1 /*-
2 * SPDX-License-Identifier: BSD-2-Clause-FreeBSD
3 *
4 * Copyright (c) 2009 Rick Macklem, University of Guelph
5 * All rights reserved.
6 *
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
9 * are met:
10 * 1. Redistributions of source code must retain the above copyright
11 * notice, this list of conditions and the following disclaimer.
12 * 2. Redistributions in binary form must reproduce the above copyright
13 * notice, this list of conditions and the following disclaimer in the
14 * documentation and/or other materials provided with the distribution.
15 *
16 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
17 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
18 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
19 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
20 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
21 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
22 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
23 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
24 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
25 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
26 * SUCH DAMAGE.
27 *
28 */
29
30 #include <sys/cdefs.h>
31 __FBSDID("$FreeBSD$");
32
33 #include "opt_inet.h"
34 #include "opt_inet6.h"
35 #include <sys/extattr.h>
36 #include <fs/nfs/nfsport.h>
37
38 struct nfsrv_stablefirst nfsrv_stablefirst;
39 int nfsrv_issuedelegs = 0;
40 int nfsrv_dolocallocks = 0;
41 struct nfsv4lock nfsv4rootfs_lock;
42 time_t nfsdev_time = 0;
43 int nfsrv_layouthashsize;
44 volatile int nfsrv_layoutcnt = 0;
45 extern uint32_t nfs_srvmaxio;
46
47 extern int newnfs_numnfsd;
48 extern struct nfsstatsv1 nfsstatsv1;
49 extern int nfsrv_lease;
50 extern struct timeval nfsboottime;
51 extern u_int32_t newnfs_true, newnfs_false;
52 extern struct mtx nfsrv_dslock_mtx;
53 extern struct mtx nfsrv_recalllock_mtx;
54 extern struct mtx nfsrv_dontlistlock_mtx;
55 extern int nfsd_debuglevel;
56 extern u_int nfsrv_dsdirsize;
57 extern struct nfsdevicehead nfsrv_devidhead;
58 extern int nfsrv_doflexfile;
59 extern int nfsrv_maxpnfsmirror;
60 NFSV4ROOTLOCKMUTEX;
61 NFSSTATESPINLOCK;
62 extern struct nfsdontlisthead nfsrv_dontlisthead;
63 extern volatile int nfsrv_devidcnt;
64 extern struct nfslayouthead nfsrv_recalllisthead;
65 extern char *nfsrv_zeropnfsdat;
66
67 SYSCTL_DECL(_vfs_nfsd);
68 int nfsrv_statehashsize = NFSSTATEHASHSIZE;
69 SYSCTL_INT(_vfs_nfsd, OID_AUTO, statehashsize, CTLFLAG_RDTUN,
70 &nfsrv_statehashsize, 0,
71 "Size of state hash table set via loader.conf");
72
73 int nfsrv_clienthashsize = NFSCLIENTHASHSIZE;
74 SYSCTL_INT(_vfs_nfsd, OID_AUTO, clienthashsize, CTLFLAG_RDTUN,
75 &nfsrv_clienthashsize, 0,
76 "Size of client hash table set via loader.conf");
77
78 int nfsrv_lockhashsize = NFSLOCKHASHSIZE;
79 SYSCTL_INT(_vfs_nfsd, OID_AUTO, fhhashsize, CTLFLAG_RDTUN,
80 &nfsrv_lockhashsize, 0,
81 "Size of file handle hash table set via loader.conf");
82
83 int nfsrv_sessionhashsize = NFSSESSIONHASHSIZE;
84 SYSCTL_INT(_vfs_nfsd, OID_AUTO, sessionhashsize, CTLFLAG_RDTUN,
85 &nfsrv_sessionhashsize, 0,
86 "Size of session hash table set via loader.conf");
87
88 int nfsrv_layouthighwater = NFSLAYOUTHIGHWATER;
89 SYSCTL_INT(_vfs_nfsd, OID_AUTO, layouthighwater, CTLFLAG_RDTUN,
90 &nfsrv_layouthighwater, 0,
91 "High water mark for number of layouts set via loader.conf");
92
93 static int nfsrv_v4statelimit = NFSRV_V4STATELIMIT;
94 SYSCTL_INT(_vfs_nfsd, OID_AUTO, v4statelimit, CTLFLAG_RWTUN,
95 &nfsrv_v4statelimit, 0,
96 "High water limit for NFSv4 opens+locks+delegations");
97
98 static int nfsrv_writedelegifpos = 0;
99 SYSCTL_INT(_vfs_nfsd, OID_AUTO, writedelegifpos, CTLFLAG_RW,
100 &nfsrv_writedelegifpos, 0,
101 "Issue a write delegation for read opens if possible");
102
103 static int nfsrv_allowreadforwriteopen = 1;
104 SYSCTL_INT(_vfs_nfsd, OID_AUTO, allowreadforwriteopen, CTLFLAG_RW,
105 &nfsrv_allowreadforwriteopen, 0,
106 "Allow Reads to be done with Write Access StateIDs");
107
108 int nfsrv_pnfsatime = 0;
109 SYSCTL_INT(_vfs_nfsd, OID_AUTO, pnfsstrictatime, CTLFLAG_RW,
110 &nfsrv_pnfsatime, 0,
111 "For pNFS service, do Getattr ops to keep atime up-to-date");
112
113 int nfsrv_flexlinuxhack = 0;
114 SYSCTL_INT(_vfs_nfsd, OID_AUTO, flexlinuxhack, CTLFLAG_RW,
115 &nfsrv_flexlinuxhack, 0,
116 "For Linux clients, hack around Flex File Layout bug");
117
118 /*
119 * Hash lists for nfs V4.
120 */
121 struct nfsclienthashhead *nfsclienthash;
122 struct nfslockhashhead *nfslockhash;
123 struct nfssessionhash *nfssessionhash;
124 struct nfslayouthash *nfslayouthash;
125 volatile int nfsrv_dontlistlen = 0;
126
127 static u_int32_t nfsrv_openpluslock = 0, nfsrv_delegatecnt = 0;
128 static time_t nfsrvboottime;
129 static int nfsrv_returnoldstateid = 0, nfsrv_clients = 0;
130 static int nfsrv_clienthighwater = NFSRV_CLIENTHIGHWATER;
131 static int nfsrv_nogsscallback = 0;
132 static volatile int nfsrv_writedelegcnt = 0;
133 static int nfsrv_faildscnt;
134
135 /* local functions */
136 static void nfsrv_dumpaclient(struct nfsclient *clp,
137 struct nfsd_dumpclients *dumpp);
138 static void nfsrv_freeopenowner(struct nfsstate *stp, int cansleep,
139 NFSPROC_T *p);
140 static int nfsrv_freeopen(struct nfsstate *stp, vnode_t vp, int cansleep,
141 NFSPROC_T *p);
142 static void nfsrv_freelockowner(struct nfsstate *stp, vnode_t vp, int cansleep,
143 NFSPROC_T *p);
144 static void nfsrv_freeallnfslocks(struct nfsstate *stp, vnode_t vp,
145 int cansleep, NFSPROC_T *p);
146 static void nfsrv_freenfslock(struct nfslock *lop);
147 static void nfsrv_freenfslockfile(struct nfslockfile *lfp);
148 static void nfsrv_freedeleg(struct nfsstate *);
149 static int nfsrv_getstate(struct nfsclient *clp, nfsv4stateid_t *stateidp,
150 u_int32_t flags, struct nfsstate **stpp);
151 static void nfsrv_getowner(struct nfsstatehead *hp, struct nfsstate *new_stp,
152 struct nfsstate **stpp);
153 static int nfsrv_getlockfh(vnode_t vp, u_short flags,
154 struct nfslockfile *new_lfp, fhandle_t *nfhp, NFSPROC_T *p);
155 static int nfsrv_getlockfile(u_short flags, struct nfslockfile **new_lfpp,
156 struct nfslockfile **lfpp, fhandle_t *nfhp, int lockit);
157 static void nfsrv_insertlock(struct nfslock *new_lop,
158 struct nfslock *insert_lop, struct nfsstate *stp, struct nfslockfile *lfp);
159 static void nfsrv_updatelock(struct nfsstate *stp, struct nfslock **new_lopp,
160 struct nfslock **other_lopp, struct nfslockfile *lfp);
161 static int nfsrv_getipnumber(u_char *cp);
162 static int nfsrv_checkrestart(nfsquad_t clientid, u_int32_t flags,
163 nfsv4stateid_t *stateidp, int specialid);
164 static int nfsrv_checkgrace(struct nfsrv_descript *nd, struct nfsclient *clp,
165 u_int32_t flags);
166 static int nfsrv_docallback(struct nfsclient *clp, int procnum,
167 nfsv4stateid_t *stateidp, int trunc, fhandle_t *fhp,
168 struct nfsvattr *nap, nfsattrbit_t *attrbitp, int laytype, NFSPROC_T *p);
169 static int nfsrv_cbcallargs(struct nfsrv_descript *nd, struct nfsclient *clp,
170 uint32_t callback, int op, const char *optag, struct nfsdsession **sepp,
171 int *slotposp);
172 static u_int32_t nfsrv_nextclientindex(void);
173 static u_int32_t nfsrv_nextstateindex(struct nfsclient *clp);
174 static void nfsrv_markstable(struct nfsclient *clp);
175 static void nfsrv_markreclaim(struct nfsclient *clp);
176 static int nfsrv_checkstable(struct nfsclient *clp);
177 static int nfsrv_clientconflict(struct nfsclient *clp, int *haslockp, struct
178 vnode *vp, NFSPROC_T *p);
179 static int nfsrv_delegconflict(struct nfsstate *stp, int *haslockp,
180 NFSPROC_T *p, vnode_t vp);
181 static int nfsrv_cleandeleg(vnode_t vp, struct nfslockfile *lfp,
182 struct nfsclient *clp, int *haslockp, NFSPROC_T *p);
183 static int nfsrv_notsamecredname(struct nfsrv_descript *nd,
184 struct nfsclient *clp);
185 static time_t nfsrv_leaseexpiry(void);
186 static void nfsrv_delaydelegtimeout(struct nfsstate *stp);
187 static int nfsrv_checkseqid(struct nfsrv_descript *nd, u_int32_t seqid,
188 struct nfsstate *stp, struct nfsrvcache *op);
189 static int nfsrv_nootherstate(struct nfsstate *stp);
190 static int nfsrv_locallock(vnode_t vp, struct nfslockfile *lfp, int flags,
191 uint64_t first, uint64_t end, struct nfslockconflict *cfp, NFSPROC_T *p);
192 static void nfsrv_localunlock(vnode_t vp, struct nfslockfile *lfp,
193 uint64_t init_first, uint64_t init_end, NFSPROC_T *p);
194 static int nfsrv_dolocal(vnode_t vp, struct nfslockfile *lfp, int flags,
195 int oldflags, uint64_t first, uint64_t end, struct nfslockconflict *cfp,
196 NFSPROC_T *p);
197 static void nfsrv_locallock_rollback(vnode_t vp, struct nfslockfile *lfp,
198 NFSPROC_T *p);
199 static void nfsrv_locallock_commit(struct nfslockfile *lfp, int flags,
200 uint64_t first, uint64_t end);
201 static void nfsrv_locklf(struct nfslockfile *lfp);
202 static void nfsrv_unlocklf(struct nfslockfile *lfp);
203 static struct nfsdsession *nfsrv_findsession(uint8_t *sessionid);
204 static int nfsrv_freesession(struct nfsdsession *sep, uint8_t *sessionid);
205 static int nfsv4_setcbsequence(struct nfsrv_descript *nd, struct nfsclient *clp,
206 int dont_replycache, struct nfsdsession **sepp, int *slotposp);
207 static int nfsv4_getcbsession(struct nfsclient *clp, struct nfsdsession **sepp);
208 static int nfsrv_addlayout(struct nfsrv_descript *nd, struct nfslayout **lypp,
209 nfsv4stateid_t *stateidp, char *layp, int *layoutlenp, NFSPROC_T *p);
210 static void nfsrv_freelayout(struct nfslayouthead *lhp, struct nfslayout *lyp);
211 static void nfsrv_freelayoutlist(nfsquad_t clientid);
212 static void nfsrv_freelayouts(nfsquad_t *clid, fsid_t *fs, int laytype,
213 int iomode);
214 static void nfsrv_freealllayouts(void);
215 static void nfsrv_freedevid(struct nfsdevice *ds);
216 static int nfsrv_setdsserver(char *dspathp, char *mdspathp, NFSPROC_T *p,
217 struct nfsdevice **dsp);
218 static void nfsrv_deleteds(struct nfsdevice *fndds);
219 static void nfsrv_allocdevid(struct nfsdevice *ds, char *addr, char *dnshost);
220 static void nfsrv_freealldevids(void);
221 static void nfsrv_flexlayouterr(struct nfsrv_descript *nd, uint32_t *layp,
222 int maxcnt, NFSPROC_T *p);
223 static int nfsrv_recalllayout(nfsquad_t clid, nfsv4stateid_t *stateidp,
224 fhandle_t *fhp, struct nfslayout *lyp, int changed, int laytype,
225 NFSPROC_T *p);
226 static int nfsrv_findlayout(nfsquad_t *clientidp, fhandle_t *fhp, int laytype,
227 NFSPROC_T *, struct nfslayout **lypp);
228 static int nfsrv_fndclid(nfsquad_t *clidvec, nfsquad_t clid, int clidcnt);
229 static struct nfslayout *nfsrv_filelayout(struct nfsrv_descript *nd, int iomode,
230 fhandle_t *fhp, fhandle_t *dsfhp, char *devid, fsid_t fs);
231 static struct nfslayout *nfsrv_flexlayout(struct nfsrv_descript *nd, int iomode,
232 int mirrorcnt, fhandle_t *fhp, fhandle_t *dsfhp, char *devid, fsid_t fs);
233 static int nfsrv_dontlayout(fhandle_t *fhp);
234 static int nfsrv_createdsfile(vnode_t vp, fhandle_t *fhp, struct pnfsdsfile *pf,
235 vnode_t dvp, struct nfsdevice *ds, struct ucred *cred, NFSPROC_T *p,
236 vnode_t *tvpp);
237 static struct nfsdevice *nfsrv_findmirroredds(struct nfsmount *nmp);
238
239 /*
240 * Scan the client list for a match and either return the current one,
241 * create a new entry or return an error.
242 * If returning a non-error, the clp structure must either be linked into
243 * the client list or free'd.
244 */
245 int
nfsrv_setclient(struct nfsrv_descript * nd,struct nfsclient ** new_clpp,nfsquad_t * clientidp,nfsquad_t * confirmp,NFSPROC_T * p)246 nfsrv_setclient(struct nfsrv_descript *nd, struct nfsclient **new_clpp,
247 nfsquad_t *clientidp, nfsquad_t *confirmp, NFSPROC_T *p)
248 {
249 struct nfsclient *clp = NULL, *new_clp = *new_clpp;
250 int i, error = 0, ret;
251 struct nfsstate *stp, *tstp;
252 #ifdef INET
253 struct sockaddr_in *sin, *rin;
254 #endif
255 #ifdef INET6
256 struct sockaddr_in6 *sin6, *rin6;
257 #endif
258 struct nfsdsession *sep, *nsep;
259 int zapit = 0, gotit, hasstate = 0, igotlock;
260 static u_int64_t confirm_index = 0;
261
262 /*
263 * Check for state resource limit exceeded.
264 */
265 if (nfsrv_openpluslock > nfsrv_v4statelimit) {
266 error = NFSERR_RESOURCE;
267 goto out;
268 }
269
270 if (nfsrv_issuedelegs == 0 ||
271 ((nd->nd_flag & ND_GSS) != 0 && nfsrv_nogsscallback != 0))
272 /*
273 * Don't do callbacks when delegations are disabled or
274 * for AUTH_GSS unless enabled via nfsrv_nogsscallback.
275 * If establishing a callback connection is attempted
276 * when a firewall is blocking the callback path, the
277 * server may wait too long for the connect attempt to
278 * succeed during the Open. Some clients, such as Linux,
279 * may timeout and give up on the Open before the server
280 * replies. Also, since AUTH_GSS callbacks are not
281 * yet interoperability tested, they might cause the
282 * server to crap out, if they get past the Init call to
283 * the client.
284 */
285 new_clp->lc_program = 0;
286
287 /* Lock out other nfsd threads */
288 NFSLOCKV4ROOTMUTEX();
289 nfsv4_relref(&nfsv4rootfs_lock);
290 do {
291 igotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
292 NFSV4ROOTLOCKMUTEXPTR, NULL);
293 } while (!igotlock);
294 NFSUNLOCKV4ROOTMUTEX();
295
296 /*
297 * Search for a match in the client list.
298 */
299 gotit = i = 0;
300 while (i < nfsrv_clienthashsize && !gotit) {
301 LIST_FOREACH(clp, &nfsclienthash[i], lc_hash) {
302 if (new_clp->lc_idlen == clp->lc_idlen &&
303 !NFSBCMP(new_clp->lc_id, clp->lc_id, clp->lc_idlen)) {
304 gotit = 1;
305 break;
306 }
307 }
308 if (gotit == 0)
309 i++;
310 }
311 if (!gotit ||
312 (clp->lc_flags & (LCL_NEEDSCONFIRM | LCL_ADMINREVOKED))) {
313 if ((nd->nd_flag & ND_NFSV41) != 0 && confirmp->lval[1] != 0) {
314 /*
315 * For NFSv4.1, if confirmp->lval[1] is non-zero, the
316 * client is trying to update a confirmed clientid.
317 */
318 NFSLOCKV4ROOTMUTEX();
319 nfsv4_unlock(&nfsv4rootfs_lock, 1);
320 NFSUNLOCKV4ROOTMUTEX();
321 confirmp->lval[1] = 0;
322 error = NFSERR_NOENT;
323 goto out;
324 }
325 /*
326 * Get rid of the old one.
327 */
328 if (i != nfsrv_clienthashsize) {
329 LIST_REMOVE(clp, lc_hash);
330 nfsrv_cleanclient(clp, p);
331 nfsrv_freedeleglist(&clp->lc_deleg);
332 nfsrv_freedeleglist(&clp->lc_olddeleg);
333 zapit = 1;
334 }
335 /*
336 * Add it after assigning a client id to it.
337 */
338 new_clp->lc_flags |= LCL_NEEDSCONFIRM;
339 if ((nd->nd_flag & ND_NFSV41) != 0)
340 new_clp->lc_confirm.lval[0] = confirmp->lval[0] =
341 ++confirm_index;
342 else
343 confirmp->qval = new_clp->lc_confirm.qval =
344 ++confirm_index;
345 clientidp->lval[0] = new_clp->lc_clientid.lval[0] =
346 (u_int32_t)nfsrvboottime;
347 clientidp->lval[1] = new_clp->lc_clientid.lval[1] =
348 nfsrv_nextclientindex();
349 new_clp->lc_stateindex = 0;
350 new_clp->lc_statemaxindex = 0;
351 new_clp->lc_cbref = 0;
352 new_clp->lc_expiry = nfsrv_leaseexpiry();
353 LIST_INIT(&new_clp->lc_open);
354 LIST_INIT(&new_clp->lc_deleg);
355 LIST_INIT(&new_clp->lc_olddeleg);
356 LIST_INIT(&new_clp->lc_session);
357 for (i = 0; i < nfsrv_statehashsize; i++)
358 LIST_INIT(&new_clp->lc_stateid[i]);
359 LIST_INSERT_HEAD(NFSCLIENTHASH(new_clp->lc_clientid), new_clp,
360 lc_hash);
361 nfsstatsv1.srvclients++;
362 nfsrv_openpluslock++;
363 nfsrv_clients++;
364 NFSLOCKV4ROOTMUTEX();
365 nfsv4_unlock(&nfsv4rootfs_lock, 1);
366 NFSUNLOCKV4ROOTMUTEX();
367 if (zapit)
368 nfsrv_zapclient(clp, p);
369 *new_clpp = NULL;
370 goto out;
371 }
372
373 /*
374 * Now, handle the cases where the id is already issued.
375 */
376 if (nfsrv_notsamecredname(nd, clp)) {
377 /*
378 * Check to see if there is expired state that should go away.
379 */
380 if (clp->lc_expiry < NFSD_MONOSEC &&
381 (!LIST_EMPTY(&clp->lc_open) || !LIST_EMPTY(&clp->lc_deleg))) {
382 nfsrv_cleanclient(clp, p);
383 nfsrv_freedeleglist(&clp->lc_deleg);
384 }
385
386 /*
387 * If there is outstanding state, then reply NFSERR_CLIDINUSE per
388 * RFC3530 Sec. 8.1.2 last para.
389 */
390 if (!LIST_EMPTY(&clp->lc_deleg)) {
391 hasstate = 1;
392 } else if (LIST_EMPTY(&clp->lc_open)) {
393 hasstate = 0;
394 } else {
395 hasstate = 0;
396 /* Look for an Open on the OpenOwner */
397 LIST_FOREACH(stp, &clp->lc_open, ls_list) {
398 if (!LIST_EMPTY(&stp->ls_open)) {
399 hasstate = 1;
400 break;
401 }
402 }
403 }
404 if (hasstate) {
405 /*
406 * If the uid doesn't match, return NFSERR_CLIDINUSE after
407 * filling out the correct ipaddr and portnum.
408 */
409 switch (clp->lc_req.nr_nam->sa_family) {
410 #ifdef INET
411 case AF_INET:
412 sin = (struct sockaddr_in *)new_clp->lc_req.nr_nam;
413 rin = (struct sockaddr_in *)clp->lc_req.nr_nam;
414 sin->sin_addr.s_addr = rin->sin_addr.s_addr;
415 sin->sin_port = rin->sin_port;
416 break;
417 #endif
418 #ifdef INET6
419 case AF_INET6:
420 sin6 = (struct sockaddr_in6 *)new_clp->lc_req.nr_nam;
421 rin6 = (struct sockaddr_in6 *)clp->lc_req.nr_nam;
422 sin6->sin6_addr = rin6->sin6_addr;
423 sin6->sin6_port = rin6->sin6_port;
424 break;
425 #endif
426 }
427 NFSLOCKV4ROOTMUTEX();
428 nfsv4_unlock(&nfsv4rootfs_lock, 1);
429 NFSUNLOCKV4ROOTMUTEX();
430 error = NFSERR_CLIDINUSE;
431 goto out;
432 }
433 }
434
435 if (NFSBCMP(new_clp->lc_verf, clp->lc_verf, NFSX_VERF)) {
436 /*
437 * If the verifier has changed, the client has rebooted
438 * and a new client id is issued. The old state info
439 * can be thrown away once the SETCLIENTID_CONFIRM occurs.
440 */
441 LIST_REMOVE(clp, lc_hash);
442
443 /* Get rid of all sessions on this clientid. */
444 LIST_FOREACH_SAFE(sep, &clp->lc_session, sess_list, nsep) {
445 ret = nfsrv_freesession(sep, NULL);
446 if (ret != 0)
447 printf("nfsrv_setclient: verifier changed free"
448 " session failed=%d\n", ret);
449 }
450
451 new_clp->lc_flags |= LCL_NEEDSCONFIRM;
452 if ((nd->nd_flag & ND_NFSV41) != 0)
453 new_clp->lc_confirm.lval[0] = confirmp->lval[0] =
454 ++confirm_index;
455 else
456 confirmp->qval = new_clp->lc_confirm.qval =
457 ++confirm_index;
458 clientidp->lval[0] = new_clp->lc_clientid.lval[0] =
459 nfsrvboottime;
460 clientidp->lval[1] = new_clp->lc_clientid.lval[1] =
461 nfsrv_nextclientindex();
462 new_clp->lc_stateindex = 0;
463 new_clp->lc_statemaxindex = 0;
464 new_clp->lc_cbref = 0;
465 new_clp->lc_expiry = nfsrv_leaseexpiry();
466
467 /*
468 * Save the state until confirmed.
469 */
470 LIST_NEWHEAD(&new_clp->lc_open, &clp->lc_open, ls_list);
471 LIST_FOREACH(tstp, &new_clp->lc_open, ls_list)
472 tstp->ls_clp = new_clp;
473 LIST_NEWHEAD(&new_clp->lc_deleg, &clp->lc_deleg, ls_list);
474 LIST_FOREACH(tstp, &new_clp->lc_deleg, ls_list)
475 tstp->ls_clp = new_clp;
476 LIST_NEWHEAD(&new_clp->lc_olddeleg, &clp->lc_olddeleg,
477 ls_list);
478 LIST_FOREACH(tstp, &new_clp->lc_olddeleg, ls_list)
479 tstp->ls_clp = new_clp;
480 for (i = 0; i < nfsrv_statehashsize; i++) {
481 LIST_NEWHEAD(&new_clp->lc_stateid[i],
482 &clp->lc_stateid[i], ls_hash);
483 LIST_FOREACH(tstp, &new_clp->lc_stateid[i], ls_hash)
484 tstp->ls_clp = new_clp;
485 }
486 LIST_INIT(&new_clp->lc_session);
487 LIST_INSERT_HEAD(NFSCLIENTHASH(new_clp->lc_clientid), new_clp,
488 lc_hash);
489 nfsstatsv1.srvclients++;
490 nfsrv_openpluslock++;
491 nfsrv_clients++;
492 NFSLOCKV4ROOTMUTEX();
493 nfsv4_unlock(&nfsv4rootfs_lock, 1);
494 NFSUNLOCKV4ROOTMUTEX();
495
496 /*
497 * Must wait until any outstanding callback on the old clp
498 * completes.
499 */
500 NFSLOCKSTATE();
501 while (clp->lc_cbref) {
502 clp->lc_flags |= LCL_WAKEUPWANTED;
503 (void)mtx_sleep(clp, NFSSTATEMUTEXPTR, PZERO - 1,
504 "nfsd clp", 10 * hz);
505 }
506 NFSUNLOCKSTATE();
507 nfsrv_zapclient(clp, p);
508 *new_clpp = NULL;
509 goto out;
510 }
511
512 /* For NFSv4.1, mark that we found a confirmed clientid. */
513 if ((nd->nd_flag & ND_NFSV41) != 0) {
514 clientidp->lval[0] = clp->lc_clientid.lval[0];
515 clientidp->lval[1] = clp->lc_clientid.lval[1];
516 confirmp->lval[0] = 0; /* Ignored by client */
517 confirmp->lval[1] = 1;
518 } else {
519 /*
520 * id and verifier match, so update the net address info
521 * and get rid of any existing callback authentication
522 * handle, so a new one will be acquired.
523 */
524 LIST_REMOVE(clp, lc_hash);
525 new_clp->lc_flags |= (LCL_NEEDSCONFIRM | LCL_DONTCLEAN);
526 new_clp->lc_expiry = nfsrv_leaseexpiry();
527 confirmp->qval = new_clp->lc_confirm.qval = ++confirm_index;
528 clientidp->lval[0] = new_clp->lc_clientid.lval[0] =
529 clp->lc_clientid.lval[0];
530 clientidp->lval[1] = new_clp->lc_clientid.lval[1] =
531 clp->lc_clientid.lval[1];
532 new_clp->lc_delegtime = clp->lc_delegtime;
533 new_clp->lc_stateindex = clp->lc_stateindex;
534 new_clp->lc_statemaxindex = clp->lc_statemaxindex;
535 new_clp->lc_cbref = 0;
536 LIST_NEWHEAD(&new_clp->lc_open, &clp->lc_open, ls_list);
537 LIST_FOREACH(tstp, &new_clp->lc_open, ls_list)
538 tstp->ls_clp = new_clp;
539 LIST_NEWHEAD(&new_clp->lc_deleg, &clp->lc_deleg, ls_list);
540 LIST_FOREACH(tstp, &new_clp->lc_deleg, ls_list)
541 tstp->ls_clp = new_clp;
542 LIST_NEWHEAD(&new_clp->lc_olddeleg, &clp->lc_olddeleg, ls_list);
543 LIST_FOREACH(tstp, &new_clp->lc_olddeleg, ls_list)
544 tstp->ls_clp = new_clp;
545 for (i = 0; i < nfsrv_statehashsize; i++) {
546 LIST_NEWHEAD(&new_clp->lc_stateid[i],
547 &clp->lc_stateid[i], ls_hash);
548 LIST_FOREACH(tstp, &new_clp->lc_stateid[i], ls_hash)
549 tstp->ls_clp = new_clp;
550 }
551 LIST_INIT(&new_clp->lc_session);
552 LIST_INSERT_HEAD(NFSCLIENTHASH(new_clp->lc_clientid), new_clp,
553 lc_hash);
554 nfsstatsv1.srvclients++;
555 nfsrv_openpluslock++;
556 nfsrv_clients++;
557 }
558 NFSLOCKV4ROOTMUTEX();
559 nfsv4_unlock(&nfsv4rootfs_lock, 1);
560 NFSUNLOCKV4ROOTMUTEX();
561
562 if ((nd->nd_flag & ND_NFSV41) == 0) {
563 /*
564 * Must wait until any outstanding callback on the old clp
565 * completes.
