING);
NFSEXITCODE2(error, nd);
return (error);
}
/*
* Make the malloc'd space large enough. This is a pain, but the xdr
* doesn't set an upper bound on the side, so...
*/
static void
nfsrv_refstrbigenough(int siz, u_char **cpp, u_char **cpp2, int *slenp)
{
u_char *cp;
int i;
if (siz <= *slenp)
return;
cp = malloc(siz + 1024, M_NFSSTRING, M_WAITOK);
NFSBCOPY(*cpp, cp, *slenp);
free(*cpp, M_NFSSTRING);
i = *cpp2 - *cpp;
*cpp = cp;
*cpp2 = cp + i;
*slenp = siz + 1024;
}
/*
* Initialize the reply header data structures.
*/
APPLESTATIC void
nfsrvd_rephead(struct nfsrv_descript *nd)
{
mbuf_t mreq;
/*
* If this is a big reply, use a cluster.
*/
if ((nd->nd_flag & ND_GSSINITREPLY) == 0 &&
nfs_bigreply[nd->nd_procnum]) {
NFSMCLGET(mreq, M_WAITOK);
nd->nd_mreq = mreq;
nd->nd_mb = mreq;
} else {
NFSMGET(mreq);
nd->nd_mreq = mreq;
nd->nd_mb = mreq;
}
nd->nd_bpos = NFSMTOD(mreq, caddr_t);
mbuf_setlen(mreq, 0);
if ((nd->nd_flag & ND_GSSINITREPLY) == 0)
NFSM_BUILD(nd->nd_errp, int *, NFSX_UNSIGNED);
}
/*
* Lock a socket against others.
* Currently used to serialize connect/disconnect attempts.
*/
int
newnfs_sndlock(int *flagp)
{
struct timespec ts;
NFSLOCKSOCK();
while (*flagp & NFSR_SNDLOCK) {
*flagp |= NFSR_WANTSND;
ts.tv_sec = 0;
ts.tv_nsec = 0;
(void) nfsmsleep((caddr_t)flagp, NFSSOCKMUTEXPTR,
PZERO - 1, "nfsndlck", &ts);
}
*flagp |= NFSR_SNDLOCK;
NFSUNLOCKSOCK();
return (0);
}
/*
* Unlock the stream socket for others.
*/
void
newnfs_sndunlock(int *flagp)
{
NFSLOCKSOCK();
if ((*flagp & NFSR_SNDLOCK) == 0)
panic("nfs sndunlock");
*flagp &= ~NFSR_SNDLOCK;
if (*flagp & NFSR_WANTSND) {
*flagp &= ~NFSR_WANTSND;
wakeup((caddr_t)flagp);
}
NFSUNLOCKSOCK();
}
APPLESTATIC int
nfsv4_getipaddr(struct nfsrv_descript *nd, struct sockaddr_storage *sa,
int *isudp)
{
struct sockaddr_in *sad;
struct sockaddr_in6 *sad6;
struct in_addr saddr;
uint32_t portnum, *tl;
int af = 0, i, j, k;
char addr[64], protocol[5], *cp;
int cantparse = 0, error = 0;
uint16_t portv;
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
i = fxdr_unsigned(int, *tl);
if (i >= 3 && i <= 4) {
error = nfsrv_mtostr(nd, protocol, i);
if (error)
goto nfsmout;
if (strcmp(protocol, "tcp") == 0) {
af = AF_INET;
*isudp = 0;
} else if (strcmp(protocol, "udp") == 0) {
af = AF_INET;
*isudp = 1;
} else if (strcmp(protocol, "tcp6") == 0) {
af = AF_INET6;
*isudp = 0;
} else if (strcmp(protocol, "udp6") == 0) {
af = AF_INET6;
*isudp = 1;
} else
cantparse = 1;
} else {
cantparse = 1;
if (i > 0) {
error = nfsm_advance(nd, NFSM_RNDUP(i), -1);
if (error)
goto nfsmout;
}
}
NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
i = fxdr_unsigned(int, *tl);
if (i < 0) {
error = NFSERR_BADXDR;
goto nfsmout;
} else if (cantparse == 0 && i >= 11 && i < 64) {
/*
* The shortest address is 11chars and the longest is < 64.