566 */
567 NFSLOCKSTATE();
568 while (clp->lc_cbref) {
569 clp->lc_flags |= LCL_WAKEUPWANTED;
570 (void)mtx_sleep(clp, NFSSTATEMUTEXPTR, PZERO - 1,
571 "nfsdclp", 10 * hz);
572 }
573 NFSUNLOCKSTATE();
574 nfsrv_zapclient(clp, p);
575 *new_clpp = NULL;
576 }
577
578 out:
579 NFSEXITCODE2(error, nd);
580 return (error);
581 }
582
583 /*
584 * Check to see if the client id exists and optionally confirm it.
585 */
586 int
nfsrv_getclient(nfsquad_t clientid,int opflags,struct nfsclient ** clpp,struct nfsdsession * nsep,nfsquad_t confirm,uint32_t cbprogram,struct nfsrv_descript * nd,NFSPROC_T * p)587 nfsrv_getclient(nfsquad_t clientid, int opflags, struct nfsclient **clpp,
588 struct nfsdsession *nsep, nfsquad_t confirm, uint32_t cbprogram,
589 struct nfsrv_descript *nd, NFSPROC_T *p)
590 {
591 struct nfsclient *clp;
592 struct nfsstate *stp;
593 int i;
594 struct nfsclienthashhead *hp;
595 int error = 0, igotlock, doneok;
596 struct nfssessionhash *shp;
597 struct nfsdsession *sep;
598 uint64_t sessid[2];
599 static uint64_t next_sess = 0;
600
601 if (clpp)
602 *clpp = NULL;
603 if ((nd == NULL || (nd->nd_flag & ND_NFSV41) == 0 ||
604 opflags != CLOPS_RENEW) && nfsrvboottime != clientid.lval[0]) {
605 error = NFSERR_STALECLIENTID;
606 goto out;
607 }
608
609 /*
610 * If called with opflags == CLOPS_RENEW, the State Lock is
611 * already held. Otherwise, we need to get either that or,
612 * for the case of Confirm, lock out the nfsd threads.
613 */
614 if (opflags & CLOPS_CONFIRM) {
615 NFSLOCKV4ROOTMUTEX();
616 nfsv4_relref(&nfsv4rootfs_lock);
617 do {
618 igotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
619 NFSV4ROOTLOCKMUTEXPTR, NULL);
620 } while (!igotlock);
621 /*
622 * Create a new sessionid here, since we need to do it where
623 * there is a mutex held to serialize update of next_sess.
624 */
625 if ((nd->nd_flag & ND_NFSV41) != 0) {
626 sessid[0] = ++next_sess;
627 sessid[1] = clientid.qval;
628 }
629 NFSUNLOCKV4ROOTMUTEX();
630 } else if (opflags != CLOPS_RENEW) {
631 NFSLOCKSTATE();
632 }
633
634 /* For NFSv4.1, the clp is acquired from the associated session. */
635 if (nd != NULL && (nd->nd_flag & ND_NFSV41) != 0 &&
636 opflags == CLOPS_RENEW) {
637 clp = NULL;
638 if ((nd->nd_flag & ND_HASSEQUENCE) != 0) {
639 shp = NFSSESSIONHASH(nd->nd_sessionid);
640 NFSLOCKSESSION(shp);
641 sep = nfsrv_findsession(nd->nd_sessionid);
642 if (sep != NULL)
643 clp = sep->sess_clp;
644 NFSUNLOCKSESSION(shp);
645 }
646 } else {
647 hp = NFSCLIENTHASH(clientid);
648 LIST_FOREACH(clp, hp, lc_hash) {
649 if (clp->lc_clientid.lval[1] == clientid.lval[1])
650 break;
651 }
652 }
653 if (clp == NULL) {
654 if (opflags & CLOPS_CONFIRM)
655 error = NFSERR_STALECLIENTID;
656 else
657 error = NFSERR_EXPIRED;
658 } else if (clp->lc_flags & LCL_ADMINREVOKED) {
659 /*
660 * If marked admin revoked, just return the error.
661 */
662 error = NFSERR_ADMINREVOKED;
663 }
664 if (error) {
665 if (opflags & CLOPS_CONFIRM) {
666 NFSLOCKV4ROOTMUTEX();
667 nfsv4_unlock(&nfsv4rootfs_lock, 1);
668 NFSUNLOCKV4ROOTMUTEX();
669 } else if (opflags != CLOPS_RENEW) {
670 NFSUNLOCKSTATE();
671 }
672 goto out;
673 }
674
675 /*
676 * Perform any operations specified by the opflags.
677 */
678 if (opflags & CLOPS_CONFIRM) {
679 if ((nd->nd_flag & ND_NFSV41) != 0 &&
680 clp->lc_confirm.lval[0] != confirm.lval[0])
681 error = NFSERR_SEQMISORDERED;
682 else if ((nd->nd_flag & ND_NFSV41) == 0 &&
683 clp->lc_confirm.qval != confirm.qval)
684 error = NFSERR_STALECLIENTID;
685 else if (nfsrv_notsamecredname(nd, clp))
686 error = NFSERR_CLIDINUSE;
687
688 if (!error) {
689 if ((clp->lc_flags & (LCL_NEEDSCONFIRM | LCL_DONTCLEAN)) ==
690 LCL_NEEDSCONFIRM) {
691 /*
692 * Hang onto the delegations (as old delegations)
693 * for an Open with CLAIM_DELEGATE_PREV unless in
694 * grace, but get rid of the rest of the state.
695 */
696 nfsrv_cleanclient(clp, p);
697 nfsrv_freedeleglist(&clp->lc_olddeleg);
698 if (nfsrv_checkgrace(nd, clp, 0)) {
699 /* In grace, so just delete delegations */
700 nfsrv_freedeleglist(&clp->lc_deleg);
701 } else {
702 LIST_FOREACH(stp, &clp->lc_deleg, ls_list)
703 stp->ls_flags |= NFSLCK_OLDDELEG;
704 clp->lc_delegtime = NFSD_MONOSEC +
705 nfsrv_lease + NFSRV_LEASEDELTA;
706 LIST_NEWHEAD(&clp->lc_olddeleg, &clp->lc_deleg,
707 ls_list);
708 }
709 if ((nd->nd_flag & ND_NFSV41) != 0)
710 clp->lc_program = cbprogram;
711 }
712 clp->lc_flags &= ~(LCL_NEEDSCONFIRM | LCL_DONTCLEAN);
713 if (clp->lc_program)
714 clp->lc_flags |= LCL_NEEDSCBNULL;
715 /* For NFSv4.1, link the session onto the client. */
716 if (nsep != NULL) {
717 /* Hold a reference on the xprt for a backchannel. */
718 if ((nsep->sess_crflags & NFSV4CRSESS_CONNBACKCHAN)
719 != 0) {
720 if (clp->lc_req.nr_client == NULL)
721 clp->lc_req.nr_client = (struct __rpc_client *)
722 clnt_bck_create(nd->nd_xprt->xp_socket,
723 cbprogram, NFSV4_CBVERS);
724 if (clp->lc_req.nr_client != NULL) {
725 SVC_ACQUIRE(nd->nd_xprt);
726 CLNT_ACQUIRE(clp->lc_req.nr_client);
727 nd->nd_xprt->xp_p2 = clp->lc_req.nr_client;
728 /* Disable idle timeout. */
729 nd->nd_xprt->xp_idletimeout = 0;
730 nsep->sess_cbsess.nfsess_xprt = nd->nd_xprt;
731 } else
732 nsep->sess_crflags &= ~NFSV4CRSESS_CONNBACKCHAN;
733 }
734 NFSBCOPY(sessid, nsep->sess_sessionid,
735 NFSX_V4SESSIONID);
736 NFSBCOPY(sessid, nsep->sess_cbsess.nfsess_sessionid,
737 NFSX_V4SESSIONID);
738 shp = NFSSESSIONHASH(nsep->sess_sessionid);
739 NFSLOCKSTATE();
740 NFSLOCKSESSION(shp);
741 LIST_INSERT_HEAD(&shp->list, nsep, sess_hash);
742 LIST_INSERT_HEAD(&clp->lc_session, nsep, sess_list);
743 nsep->sess_clp = clp;
744 NFSUNLOCKSESSION(shp);
745 NFSUNLOCKSTATE();
746 }
747 }
748 } else if (clp->lc_flags & LCL_NEEDSCONFIRM) {
749 error = NFSERR_EXPIRED;
750 }
751
752 /*
753 * If called by the Renew Op, we must check the principal.
754 */
755 if (!error && (opflags & CLOPS_RENEWOP)) {
756 if (nfsrv_notsamecredname(nd, clp)) {
757 doneok = 0;
758 for (i = 0; i < nfsrv_statehashsize && doneok == 0; i++) {
759 LIST_FOREACH(stp, &clp->lc_stateid[i], ls_hash) {
760 if ((stp->ls_flags & NFSLCK_OPEN) &&
761 stp->ls_uid == nd->nd_cred->cr_uid) {
762 doneok = 1;
763 break;
764 }
765 }
766 }
767 if (!doneok)
768 error = NFSERR_ACCES;
769 }
770 if (!error && (clp->lc_flags & LCL_CBDOWN))
771 error = NFSERR_CBPATHDOWN;
772 }
773 if ((!error || error == NFSERR_CBPATHDOWN) &&
774 (opflags & CLOPS_RENEW)) {
775 clp->lc_expiry = nfsrv_leaseexpiry();
776 }
777 if (opflags & CLOPS_CONFIRM) {
778 NFSLOCKV4ROOTMUTEX();
779 nfsv4_unlock(&nfsv4rootfs_lock, 1);
780 NFSUNLOCKV4ROOTMUTEX();
781 } else if (opflags != CLOPS_RENEW) {
782 NFSUNLOCKSTATE();
783 }
784 if (clpp)
785 *clpp = clp;
786
787 out:
788 NFSEXITCODE2(error, nd);
789 return (error);
790 }
791
792 /*
793 * Perform the NFSv4.1 destroy clientid.
794 */
795 int
nfsrv_destroyclient(nfsquad_t clientid,NFSPROC_T * p)796 nfsrv_destroyclient(nfsquad_t clientid, NFSPROC_T *p)
797 {
798 struct nfsclient *clp;
799 struct nfsclienthashhead *hp;
800 int error = 0, i, igotlock;
801
802 if (nfsrvboottime != clientid.lval[0]) {
803 error = NFSERR_STALECLIENTID;
804 goto out;
805 }
806
807 /* Lock out other nfsd threads */
808 NFSLOCKV4ROOTMUTEX();
809 nfsv4_relref(&nfsv4rootfs_lock);
810 do {
811 igotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
812 NFSV4ROOTLOCKMUTEXPTR, NULL);
813 } while (igotlock == 0);
814 NFSUNLOCKV4ROOTMUTEX();
815
816 hp = NFSCLIENTHASH(clientid);
817 LIST_FOREACH(clp, hp, lc_hash) {
818 if (clp->lc_clientid.lval[1] == clientid.lval[1])
819 break;
820 }
821 if (clp == NULL) {
822 NFSLOCKV4ROOTMUTEX();
823 nfsv4_unlock(&nfsv4rootfs_lock, 1);
824 NFSUNLOCKV4ROOTMUTEX();
825 /* Just return ok, since it is gone. */
826 goto out;
827 }
828
829 /*
830 * Free up all layouts on the clientid. Should the client return the
831 * layouts?
832 */
833 nfsrv_freelayoutlist(clientid);
834
835 /* Scan for state on the clientid. */
836 for (i = 0; i < nfsrv_statehashsize; i++)
837 if (!LIST_EMPTY(&clp->lc_stateid[i])) {
838 NFSLOCKV4ROOTMUTEX();
839 nfsv4_unlock(&nfsv4rootfs_lock, 1);
840 NFSUNLOCKV4ROOTMUTEX();
841 error = NFSERR_CLIENTIDBUSY;
842 goto out;
843 }
844 if (!LIST_EMPTY(&clp->lc_session) || !LIST_EMPTY(&clp->lc_deleg)) {
845 NFSLOCKV4ROOTMUTEX();
846 nfsv4_unlock(&nfsv4rootfs_lock, 1);
847 NFSUNLOCKV4ROOTMUTEX();
848 error = NFSERR_CLIENTIDBUSY;
849 goto out;
850 }
851
852 /* Destroy the clientid and return ok. */
853 nfsrv_cleanclient(clp, p);
854 nfsrv_freedeleglist(&clp->lc_deleg);
855 nfsrv_freedeleglist(&clp->lc_olddeleg);
856 LIST_REMOVE(clp, lc_hash);
857 NFSLOCKV4ROOTMUTEX();
858 nfsv4_unlock(&nfsv4rootfs_lock, 1);
859 NFSUNLOCKV4ROOTMUTEX();
860 nfsrv_zapclient(clp, p);
861 out:
862 NFSEXITCODE2(error, nd);
863 return (error);
864 }
865
866 /*
867 * Called from the new nfssvc syscall to admin revoke a clientid.
868 * Returns 0 for success, error otherwise.
869 */
870 int
nfsrv_adminrevoke(struct nfsd_clid * revokep,NFSPROC_T * p)871 nfsrv_adminrevoke(struct nfsd_clid *revokep, NFSPROC_T *p)
872 {
873 struct nfsclient *clp = NULL;
874 int i, error = 0;
875 int gotit, igotlock;
876
877 /*
878 * First, lock out the nfsd so that state won't change while the
879 * revocation record is being written to the stable storage restart
880 * file.
881 */
882 NFSLOCKV4ROOTMUTEX();
883 do {
884 igotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
885 NFSV4ROOTLOCKMUTEXPTR, NULL);
886 } while (!igotlock);
887 NFSUNLOCKV4ROOTMUTEX();
888
889 /*
890 * Search for a match in the client list.
891 */
892 gotit = i = 0;
893 while (i < nfsrv_clienthashsize && !gotit) {
894 LIST_FOREACH(clp, &nfsclienthash[i], lc_hash) {
895 if (revokep->nclid_idlen == clp->lc_idlen &&
896 !NFSBCMP(revokep->nclid_id, clp->lc_id, clp->lc_idlen)) {
897 gotit = 1;
898 break;
899 }
900 }
901 i++;
902 }
903 if (!gotit) {
904 NFSLOCKV4ROOTMUTEX();
905 nfsv4_unlock(&nfsv4rootfs_lock, 0);
906 NFSUNLOCKV4ROOTMUTEX();
907 error = EPERM;
908 goto out;
909 }
910
911 /*
912 * Now, write out the revocation record
913 */
914 nfsrv_writestable(clp->lc_id, clp->lc_idlen, NFSNST_REVOKE, p);
915 nfsrv_backupstable();
916
917 /*
918 * and clear out the state, marking the clientid revoked.
919 */
920 clp->lc_flags &= ~LCL_CALLBACKSON;
921 clp->lc_flags |= LCL_ADMINREVOKED;
922 nfsrv_cleanclient(clp, p);
923 nfsrv_freedeleglist(&clp->lc_deleg);
924 nfsrv_freedeleglist(&clp->lc_olddeleg);
925 NFSLOCKV4ROOTMUTEX();
926 nfsv4_unlock(&nfsv4rootfs_lock, 0);
927 NFSUNLOCKV4ROOTMUTEX();
928
929 out:
930 NFSEXITCODE(error);
931 return (error);
932 }
933
934 /*
935 * Dump out stats for all clients. Called from nfssvc(2), that is used
936 * nfsstatsv1.
937 */
938 void
nfsrv_dumpclients(struct nfsd_dumpclients * dumpp,int maxcnt)939 nfsrv_dumpclients(struct nfsd_dumpclients *dumpp, int maxcnt)
940 {
941 struct nfsclient *clp;
942 int i = 0, cnt = 0;
943
944 /*
945 * First, get a reference on the nfsv4rootfs_lock so that an
946 * exclusive lock cannot be acquired while dumping the clients.
947 */
948 NFSLOCKV4ROOTMUTEX();
949 nfsv4_getref(&nfsv4rootfs_lock, NULL, NFSV4ROOTLOCKMUTEXPTR, NULL);
950 NFSUNLOCKV4ROOTMUTEX();
951 NFSLOCKSTATE();
952 /*
953 * Rattle through the client lists until done.
954 */
955 while (i < nfsrv_clienthashsize && cnt < maxcnt) {
956 clp = LIST_FIRST(&nfsclienthash[i]);
957 while (clp != LIST_END(&nfsclienthash[i]) && cnt < maxcnt) {
958 nfsrv_dumpaclient(clp, &dumpp[cnt]);
959 cnt++;
960 clp = LIST_NEXT(clp, lc_hash);
961 }
962 i++;
963 }
964 if (cnt < maxcnt)
965 dumpp[cnt].ndcl_clid.nclid_idlen = 0;
966 NFSUNLOCKSTATE();
967 NFSLOCKV4ROOTMUTEX();
968 nfsv4_relref(&nfsv4rootfs_lock);
969 NFSUNLOCKV4ROOTMUTEX();
970 }
971
972 /*
973 * Dump stats for a client. Must be called with the NFSSTATELOCK and spl'd.
974 */
975 static void
nfsrv_dumpaclient(struct nfsclient * clp,struct nfsd_dumpclients * dumpp)976 nfsrv_dumpaclient(struct nfsclient *clp, struct nfsd_dumpclients *dumpp)
977 {
978 struct nfsstate *stp, *openstp, *lckownstp;
979 struct nfslock *lop;
980 sa_family_t af;
981 #ifdef INET
982 struct sockaddr_in *rin;
983 #endif
984 #ifdef INET6
985 struct sockaddr_in6 *rin6;
986 #endif
987
988 dumpp->ndcl_nopenowners = dumpp->ndcl_nlockowners = 0;
989 dumpp->ndcl_nopens = dumpp->ndcl_nlocks = 0;
990 dumpp->ndcl_ndelegs = dumpp->ndcl_nolddelegs = 0;
991 dumpp->ndcl_flags = clp->lc_flags;
992 dumpp->ndcl_clid.nclid_idlen = clp->lc_idlen;
993 NFSBCOPY(clp->lc_id, dumpp->ndcl_clid.nclid_id, clp->lc_idlen);
994 af = clp->lc_req.nr_nam->sa_family;
995 dumpp->ndcl_addrfam = af;
996 switch (af) {
997 #ifdef INET
998 case AF_INET:
999 rin = (struct sockaddr_in *)clp->lc_req.nr_nam;
1000 dumpp->ndcl_cbaddr.sin_addr = rin->sin_addr;
1001 break;
1002 #endif
1003 #ifdef INET6
1004 case AF_INET6:
1005 rin6 = (struct sockaddr_in6 *)clp->lc_req.nr_nam;
1006 dumpp->ndcl_cbaddr.sin6_addr = rin6->sin6_addr;
1007 break;
1008 #endif
1009 }
1010
1011 /*
1012 * Now, scan the state lists and total up the opens and locks.
1013 */
1014 LIST_FOREACH(stp, &clp->lc_open, ls_list) {
1015 dumpp->ndcl_nopenowners++;
1016 LIST_FOREACH(openstp, &stp->ls_open, ls_list) {
1017 dumpp->ndcl_nopens++;
1018 LIST_FOREACH(lckownstp, &openstp->ls_open, ls_list) {
1019 dumpp->ndcl_nlockowners++;
1020 LIST_FOREACH(lop, &lckownstp->ls_lock, lo_lckowner) {
1021 dumpp->ndcl_nlocks++;
1022 }
1023 }
1024 }
1025 }
1026
1027 /*
1028 * and the delegation lists.
1029 */
1030 LIST_FOREACH(stp, &clp->lc_deleg, ls_list) {
1031 dumpp->ndcl_ndelegs++;
1032 }
1033 LIST_FOREACH(stp, &clp->lc_olddeleg, ls_list) {
1034 dumpp->ndcl_nolddelegs++;
1035 }
1036 }
1037
1038 /*
1039 * Dump out lock stats for a file.
1040 */
1041 void
nfsrv_dumplocks(vnode_t vp,struct nfsd_dumplocks * ldumpp,int maxcnt,NFSPROC_T * p)1042 nfsrv_dumplocks(vnode_t vp, struct nfsd_dumplocks *ldumpp, int maxcnt,
1043 NFSPROC_T *p)
1044 {
1045 struct nfsstate *stp;
1046 struct nfslock *lop;
1047 int cnt = 0;
1048 struct nfslockfile *lfp;
1049 sa_family_t af;
1050 #ifdef INET
1051 struct sockaddr_in *rin;
1052 #endif
1053 #ifdef INET6
1054 struct sockaddr_in6 *rin6;
1055 #endif
1056 int ret;
1057 fhandle_t nfh;
1058
1059 ret = nfsrv_getlockfh(vp, 0, NULL, &nfh, p);
1060 /*
1061 * First, get a reference on the nfsv4rootfs_lock so that an
1062 * exclusive lock on it cannot be acquired while dumping the locks.
1063 */
1064 NFSLOCKV4ROOTMUTEX();
1065 nfsv4_getref(&nfsv4rootfs_lock, NULL, NFSV4ROOTLOCKMUTEXPTR, NULL);
1066 NFSUNLOCKV4ROOTMUTEX();
1067 NFSLOCKSTATE();
1068 if (!ret)
1069 ret = nfsrv_getlockfile(0, NULL, &lfp, &nfh, 0);
1070 if (ret) {
1071 ldumpp[0].ndlck_clid.nclid_idlen = 0;
1072 NFSUNLOCKSTATE();
1073 NFSLOCKV4ROOTMUTEX();
1074 nfsv4_relref(&nfsv4rootfs_lock);
1075 NFSUNLOCKV4ROOTMUTEX();
1076 return;
1077 }
1078
1079 /*
1080 * For each open share on file, dump it out.
1081 */
1082 stp = LIST_FIRST(&lfp->lf_open);
1083 while (stp != LIST_END(&lfp->lf_open) && cnt < maxcnt) {
1084 ldumpp[cnt].ndlck_flags = stp->ls_flags;
1085 ldumpp[cnt].ndlck_stateid.seqid = stp->ls_stateid.seqid;
1086 ldumpp[cnt].ndlck_stateid.other[0] = stp->ls_stateid.other[0];
1087 ldumpp[cnt].ndlck_stateid.other[1] = stp->ls_stateid.other[1];
1088 ldumpp[cnt].ndlck_stateid.other[2] = stp->ls_stateid.other[2];
1089 ldumpp[cnt].ndlck_owner.nclid_idlen =
1090 stp->ls_openowner->ls_ownerlen;
1091 NFSBCOPY(stp->ls_openowner->ls_owner,
1092 ldumpp[cnt].ndlck_owner.nclid_id,
1093 stp->ls_openowner->ls_ownerlen);
1094 ldumpp[cnt].ndlck_clid.nclid_idlen = stp->ls_clp->lc_idlen;
1095 NFSBCOPY(stp->ls_clp->lc_id, ldumpp[cnt].ndlck_clid.nclid_id,
1096 stp->ls_clp->lc_idlen);
1097 af = stp->ls_clp->lc_req.nr_nam->sa_family;
1098 ldumpp[cnt].ndlck_addrfam = af;
1099 switch (af) {
1100 #ifdef INET
1101 case AF_INET:
1102 rin = (struct sockaddr_in *)stp->ls_clp->lc_req.nr_nam;
1103 ldumpp[cnt].ndlck_cbaddr.sin_addr = rin->sin_addr;
1104 break;
1105 #endif
1106 #ifdef INET6
1107 case AF_INET6:
1108 rin6 = (struct sockaddr_in6 *)
1109 stp->ls_clp->lc_req.nr_nam;
1110 ldumpp[cnt].ndlck_cbaddr.sin6_addr = rin6->sin6_addr;
1111 break;
1112 #endif
1113 }
1114 stp = LIST_NEXT(stp, ls_file);
1115 cnt++;
1116 }
1117
1118 /*
1119 * and all locks.
1120 */
1121 lop = LIST_FIRST(&lfp->lf_lock);
1122 while (lop != LIST_END(&lfp->lf_lock) && cnt < maxcnt) {
1123 stp = lop->lo_stp;
1124 ldumpp[cnt].ndlck_flags = lop->lo_flags;
1125 ldumpp[cnt].ndlck_first = lop->lo_first;
1126 ldumpp[cnt].ndlck_end = lop->lo_end;
1127 ldumpp[cnt].ndlck_stateid.seqid = stp->ls_stateid.seqid;
1128 ldumpp[cnt].ndlck_stateid.other[0] = stp->ls_stateid.other[0];
1129 ldumpp[cnt].ndlck_stateid.other[1] = stp->ls_stateid.other[1];
1130 ldumpp[cnt].ndlck_stateid.other[2] = stp->ls_stateid.other[2];
1131 ldumpp[cnt].ndlck_owner.nclid_idlen = stp->ls_ownerlen;
1132 NFSBCOPY(stp->ls_owner, ldumpp[cnt].ndlck_owner.nclid_id,
1133 stp->ls_ownerlen);
1134 ldumpp[cnt].ndlck_clid.nclid_idlen = stp->ls_clp->lc_idlen;
1135 NFSBCOPY(stp->ls_clp->lc_id, ldumpp[cnt].ndlck_clid.nclid_id,
1136 stp->ls_clp->lc_idlen);
1137 af = stp->ls_clp->lc_req.nr_nam->sa_family;
1138 ldumpp[cnt].ndlck_addrfam = af;
1139 switch (af) {
1140 #ifdef INET
1141 case AF_INET:
1142 rin = (struct sockaddr_in *)stp->ls_clp->lc_req.nr_nam;
1143 ldumpp[cnt].ndlck_cbaddr.sin_addr = rin->sin_addr;
1144 break;
1145 #endif
1146 #ifdef INET6
1147 case AF_INET6:
1148 rin6 = (struct sockaddr_in6 *)
1149 stp->ls_clp->lc_req.nr_nam;
1150 ldumpp[cnt].ndlck_cbaddr.sin6_addr = rin6->sin6_addr;
1151 break;
1152 #endif
1153 }
1154 lop = LIST_NEXT(lop, lo_lckfile);
1155 cnt++;
1156 }
1157
1158 /*
1159 * and the delegations.
1160 */
1161 stp = LIST_FIRST(&lfp->lf_deleg);
1162 while (stp != LIST_END(&lfp->lf_deleg) && cnt < maxcnt) {
1163 ldumpp[cnt].ndlck_flags = stp->ls_flags;
1164 ldumpp[cnt].ndlck_stateid.seqid = stp->ls_stateid.seqid;
1165 ldumpp[cnt].ndlck_stateid.other[0] = stp->ls_stateid.other[0];
1166 ldumpp[cnt].ndlck_stateid.other[1] = stp->ls_stateid.other[1];
1167 ldumpp[cnt].ndlck_stateid.other[2] = stp->ls_stateid.other[2];
1168 ldumpp[cnt].ndlck_owner.nclid_idlen = 0;
1169 ldumpp[cnt].ndlck_clid.nclid_idlen = stp->ls_clp->lc_idlen;
1170 NFSBCOPY(stp->ls_clp->lc_id, ldumpp[cnt].ndlck_clid.nclid_id,
1171 stp->ls_clp->lc_idlen);
1172 af = stp->ls_clp->lc_req.nr_nam->sa_family;
1173 ldumpp[cnt].ndlck_addrfam = af;
1174 switch (af) {
1175 #ifdef INET
1176 case AF_INET:
1177 rin = (struct sockaddr_in *)stp->ls_clp->lc_req.nr_nam;
1178 ldumpp[cnt].ndlck_cbaddr.sin_addr = rin->sin_addr;
1179 break;
1180 #endif
1181 #ifdef INET6
1182 case AF_INET6:
1183 rin6 = (struct sockaddr_in6 *)
1184 stp->ls_clp->lc_req.nr_nam;
1185 ldumpp[cnt].ndlck_cbaddr.sin6_addr = rin6->sin6_addr;
1186 break;
1187 #endif
1188 }
1189 stp = LIST_NEXT(stp, ls_file);
1190 cnt++;
1191 }
1192
1193 /*
1194 * If list isn't full, mark end of list by setting the client name
1195 * to zero length.
1196 */
1197 if (cnt < maxcnt)
1198 ldumpp[cnt].ndlck_clid.nclid_idlen = 0;
1199 NFSUNLOCKSTATE();
1200 NFSLOCKV4ROOTMUTEX();
1201 nfsv4_relref(&nfsv4rootfs_lock);
1202 NFSUNLOCKV4ROOTMUTEX();
1203 }
1204
1205 /*
1206 * Server timer routine. It can scan any linked list, so long
1207 * as it holds the spin/mutex lock and there is no exclusive lock on
1208 * nfsv4rootfs_lock.
1209 * (For OpenBSD, a kthread is ok. For FreeBSD, I think it is ok
1210 * to do this from a callout, since the spin locks work. For
1211 * Darwin, I'm not sure what will work correctly yet.)
1212 * Should be called once per second.
1213 */
1214 void
nfsrv_servertimer(void)1215 nfsrv_servertimer(void)
1216 {
1217 struct nfsclient *clp, *nclp;
1218 struct nfsstate *stp, *nstp;
1219 int got_ref, i;
1220
1221 /*
1222 * Make sure nfsboottime is set. This is used by V3 as well
1223 * as V4. Note that nfsboottime is not nfsrvboottime, which is
1224 * only used by the V4 server for leases.
1225 */
1226 if (nfsboottime.tv_sec == 0)
1227 NFSSETBOOTTIME(nfsboottime);
1228
1229 /*
1230 * If server hasn't started yet, just return.
1231 */
1232 NFSLOCKSTATE();
1233 if (nfsrv_stablefirst.nsf_eograce == 0) {
1234 NFSUNLOCKSTATE();
1235 return;
1236 }
1237 if (!(nfsrv_stablefirst.nsf_flags & NFSNSF_UPDATEDONE)) {
1238 if (!(nfsrv_stablefirst.nsf_flags & NFSNSF_GRACEOVER) &&
1239 NFSD_MONOSEC > nfsrv_stablefirst.nsf_eograce)
1240 nfsrv_stablefirst.nsf_flags |=
1241 (NFSNSF_GRACEOVER | NFSNSF_NEEDLOCK);
1242 NFSUNLOCKSTATE();
1243 return;
1244 }
1245
1246 /*
1247 * Try and get a reference count on the nfsv4rootfs_lock so that
1248 * no nfsd thread can acquire an exclusive lock on it before this
1249 * call is done. If it is already exclusively locked, just return.
1250 */
1251 NFSLOCKV4ROOTMUTEX();
1252 got_ref = nfsv4_getref_nonblock(&nfsv4rootfs_lock);
1253 NFSUNLOCKV4ROOTMUTEX();
1254 if (got_ref == 0) {
1255 NFSUNLOCKSTATE();
1256 return;
1257 }
1258
1259 /*
1260 * For each client...
1261 */
1262 for (i = 0; i < nfsrv_clienthashsize; i++) {
1263 clp = LIST_FIRST(&nfsclienthash[i]);
1264 while (clp != LIST_END(&nfsclienthash[i])) {
1265 nclp = LIST_NEXT(clp, lc_hash);
1266 if (!(clp->lc_flags & LCL_EXPIREIT)) {
1267 if (((clp->lc_expiry + NFSRV_STALELEASE) < NFSD_MONOSEC
1268 && ((LIST_EMPTY(&clp->lc_deleg)
1269 && LIST_EMPTY(&clp->lc_open)) ||
1270 nfsrv_clients > nfsrv_clienthighwater)) ||
1271 (clp->lc_expiry + NFSRV_MOULDYLEASE) < NFSD_MONOSEC ||
1272 (clp->lc_expiry < NFSD_MONOSEC &&
1273 (nfsrv_openpluslock * 10 / 9) > nfsrv_v4statelimit)) {
1274 /*
1275 * Lease has expired several nfsrv_lease times ago:
1276 * PLUS
1277 * - no state is associated with it
1278 * OR
1279 * - above high water mark for number of clients
1280 * (nfsrv_clienthighwater should be large enough
1281 * that this only occurs when clients fail to
1282 * use the same nfs_client_id4.id. Maybe somewhat
1283 * higher that the maximum number of clients that
1284 * will mount this server?)
1285 * OR
1286 * Lease has expired a very long time ago
1287 * OR
1288 * Lease has expired PLUS the number of opens + locks
1289 * has exceeded 90% of capacity
1290 *
1291 * --> Mark for expiry. The actual expiry will be done
1292 * by an nfsd sometime soon.
1293 */
1294 clp->lc_flags |= LCL_EXPIREIT;
1295 nfsrv_stablefirst.nsf_flags |=
1296 (NFSNSF_NEEDLOCK | NFSNSF_EXPIREDCLIENT);
1297 } else {
1298 /*
1299 * If there are no opens, increment no open tick cnt
1300 * If time exceeds NFSNOOPEN, mark it to be thrown away
1301 * otherwise, if there is an open, reset no open time
1302 * Hopefully, this will avoid excessive re-creation
1303 * of open owners and subsequent open confirms.
1304 */
1305 stp = LIST_FIRST(&clp->lc_open);
1306 while (stp != LIST_END(&clp->lc_open)) {
1307 nstp = LIST_NEXT(stp, ls_list);
1308 if (LIST_EMPTY(&stp->ls_open)) {
1309 stp->ls_noopens++;
1310 if (stp->ls_noopens > NFSNOOPEN ||
1311 (nfsrv_openpluslock * 2) >
1312 nfsrv_v4statelimit)
1313 nfsrv_stablefirst.nsf_flags |=
1314 NFSNSF_NOOPENS;
1315 } else {
1316 stp->ls_noopens = 0;
1317 }
1318 stp = nstp;
1319 }
1320 }
1321 }
1322 clp = nclp;
1323 }
1324 }
1325 NFSUNLOCKSTATE();
1326 NFSLOCKV4ROOTMUTEX();
1327 nfsv4_relref(&nfsv4rootfs_lock);
1328 NFSUNLOCKV4ROOTMUTEX();
1329 }
1330
1331 /*
1332 * The following set of functions free up the various data structures.
1333 */
1334 /*
1335 * Clear out all open/lock state related to this nfsclient.
1336 * Caller must hold an exclusive lock on nfsv4rootfs_lock, so that
1337 * there are no other active nfsd threads.
1338 */
1339 void
nfsrv_cleanclient(struct nfsclient * clp,NFSPROC_T * p)1340 nfsrv_cleanclient(struct nfsclient *clp, NFSPROC_T *p)
1341 {
1342 struct nfsstate *stp, *nstp;
1343 struct nfsdsession *sep, *nsep;
1344
1345 LIST_FOREACH_SAFE(stp, &clp->lc_open, ls_list, nstp)
1346 nfsrv_freeopenowner(stp, 1, p);
1347 if ((clp->lc_flags & LCL_ADMINREVOKED) == 0)
1348 LIST_FOREACH_SAFE(sep, &clp->lc_session, sess_list, nsep)
1349 (void)nfsrv_freesession(sep, NULL);
1350 }
1351
1352 /*
1353 * Free a client that has been cleaned. It should also already have been
1354 * removed from the lists.
1355 * (Just to be safe w.r.t. newnfs_disconnect(), call this function when
1356 * softclock interrupts are enabled.)
1357 */
1358 void
nfsrv_zapclient(struct nfsclient * clp,NFSPROC_T * p)1359 nfsrv_zapclient(struct nfsclient *clp, NFSPROC_T *p)
1360 {
1361
1362 #ifdef notyet
1363 if ((clp->lc_flags & (LCL_GSS | LCL_CALLBACKSON)) ==
1364 (LCL_GSS | LCL_CALLBACKSON) &&
1365 (clp->lc_hand.nfsh_flag & NFSG_COMPLETE) &&
1366 clp->lc_handlelen > 0) {
1367 clp->lc_hand.nfsh_flag &= ~NFSG_COMPLETE;
1368 clp->lc_hand.nfsh_flag |= NFSG_DESTROYED;
1369 (void) nfsrv_docallback(clp, NFSV4PROC_CBNULL,
1370 NULL, 0, NULL, NULL, NULL, 0, p);
1371 }
1372 #endif
1373 newnfs_disconnect(NULL, &clp->lc_req);
1374 free(clp->lc_req.nr_nam, M_SONAME);
1375 NFSFREEMUTEX(&clp->lc_req.nr_mtx);
1376 free(clp->lc_stateid, M_NFSDCLIENT);
1377 free(clp, M_NFSDCLIENT);
1378 NFSLOCKSTATE();
1379 nfsstatsv1.srvclients--;
1380 nfsrv_openpluslock--;
1381 nfsrv_clients--;
1382 NFSUNLOCKSTATE();
1383 }
1384
1385 /*
1386 * Free a list of delegation state structures.
1387 * (This function will also free all nfslockfile structures that no
1388 * longer have associated state.)
1389 */
1390 void
nfsrv_freedeleglist(struct nfsstatehead * sthp)1391 nfsrv_freedeleglist(struct nfsstatehead *sthp)
1392 {
1393 struct nfsstate *stp, *nstp;
1394
1395 LIST_FOREACH_SAFE(stp, sthp, ls_list, nstp) {
1396 nfsrv_freedeleg(stp);
1397 }
1398 LIST_INIT(sthp);
1399 }
1400
1401 /*
1402 * Free up a delegation.
1403 */
1404 static void
nfsrv_freedeleg(struct nfsstate * stp)1405 nfsrv_freedeleg(struct nfsstate *stp)
1406 {
1407 struct nfslockfile *lfp;
1408
1409 LIST_REMOVE(stp, ls_hash);
1410 LIST_REMOVE(stp, ls_list);
1411 LIST_REMOVE(stp, ls_file);
1412 if ((stp->ls_flags & NFSLCK_DELEGWRITE) != 0)
1413 nfsrv_writedelegcnt--;
1414 lfp = stp->ls_lfp;
1415 if (LIST_EMPTY(&lfp->lf_open) &&
1416 LIST_EMPTY(&lfp->lf_lock) && LIST_EMPTY(&lfp->lf_deleg) &&
1417 LIST_EMPTY(&lfp->lf_locallock) && LIST_EMPTY(&lfp->lf_rollback) &&
1418 lfp->lf_usecount == 0 &&
1419 nfsv4_testlock(&lfp->lf_locallock_lck) == 0)
1420 nfsrv_freenfslockfile(lfp);
1421 free(stp, M_NFSDSTATE);
1422 nfsstatsv1.srvdelegates--;
1423 nfsrv_openpluslock--;
1424 nfsrv_delegatecnt--;
1425 }
1426
1427 /*
1428 * This function frees an open owner and all associated opens.
1429 */
1430 static void
nfsrv_freeopenowner(struct nfsstate * stp,int cansleep,NFSPROC_T * p)1431 nfsrv_freeopenowner(struct nfsstate *stp, int cansleep, NFSPROC_T *p)
1432 {
1433 struct nfsstate *nstp, *tstp;
1434
1435 LIST_REMOVE(stp, ls_list);
1436 /*
1437 * Now, free all associated opens.
1438 */
1439 nstp = LIST_FIRST(&stp->ls_open);
1440 while (nstp != LIST_END(&stp->ls_open)) {
1441 tstp = nstp;
1442 nstp = LIST_NEXT(nstp, ls_list);
1443 (void) nfsrv_freeopen(tstp, NULL, cansleep, p);
1444 }
1445 if (stp->ls_op)
1446 nfsrvd_derefcache(stp->ls_op);
1447 free(stp, M_NFSDSTATE);
1448 nfsstatsv1.srvopenowners--;
1449 nfsrv_openpluslock--;
1450 }
1451
1452 /*
1453 * This function frees an open (nfsstate open structure) with all associated
1454 * lock_owners and locks. It also frees the nfslockfile structure iff there
1455 * are no other opens on the file.
1456 * Returns 1 if it free'd the nfslockfile, 0 otherwise.
1457 */
1458 static int
nfsrv_freeopen(struct nfsstate * stp,vnode_t vp,int cansleep,NFSPROC_T * p)1459 nfsrv_freeopen(struct nfsstate *stp, vnode_t vp, int cansleep, NFSPROC_T *p)
1460 {
1461 struct nfsstate *nstp, *tstp;
1462 struct nfslockfile *lfp;
1463 int ret;
1464
1465 LIST_REMOVE(stp, ls_hash);
1466 LIST_REMOVE(stp, ls_list);
1467 LIST_REMOVE(stp, ls_file);
1468
1469 lfp = stp->ls_lfp;
1470 /*
1471 * Now, free all lockowners associated with this open.
1472 */
1473 LIST_FOREACH_SAFE(tstp, &stp->ls_open, ls_list, nstp)
1474 nfsrv_freelockowner(tstp, vp, cansleep, p);
1475
1476 /*
1477 * The nfslockfile is freed here if there are no locks
1478 * associated with the open.
1479 * If there are locks associated with the open, the
1480 * nfslockfile structure can be freed via nfsrv_freelockowner().
1481 * Acquire the state mutex to avoid races with calls to
1482 * nfsrv_getlockfile().
1483 */
1484 if (cansleep != 0)
1485 NFSLOCKSTATE();
1486 if (lfp != NULL && LIST_EMPTY(&lfp->lf_open) &&
1487 LIST_EMPTY(&lfp->lf_deleg) && LIST_EMPTY(&lfp->lf_lock) &&
1488 LIST_EMPTY(&lfp->lf_locallock) && LIST_EMPTY(&lfp->lf_rollback) &&
1489 lfp->lf_usecount == 0 &&
1490 (cansleep != 0 || nfsv4_testlock(&lfp->lf_locallock_lck) == 0)) {
1491 nfsrv_freenfslockfile(lfp);
1492 ret = 1;
1493 } else
1494 ret = 0;
1495 if (cansleep != 0)
1496 NFSUNLOCKSTATE();
1497 free(stp, M_NFSDSTATE);
1498 nfsstatsv1.srvopens--;
1499 nfsrv_openpluslock--;
1500 return (ret);
1501 }
1502
1503 /*
1504 * Frees a lockowner and all associated locks.
1505 */
1506 static void
nfsrv_freelockowner(struct nfsstate * stp,vnode_t vp,int cansleep,NFSPROC_T * p)1507 nfsrv_freelockowner(struct nfsstate *stp, vnode_t vp, int cansleep,
1508 NFSPROC_T *p)
1509 {
1510
1511 LIST_REMOVE(stp, ls_hash);
1512 LIST_REMOVE(stp, ls_list);
1513 nfsrv_freeallnfslocks(stp, vp, cansleep, p);
1514 if (stp->ls_op)
1515 nfsrvd_derefcache(stp->ls_op);
1516 free(stp, M_NFSDSTATE);
1517 nfsstatsv1.srvlockowners--;
1518 nfsrv_openpluslock--;
1519 }
1520
1521 /*
1522 * Free all the nfs locks on a lockowner.
1523 */
1524 static void
nfsrv_freeallnfslocks(struct nfsstate * stp,vnode_t vp,int cansleep,NFSPROC_T * p)1525 nfsrv_freeallnfslocks(struct nfsstate *stp, vnode_t vp, int cansleep,
1526 NFSPROC_T *p)
1527 {
1528 struct nfslock *lop, *nlop;
1529 struct nfsrollback *rlp, *nrlp;
1530 struct nfslockfile *lfp = NULL;
1531 int gottvp = 0;
1532 vnode_t tvp = NULL;
1533 uint64_t first, end;
1534
1535 if (vp != NULL)
1536 ASSERT_VOP_UNLOCKED(vp, "nfsrv_freeallnfslocks: vnode locked");
1537 lop = LIST_FIRST(&stp->ls_lock);
1538 while (lop != LIST_END(&stp->ls_lock)) {
1539 nlop = LIST_NEXT(lop, lo_lckowner);
1540 /*
1541 * Since all locks should be for the same file, lfp should
1542 * not change.
1543 */
1544 if (lfp == NULL)
1545 lfp = lop->lo_lfp;
1546 else if (lfp != lop->lo_lfp)
1547 panic("allnfslocks");
1548 /*
1549 * If vp is NULL and cansleep != 0, a vnode must be acquired
1550 * from the file handle. This only occurs when called from
1551 * nfsrv_cleanclient().
1552 */
1553 if (gottvp == 0) {
1554 if (nfsrv_dolocallocks == 0)
1555 tvp = NULL;
1556 else if (vp == NULL && cansleep != 0) {
1557 tvp = nfsvno_getvp(&lfp->lf_fh);
1558 if (tvp != NULL)
1559 NFSVOPUNLOCK(tvp);
1560 } else
1561 tvp = vp;
1562 gottvp = 1;
1563 }
1564
1565 if (tvp != NULL) {
1566 if (cansleep == 0)
1567 panic("allnfs2");
1568 first = lop->lo_first;
1569 end = lop->lo_end;
1570 nfsrv_freenfslock(lop);
1571 nfsrv_localunlock(tvp, lfp, first, end, p);
1572 LIST_FOREACH_SAFE(rlp, &lfp->lf_rollback, rlck_list,
1573 nrlp)
1574 free(rlp, M_NFSDROLLBACK);
1575 LIST_INIT(&lfp->lf_rollback);
1576 } else
1577 nfsrv_freenfslock(lop);
1578 lop = nlop;
1579 }
1580 if (vp == NULL && tvp != NULL)
1581 vrele(tvp);
1582 }
1583
1584 /*
1585 * Free an nfslock structure.
1586 */
1587 static void
nfsrv_freenfslock(struct nfslock * lop)1588 nfsrv_freenfslock(struct nfslock *lop)
1589 {
1590
1591 if (lop->lo_lckfile.le_prev != NULL) {
1592 LIST_REMOVE(lop, lo_lckfile);
1593 nfsstatsv1.srvlocks--;
1594 nfsrv_openpluslock--;
1595 }
1596 LIST_REMOVE(lop, lo_lckowner);
1597 free(lop, M_NFSDLOCK);
1598 }
1599
1600 /*
1601 * This function frees an nfslockfile structure.
1602 */
1603 static void
nfsrv_freenfslockfile(struct nfslockfile * lfp)1604 nfsrv_freenfslockfile(struct nfslockfile *lfp)
1605 {
1606
1607 LIST_REMOVE(lfp, lf_hash);
1608 free(lfp, M_NFSDLOCKFILE);
1609 }
1610
1611 /*
1612 * This function looks up an nfsstate structure via stateid.
1613 */
1614 static int
nfsrv_getstate(struct nfsclient * clp,nfsv4stateid_t * stateidp,__unused u_int32_t flags,struct nfsstate ** stpp)1615 nfsrv_getstate(struct nfsclient *clp, nfsv4stateid_t *stateidp, __unused u_int32_t flags,
1616 struct nfsstate **stpp)
1617 {
1618 struct nfsstate *stp;
1619 struct nfsstatehead *hp;
1620 int error = 0;
1621
1622 *stpp = NULL;
1623 hp = NFSSTATEHASH(clp, *stateidp);
1624 LIST_FOREACH(stp, hp, ls_hash) {
1625 if (!NFSBCMP(stp->ls_stateid.other, stateidp->other,
1626 NFSX_STATEIDOTHER))
1627 break;
1628 }
1629
1630 /*
1631 * If no state id in list, return NFSERR_BADSTATEID.
1632 */
1633 if (stp == LIST_END(hp)) {
1634 error = NFSERR_BADSTATEID;
1635 goto out;
1636 }
1637 *stpp = stp;
1638
1639 out:
1640 NFSEXITCODE(error);
1641 return (error);
1642 }
1643
1644 /*
1645 * This function gets an nfsstate structure via owner string.
1646 */
1647 static void
nfsrv_getowner(struct nfsstatehead * hp,struct nfsstate * new_stp,struct nfsstate ** stpp)1648 nfsrv_getowner(struct nfsstatehead *hp, struct nfsstate *new_stp,
1649 struct nfsstate **stpp)
1650 {
1651 struct nfsstate *stp;
1652
1653 *stpp = NULL;
1654 LIST_FOREACH(stp, hp, ls_list) {
1655 if (new_stp->ls_ownerlen == stp->ls_ownerlen &&
1656 !NFSBCMP(new_stp->ls_owner,stp->ls_owner,stp->ls_ownerlen)) {
1657 *stpp = stp;
1658 return;
1659 }
1660 }
1661 }
1662
1663 /*
1664 * Lock control function called to update lock status.
1665 * Returns 0 upon success, -1 if there is no lock and the flags indicate
1666 * that one isn't to be created and an NFSERR_xxx for other errors.
1667 * The structures new_stp and new_lop are passed in as pointers that should
1668 * be set to NULL if the structure is used and shouldn't be free'd.
1669 * For the NFSLCK_TEST and NFSLCK_CHECK cases, the structures are
1670 * never used and can safely be allocated on the stack. For all other
1671 * cases, *new_stpp and *new_lopp should be malloc'd before the call,
1672 * in case they are used.
1673 */
1674 int
nfsrv_lockctrl(vnode_t vp,struct nfsstate ** new_stpp,struct nfslock ** new_lopp,struct nfslockconflict * cfp,nfsquad_t clientid,nfsv4stateid_t * stateidp,__unused struct nfsexstuff * exp,struct nfsrv_descript * nd,NFSPROC_T * p)1675 nfsrv_lockctrl(vnode_t vp, struct nfsstate **new_stpp,
1676 struct nfslock **new_lopp, struct nfslockconflict *cfp,
1677 nfsquad_t clientid, nfsv4stateid_t *stateidp,
1678 __unused struct nfsexstuff *exp,
1679 struct nfsrv_descript *nd, NFSPROC_T *p)
1680 {
1681 struct nfslock *lop;
1682 struct nfsstate *new_stp = *new_stpp;
1683 struct nfslock *new_lop = *new_lopp;
1684 struct nfsstate *tstp, *mystp, *nstp;
1685 int specialid = 0;
1686 struct nfslockfile *lfp;
1687 struct nfslock *other_lop = NULL;
1688 struct nfsstate *stp, *lckstp = NULL;
1689 struct nfsclient *clp = NULL;
1690 u_int32_t bits;
1691 int error = 0, haslock = 0, ret, reterr;
1692 int getlckret, delegation = 0, filestruct_locked, vnode_unlocked = 0;
1693 fhandle_t nfh;
1694 uint64_t first, end;
1695 uint32_t lock_flags;
1696
1697 if (new_stp->ls_flags & (NFSLCK_CHECK | NFSLCK_SETATTR)) {
1698 /*
1699 * Note the special cases of "all 1s" or "all 0s" stateids and
1700 * let reads with all 1s go ahead.
1701 */
1702 if (new_stp->ls_stateid.seqid == 0x0 &&
1703 new_stp->ls_stateid.other[0] == 0x0 &&
1704 new_stp->ls_stateid.other[1] == 0x0 &&
1705 new_stp->ls_stateid.other[2] == 0x0)
1706 specialid = 1;
1707 else if (new_stp->ls_stateid.seqid == 0xffffffff &&
1708 new_stp->ls_stateid.other[0] == 0xffffffff &&
1709 new_stp->ls_stateid.other[1] == 0xffffffff &&
1710 new_stp->ls_stateid.other[2] == 0xffffffff)
1711 specialid = 2;
1712 }
1713
1714 /*
1715 * Check for restart conditions (client and server).
1716 */
1717 error = nfsrv_checkrestart(clientid, new_stp->ls_flags,
1718 &new_stp->ls_stateid, specialid);
1719 if (error)
1720 goto out;
1721
1722 /*
1723 * Check for state resource limit exceeded.
1724 */
1725 if ((new_stp->ls_flags & NFSLCK_LOCK) &&
1726 nfsrv_openpluslock > nfsrv_v4statelimit) {
1727 error = NFSERR_RESOURCE;
1728 goto out;
1729 }
1730
1731 /*
1732 * For the lock case, get another nfslock structure,
1733 * just in case we need it.
1734 * Malloc now, before we start sifting through the linked lists,
1735 * in case we have to wait for memory.
1736 */
1737 tryagain:
1738 if (new_stp->ls_flags & NFSLCK_LOCK)
1739 other_lop = malloc(sizeof (struct nfslock),
1740 M_NFSDLOCK, M_WAITOK);
1741 filestruct_locked = 0;
1742 reterr = 0;
1743 lfp = NULL;
1744
1745 /*
1746 * Get the lockfile structure for CFH now, so we can do a sanity
1747 * check against the stateid, before incrementing the seqid#, since
1748 * we want to return NFSERR_BADSTATEID on failure and the seqid#
1749 * shouldn't be incremented for this case.
1750 * If nfsrv_getlockfile() returns -1, it means "not found", which
1751 * will be handled later.
1752 * If we are doing Lock/LockU and local locking is enabled, sleep
1753 * lock the nfslockfile structure.
1754 */
1755 getlckret = nfsrv_getlockfh(vp, new_stp->ls_flags, NULL, &nfh, p);
1756 NFSLOCKSTATE();
1757 if (getlckret == 0) {
1758 if ((new_stp->ls_flags & (NFSLCK_LOCK | NFSLCK_UNLOCK)) != 0 &&
1759 nfsrv_dolocallocks != 0 && nd->nd_repstat == 0) {
1760 getlckret = nfsrv_getlockfile(new_stp->ls_flags, NULL,
1761 &lfp, &nfh, 1);
1762 if (getlckret == 0)
1763 filestruct_locked = 1;
1764 } else
1765 getlckret = nfsrv_getlockfile(new_stp->ls_flags, NULL,
1766 &lfp, &nfh, 0);
1767 }
1768 if (getlckret != 0 && getlckret != -1)
1769 reterr = getlckret;
1770
1771 if (filestruct_locked != 0) {
1772 LIST_INIT(&lfp->lf_rollback);
1773 if ((new_stp->ls_flags & NFSLCK_LOCK)) {
1774 /*
1775 * For local locking, do the advisory locking now, so
1776 * that any conflict can be detected. A failure later
1777 * can be rolled back locally. If an error is returned,
1778 * struct nfslockfile has been unlocked and any local
1779 * locking rolled back.
1780 */
1781 NFSUNLOCKSTATE();
1782 if (vnode_unlocked == 0) {
1783 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl1");
1784 vnode_unlocked = 1;
1785 NFSVOPUNLOCK(vp);
1786 }
1787 reterr = nfsrv_locallock(vp, lfp,
1788 (new_lop->lo_flags & (NFSLCK_READ | NFSLCK_WRITE)),
1789 new_lop->lo_first, new_lop->lo_end, cfp, p);
1790 NFSLOCKSTATE();
1791 }
1792 }
1793
1794 if (specialid == 0) {
1795 if (new_stp->ls_flags & NFSLCK_TEST) {
1796 /*
1797 * RFC 3530 does not list LockT as an op that renews a
1798 * lease, but the consensus seems to be that it is ok
1799 * for a server to do so.
1800 */
1801 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
1802 (nfsquad_t)((u_quad_t)0), 0, nd, p);
1803
1804 /*
1805 * Since NFSERR_EXPIRED, NFSERR_ADMINREVOKED are not valid
1806 * error returns for LockT, just go ahead and test for a lock,
1807 * since there are no locks for this client, but other locks
1808 * can conflict. (ie. same client will always be false)
1809 */
1810 if (error == NFSERR_EXPIRED || error == NFSERR_ADMINREVOKED)
1811 error = 0;
1812 lckstp = new_stp;
1813 } else {
1814 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
1815 (nfsquad_t)((u_quad_t)0), 0, nd, p);
1816 if (error == 0)
1817 /*
1818 * Look up the stateid
1819 */
1820 error = nfsrv_getstate(clp, &new_stp->ls_stateid,
1821 new_stp->ls_flags, &stp);
1822 /*
1823 * do some sanity checks for an unconfirmed open or a
1824 * stateid that refers to the wrong file, for an open stateid
1825 */
1826 if (error == 0 && (stp->ls_flags & NFSLCK_OPEN) &&
1827 ((stp->ls_openowner->ls_flags & NFSLCK_NEEDSCONFIRM) ||
1828 (getlckret == 0 && stp->ls_lfp != lfp))){
1829 /*
1830 * NFSLCK_SETATTR should return OK rather than NFSERR_BADSTATEID
1831 * The only exception is using SETATTR with SIZE.
1832 * */
1833 if ((new_stp->ls_flags &
1834 (NFSLCK_SETATTR | NFSLCK_CHECK)) != NFSLCK_SETATTR)
1835 error = NFSERR_BADSTATEID;
1836 }
1837
1838 if (error == 0 &&
1839 (stp->ls_flags & (NFSLCK_DELEGREAD | NFSLCK_DELEGWRITE)) &&
1840 getlckret == 0 && stp->ls_lfp != lfp)
1841 error = NFSERR_BADSTATEID;
1842
1843 /*
1844 * If the lockowner stateid doesn't refer to the same file,
1845 * I believe that is considered ok, since some clients will
1846 * only create a single lockowner and use that for all locks
1847 * on all files.
1848 * For now, log it as a diagnostic, instead of considering it
1849 * a BadStateid.
1850 */
1851 if (error == 0 && (stp->ls_flags &
1852 (NFSLCK_OPEN | NFSLCK_DELEGREAD | NFSLCK_DELEGWRITE)) == 0 &&
1853 getlckret == 0 && stp->ls_lfp != lfp) {
1854 #ifdef DIAGNOSTIC
1855 printf("Got a lock statid for different file open\n");
1856 #endif
1857 /*
1858 error = NFSERR_BADSTATEID;
1859 */
1860 }
1861
1862 if (error == 0) {
1863 if (new_stp->ls_flags & NFSLCK_OPENTOLOCK) {
1864 /*
1865 * If haslock set, we've already checked the seqid.
1866 */
1867 if (!haslock) {
1868 if (stp->ls_flags & NFSLCK_OPEN)
1869 error = nfsrv_checkseqid(nd, new_stp->ls_seq,
1870 stp->ls_openowner, new_stp->ls_op);
1871 else
1872 error = NFSERR_BADSTATEID;
1873 }
1874 if (!error)
1875 nfsrv_getowner(&stp->ls_open, new_stp, &lckstp);
1876 if (lckstp) {
1877 /*
1878 * For NFSv4.1 and NFSv4.2 allow an
1879 * open_to_lock_owner when the lock_owner already
1880 * exists. Just clear NFSLCK_OPENTOLOCK so that
1881 * a new lock_owner will not be created.
1882 * RFC7530 states that the error for NFSv4.0
1883 * is NFS4ERR_BAD_SEQID.