*/
error = nfsrv_mtostr(nd, addr, i);
if (error)
goto nfsmout;
/* Find the port# at the end and extract that. */
i = strlen(addr);
k = 0;
cp = &addr[i - 1];
/* Count back two '.'s from end to get port# field. */
for (j = 0; j < i; j++) {
if (*cp == '.') {
k++;
if (k == 2)
break;
}
cp--;
}
if (k == 2) {
/*
* The NFSv4 port# is appended as .N.N, where N is
* a decimal # in the range 0-255, just like an inet4
* address. Cheat and use inet_aton(), which will
* return a Class A address and then shift the high
* order 8bits over to convert it to the port#.
*/
*cp++ = '\0';
if (inet_aton(cp, &saddr) == 1) {
portnum = ntohl(saddr.s_addr);
portv = (uint16_t)((portnum >> 16) |
(portnum & 0xff));
} else
cantparse = 1;
} else
cantparse = 1;
if (cantparse == 0) {
if (af == AF_INET) {
sad = (struct sockaddr_in *)sa;
if (inet_pton(af, addr, &sad->sin_addr) == 1) {
sad->sin_len = sizeof(*sad);
sad->sin_family = AF_INET;
sad->sin_port = htons(portv);
return (0);
}
} else {
sad6 = (struct sockaddr_in6 *)sa;
if (inet_pton(af, addr, &sad6->sin6_addr)
== 1) {
sad6->sin6_len = sizeof(*sad6);
sad6->sin6_family = AF_INET6;
sad6->sin6_port = htons(portv);
return (0);
}
}
}
} else {
if (i > 0) {
error = nfsm_advance(nd, NFSM_RNDUP(i), -1);
if (error)
goto nfsmout;
}
}
error = EPERM;
nfsmout:
return (error);
}
/*
* Handle an NFSv4.1 Sequence request for the session.
* If reply != NULL, use it to return the cached reply, as required.
* The client gets a cached reply via this call for callbacks, however the
* server gets a cached reply via the nfsv4_seqsess_cachereply() call.
*/
int
nfsv4_seqsession(uint32_t seqid, uint32_t slotid, uint32_t highslot,
struct nfsslot *slots, struct mbuf **reply, uint16_t maxslot)
{
int error;
error = 0;
if (reply != NULL)
*reply = NULL;
if (slotid > maxslot)
return (NFSERR_BADSLOT);
if (seqid == slots[slotid].nfssl_seq) {
/* A retry. */
if (slots[slotid].nfssl_inprog != 0)
error = NFSERR_DELAY;
else if (slots[slotid].nfssl_reply != NULL) {
if (reply != NULL) {
*reply = slots[slotid].nfssl_reply;
slots[slotid].nfssl_reply = NULL;
}
slots[slotid].nfssl_inprog = 1;
error = NFSERR_REPLYFROMCACHE;
} else
/* No reply cached, so just do it. */
slots[slotid].nfssl_inprog = 1;
} else if ((slots[slotid].nfssl_seq + 1) == seqid) {
if (slots[slotid].nfssl_reply != NULL)
m_freem(slots[slotid].nfssl_reply);
slots[slotid].nfssl_reply = NULL;
slots[slotid].nfssl_inprog = 1;
slots[slotid].nfssl_seq++;
} else
error = NFSERR_SEQMISORDERED;
return (error);
}
/*
* Cache this reply for the slot.
* Use the "rep" argument to return the cached reply if repstat is set to
* NFSERR_REPLYFROMCACHE. The client never sets repstat to this value.
*/
void
nfsv4_seqsess_cacherep(uint32_t slotid, struct nfsslot *slots, int repstat,
struct mbuf **rep)
{
if (repstat == NFSERR_REPLYFROMCACHE) {
*rep = slots[slotid].nfssl_reply;
slots[slotid].nfssl_reply = NULL;
} else {
if (slots[slotid].nfssl_reply != NULL)
m_freem(slots[slotid].nfssl_reply);
slots[slotid].nfssl_reply = *rep;
}
slots[slotid].nfssl_inprog = 0;
}
/*
* Generate the xdr for an NFSv4.1 Sequence Operation.