1884 */
1885 if ((nd->nd_flag & ND_NFSV41) != 0)
1886 new_stp->ls_flags &= ~NFSLCK_OPENTOLOCK;
1887 else
1888 error = NFSERR_BADSEQID;
1889 } else
1890 lckstp = new_stp;
1891 } else if (new_stp->ls_flags&(NFSLCK_LOCK|NFSLCK_UNLOCK)) {
1892 /*
1893 * If haslock set, ditto above.
1894 */
1895 if (!haslock) {
1896 if (stp->ls_flags & NFSLCK_OPEN)
1897 error = NFSERR_BADSTATEID;
1898 else
1899 error = nfsrv_checkseqid(nd, new_stp->ls_seq,
1900 stp, new_stp->ls_op);
1901 }
1902 lckstp = stp;
1903 } else {
1904 lckstp = stp;
1905 }
1906 }
1907 /*
1908 * If the seqid part of the stateid isn't the same, return
1909 * NFSERR_OLDSTATEID for cases other than I/O Ops.
1910 * For I/O Ops, only return NFSERR_OLDSTATEID if
1911 * nfsrv_returnoldstateid is set. (The consensus on the email
1912 * list was that most clients would prefer to not receive
1913 * NFSERR_OLDSTATEID for I/O Ops, but the RFC suggests that that
1914 * is what will happen, so I use the nfsrv_returnoldstateid to
1915 * allow for either server configuration.)
1916 */
1917 if (!error && stp->ls_stateid.seqid!=new_stp->ls_stateid.seqid &&
1918 (((nd->nd_flag & ND_NFSV41) == 0 &&
1919 (!(new_stp->ls_flags & NFSLCK_CHECK) ||
1920 nfsrv_returnoldstateid)) ||
1921 ((nd->nd_flag & ND_NFSV41) != 0 &&
1922 new_stp->ls_stateid.seqid != 0)))
1923 error = NFSERR_OLDSTATEID;
1924 }
1925 }
1926
1927 /*
1928 * Now we can check for grace.
1929 */
1930 if (!error)
1931 error = nfsrv_checkgrace(nd, clp, new_stp->ls_flags);
1932 if ((new_stp->ls_flags & NFSLCK_RECLAIM) && !error &&
1933 nfsrv_checkstable(clp))
1934 error = NFSERR_NOGRACE;
1935 /*
1936 * If we successfully Reclaimed state, note that.
1937 */
1938 if ((new_stp->ls_flags & NFSLCK_RECLAIM) && !error)
1939 nfsrv_markstable(clp);
1940
1941 /*
1942 * At this point, either error == NFSERR_BADSTATEID or the
1943 * seqid# has been updated, so we can return any error.
1944 * If error == 0, there may be an error in:
1945 * nd_repstat - Set by the calling function.
1946 * reterr - Set above, if getting the nfslockfile structure
1947 * or acquiring the local lock failed.
1948 * (If both of these are set, nd_repstat should probably be
1949 * returned, since that error was detected before this
1950 * function call.)
1951 */
1952 if (error != 0 || nd->nd_repstat != 0 || reterr != 0) {
1953 if (error == 0) {
1954 if (nd->nd_repstat != 0)
1955 error = nd->nd_repstat;
1956 else
1957 error = reterr;
1958 }
1959 if (filestruct_locked != 0) {
1960 /* Roll back local locks. */
1961 NFSUNLOCKSTATE();
1962 if (vnode_unlocked == 0) {
1963 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl2");
1964 vnode_unlocked = 1;
1965 NFSVOPUNLOCK(vp);
1966 }
1967 nfsrv_locallock_rollback(vp, lfp, p);
1968 NFSLOCKSTATE();
1969 nfsrv_unlocklf(lfp);
1970 }
1971 NFSUNLOCKSTATE();
1972 goto out;
1973 }
1974
1975 /*
1976 * Check the nfsrv_getlockfile return.
1977 * Returned -1 if no structure found.
1978 */
1979 if (getlckret == -1) {
1980 error = NFSERR_EXPIRED;
1981 /*
1982 * Called from lockt, so no lock is OK.
1983 */
1984 if (new_stp->ls_flags & NFSLCK_TEST) {
1985 error = 0;
1986 } else if (new_stp->ls_flags &
1987 (NFSLCK_CHECK | NFSLCK_SETATTR)) {
1988 /*
1989 * Called to check for a lock, OK if the stateid is all
1990 * 1s or all 0s, but there should be an nfsstate
1991 * otherwise.
1992 * (ie. If there is no open, I'll assume no share
1993 * deny bits.)
1994 */
1995 if (specialid)
1996 error = 0;
1997 else
1998 error = NFSERR_BADSTATEID;
1999 }
2000 NFSUNLOCKSTATE();
2001 goto out;
2002 }
2003
2004 /*
2005 * For NFSLCK_CHECK and NFSLCK_LOCK, test for a share conflict.
2006 * For NFSLCK_CHECK, allow a read if write access is granted,
2007 * but check for a deny. For NFSLCK_LOCK, require correct access,
2008 * which implies a conflicting deny can't exist.
2009 */
2010 if (new_stp->ls_flags & (NFSLCK_CHECK | NFSLCK_LOCK)) {
2011 /*
2012 * Four kinds of state id:
2013 * - specialid (all 0s or all 1s), only for NFSLCK_CHECK
2014 * - stateid for an open
2015 * - stateid for a delegation
2016 * - stateid for a lock owner
2017 */
2018 if (!specialid) {
2019 if (stp->ls_flags & (NFSLCK_DELEGREAD | NFSLCK_DELEGWRITE)) {
2020 delegation = 1;
2021 mystp = stp;
2022 nfsrv_delaydelegtimeout(stp);
2023 } else if (stp->ls_flags & NFSLCK_OPEN) {
2024 mystp = stp;
2025 } else {
2026 mystp = stp->ls_openstp;
2027 }
2028 /*
2029 * If locking or checking, require correct access
2030 * bit set.
2031 */
2032 if (((new_stp->ls_flags & NFSLCK_LOCK) &&
2033 !((new_lop->lo_flags >> NFSLCK_LOCKSHIFT) &
2034 mystp->ls_flags & NFSLCK_ACCESSBITS)) ||
2035 ((new_stp->ls_flags & (NFSLCK_CHECK|NFSLCK_READACCESS)) ==
2036 (NFSLCK_CHECK | NFSLCK_READACCESS) &&
2037 !(mystp->ls_flags & NFSLCK_READACCESS) &&
2038 nfsrv_allowreadforwriteopen == 0) ||
2039 ((new_stp->ls_flags & (NFSLCK_CHECK|NFSLCK_WRITEACCESS)) ==
2040 (NFSLCK_CHECK | NFSLCK_WRITEACCESS) &&
2041 !(mystp->ls_flags & NFSLCK_WRITEACCESS))) {
2042 if (filestruct_locked != 0) {
2043 /* Roll back local locks. */
2044 NFSUNLOCKSTATE();
2045 if (vnode_unlocked == 0) {
2046 ASSERT_VOP_ELOCKED(vp,
2047 "nfsrv_lockctrl3");
2048 vnode_unlocked = 1;
2049 NFSVOPUNLOCK(vp);
2050 }
2051 nfsrv_locallock_rollback(vp, lfp, p);
2052 NFSLOCKSTATE();
2053 nfsrv_unlocklf(lfp);
2054 }
2055 NFSUNLOCKSTATE();
2056 error = NFSERR_OPENMODE;
2057 goto out;
2058 }
2059 } else
2060 mystp = NULL;
2061 if ((new_stp->ls_flags & NFSLCK_CHECK) && !delegation) {
2062 /*
2063 * Check for a conflicting deny bit.
2064 */
2065 LIST_FOREACH(tstp, &lfp->lf_open, ls_file) {
2066 if (tstp != mystp) {
2067 bits = tstp->ls_flags;
2068 bits >>= NFSLCK_SHIFT;
2069 if (new_stp->ls_flags & bits & NFSLCK_ACCESSBITS) {
2070 KASSERT(vnode_unlocked == 0,
2071 ("nfsrv_lockctrl: vnode unlocked1"));
2072 ret = nfsrv_clientconflict(tstp->ls_clp, &haslock,
2073 vp, p);
2074 if (ret == 1) {
2075 /*
2076 * nfsrv_clientconflict unlocks state
2077 * when it returns non-zero.
2078 */
2079 lckstp = NULL;
2080 goto tryagain;
2081 }
2082 if (ret == 0)
2083 NFSUNLOCKSTATE();
2084 if (ret == 2)
2085 error = NFSERR_PERM;
2086 else
2087 error = NFSERR_OPENMODE;
2088 goto out;
2089 }
2090 }
2091 }
2092
2093 /* We're outta here */
2094 NFSUNLOCKSTATE();
2095 goto out;
2096 }
2097 }
2098
2099 /*
2100 * For setattr, just get rid of all the Delegations for other clients.
2101 */
2102 if (new_stp->ls_flags & NFSLCK_SETATTR) {
2103 KASSERT(vnode_unlocked == 0,
2104 ("nfsrv_lockctrl: vnode unlocked2"));
2105 ret = nfsrv_cleandeleg(vp, lfp, clp, &haslock, p);
2106 if (ret) {
2107 /*
2108 * nfsrv_cleandeleg() unlocks state when it
2109 * returns non-zero.
2110 */
2111 if (ret == -1) {
2112 lckstp = NULL;
2113 goto tryagain;
2114 }
2115 error = ret;
2116 goto out;
2117 }
2118 if (!(new_stp->ls_flags & NFSLCK_CHECK) ||
2119 (LIST_EMPTY(&lfp->lf_open) && LIST_EMPTY(&lfp->lf_lock) &&
2120 LIST_EMPTY(&lfp->lf_deleg))) {
2121 NFSUNLOCKSTATE();
2122 goto out;
2123 }
2124 }
2125
2126 /*
2127 * Check for a conflicting delegation. If one is found, call
2128 * nfsrv_delegconflict() to handle it. If the v4root lock hasn't
2129 * been set yet, it will get the lock. Otherwise, it will recall
2130 * the delegation. Then, we try try again...
2131 * I currently believe the conflict algorithm to be:
2132 * For Lock Ops (Lock/LockT/LockU)
2133 * - there is a conflict iff a different client has a write delegation
2134 * For Reading (Read Op)
2135 * - there is a conflict iff a different client has a write delegation
2136 * (the specialids are always a different client)
2137 * For Writing (Write/Setattr of size)
2138 * - there is a conflict if a different client has any delegation
2139 * - there is a conflict if the same client has a read delegation
2140 * (I don't understand why this isn't allowed, but that seems to be
2141 * the current consensus?)
2142 */
2143 tstp = LIST_FIRST(&lfp->lf_deleg);
2144 while (tstp != LIST_END(&lfp->lf_deleg)) {
2145 nstp = LIST_NEXT(tstp, ls_file);
2146 if ((((new_stp->ls_flags&(NFSLCK_LOCK|NFSLCK_UNLOCK|NFSLCK_TEST))||
2147 ((new_stp->ls_flags & NFSLCK_CHECK) &&
2148 (new_lop->lo_flags & NFSLCK_READ))) &&
2149 clp != tstp->ls_clp &&
2150 (tstp->ls_flags & NFSLCK_DELEGWRITE)) ||
2151 ((new_stp->ls_flags & NFSLCK_CHECK) &&
2152 (new_lop->lo_flags & NFSLCK_WRITE) &&
2153 (clp != tstp->ls_clp ||
2154 (tstp->ls_flags & NFSLCK_DELEGREAD)))) {
2155 ret = 0;
2156 if (filestruct_locked != 0) {
2157 /* Roll back local locks. */
2158 NFSUNLOCKSTATE();
2159 if (vnode_unlocked == 0) {
2160 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl4");
2161 NFSVOPUNLOCK(vp);
2162 }
2163 nfsrv_locallock_rollback(vp, lfp, p);
2164 NFSLOCKSTATE();
2165 nfsrv_unlocklf(lfp);
2166 NFSUNLOCKSTATE();
2167 NFSVOPLOCK(vp, LK_EXCLUSIVE | LK_RETRY);
2168 vnode_unlocked = 0;
2169 if (VN_IS_DOOMED(vp))
2170 ret = NFSERR_SERVERFAULT;
2171 NFSLOCKSTATE();
2172 }
2173 if (ret == 0)
2174 ret = nfsrv_delegconflict(tstp, &haslock, p, vp);
2175 if (ret) {
2176 /*
2177 * nfsrv_delegconflict unlocks state when it
2178 * returns non-zero, which it always does.
2179 */
2180 if (other_lop) {
2181 free(other_lop, M_NFSDLOCK);
2182 other_lop = NULL;
2183 }
2184 if (ret == -1) {
2185 lckstp = NULL;
2186 goto tryagain;
2187 }
2188 error = ret;
2189 goto out;
2190 }
2191 /* Never gets here. */
2192 }
2193 tstp = nstp;
2194 }
2195
2196 /*
2197 * Handle the unlock case by calling nfsrv_updatelock().
2198 * (Should I have done some access checking above for unlock? For now,
2199 * just let it happen.)
2200 */
2201 if (new_stp->ls_flags & NFSLCK_UNLOCK) {
2202 first = new_lop->lo_first;
2203 end = new_lop->lo_end;
2204 nfsrv_updatelock(stp, new_lopp, &other_lop, lfp);
2205 stateidp->seqid = ++(stp->ls_stateid.seqid);
2206 if ((nd->nd_flag & ND_NFSV41) != 0 && stateidp->seqid == 0)
2207 stateidp->seqid = stp->ls_stateid.seqid = 1;
2208 stateidp->other[0] = stp->ls_stateid.other[0];
2209 stateidp->other[1] = stp->ls_stateid.other[1];
2210 stateidp->other[2] = stp->ls_stateid.other[2];
2211 if (filestruct_locked != 0) {
2212 NFSUNLOCKSTATE();
2213 if (vnode_unlocked == 0) {
2214 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl5");
2215 vnode_unlocked = 1;
2216 NFSVOPUNLOCK(vp);
2217 }
2218 /* Update the local locks. */
2219 nfsrv_localunlock(vp, lfp, first, end, p);
2220 NFSLOCKSTATE();
2221 nfsrv_unlocklf(lfp);
2222 }
2223 NFSUNLOCKSTATE();
2224 goto out;
2225 }
2226
2227 /*
2228 * Search for a conflicting lock. A lock conflicts if:
2229 * - the lock range overlaps and
2230 * - at least one lock is a write lock and
2231 * - it is not owned by the same lock owner
2232 */
2233 if (!delegation) {
2234 LIST_FOREACH(lop, &lfp->lf_lock, lo_lckfile) {
2235 if (new_lop->lo_end > lop->lo_first &&
2236 new_lop->lo_first < lop->lo_end &&
2237 (new_lop->lo_flags == NFSLCK_WRITE ||
2238 lop->lo_flags == NFSLCK_WRITE) &&
2239 lckstp != lop->lo_stp &&
2240 (clp != lop->lo_stp->ls_clp ||
2241 lckstp->ls_ownerlen != lop->lo_stp->ls_ownerlen ||
2242 NFSBCMP(lckstp->ls_owner, lop->lo_stp->ls_owner,
2243 lckstp->ls_ownerlen))) {
2244 if (other_lop) {
2245 free(other_lop, M_NFSDLOCK);
2246 other_lop = NULL;
2247 }
2248 if (vnode_unlocked != 0)
2249 ret = nfsrv_clientconflict(lop->lo_stp->ls_clp, &haslock,
2250 NULL, p);
2251 else
2252 ret = nfsrv_clientconflict(lop->lo_stp->ls_clp, &haslock,
2253 vp, p);
2254 if (ret == 1) {
2255 if (filestruct_locked != 0) {
2256 if (vnode_unlocked == 0) {
2257 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl6");
2258 NFSVOPUNLOCK(vp);
2259 }
2260 /* Roll back local locks. */
2261 nfsrv_locallock_rollback(vp, lfp, p);
2262 NFSLOCKSTATE();
2263 nfsrv_unlocklf(lfp);
2264 NFSUNLOCKSTATE();
2265 NFSVOPLOCK(vp, LK_EXCLUSIVE | LK_RETRY);
2266 vnode_unlocked = 0;
2267 if (VN_IS_DOOMED(vp)) {
2268 error = NFSERR_SERVERFAULT;
2269 goto out;
2270 }
2271 }
2272 /*
2273 * nfsrv_clientconflict() unlocks state when it
2274 * returns non-zero.
2275 */
2276 lckstp = NULL;
2277 goto tryagain;
2278 }
2279 /*
2280 * Found a conflicting lock, so record the conflict and
2281 * return the error.
2282 */
2283 if (cfp != NULL && ret == 0) {
2284 cfp->cl_clientid.lval[0]=lop->lo_stp->ls_stateid.other[0];
2285 cfp->cl_clientid.lval[1]=lop->lo_stp->ls_stateid.other[1];
2286 cfp->cl_first = lop->lo_first;
2287 cfp->cl_end = lop->lo_end;
2288 cfp->cl_flags = lop->lo_flags;
2289 cfp->cl_ownerlen = lop->lo_stp->ls_ownerlen;
2290 NFSBCOPY(lop->lo_stp->ls_owner, cfp->cl_owner,
2291 cfp->cl_ownerlen);
2292 }
2293 if (ret == 2)
2294 error = NFSERR_PERM;
2295 else if (new_stp->ls_flags & NFSLCK_RECLAIM)
2296 error = NFSERR_RECLAIMCONFLICT;
2297 else if (new_stp->ls_flags & NFSLCK_CHECK)
2298 error = NFSERR_LOCKED;
2299 else
2300 error = NFSERR_DENIED;
2301 if (filestruct_locked != 0 && ret == 0) {
2302 /* Roll back local locks. */
2303 NFSUNLOCKSTATE();
2304 if (vnode_unlocked == 0) {
2305 ASSERT_VOP_ELOCKED(vp, "nfsrv_lockctrl7");
2306 vnode_unlocked = 1;
2307 NFSVOPUNLOCK(vp);
2308 }
2309 nfsrv_locallock_rollback(vp, lfp, p);
2310 NFSLOCKSTATE();
2311 nfsrv_unlocklf(lfp);
2312 }
2313 if (ret == 0)
2314 NFSUNLOCKSTATE();
2315 goto out;
2316 }
2317 }
2318 }
2319
2320 /*
2321 * We only get here if there was no lock that conflicted.
2322 */
2323 if (new_stp->ls_flags & (NFSLCK_TEST | NFSLCK_CHECK)) {
2324 NFSUNLOCKSTATE();
2325 goto out;
2326 }
2327
2328 /*
2329 * We only get here when we are creating or modifying a lock.
2330 * There are two variants:
2331 * - exist_lock_owner where lock_owner exists
2332 * - open_to_lock_owner with new lock_owner
2333 */
2334 first = new_lop->lo_first;
2335 end = new_lop->lo_end;
2336 lock_flags = new_lop->lo_flags;
2337 if (!(new_stp->ls_flags & NFSLCK_OPENTOLOCK)) {
2338 nfsrv_updatelock(lckstp, new_lopp, &other_lop, lfp);
2339 stateidp->seqid = ++(lckstp->ls_stateid.seqid);
2340 if ((nd->nd_flag & ND_NFSV41) != 0 && stateidp->seqid == 0)
2341 stateidp->seqid = lckstp->ls_stateid.seqid = 1;
2342 stateidp->other[0] = lckstp->ls_stateid.other[0];
2343 stateidp->other[1] = lckstp->ls_stateid.other[1];
2344 stateidp->other[2] = lckstp->ls_stateid.other[2];
2345 } else {
2346 /*
2347 * The new open_to_lock_owner case.
2348 * Link the new nfsstate into the lists.
2349 */
2350 new_stp->ls_seq = new_stp->ls_opentolockseq;
2351 nfsrvd_refcache(new_stp->ls_op);
2352 stateidp->seqid = new_stp->ls_stateid.seqid = 1;
2353 stateidp->other[0] = new_stp->ls_stateid.other[0] =
2354 clp->lc_clientid.lval[0];
2355 stateidp->other[1] = new_stp->ls_stateid.other[1] =
2356 clp->lc_clientid.lval[1];
2357 stateidp->other[2] = new_stp->ls_stateid.other[2] =
2358 nfsrv_nextstateindex(clp);
2359 new_stp->ls_clp = clp;
2360 LIST_INIT(&new_stp->ls_lock);
2361 new_stp->ls_openstp = stp;
2362 new_stp->ls_lfp = lfp;
2363 nfsrv_insertlock(new_lop, (struct nfslock *)new_stp, new_stp,
2364 lfp);
2365 LIST_INSERT_HEAD(NFSSTATEHASH(clp, new_stp->ls_stateid),
2366 new_stp, ls_hash);
2367 LIST_INSERT_HEAD(&stp->ls_open, new_stp, ls_list);
2368 *new_lopp = NULL;
2369 *new_stpp = NULL;
2370 nfsstatsv1.srvlockowners++;
2371 nfsrv_openpluslock++;
2372 }
2373 if (filestruct_locked != 0) {
2374 NFSUNLOCKSTATE();
2375 nfsrv_locallock_commit(lfp, lock_flags, first, end);
2376 NFSLOCKSTATE();
2377 nfsrv_unlocklf(lfp);
2378 }
2379 NFSUNLOCKSTATE();
2380
2381 out:
2382 if (haslock) {
2383 NFSLOCKV4ROOTMUTEX();
2384 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2385 NFSUNLOCKV4ROOTMUTEX();
2386 }
2387 if (vnode_unlocked != 0) {
2388 NFSVOPLOCK(vp, LK_EXCLUSIVE | LK_RETRY);
2389 if (error == 0 && VN_IS_DOOMED(vp))
2390 error = NFSERR_SERVERFAULT;
2391 }
2392 if (other_lop)
2393 free(other_lop, M_NFSDLOCK);
2394 NFSEXITCODE2(error, nd);
2395 return (error);
2396 }
2397
2398 /*
2399 * Check for state errors for Open.
2400 * repstat is passed back out as an error if more critical errors
2401 * are not detected.
2402 */
2403 int
nfsrv_opencheck(nfsquad_t clientid,nfsv4stateid_t * stateidp,struct nfsstate * new_stp,vnode_t vp,struct nfsrv_descript * nd,NFSPROC_T * p,int repstat)2404 nfsrv_opencheck(nfsquad_t clientid, nfsv4stateid_t *stateidp,
2405 struct nfsstate *new_stp, vnode_t vp, struct nfsrv_descript *nd,
2406 NFSPROC_T *p, int repstat)
2407 {
2408 struct nfsstate *stp, *nstp;
2409 struct nfsclient *clp;
2410 struct nfsstate *ownerstp;
2411 struct nfslockfile *lfp, *new_lfp;
2412 int error = 0, haslock = 0, ret, readonly = 0, getfhret = 0;
2413
2414 if ((new_stp->ls_flags & NFSLCK_SHAREBITS) == NFSLCK_READACCESS)
2415 readonly = 1;
2416 /*
2417 * Check for restart conditions (client and server).
2418 */
2419 error = nfsrv_checkrestart(clientid, new_stp->ls_flags,
2420 &new_stp->ls_stateid, 0);
2421 if (error)
2422 goto out;
2423
2424 /*
2425 * Check for state resource limit exceeded.
2426 * Technically this should be SMP protected, but the worst
2427 * case error is "out by one or two" on the count when it
2428 * returns NFSERR_RESOURCE and the limit is just a rather
2429 * arbitrary high water mark, so no harm is done.
2430 */
2431 if (nfsrv_openpluslock > nfsrv_v4statelimit) {
2432 error = NFSERR_RESOURCE;
2433 goto out;
2434 }
2435
2436 tryagain:
2437 new_lfp = malloc(sizeof (struct nfslockfile),
2438 M_NFSDLOCKFILE, M_WAITOK);
2439 if (vp)
2440 getfhret = nfsrv_getlockfh(vp, new_stp->ls_flags, new_lfp,
2441 NULL, p);
2442 NFSLOCKSTATE();
2443 /*
2444 * Get the nfsclient structure.
2445 */
2446 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
2447 (nfsquad_t)((u_quad_t)0), 0, nd, p);
2448
2449 /*
2450 * Look up the open owner. See if it needs confirmation and
2451 * check the seq#, as required.
2452 */
2453 if (!error)
2454 nfsrv_getowner(&clp->lc_open, new_stp, &ownerstp);
2455
2456 if (!error && ownerstp) {
2457 error = nfsrv_checkseqid(nd, new_stp->ls_seq, ownerstp,
2458 new_stp->ls_op);
2459 /*
2460 * If the OpenOwner hasn't been confirmed, assume the
2461 * old one was a replay and this one is ok.
2462 * See: RFC3530 Sec. 14.2.18.
2463 */
2464 if (error == NFSERR_BADSEQID &&
2465 (ownerstp->ls_flags & NFSLCK_NEEDSCONFIRM))
2466 error = 0;
2467 }
2468
2469 /*
2470 * Check for grace.
2471 */
2472 if (!error)
2473 error = nfsrv_checkgrace(nd, clp, new_stp->ls_flags);
2474 if ((new_stp->ls_flags & NFSLCK_RECLAIM) && !error &&
2475 nfsrv_checkstable(clp))
2476 error = NFSERR_NOGRACE;
2477
2478 /*
2479 * If none of the above errors occurred, let repstat be
2480 * returned.
2481 */
2482 if (repstat && !error)
2483 error = repstat;
2484 if (error) {
2485 NFSUNLOCKSTATE();
2486 if (haslock) {
2487 NFSLOCKV4ROOTMUTEX();
2488 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2489 NFSUNLOCKV4ROOTMUTEX();
2490 }
2491 free(new_lfp, M_NFSDLOCKFILE);
2492 goto out;
2493 }
2494
2495 /*
2496 * If vp == NULL, the file doesn't exist yet, so return ok.
2497 * (This always happens on the first pass, so haslock must be 0.)
2498 */
2499 if (vp == NULL) {
2500 NFSUNLOCKSTATE();
2501 free(new_lfp, M_NFSDLOCKFILE);
2502 goto out;
2503 }
2504
2505 /*
2506 * Get the structure for the underlying file.
2507 */
2508 if (getfhret)
2509 error = getfhret;
2510 else
2511 error = nfsrv_getlockfile(new_stp->ls_flags, &new_lfp, &lfp,
2512 NULL, 0);
2513 if (new_lfp)
2514 free(new_lfp, M_NFSDLOCKFILE);
2515 if (error) {
2516 NFSUNLOCKSTATE();
2517 if (haslock) {
2518 NFSLOCKV4ROOTMUTEX();
2519 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2520 NFSUNLOCKV4ROOTMUTEX();
2521 }
2522 goto out;
2523 }
2524
2525 /*
2526 * Search for a conflicting open/share.
2527 */
2528 if (new_stp->ls_flags & NFSLCK_DELEGCUR) {
2529 /*
2530 * For Delegate_Cur, search for the matching Delegation,
2531 * which indicates no conflict.
2532 * An old delegation should have been recovered by the
2533 * client doing a Claim_DELEGATE_Prev, so I won't let
2534 * it match and return NFSERR_EXPIRED. Should I let it
2535 * match?
2536 */
2537 LIST_FOREACH(stp, &lfp->lf_deleg, ls_file) {
2538 if (!(stp->ls_flags & NFSLCK_OLDDELEG) &&
2539 (((nd->nd_flag & ND_NFSV41) != 0 &&
2540 stateidp->seqid == 0) ||
2541 stateidp->seqid == stp->ls_stateid.seqid) &&
2542 !NFSBCMP(stateidp->other, stp->ls_stateid.other,
2543 NFSX_STATEIDOTHER))
2544 break;
2545 }
2546 if (stp == LIST_END(&lfp->lf_deleg) ||
2547 ((new_stp->ls_flags & NFSLCK_WRITEACCESS) &&
2548 (stp->ls_flags & NFSLCK_DELEGREAD))) {
2549 NFSUNLOCKSTATE();
2550 if (haslock) {
2551 NFSLOCKV4ROOTMUTEX();
2552 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2553 NFSUNLOCKV4ROOTMUTEX();
2554 }
2555 error = NFSERR_EXPIRED;
2556 goto out;
2557 }
2558 }
2559
2560 /*
2561 * Check for access/deny bit conflicts. I check for the same
2562 * owner as well, in case the client didn't bother.
2563 */
2564 LIST_FOREACH(stp, &lfp->lf_open, ls_file) {
2565 if (!(new_stp->ls_flags & NFSLCK_DELEGCUR) &&
2566 (((new_stp->ls_flags & NFSLCK_ACCESSBITS) &
2567 ((stp->ls_flags>>NFSLCK_SHIFT) & NFSLCK_ACCESSBITS))||
2568 ((stp->ls_flags & NFSLCK_ACCESSBITS) &
2569 ((new_stp->ls_flags>>NFSLCK_SHIFT)&NFSLCK_ACCESSBITS)))){
2570 ret = nfsrv_clientconflict(stp->ls_clp,&haslock,vp,p);
2571 if (ret == 1) {
2572 /*
2573 * nfsrv_clientconflict() unlocks
2574 * state when it returns non-zero.