*/
APPLESTATIC void
nfsv4_setsequence(struct nfsmount *nmp, struct nfsrv_descript *nd,
struct nfsclsession *sep, int dont_replycache)
{
uint32_t *tl, slotseq = 0;
int error, maxslot, slotpos;
uint8_t sessionid[NFSX_V4SESSIONID];
error = nfsv4_sequencelookup(nmp, sep, &slotpos, &maxslot, &slotseq,
sessionid);
/* Build the Sequence arguments. */
NFSM_BUILD(tl, uint32_t *, NFSX_V4SESSIONID + 4 * NFSX_UNSIGNED);
Fix NFSv4.1 client recovery from NFS4ERR_BAD_SESSION errors. For most NFSv4.1 servers, a NFS4ERR_BAD_SESSION error is a rare failure that indicates that the server has lost session/open/lock state. However, recent testing by cperciva@ against the AmazonEFS server found several problems with client recovery from this due to it generating this failure frequently. Briefly, the problems fixed are: - If all session slots were in use at the time of the failure, some processes would continue to loop waiting for a slot on the old session forever. - If an RPC that doesn't use open/lock state failed with NFS4ERR_BAD_SESSION, it would fail the RPC/syscall instead of initiating recovery and then looping to retry the RPC. - If a successful reply to an RPC for an old session wasn't processed until after a new session was created for a NFS4ERR_BAD_SESSION error, it would erroneously update the new session and corrupt it. - The use of the first element of the session list in the nfs mount structure (which is always the current metadata session) was slightly racey. With changes for the above problems it became more racey, so all uses of this head pointer was wrapped with a NFSLOCKMNT()/NFSUNLOCKMNT(). - Although the kernel malloc() usually allocates more bytes than requested and, as such, this wouldn't have caused problems, the allocation of a session structure was 1 byte smaller than it should have been. (Null termination byte for the string not included in byte count.) There are probably still problems with a pNFS data server that fails with NFS4ERR_BAD_SESSION, but I have no server that does this to test against (the AmazonEFS server doesn't do pNFS), so I can't fix these yet. Although this patch is fairly large, it should only affect the handling of NFS4ERR_BAD_SESSION error replies from an NFSv4.1 server. Thanks go to cperciva@ for the extension testing he did to help isolate/fix these problems. Reported by: cperciva Tested by: cperciva MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D8745
2016-12-23 23:14:53 +00:00
nd->nd_sequence = tl;
bcopy(sessionid, tl, NFSX_V4SESSIONID);
tl += NFSX_V4SESSIONID / NFSX_UNSIGNED;
nd->nd_slotseq = tl;
Fix NFSv4.1 client recovery from NFS4ERR_BAD_SESSION errors. For most NFSv4.1 servers, a NFS4ERR_BAD_SESSION error is a rare failure that indicates that the server has lost session/open/lock state. However, recent testing by cperciva@ against the AmazonEFS server found several problems with client recovery from this due to it generating this failure frequently. Briefly, the problems fixed are: - If all session slots were in use at the time of the failure, some processes would continue to loop waiting for a slot on the old session forever. - If an RPC that doesn't use open/lock state failed with NFS4ERR_BAD_SESSION, it would fail the RPC/syscall instead of initiating recovery and then looping to retry the RPC. - If a successful reply to an RPC for an old session wasn't processed until after a new session was created for a NFS4ERR_BAD_SESSION error, it would erroneously update the new session and corrupt it. - The use of the first element of the session list in the nfs mount structure (which is always the current metadata session) was slightly racey. With changes for the above problems it became more racey, so all uses of this head pointer was wrapped with a NFSLOCKMNT()/NFSUNLOCKMNT(). - Although the kernel malloc() usually allocates more bytes than requested and, as such, this wouldn't have caused problems, the allocation of a session structure was 1 byte smaller than it should have been. (Null termination byte for the string not included in byte count.) There are probably still problems with a pNFS data server that fails with NFS4ERR_BAD_SESSION, but I have no server that does this to test against (the AmazonEFS server doesn't do pNFS), so I can't fix these yet. Although this patch is fairly large, it should only affect the handling of NFS4ERR_BAD_SESSION error replies from an NFSv4.1 server. Thanks go to cperciva@ for the extension testing he did to help isolate/fix these problems. Reported by: cperciva Tested by: cperciva MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D8745
2016-12-23 23:14:53 +00:00
if (error == 0) {
*tl++ = txdr_unsigned(slotseq);
*tl++ = txdr_unsigned(slotpos);
*tl++ = txdr_unsigned(maxslot);
if (dont_replycache == 0)
*tl = newnfs_true;
else
*tl = newnfs_false;
} else {
/*
* There are two errors and the rest of the session can
* just be zeros.
* NFSERR_BADSESSION: This bad session should just generate
* the same error again when the RPC is retried.
* ESTALE: A forced dismount is in progress and will cause the
* RPC to fail later.