2575 */
2576 goto tryagain;
2577 }
2578 if (ret == 2)
2579 error = NFSERR_PERM;
2580 else if (new_stp->ls_flags & NFSLCK_RECLAIM)
2581 error = NFSERR_RECLAIMCONFLICT;
2582 else
2583 error = NFSERR_SHAREDENIED;
2584 if (ret == 0)
2585 NFSUNLOCKSTATE();
2586 if (haslock) {
2587 NFSLOCKV4ROOTMUTEX();
2588 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2589 NFSUNLOCKV4ROOTMUTEX();
2590 }
2591 goto out;
2592 }
2593 }
2594
2595 /*
2596 * Check for a conflicting delegation. If one is found, call
2597 * nfsrv_delegconflict() to handle it. If the v4root lock hasn't
2598 * been set yet, it will get the lock. Otherwise, it will recall
2599 * the delegation. Then, we try try again...
2600 * (If NFSLCK_DELEGCUR is set, it has a delegation, so there
2601 * isn't a conflict.)
2602 * I currently believe the conflict algorithm to be:
2603 * For Open with Read Access and Deny None
2604 * - there is a conflict iff a different client has a write delegation
2605 * For Open with other Write Access or any Deny except None
2606 * - there is a conflict if a different client has any delegation
2607 * - there is a conflict if the same client has a read delegation
2608 * (The current consensus is that this last case should be
2609 * considered a conflict since the client with a read delegation
2610 * could have done an Open with ReadAccess and WriteDeny
2611 * locally and then not have checked for the WriteDeny.)
2612 * Don't check for a Reclaim, since that will be dealt with
2613 * by nfsrv_openctrl().
2614 */
2615 if (!(new_stp->ls_flags &
2616 (NFSLCK_DELEGPREV | NFSLCK_DELEGCUR | NFSLCK_RECLAIM))) {
2617 stp = LIST_FIRST(&lfp->lf_deleg);
2618 while (stp != LIST_END(&lfp->lf_deleg)) {
2619 nstp = LIST_NEXT(stp, ls_file);
2620 if ((readonly && stp->ls_clp != clp &&
2621 (stp->ls_flags & NFSLCK_DELEGWRITE)) ||
2622 (!readonly && (stp->ls_clp != clp ||
2623 (stp->ls_flags & NFSLCK_DELEGREAD)))) {
2624 ret = nfsrv_delegconflict(stp, &haslock, p, vp);
2625 if (ret) {
2626 /*
2627 * nfsrv_delegconflict() unlocks state
2628 * when it returns non-zero.
2629 */
2630 if (ret == -1)
2631 goto tryagain;
2632 error = ret;
2633 goto out;
2634 }
2635 }
2636 stp = nstp;
2637 }
2638 }
2639 NFSUNLOCKSTATE();
2640 if (haslock) {
2641 NFSLOCKV4ROOTMUTEX();
2642 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2643 NFSUNLOCKV4ROOTMUTEX();
2644 }
2645
2646 out:
2647 NFSEXITCODE2(error, nd);
2648 return (error);
2649 }
2650
2651 /*
2652 * Open control function to create/update open state for an open.
2653 */
2654 int
nfsrv_openctrl(struct nfsrv_descript * nd,vnode_t vp,struct nfsstate ** new_stpp,nfsquad_t clientid,nfsv4stateid_t * stateidp,nfsv4stateid_t * delegstateidp,u_int32_t * rflagsp,struct nfsexstuff * exp,NFSPROC_T * p,u_quad_t filerev)2655 nfsrv_openctrl(struct nfsrv_descript *nd, vnode_t vp,
2656 struct nfsstate **new_stpp, nfsquad_t clientid, nfsv4stateid_t *stateidp,
2657 nfsv4stateid_t *delegstateidp, u_int32_t *rflagsp, struct nfsexstuff *exp,
2658 NFSPROC_T *p, u_quad_t filerev)
2659 {
2660 struct nfsstate *new_stp = *new_stpp;
2661 struct nfsstate *stp, *nstp;
2662 struct nfsstate *openstp = NULL, *new_open, *ownerstp, *new_deleg;
2663 struct nfslockfile *lfp, *new_lfp;
2664 struct nfsclient *clp;
2665 int error = 0, haslock = 0, ret, delegate = 1, writedeleg = 1;
2666 int readonly = 0, cbret = 1, getfhret = 0;
2667 int gotstate = 0, len = 0;
2668 u_char *clidp = NULL;
2669
2670 if ((new_stp->ls_flags & NFSLCK_SHAREBITS) == NFSLCK_READACCESS)
2671 readonly = 1;
2672 /*
2673 * Check for restart conditions (client and server).
2674 * (Paranoia, should have been detected by nfsrv_opencheck().)
2675 * If an error does show up, return NFSERR_EXPIRED, since the
2676 * the seqid# has already been incremented.
2677 */
2678 error = nfsrv_checkrestart(clientid, new_stp->ls_flags,
2679 &new_stp->ls_stateid, 0);
2680 if (error) {
2681 printf("Nfsd: openctrl unexpected restart err=%d\n",
2682 error);
2683 error = NFSERR_EXPIRED;
2684 goto out;
2685 }
2686
2687 clidp = malloc(NFSV4_OPAQUELIMIT, M_TEMP, M_WAITOK);
2688 tryagain:
2689 new_lfp = malloc(sizeof (struct nfslockfile),
2690 M_NFSDLOCKFILE, M_WAITOK);
2691 new_open = malloc(sizeof (struct nfsstate),
2692 M_NFSDSTATE, M_WAITOK);
2693 new_deleg = malloc(sizeof (struct nfsstate),
2694 M_NFSDSTATE, M_WAITOK);
2695 getfhret = nfsrv_getlockfh(vp, new_stp->ls_flags, new_lfp,
2696 NULL, p);
2697 NFSLOCKSTATE();
2698 /*
2699 * Get the client structure. Since the linked lists could be changed
2700 * by other nfsd processes if this process does a tsleep(), one of
2701 * two things must be done.
2702 * 1 - don't tsleep()
2703 * or
2704 * 2 - get the nfsv4_lock() { indicated by haslock == 1 }
2705 * before using the lists, since this lock stops the other
2706 * nfsd. This should only be used for rare cases, since it
2707 * essentially single threads the nfsd.
2708 * At this time, it is only done for cases where the stable
2709 * storage file must be written prior to completion of state
2710 * expiration.
2711 */
2712 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
2713 (nfsquad_t)((u_quad_t)0), 0, nd, p);
2714 if (!error && (clp->lc_flags & LCL_NEEDSCBNULL) &&
2715 clp->lc_program) {
2716 /*
2717 * This happens on the first open for a client
2718 * that supports callbacks.
2719 */
2720 NFSUNLOCKSTATE();
2721 /*
2722 * Although nfsrv_docallback() will sleep, clp won't
2723 * go away, since they are only removed when the
2724 * nfsv4_lock() has blocked the nfsd threads. The
2725 * fields in clp can change, but having multiple
2726 * threads do this Null callback RPC should be
2727 * harmless.
2728 */
2729 cbret = nfsrv_docallback(clp, NFSV4PROC_CBNULL,
2730 NULL, 0, NULL, NULL, NULL, 0, p);
2731 NFSLOCKSTATE();
2732 clp->lc_flags &= ~LCL_NEEDSCBNULL;
2733 if (!cbret)
2734 clp->lc_flags |= LCL_CALLBACKSON;
2735 }
2736
2737 /*
2738 * Look up the open owner. See if it needs confirmation and
2739 * check the seq#, as required.
2740 */
2741 if (!error)
2742 nfsrv_getowner(&clp->lc_open, new_stp, &ownerstp);
2743
2744 if (error) {
2745 NFSUNLOCKSTATE();
2746 printf("Nfsd: openctrl unexpected state err=%d\n",
2747 error);
2748 free(new_lfp, M_NFSDLOCKFILE);
2749 free(new_open, M_NFSDSTATE);
2750 free(new_deleg, M_NFSDSTATE);
2751 if (haslock) {
2752 NFSLOCKV4ROOTMUTEX();
2753 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2754 NFSUNLOCKV4ROOTMUTEX();
2755 }
2756 error = NFSERR_EXPIRED;
2757 goto out;
2758 }
2759
2760 if (new_stp->ls_flags & NFSLCK_RECLAIM)
2761 nfsrv_markstable(clp);
2762
2763 /*
2764 * Get the structure for the underlying file.
2765 */
2766 if (getfhret)
2767 error = getfhret;
2768 else
2769 error = nfsrv_getlockfile(new_stp->ls_flags, &new_lfp, &lfp,
2770 NULL, 0);
2771 if (new_lfp)
2772 free(new_lfp, M_NFSDLOCKFILE);
2773 if (error) {
2774 NFSUNLOCKSTATE();
2775 printf("Nfsd openctrl unexpected getlockfile err=%d\n",
2776 error);
2777 free(new_open, M_NFSDSTATE);
2778 free(new_deleg, M_NFSDSTATE);
2779 if (haslock) {
2780 NFSLOCKV4ROOTMUTEX();
2781 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2782 NFSUNLOCKV4ROOTMUTEX();
2783 }
2784 goto out;
2785 }
2786
2787 /*
2788 * Search for a conflicting open/share.
2789 */
2790 if (new_stp->ls_flags & NFSLCK_DELEGCUR) {
2791 /*
2792 * For Delegate_Cur, search for the matching Delegation,
2793 * which indicates no conflict.
2794 * An old delegation should have been recovered by the
2795 * client doing a Claim_DELEGATE_Prev, so I won't let
2796 * it match and return NFSERR_EXPIRED. Should I let it
2797 * match?
2798 */
2799 LIST_FOREACH(stp, &lfp->lf_deleg, ls_file) {
2800 if (!(stp->ls_flags & NFSLCK_OLDDELEG) &&
2801 (((nd->nd_flag & ND_NFSV41) != 0 &&
2802 stateidp->seqid == 0) ||
2803 stateidp->seqid == stp->ls_stateid.seqid) &&
2804 !NFSBCMP(stateidp->other, stp->ls_stateid.other,
2805 NFSX_STATEIDOTHER))
2806 break;
2807 }
2808 if (stp == LIST_END(&lfp->lf_deleg) ||
2809 ((new_stp->ls_flags & NFSLCK_WRITEACCESS) &&
2810 (stp->ls_flags & NFSLCK_DELEGREAD))) {
2811 NFSUNLOCKSTATE();
2812 printf("Nfsd openctrl unexpected expiry\n");
2813 free(new_open, M_NFSDSTATE);
2814 free(new_deleg, M_NFSDSTATE);
2815 if (haslock) {
2816 NFSLOCKV4ROOTMUTEX();
2817 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2818 NFSUNLOCKV4ROOTMUTEX();
2819 }
2820 error = NFSERR_EXPIRED;
2821 goto out;
2822 }
2823
2824 /*
2825 * Don't issue a Delegation, since one already exists and
2826 * delay delegation timeout, as required.
2827 */
2828 delegate = 0;
2829 nfsrv_delaydelegtimeout(stp);
2830 }
2831
2832 /*
2833 * Check for access/deny bit conflicts. I also check for the
2834 * same owner, since the client might not have bothered to check.
2835 * Also, note an open for the same file and owner, if found,
2836 * which is all we do here for Delegate_Cur, since conflict
2837 * checking is already done.
2838 */
2839 LIST_FOREACH(stp, &lfp->lf_open, ls_file) {
2840 if (ownerstp && stp->ls_openowner == ownerstp)
2841 openstp = stp;
2842 if (!(new_stp->ls_flags & NFSLCK_DELEGCUR)) {
2843 /*
2844 * If another client has the file open, the only
2845 * delegation that can be issued is a Read delegation
2846 * and only if it is a Read open with Deny none.
2847 */
2848 if (clp != stp->ls_clp) {
2849 if ((stp->ls_flags & NFSLCK_SHAREBITS) ==
2850 NFSLCK_READACCESS)
2851 writedeleg = 0;
2852 else
2853 delegate = 0;
2854 }
2855 if(((new_stp->ls_flags & NFSLCK_ACCESSBITS) &
2856 ((stp->ls_flags>>NFSLCK_SHIFT) & NFSLCK_ACCESSBITS))||
2857 ((stp->ls_flags & NFSLCK_ACCESSBITS) &
2858 ((new_stp->ls_flags>>NFSLCK_SHIFT)&NFSLCK_ACCESSBITS))){
2859 ret = nfsrv_clientconflict(stp->ls_clp,&haslock,vp,p);
2860 if (ret == 1) {
2861 /*
2862 * nfsrv_clientconflict() unlocks state
2863 * when it returns non-zero.
2864 */
2865 free(new_open, M_NFSDSTATE);
2866 free(new_deleg, M_NFSDSTATE);
2867 openstp = NULL;
2868 goto tryagain;
2869 }
2870 if (ret == 2)
2871 error = NFSERR_PERM;
2872 else if (new_stp->ls_flags & NFSLCK_RECLAIM)
2873 error = NFSERR_RECLAIMCONFLICT;
2874 else
2875 error = NFSERR_SHAREDENIED;
2876 if (ret == 0)
2877 NFSUNLOCKSTATE();
2878 if (haslock) {
2879 NFSLOCKV4ROOTMUTEX();
2880 nfsv4_unlock(&nfsv4rootfs_lock, 1);
2881 NFSUNLOCKV4ROOTMUTEX();
2882 }
2883 free(new_open, M_NFSDSTATE);
2884 free(new_deleg, M_NFSDSTATE);
2885 printf("nfsd openctrl unexpected client cnfl\n");
2886 goto out;
2887 }
2888 }
2889 }
2890
2891 /*
2892 * Check for a conflicting delegation. If one is found, call
2893 * nfsrv_delegconflict() to handle it. If the v4root lock hasn't
2894 * been set yet, it will get the lock. Otherwise, it will recall
2895 * the delegation. Then, we try try again...
2896 * (If NFSLCK_DELEGCUR is set, it has a delegation, so there
2897 * isn't a conflict.)
2898 * I currently believe the conflict algorithm to be:
2899 * For Open with Read Access and Deny None
2900 * - there is a conflict iff a different client has a write delegation
2901 * For Open with other Write Access or any Deny except None
2902 * - there is a conflict if a different client has any delegation
2903 * - there is a conflict if the same client has a read delegation
2904 * (The current consensus is that this last case should be
2905 * considered a conflict since the client with a read delegation
2906 * could have done an Open with ReadAccess and WriteDeny
2907 * locally and then not have checked for the WriteDeny.)
2908 */
2909 if (!(new_stp->ls_flags & (NFSLCK_DELEGPREV | NFSLCK_DELEGCUR))) {
2910 stp = LIST_FIRST(&lfp->lf_deleg);
2911 while (stp != LIST_END(&lfp->lf_deleg)) {
2912 nstp = LIST_NEXT(stp, ls_file);
2913 if (stp->ls_clp != clp && (stp->ls_flags & NFSLCK_DELEGREAD))
2914 writedeleg = 0;
2915 else
2916 delegate = 0;
2917 if ((readonly && stp->ls_clp != clp &&
2918 (stp->ls_flags & NFSLCK_DELEGWRITE)) ||
2919 (!readonly && (stp->ls_clp != clp ||
2920 (stp->ls_flags & NFSLCK_DELEGREAD)))) {
2921 if (new_stp->ls_flags & NFSLCK_RECLAIM) {
2922 delegate = 2;
2923 } else {
2924 ret = nfsrv_delegconflict(stp, &haslock, p, vp);
2925 if (ret) {
2926 /*
2927 * nfsrv_delegconflict() unlocks state
2928 * when it returns non-zero.
2929 */
2930 printf("Nfsd openctrl unexpected deleg cnfl\n");
2931 free(new_open, M_NFSDSTATE);
2932 free(new_deleg, M_NFSDSTATE);
2933 if (ret == -1) {
2934 openstp = NULL;
2935 goto tryagain;
2936 }
2937 error = ret;
2938 goto out;
2939 }
2940 }
2941 }
2942 stp = nstp;
2943 }
2944 }
2945
2946 /*
2947 * We only get here if there was no open that conflicted.
2948 * If an open for the owner exists, or in the access/deny bits.
2949 * Otherwise it is a new open. If the open_owner hasn't been
2950 * confirmed, replace the open with the new one needing confirmation,
2951 * otherwise add the open.
2952 */
2953 if (new_stp->ls_flags & NFSLCK_DELEGPREV) {
2954 /*
2955 * Handle NFSLCK_DELEGPREV by searching the old delegations for
2956 * a match. If found, just move the old delegation to the current
2957 * delegation list and issue open. If not found, return
2958 * NFSERR_EXPIRED.
2959 */
2960 LIST_FOREACH(stp, &clp->lc_olddeleg, ls_list) {
2961 if (stp->ls_lfp == lfp) {
2962 /* Found it */
2963 if (stp->ls_clp != clp)
2964 panic("olddeleg clp");
2965 LIST_REMOVE(stp, ls_list);
2966 LIST_REMOVE(stp, ls_hash);
2967 stp->ls_flags &= ~NFSLCK_OLDDELEG;
2968 stp->ls_stateid.seqid = delegstateidp->seqid = 1;
2969 stp->ls_stateid.other[0] = delegstateidp->other[0] =
2970 clp->lc_clientid.lval[0];
2971 stp->ls_stateid.other[1] = delegstateidp->other[1] =
2972 clp->lc_clientid.lval[1];
2973 stp->ls_stateid.other[2] = delegstateidp->other[2] =
2974 nfsrv_nextstateindex(clp);
2975 stp->ls_compref = nd->nd_compref;
2976 LIST_INSERT_HEAD(&clp->lc_deleg, stp, ls_list);
2977 LIST_INSERT_HEAD(NFSSTATEHASH(clp,
2978 stp->ls_stateid), stp, ls_hash);
2979 if (stp->ls_flags & NFSLCK_DELEGWRITE)
2980 *rflagsp |= NFSV4OPEN_WRITEDELEGATE;
2981 else
2982 *rflagsp |= NFSV4OPEN_READDELEGATE;
2983 clp->lc_delegtime = NFSD_MONOSEC +
2984 nfsrv_lease + NFSRV_LEASEDELTA;
2985
2986 /*
2987 * Now, do the associated open.
2988 */
2989 new_open->ls_stateid.seqid = 1;
2990 new_open->ls_stateid.other[0] = clp->lc_clientid.lval[0];
2991 new_open->ls_stateid.other[1] = clp->lc_clientid.lval[1];
2992 new_open->ls_stateid.other[2] = nfsrv_nextstateindex(clp);
2993 new_open->ls_flags = (new_stp->ls_flags&NFSLCK_DENYBITS)|
2994 NFSLCK_OPEN;
2995 if (stp->ls_flags & NFSLCK_DELEGWRITE)
2996 new_open->ls_flags |= (NFSLCK_READACCESS |
2997 NFSLCK_WRITEACCESS);
2998 else
2999 new_open->ls_flags |= NFSLCK_READACCESS;
3000 new_open->ls_uid = new_stp->ls_uid;
3001 new_open->ls_lfp = lfp;
3002 new_open->ls_clp = clp;
3003 LIST_INIT(&new_open->ls_open);
3004 LIST_INSERT_HEAD(&lfp->lf_open, new_open, ls_file);
3005 LIST_INSERT_HEAD(NFSSTATEHASH(clp, new_open->ls_stateid),
3006 new_open, ls_hash);
3007 /*
3008 * and handle the open owner
3009 */
3010 if (ownerstp) {
3011 new_open->ls_openowner = ownerstp;
3012 LIST_INSERT_HEAD(&ownerstp->ls_open,new_open,ls_list);
3013 } else {
3014 new_open->ls_openowner = new_stp;
3015 new_stp->ls_flags = 0;
3016 nfsrvd_refcache(new_stp->ls_op);
3017 new_stp->ls_noopens = 0;
3018 LIST_INIT(&new_stp->ls_open);
3019 LIST_INSERT_HEAD(&new_stp->ls_open, new_open, ls_list);
3020 LIST_INSERT_HEAD(&clp->lc_open, new_stp, ls_list);
3021 *new_stpp = NULL;
3022 nfsstatsv1.srvopenowners++;
3023 nfsrv_openpluslock++;
3024 }
3025 openstp = new_open;
3026 new_open = NULL;
3027 nfsstatsv1.srvopens++;
3028 nfsrv_openpluslock++;
3029 break;
3030 }
3031 }
3032 if (stp == LIST_END(&clp->lc_olddeleg))
3033 error = NFSERR_EXPIRED;
3034 } else if (new_stp->ls_flags & (NFSLCK_DELEGREAD | NFSLCK_DELEGWRITE)) {
3035 /*
3036 * Scan to see that no delegation for this client and file
3037 * doesn't already exist.
3038 * There also shouldn't yet be an Open for this file and
3039 * openowner.
3040 */
3041 LIST_FOREACH(stp, &lfp->lf_deleg, ls_file) {
3042 if (stp->ls_clp == clp)
3043 break;
3044 }
3045 if (stp == LIST_END(&lfp->lf_deleg) && openstp == NULL) {
3046 /*
3047 * This is the Claim_Previous case with a delegation
3048 * type != Delegate_None.
3049 */
3050 /*
3051 * First, add the delegation. (Although we must issue the
3052 * delegation, we can also ask for an immediate return.)
3053 */
3054 new_deleg->ls_stateid.seqid = delegstateidp->seqid = 1;
3055 new_deleg->ls_stateid.other[0] = delegstateidp->other[0] =
3056 clp->lc_clientid.lval[0];
3057 new_deleg->ls_stateid.other[1] = delegstateidp->other[1] =
3058 clp->lc_clientid.lval[1];
3059 new_deleg->ls_stateid.other[2] = delegstateidp->other[2] =
3060 nfsrv_nextstateindex(clp);
3061 if (new_stp->ls_flags & NFSLCK_DELEGWRITE) {
3062 new_deleg->ls_flags = (NFSLCK_DELEGWRITE |
3063 NFSLCK_READACCESS | NFSLCK_WRITEACCESS);
3064 *rflagsp |= NFSV4OPEN_WRITEDELEGATE;
3065 nfsrv_writedelegcnt++;
3066 } else {
3067 new_deleg->ls_flags = (NFSLCK_DELEGREAD |
3068 NFSLCK_READACCESS);
3069 *rflagsp |= NFSV4OPEN_READDELEGATE;
3070 }
3071 new_deleg->ls_uid = new_stp->ls_uid;
3072 new_deleg->ls_lfp = lfp;
3073 new_deleg->ls_clp = clp;
3074 new_deleg->ls_filerev = filerev;
3075 new_deleg->ls_compref = nd->nd_compref;
3076 new_deleg->ls_lastrecall = 0;
3077 LIST_INSERT_HEAD(&lfp->lf_deleg, new_deleg, ls_file);
3078 LIST_INSERT_HEAD(NFSSTATEHASH(clp,
3079 new_deleg->ls_stateid), new_deleg, ls_hash);
3080 LIST_INSERT_HEAD(&clp->lc_deleg, new_deleg, ls_list);
3081 new_deleg = NULL;
3082 if (delegate == 2 || nfsrv_issuedelegs == 0 ||
3083 (clp->lc_flags & (LCL_CALLBACKSON | LCL_CBDOWN)) !=
3084 LCL_CALLBACKSON ||
3085 NFSRV_V4DELEGLIMIT(nfsrv_delegatecnt) ||
3086 !NFSVNO_DELEGOK(vp))
3087 *rflagsp |= NFSV4OPEN_RECALL;
3088 nfsstatsv1.srvdelegates++;
3089 nfsrv_openpluslock++;
3090 nfsrv_delegatecnt++;
3091
3092 /*
3093 * Now, do the associated open.
3094 */
3095 new_open->ls_stateid.seqid = 1;
3096 new_open->ls_stateid.other[0] = clp->lc_clientid.lval[0];
3097 new_open->ls_stateid.other[1] = clp->lc_clientid.lval[1];
3098 new_open->ls_stateid.other[2] = nfsrv_nextstateindex(clp);
3099 new_open->ls_flags = (new_stp->ls_flags & NFSLCK_DENYBITS) |
3100 NFSLCK_OPEN;
3101 if (new_stp->ls_flags & NFSLCK_DELEGWRITE)
3102 new_open->ls_flags |= (NFSLCK_READACCESS |
3103 NFSLCK_WRITEACCESS);
3104 else
3105 new_open->ls_flags |= NFSLCK_READACCESS;
3106 new_open->ls_uid = new_stp->ls_uid;
3107 new_open->ls_lfp = lfp;
3108 new_open->ls_clp = clp;
3109 LIST_INIT(&new_open->ls_open);
3110 LIST_INSERT_HEAD(&lfp->lf_open, new_open, ls_file);
3111 LIST_INSERT_HEAD(NFSSTATEHASH(clp, new_open->ls_stateid),
3112 new_open, ls_hash);
3113 /*
3114 * and handle the open owner
3115 */
3116 if (ownerstp) {
3117 new_open->ls_openowner = ownerstp;
3118 LIST_INSERT_HEAD(&ownerstp->ls_open, new_open, ls_list);
3119 } else {
3120 new_open->ls_openowner = new_stp;
3121 new_stp->ls_flags = 0;
3122 nfsrvd_refcache(new_stp->ls_op);
3123 new_stp->ls_noopens = 0;
3124 LIST_INIT(&new_stp->ls_open);
3125 LIST_INSERT_HEAD(&new_stp->ls_open, new_open, ls_list);
3126 LIST_INSERT_HEAD(&clp->lc_open, new_stp, ls_list);
3127 *new_stpp = NULL;
3128 nfsstatsv1.srvopenowners++;
3129 nfsrv_openpluslock++;
3130 }
3131 openstp = new_open;
3132 new_open = NULL;
3133 nfsstatsv1.srvopens++;
3134 nfsrv_openpluslock++;
3135 } else {
3136 error = NFSERR_RECLAIMCONFLICT;
3137 }
3138 } else if (ownerstp) {
3139 if (ownerstp->ls_flags & NFSLCK_NEEDSCONFIRM) {
3140 /* Replace the open */
3141 if (ownerstp->ls_op)
3142 nfsrvd_derefcache(ownerstp->ls_op);
3143 ownerstp->ls_op = new_stp->ls_op;
3144 nfsrvd_refcache(ownerstp->ls_op);
3145 ownerstp->ls_seq = new_stp->ls_seq;
3146 *rflagsp |= NFSV4OPEN_RESULTCONFIRM;
3147 stp = LIST_FIRST(&ownerstp->ls_open);
3148 stp->ls_flags = (new_stp->ls_flags & NFSLCK_SHAREBITS) |
3149 NFSLCK_OPEN;
3150 stp->ls_stateid.seqid = 1;
3151 stp->ls_uid = new_stp->ls_uid;
3152 if (lfp != stp->ls_lfp) {
3153 LIST_REMOVE(stp, ls_file);
3154 LIST_INSERT_HEAD(&lfp->lf_open, stp, ls_file);
3155 stp->ls_lfp = lfp;
3156 }
3157 openstp = stp;
3158 } else if (openstp) {
3159 openstp->ls_flags |= (new_stp->ls_flags & NFSLCK_SHAREBITS);
3160 openstp->ls_stateid.seqid++;
3161 if ((nd->nd_flag & ND_NFSV41) != 0 &&
3162 openstp->ls_stateid.seqid == 0)
3163 openstp->ls_stateid.seqid = 1;
3164
3165 /*
3166 * This is where we can choose to issue a delegation.
3167 */
3168 if ((new_stp->ls_flags & NFSLCK_WANTNODELEG) != 0)
3169 *rflagsp |= NFSV4OPEN_WDNOTWANTED;
3170 else if (nfsrv_issuedelegs == 0)
3171 *rflagsp |= NFSV4OPEN_WDSUPPFTYPE;
3172 else if (NFSRV_V4DELEGLIMIT(nfsrv_delegatecnt))
3173 *rflagsp |= NFSV4OPEN_WDRESOURCE;
3174 else if (delegate == 0 || writedeleg == 0 ||
3175 NFSVNO_EXRDONLY(exp) || (readonly != 0 &&
3176 nfsrv_writedelegifpos == 0) ||
3177 !NFSVNO_DELEGOK(vp) ||
3178 (new_stp->ls_flags & NFSLCK_WANTRDELEG) != 0 ||
3179 (clp->lc_flags & (LCL_CALLBACKSON | LCL_CBDOWN)) !=
3180 LCL_CALLBACKSON)
3181 *rflagsp |= NFSV4OPEN_WDCONTENTION;
3182 else {
3183 new_deleg->ls_stateid.seqid = delegstateidp->seqid = 1;
3184 new_deleg->ls_stateid.other[0] = delegstateidp->other[0]
3185 = clp->lc_clientid.lval[0];
3186 new_deleg->ls_stateid.other[1] = delegstateidp->other[1]
3187 = clp->lc_clientid.lval[1];
3188 new_deleg->ls_stateid.other[2] = delegstateidp->other[2]
3189 = nfsrv_nextstateindex(clp);
3190 new_deleg->ls_flags = (NFSLCK_DELEGWRITE |
3191 NFSLCK_READACCESS | NFSLCK_WRITEACCESS);
3192 *rflagsp |= NFSV4OPEN_WRITEDELEGATE;
3193 new_deleg->ls_uid = new_stp->ls_uid;
3194 new_deleg->ls_lfp = lfp;
3195 new_deleg->ls_clp = clp;
3196 new_deleg->ls_filerev = filerev;
3197 new_deleg->ls_compref = nd->nd_compref;
3198 new_deleg->ls_lastrecall = 0;
3199 nfsrv_writedelegcnt++;
3200 LIST_INSERT_HEAD(&lfp->lf_deleg, new_deleg, ls_file);
3201 LIST_INSERT_HEAD(NFSSTATEHASH(clp,
3202 new_deleg->ls_stateid), new_deleg, ls_hash);
3203 LIST_INSERT_HEAD(&clp->lc_deleg, new_deleg, ls_list);
3204 new_deleg = NULL;
3205 nfsstatsv1.srvdelegates++;
3206 nfsrv_openpluslock++;
3207 nfsrv_delegatecnt++;
3208 }
3209 } else {
3210 new_open->ls_stateid.seqid = 1;
3211 new_open->ls_stateid.other[0] = clp->lc_clientid.lval[0];
3212 new_open->ls_stateid.other[1] = clp->lc_clientid.lval[1];
3213 new_open->ls_stateid.other[2] = nfsrv_nextstateindex(clp);
3214 new_open->ls_flags = (new_stp->ls_flags & NFSLCK_SHAREBITS)|
3215 NFSLCK_OPEN;
3216 new_open->ls_uid = new_stp->ls_uid;
3217 new_open->ls_openowner = ownerstp;
3218 new_open->ls_lfp = lfp;
3219 new_open->ls_clp = clp;
3220 LIST_INIT(&new_open->ls_open);
3221 LIST_INSERT_HEAD(&lfp->lf_open, new_open, ls_file);
3222 LIST_INSERT_HEAD(&ownerstp->ls_open, new_open, ls_list);
3223 LIST_INSERT_HEAD(NFSSTATEHASH(clp, new_open->ls_stateid),
3224 new_open, ls_hash);
3225 openstp = new_open;
3226 new_open = NULL;
3227 nfsstatsv1.srvopens++;
3228 nfsrv_openpluslock++;
3229
3230 /*
3231 * This is where we can choose to issue a delegation.
3232 */
3233 if ((new_stp->ls_flags & NFSLCK_WANTNODELEG) != 0)
3234 *rflagsp |= NFSV4OPEN_WDNOTWANTED;
3235 else if (nfsrv_issuedelegs == 0)
3236 *rflagsp |= NFSV4OPEN_WDSUPPFTYPE;
3237 else if (NFSRV_V4DELEGLIMIT(nfsrv_delegatecnt))
3238 *rflagsp |= NFSV4OPEN_WDRESOURCE;
3239 else if (delegate == 0 || (writedeleg == 0 &&
3240 readonly == 0) || !NFSVNO_DELEGOK(vp) ||
3241 (clp->lc_flags & (LCL_CALLBACKSON | LCL_CBDOWN)) !=
3242 LCL_CALLBACKSON)
3243 *rflagsp |= NFSV4OPEN_WDCONTENTION;
3244 else {
3245 new_deleg->ls_stateid.seqid = delegstateidp->seqid = 1;
3246 new_deleg->ls_stateid.other[0] = delegstateidp->other[0]
3247 = clp->lc_clientid.lval[0];
3248 new_deleg->ls_stateid.other[1] = delegstateidp->other[1]
3249 = clp->lc_clientid.lval[1];
3250 new_deleg->ls_stateid.other[2] = delegstateidp->other[2]
3251 = nfsrv_nextstateindex(clp);
3252 if (writedeleg && !NFSVNO_EXRDONLY(exp) &&
3253 (nfsrv_writedelegifpos || !readonly) &&
3254 (new_stp->ls_flags & NFSLCK_WANTRDELEG) == 0) {
3255 new_deleg->ls_flags = (NFSLCK_DELEGWRITE |
3256 NFSLCK_READACCESS | NFSLCK_WRITEACCESS);
3257 *rflagsp |= NFSV4OPEN_WRITEDELEGATE;
3258 nfsrv_writedelegcnt++;
3259 } else {
3260 new_deleg->ls_flags = (NFSLCK_DELEGREAD |
3261 NFSLCK_READACCESS);
3262 *rflagsp |= NFSV4OPEN_READDELEGATE;
3263 }
3264 new_deleg->ls_uid = new_stp->ls_uid;
3265 new_deleg->ls_lfp = lfp;
3266 new_deleg->ls_clp = clp;
3267 new_deleg->ls_filerev = filerev;
3268 new_deleg->ls_compref = nd->nd_compref;
3269 new_deleg->ls_lastrecall = 0;
3270 LIST_INSERT_HEAD(&lfp->lf_deleg, new_deleg, ls_file);
3271 LIST_INSERT_HEAD(NFSSTATEHASH(clp,
3272 new_deleg->ls_stateid), new_deleg, ls_hash);
3273 LIST_INSERT_HEAD(&clp->lc_deleg, new_deleg, ls_list);
3274 new_deleg = NULL;
3275 nfsstatsv1.srvdelegates++;
3276 nfsrv_openpluslock++;
3277 nfsrv_delegatecnt++;
3278 }
3279 }
3280 } else {
3281 /*
3282 * New owner case. Start the open_owner sequence with a
3283 * Needs confirmation (unless a reclaim) and hang the
3284 * new open off it.
3285 */
3286 new_open->ls_stateid.seqid = 1;
3287 new_open->ls_stateid.other[0] = clp->lc_clientid.lval[0];
3288 new_open->ls_stateid.other[1] = clp->lc_clientid.lval[1];
3289 new_open->ls_stateid.other[2] = nfsrv_nextstateindex(clp);
3290 new_open->ls_flags = (new_stp->ls_flags & NFSLCK_SHAREBITS) |
3291 NFSLCK_OPEN;
3292 new_open->ls_uid = new_stp->ls_uid;
3293 LIST_INIT(&new_open->ls_open);
3294 new_open->ls_openowner = new_stp;
3295 new_open->ls_lfp = lfp;
3296 new_open->ls_clp = clp;
3297 LIST_INSERT_HEAD(&lfp->lf_open, new_open, ls_file);
3298 if (new_stp->ls_flags & NFSLCK_RECLAIM) {
3299 new_stp->ls_flags = 0;
3300 } else if ((nd->nd_flag & ND_NFSV41) != 0) {
3301 /* NFSv4.1 never needs confirmation. */
3302 new_stp->ls_flags = 0;
3303
3304 /*
3305 * This is where we can choose to issue a delegation.
3306 */
3307 if (delegate && nfsrv_issuedelegs &&
3308 (writedeleg || readonly) &&
3309 (clp->lc_flags & (LCL_CALLBACKSON | LCL_CBDOWN)) ==
3310 LCL_CALLBACKSON &&
3311 !NFSRV_V4DELEGLIMIT(nfsrv_delegatecnt) &&
3312 NFSVNO_DELEGOK(vp) &&
3313 ((nd->nd_flag & ND_NFSV41) == 0 ||
3314 (new_stp->ls_flags & NFSLCK_WANTNODELEG) == 0)) {
3315 new_deleg->ls_stateid.seqid =
3316 delegstateidp->seqid = 1;
3317 new_deleg->ls_stateid.other[0] =
3318 delegstateidp->other[0]
3319 = clp->lc_clientid.lval[0];
3320 new_deleg->ls_stateid.other[1] =
3321 delegstateidp->other[1]
3322 = clp->lc_clientid.lval[1];
3323 new_deleg->ls_stateid.other[2] =
3324 delegstateidp->other[2]
3325 = nfsrv_nextstateindex(clp);
3326 if (writedeleg && !NFSVNO_EXRDONLY(exp) &&
3327 (nfsrv_writedelegifpos || !readonly) &&
3328 ((nd->nd_flag & ND_NFSV41) == 0 ||
3329 (new_stp->ls_flags & NFSLCK_WANTRDELEG) ==
3330 0)) {
3331 new_deleg->ls_flags =
3332 (NFSLCK_DELEGWRITE |
3333 NFSLCK_READACCESS |
3334 NFSLCK_WRITEACCESS);
3335 *rflagsp |= NFSV4OPEN_WRITEDELEGATE;
3336 nfsrv_writedelegcnt++;
3337 } else {
3338 new_deleg->ls_flags =
3339 (NFSLCK_DELEGREAD |
3340 NFSLCK_READACCESS);
3341 *rflagsp |= NFSV4OPEN_READDELEGATE;
3342 }
3343 new_deleg->ls_uid = new_stp->ls_uid;
3344 new_deleg->ls_lfp = lfp;
3345 new_deleg->ls_clp = clp;
3346 new_deleg->ls_filerev = filerev;
3347 new_deleg->ls_compref = nd->nd_compref;
3348 new_deleg->ls_lastrecall = 0;
3349 LIST_INSERT_HEAD(&lfp->lf_deleg, new_deleg,
3350 ls_file);
3351 LIST_INSERT_HEAD(NFSSTATEHASH(clp,
3352 new_deleg->ls_stateid), new_deleg, ls_hash);
3353 LIST_INSERT_HEAD(&clp->lc_deleg, new_deleg,
3354 ls_list);
3355 new_deleg = NULL;
3356 nfsstatsv1.srvdelegates++;
3357 nfsrv_openpluslock++;
3358 nfsrv_delegatecnt++;
3359 }
3360 /*
3361 * Since NFSv4.1 never does an OpenConfirm, the first
3362 * open state will be acquired here.
3363 */
3364 if (!(clp->lc_flags & LCL_STAMPEDSTABLE)) {
3365 clp->lc_flags |= LCL_STAMPEDSTABLE;
3366 len = clp->lc_idlen;
3367 NFSBCOPY(clp->lc_id, clidp, len);
3368 gotstate = 1;
3369 }
3370 } else {
3371 *rflagsp |= NFSV4OPEN_RESULTCONFIRM;
3372 new_stp->ls_flags = NFSLCK_NEEDSCONFIRM;
3373 }
3374 nfsrvd_refcache(new_stp->ls_op);
3375 new_stp->ls_noopens = 0;
3376 LIST_INIT(&new_stp->ls_open);
3377 LIST_INSERT_HEAD(&new_stp->ls_open, new_open, ls_list);
3378 LIST_INSERT_HEAD(&clp->lc_open, new_stp, ls_list);
3379 LIST_INSERT_HEAD(NFSSTATEHASH(clp, new_open->ls_stateid),
3380 new_open, ls_hash);
3381 openstp = new_open;
3382 new_open = NULL;
3383 *new_stpp = NULL;
3384 nfsstatsv1.srvopens++;
3385 nfsrv_openpluslock++;
3386 nfsstatsv1.srvopenowners++;
3387 nfsrv_openpluslock++;
3388 }
3389 if (!error) {
3390 stateidp->seqid = openstp->ls_stateid.seqid;
3391 stateidp->other[0] = openstp->ls_stateid.other[0];
3392 stateidp->other[1] = openstp->ls_stateid.other[1];
3393 stateidp->other[2] = openstp->ls_stateid.other[2];
3394 }
3395 NFSUNLOCKSTATE();
3396 if (haslock) {
3397 NFSLOCKV4ROOTMUTEX();
3398 nfsv4_unlock(&nfsv4rootfs_lock, 1);
3399 NFSUNLOCKV4ROOTMUTEX();
3400 }
3401 if (new_open)
3402 free(new_open, M_NFSDSTATE);
3403 if (new_deleg)
3404 free(new_deleg, M_NFSDSTATE);
3405
3406 /*
3407 * If the NFSv4.1 client just acquired its first open, write a timestamp
3408 * to the stable storage file.
3409 */
3410 if (gotstate != 0) {
3411 nfsrv_writestable(clidp, len, NFSNST_NEWSTATE, p);
3412 nfsrv_backupstable();
3413 }
3414
3415 out:
3416 free(clidp, M_TEMP);
3417 NFSEXITCODE2(error, nd);
3418 return (error);
3419 }
3420
3421 /*
3422 * Open update. Does the confirm, downgrade and close.
3423 */
3424 int
nfsrv_openupdate(vnode_t vp,struct nfsstate * new_stp,nfsquad_t clientid,nfsv4stateid_t * stateidp,struct nfsrv_descript * nd,NFSPROC_T * p,int * retwriteaccessp)3425 nfsrv_openupdate(vnode_t vp, struct nfsstate *new_stp, nfsquad_t clientid,
3426 nfsv4stateid_t *stateidp, struct nfsrv_descript *nd, NFSPROC_T *p,
3427 int *retwriteaccessp)
3428 {
3429 struct nfsstate *stp;
3430 struct nfsclient *clp;
3431 struct nfslockfile *lfp;
3432 u_int32_t bits;
3433 int error = 0, gotstate = 0, len = 0;
3434 u_char *clidp = NULL;
3435
3436 /*
3437 * Check for restart conditions (client and server).
3438 */
3439 error = nfsrv_checkrestart(clientid, new_stp->ls_flags,
3440 &new_stp->ls_stateid, 0);
3441 if (error)
3442 goto out;
3443
3444 clidp = malloc(NFSV4_OPAQUELIMIT, M_TEMP, M_WAITOK);
3445 NFSLOCKSTATE();
3446 /*
3447 * Get the open structure via clientid and stateid.
3448 */
3449 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
3450 (nfsquad_t)((u_quad_t)0), 0, nd, p);
3451 if (!error)
3452 error = nfsrv_getstate(clp, &new_stp->ls_stateid,
3453 new_stp->ls_flags, &stp);
3454
3455 /*
3456 * Sanity check the open.
3457 */
3458 if (!error && (!(stp->ls_flags & NFSLCK_OPEN) ||
3459 (!(new_stp->ls_flags & NFSLCK_CONFIRM) &&
3460 (stp->ls_openowner->ls_flags & NFSLCK_NEEDSCONFIRM)) ||
3461 ((new_stp->ls_flags & NFSLCK_CONFIRM) &&
3462 (!(stp->ls_openowner->ls_flags & NFSLCK_NEEDSCONFIRM)))))
3463 error = NFSERR_BADSTATEID;
3464
3465 if (!error)
3466 error = nfsrv_checkseqid(nd, new_stp->ls_seq,
3467 stp->ls_openowner, new_stp->ls_op);
3468 if (!error && stp->ls_stateid.seqid != new_stp->ls_stateid.seqid &&
3469 (((nd->nd_flag & ND_NFSV41) == 0 &&
3470 !(new_stp->ls_flags & NFSLCK_CONFIRM)) ||
3471 ((nd->nd_flag & ND_NFSV41) != 0 &&
3472 new_stp->ls_stateid.seqid != 0)))
3473 error = NFSERR_OLDSTATEID;
3474 if (!error && vnode_vtype(vp) != VREG) {
3475 if (vnode_vtype(vp) == VDIR)
3476 error = NFSERR_ISDIR;
3477 else
3478 error = NFSERR_INVAL;
3479 }
3480
3481 if (error) {
3482 /*
3483 * If a client tries to confirm an Open with a bad
3484 * seqid# and there are no byte range locks or other Opens
3485 * on the openowner, just throw it away, so the next use of the
3486 * openowner will start a fresh seq#.
3487 */
3488 if (error == NFSERR_BADSEQID &&
3489 (new_stp->ls_flags & NFSLCK_CONFIRM) &&
3490 nfsrv_nootherstate(stp))
3491 nfsrv_freeopenowner(stp->ls_openowner, 0, p);
3492 NFSUNLOCKSTATE();
3493 goto out;
3494 }
3495
3496 /*
3497 * Set the return stateid.
3498 */
3499 stateidp->seqid = stp->ls_stateid.seqid + 1;
3500 if ((nd->nd_flag & ND_NFSV41) != 0 && stateidp->seqid == 0)
3501 stateidp->seqid = 1;
3502 stateidp->other[0] = stp->ls_stateid.other[0];
3503 stateidp->other[1] = stp->ls_stateid.other[1];
3504 stateidp->other[2] = stp->ls_stateid.other[2];
3505 /*
3506 * Now, handle the three cases.
3507 */
3508 if (new_stp->ls_flags & NFSLCK_CONFIRM) {
3509 /*
3510 * If the open doesn't need confirmation, it seems to me that
3511 * there is a client error, but I'll just log it and keep going?
3512 */
3513 if (!(stp->ls_openowner->ls_flags & NFSLCK_NEEDSCONFIRM))
3514 printf("Nfsv4d: stray open confirm\n");
3515 stp->ls_openowner->ls_flags = 0;
3516 stp->ls_stateid.seqid++;
3517 if ((nd->nd_flag & ND_NFSV41) != 0 &&
3518 stp->ls_stateid.seqid == 0)
3519 stp->ls_stateid.seqid = 1;
3520 if (!(clp->lc_flags & LCL_STAMPEDSTABLE)) {
3521 clp->lc_flags |= LCL_STAMPEDSTABLE;
3522 len = clp->lc_idlen;
3523 NFSBCOPY(clp->lc_id, clidp, len);
3524 gotstate = 1;
3525 }
3526 NFSUNLOCKSTATE();
3527 } else if (new_stp->ls_flags & NFSLCK_CLOSE) {
3528 lfp = stp->ls_lfp;
3529 if (retwriteaccessp != NULL) {
3530 if ((stp->ls_flags & NFSLCK_WRITEACCESS) != 0)
3531 *retwriteaccessp = 1;
3532 else
3533 *retwriteaccessp = 0;
3534 }
3535 if (nfsrv_dolocallocks != 0 && !LIST_EMPTY(&stp->ls_open)) {
3536 /* Get the lf lock */
3537 nfsrv_locklf(lfp);
3538 NFSUNLOCKSTATE();
3539 ASSERT_VOP_ELOCKED(vp, "nfsrv_openupdate");
3540 NFSVOPUNLOCK(vp);
3541 if (nfsrv_freeopen(stp, vp, 1, p) == 0) {
3542 NFSLOCKSTATE();
3543 nfsrv_unlocklf(lfp);
3544 NFSUNLOCKSTATE();
3545 }
3546 NFSVOPLOCK(vp, LK_EXCLUSIVE | LK_RETRY);
3547 } else {
3548 (void) nfsrv_freeopen(stp, NULL, 0, p);
3549 NFSUNLOCKSTATE();
3550 }
3551 } else {
3552 /*
3553 * Update the share bits, making sure that the new set are a
3554 * subset of the old ones.
3555 */
3556 bits = (new_stp->ls_flags & NFSLCK_SHAREBITS);
3557 if (~(stp->ls_flags) & bits) {
3558 NFSUNLOCKSTATE();
3559 error = NFSERR_INVAL;
3560 goto out;
3561 }
3562 stp->ls_flags = (bits | NFSLCK_OPEN);
3563 stp->ls_stateid.seqid++;
3564 if ((nd->nd_flag & ND_NFSV41) != 0 &&
3565 stp->ls_stateid.seqid == 0)
3566 stp->ls_stateid.seqid = 1;
3567 NFSUNLOCKSTATE();
3568 }
3569
3570 /*
3571 * If the client just confirmed its first open, write a timestamp
3572 * to the stable storage file.
3573 */
3574 if (gotstate != 0) {
3575 nfsrv_writestable(clidp, len, NFSNST_NEWSTATE, p);
3576 nfsrv_backupstable();
3577 }
3578
3579 out:
3580 free(clidp, M_TEMP);
3581 NFSEXITCODE2(error, nd);
3582 return (error);
3583 }
3584
3585 /*
3586 * Delegation update. Does the purge and return.
3587 */
3588 int
nfsrv_delegupdate(struct nfsrv_descript * nd,nfsquad_t clientid,nfsv4stateid_t * stateidp,vnode_t vp,int op,struct ucred * cred,NFSPROC_T * p,int * retwriteaccessp)3589 nfsrv_delegupdate(struct nfsrv_descript *nd, nfsquad_t clientid,
3590 nfsv4stateid_t *stateidp, vnode_t vp, int op, struct ucred *cred,
3591 NFSPROC_T *p, int *retwriteaccessp)
3592 {
3593 struct nfsstate *stp;
3594 struct nfsclient *clp;
3595 int error = 0;
3596 fhandle_t fh;
3597
3598 /*
3599 * Do a sanity check against the file handle for DelegReturn.
3600 */
3601 if (vp) {
3602 error = nfsvno_getfh(vp, &fh, p);
3603 if (error)
3604 goto out;
3605 }
3606 /*
3607 * Check for restart conditions (client and server).
3608 */
3609 if (op == NFSV4OP_DELEGRETURN)
3610 error = nfsrv_checkrestart(clientid, NFSLCK_DELEGRETURN,
3611 stateidp, 0);
3612 else
3613 error = nfsrv_checkrestart(clientid, NFSLCK_DELEGPURGE,
3614 stateidp, 0);
3615
3616 NFSLOCKSTATE();
3617 /*
3618 * Get the open structure via clientid and stateid.
3619 */
3620 if (!error)
3621 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
3622 (nfsquad_t)((u_quad_t)0), 0, nd, p);
3623 if (error) {
3624 if (error == NFSERR_CBPATHDOWN)
3625 error = 0;
3626 if (error == NFSERR_STALECLIENTID && op == NFSV4OP_DELEGRETURN)
3627 error = NFSERR_STALESTATEID;
3628 }
3629 if (!error && op == NFSV4OP_DELEGRETURN) {
3630 error = nfsrv_getstate(clp, stateidp, NFSLCK_DELEGRETURN, &stp);
3631 if (!error && stp->ls_stateid.seqid != stateidp->seqid &&
3632 ((nd->nd_flag & ND_NFSV41) == 0 || stateidp->seqid != 0))
3633 error = NFSERR_OLDSTATEID;
3634 }
3635 /*
3636 * NFSERR_EXPIRED means that the state has gone away,
3637 * so Delegations have been purged. Just return ok.
3638 */
3639 if (error == NFSERR_EXPIRED && op == NFSV4OP_DELEGPURGE) {
3640 NFSUNLOCKSTATE();
3641 error = 0;
3642 goto out;
3643 }
3644 if (error) {
3645 NFSUNLOCKSTATE();
3646 goto out;
3647 }
3648
3649 if (op == NFSV4OP_DELEGRETURN) {
3650 if (NFSBCMP((caddr_t)&fh, (caddr_t)&stp->ls_lfp->lf_fh,
3651 sizeof (fhandle_t))) {
3652 NFSUNLOCKSTATE();
3653 error = NFSERR_BADSTATEID;
3654 goto out;
3655 }
3656 if (retwriteaccessp != NULL) {
3657 if ((stp->ls_flags & NFSLCK_DELEGWRITE) != 0)
3658 *retwriteaccessp = 1;
3659 else
3660 *retwriteaccessp = 0;
3661 }
3662 nfsrv_freedeleg(stp);
3663 } else {
3664 nfsrv_freedeleglist(&clp->lc_olddeleg);
3665 }
3666 NFSUNLOCKSTATE();
3667 error = 0;
3668
3669 out:
3670 NFSEXITCODE(error);
3671 return (error);
3672 }
3673
3674 /*
3675 * Release lock owner.
3676 */
3677 int
nfsrv_releaselckown(struct nfsstate * new_stp,nfsquad_t clientid,NFSPROC_T * p)3678 nfsrv_releaselckown(struct nfsstate *new_stp, nfsquad_t clientid,
3679 NFSPROC_T *p)
3680 {
3681 struct nfsstate *stp, *nstp, *openstp, *ownstp;
3682 struct nfsclient *clp;
3683 int error = 0;
3684
3685 /*
3686 * Check for restart conditions (client and server).
3687 */
3688 error = nfsrv_checkrestart(clientid, new_stp->ls_flags,
3689 &new_stp->ls_stateid, 0);
3690 if (error)
3691 goto out;
3692
3693 NFSLOCKSTATE();
3694 /*
3695 * Get the lock owner by name.
3696 */
3697 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
3698 (nfsquad_t)((u_quad_t)0), 0, NULL, p);
3699 if (error) {
3700 NFSUNLOCKSTATE();
3701 goto out;
3702 }
3703 LIST_FOREACH(ownstp, &clp->lc_open, ls_list) {
3704 LIST_FOREACH(openstp, &ownstp->ls_open, ls_list) {
3705 stp = LIST_FIRST(&openstp->ls_open);
3706 while (stp != LIST_END(&openstp->ls_open)) {
3707 nstp = LIST_NEXT(stp, ls_list);
3708 /*
3709 * If the owner matches, check for locks and
3710 * then free or return an error.
3711 */
3712 if (stp->ls_ownerlen == new_stp->ls_ownerlen &&
3713 !NFSBCMP(stp->ls_owner, new_stp->ls_owner,
3714 stp->ls_ownerlen)){
3715 if (LIST_EMPTY(&stp->ls_lock)) {
3716 nfsrv_freelockowner(stp, NULL, 0, p);
3717 } else {
3718 NFSUNLOCKSTATE();
3719 error = NFSERR_LOCKSHELD;
3720 goto out;
3721 }
3722 }
3723 stp = nstp;
3724 }
3725 }
3726 }
3727 NFSUNLOCKSTATE();
3728
3729 out:
3730 NFSEXITCODE(error);
3731 return (error);
3732 }
3733
3734 /*
3735 * Get the file handle for a lock structure.
3736 */
3737 static int
nfsrv_getlockfh(vnode_t vp,u_short flags,struct nfslockfile * new_lfp,fhandle_t * nfhp,NFSPROC_T * p)3738 nfsrv_getlockfh(vnode_t vp, u_short flags, struct nfslockfile *new_lfp,
3739 fhandle_t *nfhp, NFSPROC_T *p)
3740 {
3741 fhandle_t *fhp = NULL;
3742 int error;
3743
3744 /*
3745 * For lock, use the new nfslock structure, otherwise just
3746 * a fhandle_t on the stack.
3747 */
3748 if (flags & NFSLCK_OPEN) {
3749 KASSERT(new_lfp != NULL, ("nfsrv_getlockfh: new_lfp NULL"));
3750 fhp = &new_lfp->lf_fh;
3751 } else if (nfhp) {
3752 fhp = nfhp;
3753 } else {
3754 panic("nfsrv_getlockfh");
3755 }
3756 error = nfsvno_getfh(vp, fhp, p);
3757 NFSEXITCODE(error);
3758 return (error);
3759 }
3760
3761 /*
3762 * Get an nfs lock structure. Allocate one, as required, and return a
3763 * pointer to it.
3764 * Returns an NFSERR_xxx upon failure or -1 to indicate no current lock.
3765 */
3766 static int
nfsrv_getlockfile(u_short flags,struct nfslockfile ** new_lfpp,struct nfslockfile ** lfpp,fhandle_t * nfhp,int lockit)3767 nfsrv_getlockfile(u_short flags, struct nfslockfile **new_lfpp,
3768 struct nfslockfile **lfpp, fhandle_t *nfhp, int lockit)
3769 {
3770 struct nfslockfile *lfp;
3771 fhandle_t *fhp = NULL, *tfhp;
3772 struct nfslockhashhead *hp;
3773 struct nfslockfile *new_lfp = NULL;
3774
3775 /*
3776 * For lock, use the new nfslock structure, otherwise just
3777 * a fhandle_t on the stack.
3778 */
3779 if (flags & NFSLCK_OPEN) {
3780 new_lfp = *new_lfpp;
3781 fhp = &new_lfp->lf_fh;
3782 } else if (nfhp) {
3783 fhp = nfhp;
3784 } else {
3785 panic("nfsrv_getlockfile");
3786 }
3787
3788 hp = NFSLOCKHASH(fhp);
3789 LIST_FOREACH(lfp, hp, lf_hash) {
3790 tfhp = &lfp->lf_fh;
3791 if (NFSVNO_CMPFH(fhp, tfhp)) {
3792 if (lockit)
3793 nfsrv_locklf(lfp);
3794 *lfpp = lfp;
3795 return (0);
3796 }
3797 }
3798 if (!(flags & NFSLCK_OPEN))
3799 return (-1);
3800
3801 /*
3802 * No match, so chain the new one into the list.
3803 */
3804 LIST_INIT(&new_lfp->lf_open);
3805 LIST_INIT(&new_lfp->lf_lock);
3806 LIST_INIT(&new_lfp->lf_deleg);
3807 LIST_INIT(&new_lfp->lf_locallock);
3808 LIST_INIT(&new_lfp->lf_rollback);
3809 new_lfp->lf_locallock_lck.nfslock_usecnt = 0;
3810 new_lfp->lf_locallock_lck.nfslock_lock = 0;
3811 new_lfp->lf_usecount = 0;
3812 LIST_INSERT_HEAD(hp, new_lfp, lf_hash);
3813 *lfpp = new_lfp;
3814 *new_lfpp = NULL;
3815 return (0);
3816 }
3817
3818 /*
3819 * This function adds a nfslock lock structure to the list for the associated
3820 * nfsstate and nfslockfile structures. It will be inserted after the
3821 * entry pointed at by insert_lop.