*/
*tl++ = 0;
*tl++ = 0;
*tl++ = 0;
*tl = 0;
}
nd->nd_flag |= ND_HASSEQUENCE;
}
int
nfsv4_sequencelookup(struct nfsmount *nmp, struct nfsclsession *sep,
int *slotposp, int *maxslotp, uint32_t *slotseqp, uint8_t *sessionid)
{
int i, maxslot, slotpos;
uint64_t bitval;
/* Find an unused slot. */
slotpos = -1;
maxslot = -1;
mtx_lock(&sep->nfsess_mtx);
do {
Fix NFSv4.1 client recovery from NFS4ERR_BAD_SESSION errors. For most NFSv4.1 servers, a NFS4ERR_BAD_SESSION error is a rare failure that indicates that the server has lost session/open/lock state. However, recent testing by cperciva@ against the AmazonEFS server found several problems with client recovery from this due to it generating this failure frequently. Briefly, the problems fixed are: - If all session slots were in use at the time of the failure, some processes would continue to loop waiting for a slot on the old session forever. - If an RPC that doesn't use open/lock state failed with NFS4ERR_BAD_SESSION, it would fail the RPC/syscall instead of initiating recovery and then looping to retry the RPC. - If a successful reply to an RPC for an old session wasn't processed until after a new session was created for a NFS4ERR_BAD_SESSION error, it would erroneously update the new session and corrupt it. - The use of the first element of the session list in the nfs mount structure (which is always the current metadata session) was slightly racey. With changes for the above problems it became more racey, so all uses of this head pointer was wrapped with a NFSLOCKMNT()/NFSUNLOCKMNT(). - Although the kernel malloc() usually allocates more bytes than requested and, as such, this wouldn't have caused problems, the allocation of a session structure was 1 byte smaller than it should have been. (Null termination byte for the string not included in byte count.) There are probably still problems with a pNFS data server that fails with NFS4ERR_BAD_SESSION, but I have no server that does this to test against (the AmazonEFS server doesn't do pNFS), so I can't fix these yet. Although this patch is fairly large, it should only affect the handling of NFS4ERR_BAD_SESSION error replies from an NFSv4.1 server. Thanks go to cperciva@ for the extension testing he did to help isolate/fix these problems. Reported by: cperciva Tested by: cperciva MFC after: 3 months Differential Revision: https://reviews.freebsd.org/D8745
2016-12-23 23:14:53 +00:00
if (nmp != NULL && sep->nfsess_defunct != 0) {
/* Just return the bad session. */
bcopy(sep->nfsess_sessionid, sessionid,
NFSX_V4SESSIONID);
mtx_unlock(&sep->nfsess_mtx);
return (NFSERR_BADSESSION);
}
bitval = 1;
for (i = 0; i < sep->nfsess_foreslots; i++) {
if ((bitval & sep->nfsess_slots) == 0) {
slotpos = i;
sep->nfsess_slots |= bitval;
sep->nfsess_slotseq[i]++;
*slotseqp = sep->nfsess_slotseq[i];
break;
}
bitval <<= 1;
}
if (slotpos == -1) {
/*
* If a forced dismount is in progress, just return.
* This RPC attempt will fail when it calls
* newnfs_request().
*/
if (nmp != NULL &&
(nmp->nm_mountp->mnt_kern_flag & MNTK_UNMOUNTF)
!= 0) {
mtx_unlock(&sep->nfsess_mtx);
return (ESTALE);
}
/* Wake up once/sec, to check for a forced dismount. */
(void)mtx_sleep(&sep->nfsess_slots, &sep->nfsess_mtx,
PZERO, "nfsclseq", hz);
}
} while (slotpos == -1);
/* Now, find the highest slot in use. (nfsc_slots is 64bits) */
bitval = 1;
for (i = 0; i < 64; i++) {
if ((bitval & sep->nfsess_slots) != 0)
maxslot = i;
bitval <<= 1;
}
bcopy(sep->nfsess_sessionid, sessionid, NFSX_V4SESSIONID);
mtx_unlock(&sep->nfsess_mtx);
*slotposp = slotpos;
*maxslotp = maxslot;
return (0);
}
/*
* Free a session slot.
*/
APPLESTATIC void
nfsv4_freeslot(struct nfsclsession *sep, int slot)
{
uint64_t bitval;
bitval = 1;
if (slot > 0)
bitval <<= slot;
mtx_lock(&sep->nfsess_mtx);
if ((bitval & sep->nfsess_slots) == 0)
printf("freeing free slot!!\n");
sep->nfsess_slots &= ~bitval;
wakeup(&sep->nfsess_slots);
mtx_unlock(&sep->nfsess_mtx);
}