3822 */
3823 static void
nfsrv_insertlock(struct nfslock * new_lop,struct nfslock * insert_lop,struct nfsstate * stp,struct nfslockfile * lfp)3824 nfsrv_insertlock(struct nfslock *new_lop, struct nfslock *insert_lop,
3825 struct nfsstate *stp, struct nfslockfile *lfp)
3826 {
3827 struct nfslock *lop, *nlop;
3828
3829 new_lop->lo_stp = stp;
3830 new_lop->lo_lfp = lfp;
3831
3832 if (stp != NULL) {
3833 /* Insert in increasing lo_first order */
3834 lop = LIST_FIRST(&lfp->lf_lock);
3835 if (lop == LIST_END(&lfp->lf_lock) ||
3836 new_lop->lo_first <= lop->lo_first) {
3837 LIST_INSERT_HEAD(&lfp->lf_lock, new_lop, lo_lckfile);
3838 } else {
3839 nlop = LIST_NEXT(lop, lo_lckfile);
3840 while (nlop != LIST_END(&lfp->lf_lock) &&
3841 nlop->lo_first < new_lop->lo_first) {
3842 lop = nlop;
3843 nlop = LIST_NEXT(lop, lo_lckfile);
3844 }
3845 LIST_INSERT_AFTER(lop, new_lop, lo_lckfile);
3846 }
3847 } else {
3848 new_lop->lo_lckfile.le_prev = NULL; /* list not used */
3849 }
3850
3851 /*
3852 * Insert after insert_lop, which is overloaded as stp or lfp for
3853 * an empty list.
3854 */
3855 if (stp == NULL && (struct nfslockfile *)insert_lop == lfp)
3856 LIST_INSERT_HEAD(&lfp->lf_locallock, new_lop, lo_lckowner);
3857 else if ((struct nfsstate *)insert_lop == stp)
3858 LIST_INSERT_HEAD(&stp->ls_lock, new_lop, lo_lckowner);
3859 else
3860 LIST_INSERT_AFTER(insert_lop, new_lop, lo_lckowner);
3861 if (stp != NULL) {
3862 nfsstatsv1.srvlocks++;
3863 nfsrv_openpluslock++;
3864 }
3865 }
3866
3867 /*
3868 * This function updates the locking for a lock owner and given file. It
3869 * maintains a list of lock ranges ordered on increasing file offset that
3870 * are NFSLCK_READ or NFSLCK_WRITE and non-overlapping (aka POSIX style).
3871 * It always adds new_lop to the list and sometimes uses the one pointed
3872 * at by other_lopp.
3873 */
3874 static void
nfsrv_updatelock(struct nfsstate * stp,struct nfslock ** new_lopp,struct nfslock ** other_lopp,struct nfslockfile * lfp)3875 nfsrv_updatelock(struct nfsstate *stp, struct nfslock **new_lopp,
3876 struct nfslock **other_lopp, struct nfslockfile *lfp)
3877 {
3878 struct nfslock *new_lop = *new_lopp;
3879 struct nfslock *lop, *tlop, *ilop;
3880 struct nfslock *other_lop = *other_lopp;
3881 int unlock = 0, myfile = 0;
3882 u_int64_t tmp;
3883
3884 /*
3885 * Work down the list until the lock is merged.
3886 */
3887 if (new_lop->lo_flags & NFSLCK_UNLOCK)
3888 unlock = 1;
3889 if (stp != NULL) {
3890 ilop = (struct nfslock *)stp;
3891 lop = LIST_FIRST(&stp->ls_lock);
3892 } else {
3893 ilop = (struct nfslock *)lfp;
3894 lop = LIST_FIRST(&lfp->lf_locallock);
3895 }
3896 while (lop != NULL) {
3897 /*
3898 * Only check locks for this file that aren't before the start of
3899 * new lock's range.
3900 */
3901 if (lop->lo_lfp == lfp) {
3902 myfile = 1;
3903 if (lop->lo_end >= new_lop->lo_first) {
3904 if (new_lop->lo_end < lop->lo_first) {
3905 /*
3906 * If the new lock ends before the start of the
3907 * current lock's range, no merge, just insert
3908 * the new lock.
3909 */
3910 break;
3911 }
3912 if (new_lop->lo_flags == lop->lo_flags ||
3913 (new_lop->lo_first <= lop->lo_first &&
3914 new_lop->lo_end >= lop->lo_end)) {
3915 /*
3916 * This lock can be absorbed by the new lock/unlock.
3917 * This happens when it covers the entire range
3918 * of the old lock or is contiguous
3919 * with the old lock and is of the same type or an
3920 * unlock.
3921 */
3922 if (lop->lo_first < new_lop->lo_first)
3923 new_lop->lo_first = lop->lo_first;
3924 if (lop->lo_end > new_lop->lo_end)
3925 new_lop->lo_end = lop->lo_end;
3926 tlop = lop;
3927 lop = LIST_NEXT(lop, lo_lckowner);
3928 nfsrv_freenfslock(tlop);
3929 continue;
3930 }
3931
3932 /*
3933 * All these cases are for contiguous locks that are not the
3934 * same type, so they can't be merged.
3935 */
3936 if (new_lop->lo_first <= lop->lo_first) {
3937 /*
3938 * This case is where the new lock overlaps with the
3939 * first part of the old lock. Move the start of the
3940 * old lock to just past the end of the new lock. The
3941 * new lock will be inserted in front of the old, since
3942 * ilop hasn't been updated. (We are done now.)
3943 */
3944 lop->lo_first = new_lop->lo_end;
3945 break;
3946 }
3947 if (new_lop->lo_end >= lop->lo_end) {
3948 /*
3949 * This case is where the new lock overlaps with the
3950 * end of the old lock's range. Move the old lock's
3951 * end to just before the new lock's first and insert
3952 * the new lock after the old lock.
3953 * Might not be done yet, since the new lock could
3954 * overlap further locks with higher ranges.
3955 */
3956 lop->lo_end = new_lop->lo_first;
3957 ilop = lop;
3958 lop = LIST_NEXT(lop, lo_lckowner);
3959 continue;
3960 }
3961 /*
3962 * The final case is where the new lock's range is in the
3963 * middle of the current lock's and splits the current lock
3964 * up. Use *other_lopp to handle the second part of the
3965 * split old lock range. (We are done now.)
3966 * For unlock, we use new_lop as other_lop and tmp, since
3967 * other_lop and new_lop are the same for this case.
3968 * We noted the unlock case above, so we don't need
3969 * new_lop->lo_flags any longer.
3970 */
3971 tmp = new_lop->lo_first;
3972 if (other_lop == NULL) {
3973 if (!unlock)
3974 panic("nfsd srv update unlock");
3975 other_lop = new_lop;
3976 *new_lopp = NULL;
3977 }
3978 other_lop->lo_first = new_lop->lo_end;
3979 other_lop->lo_end = lop->lo_end;
3980 other_lop->lo_flags = lop->lo_flags;
3981 other_lop->lo_stp = stp;
3982 other_lop->lo_lfp = lfp;
3983 lop->lo_end = tmp;
3984 nfsrv_insertlock(other_lop, lop, stp, lfp);
3985 *other_lopp = NULL;
3986 ilop = lop;
3987 break;
3988 }
3989 }
3990 ilop = lop;
3991 lop = LIST_NEXT(lop, lo_lckowner);
3992 if (myfile && (lop == NULL || lop->lo_lfp != lfp))
3993 break;
3994 }
3995
3996 /*
3997 * Insert the new lock in the list at the appropriate place.
3998 */
3999 if (!unlock) {
4000 nfsrv_insertlock(new_lop, ilop, stp, lfp);
4001 *new_lopp = NULL;
4002 }
4003 }
4004
4005 /*
4006 * This function handles sequencing of locks, etc.
4007 * It returns an error that indicates what the caller should do.
4008 */
4009 static int
nfsrv_checkseqid(struct nfsrv_descript * nd,u_int32_t seqid,struct nfsstate * stp,struct nfsrvcache * op)4010 nfsrv_checkseqid(struct nfsrv_descript *nd, u_int32_t seqid,
4011 struct nfsstate *stp, struct nfsrvcache *op)
4012 {
4013 int error = 0;
4014
4015 if ((nd->nd_flag & ND_NFSV41) != 0)
4016 /* NFSv4.1 ignores the open_seqid and lock_seqid. */
4017 goto out;
4018 if (op != nd->nd_rp)
4019 panic("nfsrvstate checkseqid");
4020 if (!(op->rc_flag & RC_INPROG))
4021 panic("nfsrvstate not inprog");
4022 if (stp->ls_op && stp->ls_op->rc_refcnt <= 0) {
4023 printf("refcnt=%d\n", stp->ls_op->rc_refcnt);
4024 panic("nfsrvstate op refcnt");
4025 }
4026
4027 /* If ND_ERELOOKUP is set, the seqid has already been handled. */
4028 if ((nd->nd_flag & ND_ERELOOKUP) != 0)
4029 goto out;
4030
4031 if ((stp->ls_seq + 1) == seqid) {
4032 if (stp->ls_op)
4033 nfsrvd_derefcache(stp->ls_op);
4034 stp->ls_op = op;
4035 nfsrvd_refcache(op);
4036 stp->ls_seq = seqid;
4037 goto out;
4038 } else if (stp->ls_seq == seqid && stp->ls_op &&
4039 op->rc_xid == stp->ls_op->rc_xid &&
4040 op->rc_refcnt == 0 &&
4041 op->rc_reqlen == stp->ls_op->rc_reqlen &&
4042 op->rc_cksum == stp->ls_op->rc_cksum) {
4043 if (stp->ls_op->rc_flag & RC_INPROG) {
4044 error = NFSERR_DONTREPLY;
4045 goto out;
4046 }
4047 nd->nd_rp = stp->ls_op;
4048 nd->nd_rp->rc_flag |= RC_INPROG;
4049 nfsrvd_delcache(op);
4050 error = NFSERR_REPLYFROMCACHE;
4051 goto out;
4052 }
4053 error = NFSERR_BADSEQID;
4054
4055 out:
4056 NFSEXITCODE2(error, nd);
4057 return (error);
4058 }
4059
4060 /*
4061 * Get the client ip address for callbacks. If the strings can't be parsed,
4062 * just set lc_program to 0 to indicate no callbacks are possible.
4063 * (For cases where the address can't be parsed or is 0.0.0.0.0.0, set
4064 * the address to the client's transport address. This won't be used
4065 * for callbacks, but can be printed out by nfsstats for info.)
4066 * Return error if the xdr can't be parsed, 0 otherwise.
4067 */
4068 int
nfsrv_getclientipaddr(struct nfsrv_descript * nd,struct nfsclient * clp)4069 nfsrv_getclientipaddr(struct nfsrv_descript *nd, struct nfsclient *clp)
4070 {
4071 u_int32_t *tl;
4072 u_char *cp, *cp2;
4073 int i, j, maxalen = 0, minalen = 0;
4074 sa_family_t af;
4075 #ifdef INET
4076 struct sockaddr_in *rin = NULL, *sin;
4077 #endif
4078 #ifdef INET6
4079 struct sockaddr_in6 *rin6 = NULL, *sin6;
4080 #endif
4081 u_char *addr;
4082 int error = 0, cantparse = 0;
4083 union {
4084 in_addr_t ival;
4085 u_char cval[4];
4086 } ip;
4087 union {
4088 in_port_t sval;
4089 u_char cval[2];
4090 } port;
4091
4092 /* 8 is the maximum length of the port# string. */
4093 addr = malloc(INET6_ADDRSTRLEN + 8, M_TEMP, M_WAITOK);
4094 clp->lc_req.nr_client = NULL;
4095 clp->lc_req.nr_lock = 0;
4096 af = AF_UNSPEC;
4097 NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
4098 i = fxdr_unsigned(int, *tl);
4099 if (i >= 3 && i <= 4) {
4100 error = nfsrv_mtostr(nd, addr, i);
4101 if (error)
4102 goto nfsmout;
4103 #ifdef INET
4104 if (!strcmp(addr, "tcp")) {
4105 clp->lc_flags |= LCL_TCPCALLBACK;
4106 clp->lc_req.nr_sotype = SOCK_STREAM;
4107 clp->lc_req.nr_soproto = IPPROTO_TCP;
4108 af = AF_INET;
4109 } else if (!strcmp(addr, "udp")) {
4110 clp->lc_req.nr_sotype = SOCK_DGRAM;
4111 clp->lc_req.nr_soproto = IPPROTO_UDP;
4112 af = AF_INET;
4113 }
4114 #endif
4115 #ifdef INET6
4116 if (af == AF_UNSPEC) {
4117 if (!strcmp(addr, "tcp6")) {
4118 clp->lc_flags |= LCL_TCPCALLBACK;
4119 clp->lc_req.nr_sotype = SOCK_STREAM;
4120 clp->lc_req.nr_soproto = IPPROTO_TCP;
4121 af = AF_INET6;
4122 } else if (!strcmp(addr, "udp6")) {
4123 clp->lc_req.nr_sotype = SOCK_DGRAM;
4124 clp->lc_req.nr_soproto = IPPROTO_UDP;
4125 af = AF_INET6;
4126 }
4127 }
4128 #endif
4129 if (af == AF_UNSPEC) {
4130 cantparse = 1;
4131 }
4132 } else {
4133 cantparse = 1;
4134 if (i > 0) {
4135 error = nfsm_advance(nd, NFSM_RNDUP(i), -1);
4136 if (error)
4137 goto nfsmout;
4138 }
4139 }
4140 /*
4141 * The caller has allocated clp->lc_req.nr_nam to be large enough
4142 * for either AF_INET or AF_INET6 and zeroed out the contents.
4143 * maxalen is set to the maximum length of the host IP address string
4144 * plus 8 for the maximum length of the port#.
4145 * minalen is set to the minimum length of the host IP address string
4146 * plus 4 for the minimum length of the port#.
4147 * These lengths do not include NULL termination,
4148 * so INET[6]_ADDRSTRLEN - 1 is used in the calculations.
4149 */
4150 switch (af) {
4151 #ifdef INET
4152 case AF_INET:
4153 rin = (struct sockaddr_in *)clp->lc_req.nr_nam;
4154 rin->sin_family = AF_INET;
4155 rin->sin_len = sizeof(struct sockaddr_in);
4156 maxalen = INET_ADDRSTRLEN - 1 + 8;
4157 minalen = 7 + 4;
4158 break;
4159 #endif
4160 #ifdef INET6
4161 case AF_INET6:
4162 rin6 = (struct sockaddr_in6 *)clp->lc_req.nr_nam;
4163 rin6->sin6_family = AF_INET6;
4164 rin6->sin6_len = sizeof(struct sockaddr_in6);
4165 maxalen = INET6_ADDRSTRLEN - 1 + 8;
4166 minalen = 3 + 4;
4167 break;
4168 #endif
4169 }
4170 NFSM_DISSECT(tl, u_int32_t *, NFSX_UNSIGNED);
4171 i = fxdr_unsigned(int, *tl);
4172 if (i < 0) {
4173 error = NFSERR_BADXDR;
4174 goto nfsmout;
4175 } else if (i == 0) {
4176 cantparse = 1;
4177 } else if (!cantparse && i <= maxalen && i >= minalen) {
4178 error = nfsrv_mtostr(nd, addr, i);
4179 if (error)
4180 goto nfsmout;
4181
4182 /*
4183 * Parse out the address fields. We expect 6 decimal numbers
4184 * separated by '.'s for AF_INET and two decimal numbers
4185 * preceeded by '.'s for AF_INET6.
4186 */
4187 cp = NULL;
4188 switch (af) {
4189 #ifdef INET6
4190 /*
4191 * For AF_INET6, first parse the host address.
4192 */
4193 case AF_INET6:
4194 cp = strchr(addr, '.');
4195 if (cp != NULL) {
4196 *cp++ = '\0';
4197 if (inet_pton(af, addr, &rin6->sin6_addr) == 1)
4198 i = 4;
4199 else {
4200 cp = NULL;
4201 cantparse = 1;
4202 }
4203 }
4204 break;
4205 #endif
4206 #ifdef INET
4207 case AF_INET:
4208 cp = addr;
4209 i = 0;
4210 break;
4211 #endif
4212 }
4213 while (cp != NULL && *cp && i < 6) {
4214 cp2 = cp;
4215 while (*cp2 && *cp2 != '.')
4216 cp2++;
4217 if (*cp2)
4218 *cp2++ = '\0';
4219 else if (i != 5) {
4220 cantparse = 1;
4221 break;
4222 }
4223 j = nfsrv_getipnumber(cp);
4224 if (j >= 0) {
4225 if (i < 4)
4226 ip.cval[3 - i] = j;
4227 else
4228 port.cval[5 - i] = j;
4229 } else {
4230 cantparse = 1;
4231 break;
4232 }
4233 cp = cp2;
4234 i++;
4235 }
4236 if (!cantparse) {
4237 /*
4238 * The host address INADDR_ANY is (mis)used to indicate
4239 * "there is no valid callback address".
4240 */
4241 switch (af) {
4242 #ifdef INET6
4243 case AF_INET6:
4244 if (!IN6_ARE_ADDR_EQUAL(&rin6->sin6_addr,
4245 &in6addr_any))
4246 rin6->sin6_port = htons(port.sval);
4247 else
4248 cantparse = 1;
4249 break;
4250 #endif
4251 #ifdef INET
4252 case AF_INET:
4253 if (ip.ival != INADDR_ANY) {
4254 rin->sin_addr.s_addr = htonl(ip.ival);
4255 rin->sin_port = htons(port.sval);
4256 } else {
4257 cantparse = 1;
4258 }
4259 break;
4260 #endif
4261 }
4262 }
4263 } else {
4264 cantparse = 1;
4265 if (i > 0) {
4266 error = nfsm_advance(nd, NFSM_RNDUP(i), -1);
4267 if (error)
4268 goto nfsmout;
4269 }
4270 }
4271 if (cantparse) {
4272 switch (nd->nd_nam->sa_family) {
4273 #ifdef INET
4274 case AF_INET:
4275 sin = (struct sockaddr_in *)nd->nd_nam;
4276 rin = (struct sockaddr_in *)clp->lc_req.nr_nam;
4277 rin->sin_family = AF_INET;
4278 rin->sin_len = sizeof(struct sockaddr_in);
4279 rin->sin_addr.s_addr = sin->sin_addr.s_addr;
4280 rin->sin_port = 0x0;
4281 break;
4282 #endif
4283 #ifdef INET6
4284 case AF_INET6:
4285 sin6 = (struct sockaddr_in6 *)nd->nd_nam;
4286 rin6 = (struct sockaddr_in6 *)clp->lc_req.nr_nam;
4287 rin6->sin6_family = AF_INET6;
4288 rin6->sin6_len = sizeof(struct sockaddr_in6);
4289 rin6->sin6_addr = sin6->sin6_addr;
4290 rin6->sin6_port = 0x0;
4291 break;
4292 #endif
4293 }
4294 clp->lc_program = 0;
4295 }
4296 nfsmout:
4297 free(addr, M_TEMP);
4298 NFSEXITCODE2(error, nd);
4299 return (error);
4300 }
4301
4302 /*
4303 * Turn a string of up to three decimal digits into a number. Return -1 upon
4304 * error.
4305 */
4306 static int
nfsrv_getipnumber(u_char * cp)4307 nfsrv_getipnumber(u_char *cp)
4308 {
4309 int i = 0, j = 0;
4310
4311 while (*cp) {
4312 if (j > 2 || *cp < '0' || *cp > '9')
4313 return (-1);
4314 i *= 10;
4315 i += (*cp - '0');
4316 cp++;
4317 j++;
4318 }
4319 if (i < 256)
4320 return (i);
4321 return (-1);
4322 }
4323
4324 /*
4325 * This function checks for restart conditions.
4326 */
4327 static int
nfsrv_checkrestart(nfsquad_t clientid,u_int32_t flags,nfsv4stateid_t * stateidp,int specialid)4328 nfsrv_checkrestart(nfsquad_t clientid, u_int32_t flags,
4329 nfsv4stateid_t *stateidp, int specialid)
4330 {
4331 int ret = 0;
4332
4333 /*
4334 * First check for a server restart. Open, LockT, ReleaseLockOwner
4335 * and DelegPurge have a clientid, the rest a stateid.
4336 */
4337 if (flags &
4338 (NFSLCK_OPEN | NFSLCK_TEST | NFSLCK_RELEASE | NFSLCK_DELEGPURGE)) {
4339 if (clientid.lval[0] != nfsrvboottime) {
4340 ret = NFSERR_STALECLIENTID;
4341 goto out;
4342 }
4343 } else if (stateidp->other[0] != nfsrvboottime &&
4344 specialid == 0) {
4345 ret = NFSERR_STALESTATEID;
4346 goto out;
4347 }
4348
4349 /*
4350 * Read, Write, Setattr and LockT can return NFSERR_GRACE and do
4351 * not use a lock/open owner seqid#, so the check can be done now.
4352 * (The others will be checked, as required, later.)
4353 */
4354 if (!(flags & (NFSLCK_CHECK | NFSLCK_TEST)))
4355 goto out;
4356
4357 NFSLOCKSTATE();
4358 ret = nfsrv_checkgrace(NULL, NULL, flags);
4359 NFSUNLOCKSTATE();
4360
4361 out:
4362 NFSEXITCODE(ret);
4363 return (ret);
4364 }
4365
4366 /*
4367 * Check for grace.
4368 */
4369 static int
nfsrv_checkgrace(struct nfsrv_descript * nd,struct nfsclient * clp,u_int32_t flags)4370 nfsrv_checkgrace(struct nfsrv_descript *nd, struct nfsclient *clp,
4371 u_int32_t flags)
4372 {
4373 int error = 0, notreclaimed;
4374 struct nfsrv_stable *sp;
4375
4376 if ((nfsrv_stablefirst.nsf_flags & (NFSNSF_UPDATEDONE |
4377 NFSNSF_GRACEOVER)) == 0) {
4378 /*
4379 * First, check to see if all of the clients have done a
4380 * ReclaimComplete. If so, grace can end now.
4381 */
4382 notreclaimed = 0;
4383 LIST_FOREACH(sp, &nfsrv_stablefirst.nsf_head, nst_list) {
4384 if ((sp->nst_flag & NFSNST_RECLAIMED) == 0) {
4385 notreclaimed = 1;
4386 break;
4387 }
4388 }
4389 if (notreclaimed == 0)
4390 nfsrv_stablefirst.nsf_flags |= (NFSNSF_GRACEOVER |
4391 NFSNSF_NEEDLOCK);
4392 }
4393
4394 if ((nfsrv_stablefirst.nsf_flags & NFSNSF_GRACEOVER) != 0) {
4395 if (flags & NFSLCK_RECLAIM) {
4396 error = NFSERR_NOGRACE;
4397 goto out;
4398 }
4399 } else {
4400 if (!(flags & NFSLCK_RECLAIM)) {
4401 error = NFSERR_GRACE;
4402 goto out;
4403 }
4404 if (nd != NULL && clp != NULL &&
4405 (nd->nd_flag & ND_NFSV41) != 0 &&
4406 (clp->lc_flags & LCL_RECLAIMCOMPLETE) != 0) {
4407 error = NFSERR_NOGRACE;
4408 goto out;
4409 }
4410
4411 /*
4412 * If grace is almost over and we are still getting Reclaims,
4413 * extend grace a bit.
4414 */
4415 if ((NFSD_MONOSEC + NFSRV_LEASEDELTA) >
4416 nfsrv_stablefirst.nsf_eograce)
4417 nfsrv_stablefirst.nsf_eograce = NFSD_MONOSEC +
4418 NFSRV_LEASEDELTA;
4419 }
4420
4421 out:
4422 NFSEXITCODE(error);
4423 return (error);
4424 }
4425
4426 /*
4427 * Do a server callback.
4428 * The "trunc" argument is slightly overloaded and refers to different
4429 * boolean arguments for CBRECALL and CBLAYOUTRECALL.
4430 */
4431 static int
nfsrv_docallback(struct nfsclient * clp,int procnum,nfsv4stateid_t * stateidp,int trunc,fhandle_t * fhp,struct nfsvattr * nap,nfsattrbit_t * attrbitp,int laytype,NFSPROC_T * p)4432 nfsrv_docallback(struct nfsclient *clp, int procnum, nfsv4stateid_t *stateidp,
4433 int trunc, fhandle_t *fhp, struct nfsvattr *nap, nfsattrbit_t *attrbitp,
4434 int laytype, NFSPROC_T *p)
4435 {
4436 struct mbuf *m;
4437 u_int32_t *tl;
4438 struct nfsrv_descript *nd;
4439 struct ucred *cred;
4440 int error = 0, slotpos;
4441 u_int32_t callback;
4442 struct nfsdsession *sep = NULL;
4443 uint64_t tval;
4444 bool dotls;
4445
4446 nd = malloc(sizeof(*nd), M_TEMP, M_WAITOK | M_ZERO);
4447 cred = newnfs_getcred();
4448 NFSLOCKSTATE(); /* mostly for lc_cbref++ */
4449 if (clp->lc_flags & LCL_NEEDSCONFIRM) {
4450 NFSUNLOCKSTATE();
4451 panic("docallb");
4452 }
4453 clp->lc_cbref++;
4454
4455 /*
4456 * Fill the callback program# and version into the request
4457 * structure for newnfs_connect() to use.
4458 */
4459 clp->lc_req.nr_prog = clp->lc_program;
4460 #ifdef notnow
4461 if ((clp->lc_flags & LCL_NFSV41) != 0)
4462 clp->lc_req.nr_vers = NFSV41_CBVERS;
4463 else
4464 #endif
4465 clp->lc_req.nr_vers = NFSV4_CBVERS;
4466
4467 /*
4468 * First, fill in some of the fields of nd and cr.
4469 */
4470 nd->nd_flag = ND_NFSV4;
4471 if (clp->lc_flags & LCL_GSS)
4472 nd->nd_flag |= ND_KERBV;
4473 if ((clp->lc_flags & LCL_NFSV41) != 0)
4474 nd->nd_flag |= ND_NFSV41;
4475 if ((clp->lc_flags & LCL_NFSV42) != 0)
4476 nd->nd_flag |= ND_NFSV42;
4477 nd->nd_repstat = 0;
4478 cred->cr_uid = clp->lc_uid;
4479 cred->cr_gid = clp->lc_gid;
4480 callback = clp->lc_callback;
4481 NFSUNLOCKSTATE();
4482 cred->cr_ngroups = 1;
4483
4484 /*
4485 * Get the first mbuf for the request.
4486 */
4487 MGET(m, M_WAITOK, MT_DATA);
4488 m->m_len = 0;
4489 nd->nd_mreq = nd->nd_mb = m;
4490 nd->nd_bpos = mtod(m, caddr_t);
4491
4492 /*
4493 * and build the callback request.
4494 */
4495 if (procnum == NFSV4OP_CBGETATTR) {
4496 nd->nd_procnum = NFSV4PROC_CBCOMPOUND;
4497 error = nfsrv_cbcallargs(nd, clp, callback, NFSV4OP_CBGETATTR,
4498 "CB Getattr", &sep, &slotpos);
4499 if (error != 0) {
4500 m_freem(nd->nd_mreq);
4501 goto errout;
4502 }
4503 (void)nfsm_fhtom(nd, (u_int8_t *)fhp, NFSX_MYFH, 0);
4504 (void)nfsrv_putattrbit(nd, attrbitp);
4505 } else if (procnum == NFSV4OP_CBRECALL) {
4506 nd->nd_procnum = NFSV4PROC_CBCOMPOUND;
4507 error = nfsrv_cbcallargs(nd, clp, callback, NFSV4OP_CBRECALL,
4508 "CB Recall", &sep, &slotpos);
4509 if (error != 0) {
4510 m_freem(nd->nd_mreq);
4511 goto errout;
4512 }
4513 NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED + NFSX_STATEID);
4514 *tl++ = txdr_unsigned(stateidp->seqid);
4515 NFSBCOPY((caddr_t)stateidp->other, (caddr_t)tl,
4516 NFSX_STATEIDOTHER);
4517 tl += (NFSX_STATEIDOTHER / NFSX_UNSIGNED);
4518 if (trunc)
4519 *tl = newnfs_true;
4520 else
4521 *tl = newnfs_false;
4522 (void)nfsm_fhtom(nd, (u_int8_t *)fhp, NFSX_MYFH, 0);
4523 } else if (procnum == NFSV4OP_CBLAYOUTRECALL) {
4524 NFSD_DEBUG(4, "docallback layout recall\n");
4525 nd->nd_procnum = NFSV4PROC_CBCOMPOUND;
4526 error = nfsrv_cbcallargs(nd, clp, callback,
4527 NFSV4OP_CBLAYOUTRECALL, "CB Reclayout", &sep, &slotpos);
4528 NFSD_DEBUG(4, "aft cbcallargs=%d\n", error);
4529 if (error != 0) {
4530 m_freem(nd->nd_mreq);
4531 goto errout;
4532 }
4533 NFSM_BUILD(tl, u_int32_t *, 4 * NFSX_UNSIGNED);
4534 *tl++ = txdr_unsigned(laytype);
4535 *tl++ = txdr_unsigned(NFSLAYOUTIOMODE_ANY);
4536 if (trunc)
4537 *tl++ = newnfs_true;
4538 else
4539 *tl++ = newnfs_false;
4540 *tl = txdr_unsigned(NFSV4LAYOUTRET_FILE);
4541 nfsm_fhtom(nd, (uint8_t *)fhp, NFSX_MYFH, 0);
4542 NFSM_BUILD(tl, u_int32_t *, 2 * NFSX_HYPER + NFSX_STATEID);
4543 tval = 0;
4544 txdr_hyper(tval, tl); tl += 2;
4545 tval = UINT64_MAX;
4546 txdr_hyper(tval, tl); tl += 2;
4547 *tl++ = txdr_unsigned(stateidp->seqid);
4548 NFSBCOPY(stateidp->other, tl, NFSX_STATEIDOTHER);
4549 tl += (NFSX_STATEIDOTHER / NFSX_UNSIGNED);
4550 NFSD_DEBUG(4, "aft args\n");
4551 } else if (procnum == NFSV4PROC_CBNULL) {
4552 nd->nd_procnum = NFSV4PROC_CBNULL;
4553 if ((clp->lc_flags & LCL_NFSV41) != 0) {
4554 error = nfsv4_getcbsession(clp, &sep);
4555 if (error != 0) {
4556 m_freem(nd->nd_mreq);
4557 goto errout;
4558 }
4559 }
4560 } else {
4561 error = NFSERR_SERVERFAULT;
4562 m_freem(nd->nd_mreq);
4563 goto errout;
4564 }
4565
4566 /*
4567 * Call newnfs_connect(), as required, and then newnfs_request().
4568 */
4569 dotls = false;
4570 if ((clp->lc_flags & LCL_TLSCB) != 0)
4571 dotls = true;
4572 (void) newnfs_sndlock(&clp->lc_req.nr_lock);
4573 if (clp->lc_req.nr_client == NULL) {
4574 if ((clp->lc_flags & LCL_NFSV41) != 0) {
4575 error = ECONNREFUSED;
4576 if (procnum != NFSV4PROC_CBNULL)
4577 nfsv4_freeslot(&sep->sess_cbsess, slotpos,
4578 true);
4579 nfsrv_freesession(sep, NULL);
4580 } else if (nd->nd_procnum == NFSV4PROC_CBNULL)
4581 error = newnfs_connect(NULL, &clp->lc_req, cred,
4582 NULL, 1, dotls, &clp->lc_req.nr_client);
4583 else
4584 error = newnfs_connect(NULL, &clp->lc_req, cred,
4585 NULL, 3, dotls, &clp->lc_req.nr_client);
4586 }
4587 newnfs_sndunlock(&clp->lc_req.nr_lock);
4588 NFSD_DEBUG(4, "aft sndunlock=%d\n", error);
4589 if (!error) {
4590 if ((nd->nd_flag & ND_NFSV41) != 0) {
4591 KASSERT(sep != NULL, ("sep NULL"));
4592 if (sep->sess_cbsess.nfsess_xprt != NULL)
4593 error = newnfs_request(nd, NULL, clp,
4594 &clp->lc_req, NULL, NULL, cred,
4595 clp->lc_program, clp->lc_req.nr_vers, NULL,
4596 1, NULL, &sep->sess_cbsess);
4597 else {
4598 /*
4599 * This should probably never occur, but if a
4600 * client somehow does an RPC without a
4601 * SequenceID Op that causes a callback just
4602 * after the nfsd threads have been terminated
4603 * and restared we could conceivably get here
4604 * without a backchannel xprt.
4605 */
4606 printf("nfsrv_docallback: no xprt\n");
4607 error = ECONNREFUSED;
4608 }
4609 NFSD_DEBUG(4, "aft newnfs_request=%d\n", error);
4610 if (error != 0 && procnum != NFSV4PROC_CBNULL) {
4611 /*
4612 * It is likely that the callback was never
4613 * processed by the client and, as such,
4614 * the sequence# for the session slot needs
4615 * to be backed up by one to avoid a
4616 * NFSERR_SEQMISORDERED error reply.
4617 * For the unlikely case where the callback
4618 * was processed by the client, this will
4619 * make the next callback on the slot
4620 * appear to be a retry.
4621 * Since callbacks never specify that the
4622 * reply be cached, this "apparent retry"
4623 * should not be a problem.
4624 */
4625 nfsv4_freeslot(&sep->sess_cbsess, slotpos,
4626 true);
4627 }
4628 nfsrv_freesession(sep, NULL);
4629 } else
4630 error = newnfs_request(nd, NULL, clp, &clp->lc_req,
4631 NULL, NULL, cred, clp->lc_program,
4632 clp->lc_req.nr_vers, NULL, 1, NULL, NULL);
4633 }
4634 errout:
4635 NFSFREECRED(cred);
4636
4637 /*
4638 * If error is set here, the Callback path isn't working
4639 * properly, so twiddle the appropriate LCL_ flags.
4640 * (nd_repstat != 0 indicates the Callback path is working,
4641 * but the callback failed on the client.)
4642 */
4643 if (error) {
4644 /*
4645 * Mark the callback pathway down, which disabled issuing
4646 * of delegations and gets Renew to return NFSERR_CBPATHDOWN.
4647 */
4648 NFSLOCKSTATE();
4649 clp->lc_flags |= LCL_CBDOWN;
4650 NFSUNLOCKSTATE();
4651 } else {
4652 /*
4653 * Callback worked. If the callback path was down, disable
4654 * callbacks, so no more delegations will be issued. (This
4655 * is done on the assumption that the callback pathway is
4656 * flakey.)
4657 */
4658 NFSLOCKSTATE();
4659 if (clp->lc_flags & LCL_CBDOWN)
4660 clp->lc_flags &= ~(LCL_CBDOWN | LCL_CALLBACKSON);
4661 NFSUNLOCKSTATE();
4662 if (nd->nd_repstat) {
4663 error = nd->nd_repstat;
4664 NFSD_DEBUG(1, "nfsrv_docallback op=%d err=%d\n",
4665 procnum, error);
4666 } else if (error == 0 && procnum == NFSV4OP_CBGETATTR)
4667 error = nfsv4_loadattr(nd, NULL, nap, NULL, NULL, 0,
4668 NULL, NULL, NULL, NULL, NULL, 0, NULL, NULL, NULL,
4669 p, NULL);
4670 m_freem(nd->nd_mrep);
4671 }
4672 NFSLOCKSTATE();
4673 clp->lc_cbref--;
4674 if ((clp->lc_flags & LCL_WAKEUPWANTED) && clp->lc_cbref == 0) {
4675 clp->lc_flags &= ~LCL_WAKEUPWANTED;
4676 wakeup(clp);
4677 }
4678 NFSUNLOCKSTATE();
4679
4680 free(nd, M_TEMP);
4681 NFSEXITCODE(error);
4682 return (error);
4683 }
4684
4685 /*
4686 * Set up the compound RPC for the callback.
4687 */
4688 static int
nfsrv_cbcallargs(struct nfsrv_descript * nd,struct nfsclient * clp,uint32_t callback,int op,const char * optag,struct nfsdsession ** sepp,int * slotposp)4689 nfsrv_cbcallargs(struct nfsrv_descript *nd, struct nfsclient *clp,
4690 uint32_t callback, int op, const char *optag, struct nfsdsession **sepp,
4691 int *slotposp)
4692 {
4693 uint32_t *tl;
4694 int error, len;
4695
4696 len = strlen(optag);
4697 (void)nfsm_strtom(nd, optag, len);
4698 NFSM_BUILD(tl, uint32_t *, 4 * NFSX_UNSIGNED);
4699 if ((nd->nd_flag & ND_NFSV41) != 0) {
4700 if ((nd->nd_flag & ND_NFSV42) != 0)
4701 *tl++ = txdr_unsigned(NFSV42_MINORVERSION);
4702 else
4703 *tl++ = txdr_unsigned(NFSV41_MINORVERSION);
4704 *tl++ = txdr_unsigned(callback);
4705 *tl++ = txdr_unsigned(2);
4706 *tl = txdr_unsigned(NFSV4OP_CBSEQUENCE);
4707 error = nfsv4_setcbsequence(nd, clp, 1, sepp, slotposp);
4708 if (error != 0)
4709 return (error);
4710 NFSM_BUILD(tl, u_int32_t *, NFSX_UNSIGNED);
4711 *tl = txdr_unsigned(op);
4712 } else {
4713 *tl++ = txdr_unsigned(NFSV4_MINORVERSION);
4714 *tl++ = txdr_unsigned(callback);
4715 *tl++ = txdr_unsigned(1);
4716 *tl = txdr_unsigned(op);
4717 }
4718 return (0);
4719 }
4720
4721 /*
4722 * Return the next index# for a clientid. Mostly just increment and return
4723 * the next one, but... if the 32bit unsigned does actually wrap around,
4724 * it should be rebooted.
4725 * At an average rate of one new client per second, it will wrap around in
4726 * approximately 136 years. (I think the server will have been shut
4727 * down or rebooted before then.)
4728 */
4729 static u_int32_t
nfsrv_nextclientindex(void)4730 nfsrv_nextclientindex(void)
4731 {
4732 static u_int32_t client_index = 0;
4733
4734 client_index++;
4735 if (client_index != 0)
4736 return (client_index);
4737
4738 printf("%s: out of clientids\n", __func__);
4739 return (client_index);
4740 }
4741
4742 /*
4743 * Return the next index# for a stateid. Mostly just increment and return
4744 * the next one, but... if the 32bit unsigned does actually wrap around
4745 * (will a BSD server stay up that long?), find
4746 * new start and end values.
4747 */
4748 static u_int32_t
nfsrv_nextstateindex(struct nfsclient * clp)4749 nfsrv_nextstateindex(struct nfsclient *clp)
4750 {
4751 struct nfsstate *stp;
4752 int i;
4753 u_int32_t canuse, min_index, max_index;
4754
4755 if (!(clp->lc_flags & LCL_INDEXNOTOK)) {
4756 clp->lc_stateindex++;
4757 if (clp->lc_stateindex != clp->lc_statemaxindex)
4758 return (clp->lc_stateindex);
4759 }
4760
4761 /*
4762 * Yuck, we've hit the end.
4763 * Look for a new min and max.
4764 */
4765 min_index = 0;
4766 max_index = 0xffffffff;
4767 for (i = 0; i < nfsrv_statehashsize; i++) {
4768 LIST_FOREACH(stp, &clp->lc_stateid[i], ls_hash) {
4769 if (stp->ls_stateid.other[2] > 0x80000000) {
4770 if (stp->ls_stateid.other[2] < max_index)
4771 max_index = stp->ls_stateid.other[2];
4772 } else {
4773 if (stp->ls_stateid.other[2] > min_index)
4774 min_index = stp->ls_stateid.other[2];
4775 }
4776 }
4777 }
4778
4779 /*
4780 * Yikes, highly unlikely, but I'll handle it anyhow.
4781 */
4782 if (min_index == 0x80000000 && max_index == 0x80000001) {
4783 canuse = 0;
4784 /*
4785 * Loop around until we find an unused entry. Return that
4786 * and set LCL_INDEXNOTOK, so the search will continue next time.
4787 * (This is one of those rare cases where a goto is the
4788 * cleanest way to code the loop.)
4789 */
4790 tryagain:
4791 for (i = 0; i < nfsrv_statehashsize; i++) {
4792 LIST_FOREACH(stp, &clp->lc_stateid[i], ls_hash) {
4793 if (stp->ls_stateid.other[2] == canuse) {
4794 canuse++;
4795 goto tryagain;
4796 }
4797 }
4798 }
4799 clp->lc_flags |= LCL_INDEXNOTOK;
4800 return (canuse);
4801 }
4802
4803 /*
4804 * Ok to start again from min + 1.
4805 */
4806 clp->lc_stateindex = min_index + 1;
4807 clp->lc_statemaxindex = max_index;
4808 clp->lc_flags &= ~LCL_INDEXNOTOK;
4809 return (clp->lc_stateindex);
4810 }
4811
4812 /*
4813 * The following functions handle the stable storage file that deals with
4814 * the edge conditions described in RFC3530 Sec. 8.6.3.
4815 * The file is as follows:
4816 * - a single record at the beginning that has the lease time of the
4817 * previous server instance (before the last reboot) and the nfsrvboottime
4818 * values for the previous server boots.
4819 * These previous boot times are used to ensure that the current
4820 * nfsrvboottime does not, somehow, get set to a previous one.
4821 * (This is important so that Stale ClientIDs and StateIDs can
4822 * be recognized.)
4823 * The number of previous nfsvrboottime values precedes the list.
4824 * - followed by some number of appended records with:
4825 * - client id string
4826 * - flag that indicates it is a record revoking state via lease
4827 * expiration or similar
4828 * OR has successfully acquired state.
4829 * These structures vary in length, with the client string at the end, up
4830 * to NFSV4_OPAQUELIMIT in size.
4831 *
4832 * At the end of the grace period, the file is truncated, the first
4833 * record is rewritten with updated information and any acquired state
4834 * records for successful reclaims of state are written.
4835 *
4836 * Subsequent records are appended when the first state is issued to
4837 * a client and when state is revoked for a client.
4838 *
4839 * When reading the file in, state issued records that come later in
4840 * the file override older ones, since the append log is in cronological order.
4841 * If, for some reason, the file can't be read, the grace period is
4842 * immediately terminated and all reclaims get NFSERR_NOGRACE.
4843 */
4844
4845 /*
4846 * Read in the stable storage file. Called by nfssvc() before the nfsd
4847 * processes start servicing requests.
4848 */
4849 void
nfsrv_setupstable(NFSPROC_T * p)4850 nfsrv_setupstable(NFSPROC_T *p)
4851 {
4852 struct nfsrv_stablefirst *sf = &nfsrv_stablefirst;
4853 struct nfsrv_stable *sp, *nsp;
4854 struct nfst_rec *tsp;
4855 int error, i, tryagain;
4856 off_t off = 0;
4857 ssize_t aresid, len;
4858
4859 /*
4860 * If NFSNSF_UPDATEDONE is set, this is a restart of the nfsds without
4861 * a reboot, so state has not been lost.
4862 */
4863 if (sf->nsf_flags & NFSNSF_UPDATEDONE)
4864 return;
4865 /*
4866 * Set Grace over just until the file reads successfully.
4867 */
4868 nfsrvboottime = time_second;
4869 LIST_INIT(&sf->nsf_head);
4870 sf->nsf_flags = (NFSNSF_GRACEOVER | NFSNSF_NEEDLOCK);
4871 sf->nsf_eograce = NFSD_MONOSEC + NFSRV_LEASEDELTA;
4872 if (sf->nsf_fp == NULL)
4873 return;
4874 error = NFSD_RDWR(UIO_READ, NFSFPVNODE(sf->nsf_fp),
4875 (caddr_t)&sf->nsf_rec, sizeof (struct nfsf_rec), off, UIO_SYSSPACE,
4876 0, NFSFPCRED(sf->nsf_fp), &aresid, p);
4877 if (error || aresid || sf->nsf_numboots == 0 ||
4878 sf->nsf_numboots > NFSNSF_MAXNUMBOOTS)
4879 return;
4880
4881 /*
4882 * Now, read in the boottimes.
4883 */
4884 sf->nsf_bootvals = (time_t *)malloc((sf->nsf_numboots + 1) *
4885 sizeof (time_t), M_TEMP, M_WAITOK);
4886 off = sizeof (struct nfsf_rec);
4887 error = NFSD_RDWR(UIO_READ, NFSFPVNODE(sf->nsf_fp),
4888 (caddr_t)sf->nsf_bootvals, sf->nsf_numboots * sizeof (time_t), off,
4889 UIO_SYSSPACE, 0, NFSFPCRED(sf->nsf_fp), &aresid, p);
4890 if (error || aresid) {
4891 free(sf->nsf_bootvals, M_TEMP);
4892 sf->nsf_bootvals = NULL;
4893 return;
4894 }
4895
4896 /*
4897 * Make sure this nfsrvboottime is different from all recorded
4898 * previous ones.
4899 */
4900 do {
4901 tryagain = 0;
4902 for (i = 0; i < sf->nsf_numboots; i++) {
4903 if (nfsrvboottime == sf->nsf_bootvals[i]) {
4904 nfsrvboottime++;
4905 tryagain = 1;
4906 break;
4907 }
4908 }
4909 } while (tryagain);
4910
4911 sf->nsf_flags |= NFSNSF_OK;
4912 off += (sf->nsf_numboots * sizeof (time_t));
4913
4914 /*
4915 * Read through the file, building a list of records for grace
4916 * checking.
4917 * Each record is between sizeof (struct nfst_rec) and
4918 * sizeof (struct nfst_rec) + NFSV4_OPAQUELIMIT - 1
4919 * and is actually sizeof (struct nfst_rec) + nst_len - 1.
4920 */
4921 tsp = (struct nfst_rec *)malloc(sizeof (struct nfst_rec) +
4922 NFSV4_OPAQUELIMIT - 1, M_TEMP, M_WAITOK);
4923 do {
4924 error = NFSD_RDWR(UIO_READ, NFSFPVNODE(sf->nsf_fp),
4925 (caddr_t)tsp, sizeof (struct nfst_rec) + NFSV4_OPAQUELIMIT - 1,
4926 off, UIO_SYSSPACE, 0, NFSFPCRED(sf->nsf_fp), &aresid, p);
4927 len = (sizeof (struct nfst_rec) + NFSV4_OPAQUELIMIT - 1) - aresid;
4928 if (error || (len > 0 && (len < sizeof (struct nfst_rec) ||
4929 len < (sizeof (struct nfst_rec) + tsp->len - 1)))) {
4930 /*
4931 * Yuck, the file has been corrupted, so just return
4932 * after clearing out any restart state, so the grace period
4933 * is over.
4934 */
4935 LIST_FOREACH_SAFE(sp, &sf->nsf_head, nst_list, nsp) {
4936 LIST_REMOVE(sp, nst_list);
4937 free(sp, M_TEMP);
4938 }
4939 free(tsp, M_TEMP);
4940 sf->nsf_flags &= ~NFSNSF_OK;
4941 free(sf->nsf_bootvals, M_TEMP);
4942 sf->nsf_bootvals = NULL;
4943 return;
4944 }
4945 if (len > 0) {
4946 off += sizeof (struct nfst_rec) + tsp->len - 1;
4947 /*
4948 * Search the list for a matching client.
4949 */
4950 LIST_FOREACH(sp, &sf->nsf_head, nst_list) {
4951 if (tsp->len == sp->nst_len &&
4952 !NFSBCMP(tsp->client, sp->nst_client, tsp->len))
4953 break;
4954 }
4955 if (sp == LIST_END(&sf->nsf_head)) {
4956 sp = (struct nfsrv_stable *)malloc(tsp->len +
4957 sizeof (struct nfsrv_stable) - 1, M_TEMP,
4958 M_WAITOK);
4959 NFSBCOPY((caddr_t)tsp, (caddr_t)&sp->nst_rec,
4960 sizeof (struct nfst_rec) + tsp->len - 1);
4961 LIST_INSERT_HEAD(&sf->nsf_head, sp, nst_list);
4962 } else {
4963 if (tsp->flag == NFSNST_REVOKE)
4964 sp->nst_flag |= NFSNST_REVOKE;
4965 else
4966 /*
4967 * A subsequent timestamp indicates the client
4968 * did a setclientid/confirm and any previous
4969 * revoke is no longer relevant.
4970 */
4971 sp->nst_flag &= ~NFSNST_REVOKE;
4972 }
4973 }
4974 } while (len > 0);
4975 free(tsp, M_TEMP);
4976 sf->nsf_flags = NFSNSF_OK;
4977 sf->nsf_eograce = NFSD_MONOSEC + sf->nsf_lease +
4978 NFSRV_LEASEDELTA;
4979 }
4980
4981 /*
4982 * Update the stable storage file, now that the grace period is over.
4983 */
4984 void
nfsrv_updatestable(NFSPROC_T * p)4985 nfsrv_updatestable(NFSPROC_T *p)
4986 {
4987 struct nfsrv_stablefirst *sf = &nfsrv_stablefirst;
4988 struct nfsrv_stable *sp, *nsp;
4989 int i;
4990 struct nfsvattr nva;
4991 vnode_t vp;
4992 #if defined(__FreeBSD_version) && (__FreeBSD_version >= 500000)
4993 mount_t mp = NULL;
4994 #endif
4995 int error;
4996
4997 if (sf->nsf_fp == NULL || (sf->nsf_flags & NFSNSF_UPDATEDONE))
4998 return;
4999 sf->nsf_flags |= NFSNSF_UPDATEDONE;
5000 /*
5001 * Ok, we need to rewrite the stable storage file.
5002 * - truncate to 0 length
5003 * - write the new first structure
5004 * - loop through the data structures, writing out any that
5005 * have timestamps older than the old boot
5006 */
5007 if (sf->nsf_bootvals) {
5008 sf->nsf_numboots++;
5009 for (i = sf->nsf_numboots - 2; i >= 0; i--)
5010 sf->nsf_bootvals[i + 1] = sf->nsf_bootvals[i];
5011 } else {
5012 sf->nsf_numboots = 1;
5013 sf->nsf_bootvals = (time_t *)malloc(sizeof (time_t),
5014 M_TEMP, M_WAITOK);
5015 }
5016 sf->nsf_bootvals[0] = nfsrvboottime;
5017 sf->nsf_lease = nfsrv_lease;
5018 NFSVNO_ATTRINIT(&nva);
5019 NFSVNO_SETATTRVAL(&nva, size, 0);
5020 vp = NFSFPVNODE(sf->nsf_fp);
5021 vn_start_write(vp, &mp, V_WAIT);
5022 if (NFSVOPLOCK(vp, LK_EXCLUSIVE) == 0) {
5023 error = nfsvno_setattr(vp, &nva, NFSFPCRED(sf->nsf_fp), p,
5024 NULL);
5025 NFSVOPUNLOCK(vp);
5026 } else
5027 error = EPERM;
5028 vn_finished_write(mp);
5029 if (!error)
5030 error = NFSD_RDWR(UIO_WRITE, vp,
5031 (caddr_t)&sf->nsf_rec, sizeof (struct nfsf_rec), (off_t)0,
5032 UIO_SYSSPACE, IO_SYNC, NFSFPCRED(sf->nsf_fp), NULL, p);
5033 if (!error)
5034 error = NFSD_RDWR(UIO_WRITE, vp,
5035 (caddr_t)sf->nsf_bootvals,
5036 sf->nsf_numboots * sizeof (time_t),
5037 (off_t)(sizeof (struct nfsf_rec)),
5038 UIO_SYSSPACE, IO_SYNC, NFSFPCRED(sf->nsf_fp), NULL, p);
5039 free(sf->nsf_bootvals, M_TEMP);
5040 sf->nsf_bootvals = NULL;
5041 if (error) {
5042 sf->nsf_flags &= ~NFSNSF_OK;
5043 printf("EEK! Can't write NfsV4 stable storage file\n");
5044 return;
5045 }
5046 sf->nsf_flags |= NFSNSF_OK;
5047
5048 /*
5049 * Loop through the list and write out timestamp records for
5050 * any clients that successfully reclaimed state.
5051 */
5052 LIST_FOREACH_SAFE(sp, &sf->nsf_head, nst_list, nsp) {
5053 if (sp->nst_flag & NFSNST_GOTSTATE) {
5054 nfsrv_writestable(sp->nst_client, sp->nst_len,
5055 NFSNST_NEWSTATE, p);
5056 sp->nst_clp->lc_flags |= LCL_STAMPEDSTABLE;
5057 }
5058 LIST_REMOVE(sp, nst_list);
5059 free(sp, M_TEMP);
5060 }
5061 nfsrv_backupstable();
5062 }
5063
5064 /*
5065 * Append a record to the stable storage file.
5066 */
5067 void
nfsrv_writestable(u_char * client,int len,int flag,NFSPROC_T * p)5068 nfsrv_writestable(u_char *client, int len, int flag, NFSPROC_T *p)
5069 {
5070 struct nfsrv_stablefirst *sf = &nfsrv_stablefirst;
5071 struct nfst_rec *sp;
5072 int error;
5073
5074 if (!(sf->nsf_flags & NFSNSF_OK) || sf->nsf_fp == NULL)
5075 return;
5076 sp = (struct nfst_rec *)malloc(sizeof (struct nfst_rec) +
5077 len - 1, M_TEMP, M_WAITOK);
5078 sp->len = len;
5079 NFSBCOPY(client, sp->client, len);
5080 sp->flag = flag;
5081 error = NFSD_RDWR(UIO_WRITE, NFSFPVNODE(sf->nsf_fp),
5082 (caddr_t)sp, sizeof (struct nfst_rec) + len - 1, (off_t)0,
5083 UIO_SYSSPACE, (IO_SYNC | IO_APPEND), NFSFPCRED(sf->nsf_fp), NULL, p);
5084 free(sp, M_TEMP);
5085 if (error) {
5086 sf->nsf_flags &= ~NFSNSF_OK;
5087 printf("EEK! Can't write NfsV4 stable storage file\n");
5088 }
5089 }
5090
5091 /*
5092 * This function is called during the grace period to mark a client
5093 * that successfully reclaimed state.
5094 */
5095 static void
nfsrv_markstable(struct nfsclient * clp)5096 nfsrv_markstable(struct nfsclient *clp)
5097 {
5098 struct nfsrv_stable *sp;
5099
5100 /*
5101 * First find the client structure.
5102 */
5103 LIST_FOREACH(sp, &nfsrv_stablefirst.nsf_head, nst_list) {
5104 if (sp->nst_len == clp->lc_idlen &&
5105 !NFSBCMP(sp->nst_client, clp->lc_id, sp->nst_len))
5106 break;
5107 }
5108 if (sp == LIST_END(&nfsrv_stablefirst.nsf_head))
5109 return;
5110
5111 /*
5112 * Now, just mark it and set the nfsclient back pointer.
5113 */
5114 sp->nst_flag |= NFSNST_GOTSTATE;
5115 sp->nst_clp = clp;
5116 }
5117
5118 /*
5119 * This function is called when a NFSv4.1 client does a ReclaimComplete.
5120 * Very similar to nfsrv_markstable(), except for the flag being set.
5121 */
5122 static void
nfsrv_markreclaim(struct nfsclient * clp)5123 nfsrv_markreclaim(struct nfsclient *clp)
5124 {
5125 struct nfsrv_stable *sp;
5126
5127 /*
5128 * First find the client structure.
5129 */
5130 LIST_FOREACH(sp, &nfsrv_stablefirst.nsf_head, nst_list) {
5131 if (sp->nst_len == clp->lc_idlen &&
5132 !NFSBCMP(sp->nst_client, clp->lc_id, sp->nst_len))
5133 break;
5134 }
5135 if (sp == LIST_END(&nfsrv_stablefirst.nsf_head))
5136 return;
5137
5138 /*
5139 * Now, just set the flag.
5140 */
5141 sp->nst_flag |= NFSNST_RECLAIMED;
5142 }
5143
5144 /*
5145 * This function is called for a reclaim, to see if it gets grace.
5146 * It returns 0 if a reclaim is allowed, 1 otherwise.
5147 */
5148 static int
nfsrv_checkstable(struct nfsclient * clp)5149 nfsrv_checkstable(struct nfsclient *clp)
5150 {
5151 struct nfsrv_stable *sp;
5152
5153 /*
5154 * First, find the entry for the client.
5155 */
5156 LIST_FOREACH(sp, &nfsrv_stablefirst.nsf_head, nst_list) {
5157 if (sp->nst_len == clp->lc_idlen &&
5158 !NFSBCMP(sp->nst_client, clp->lc_id, sp->nst_len))
5159 break;
5160 }
5161
5162 /*
5163 * If not in the list, state was revoked or no state was issued
5164 * since the previous reboot, a reclaim is denied.
5165 */
5166 if (sp == LIST_END(&nfsrv_stablefirst.nsf_head) ||
5167 (sp->nst_flag & NFSNST_REVOKE) ||
5168 !(nfsrv_stablefirst.nsf_flags & NFSNSF_OK))
5169 return (1);
5170 return (0);
5171 }
5172
5173 /*
5174 * Test for and try to clear out a conflicting client. This is called by
5175 * nfsrv_lockctrl() and nfsrv_openctrl() when conflicts with other clients
5176 * a found.
5177 * The trick here is that it can't revoke a conflicting client with an
5178 * expired lease unless it holds the v4root lock, so...
5179 * If no v4root lock, get the lock and return 1 to indicate "try again".
5180 * Return 0 to indicate the conflict can't be revoked and 1 to indicate
5181 * the revocation worked and the conflicting client is "bye, bye", so it
5182 * can be tried again.
5183 * Return 2 to indicate that the vnode is VIRF_DOOMED after NFSVOPLOCK().
5184 * Unlocks State before a non-zero value is returned.
5185 */
5186 static int
nfsrv_clientconflict(struct nfsclient * clp,int * haslockp,vnode_t vp,NFSPROC_T * p)5187 nfsrv_clientconflict(struct nfsclient *clp, int *haslockp, vnode_t vp,
5188 NFSPROC_T *p)
5189 {
5190 int gotlock, lktype = 0;
5191
5192 /*
5193 * If lease hasn't expired, we can't fix it.
5194 */
5195 if (clp->lc_expiry >= NFSD_MONOSEC ||
5196 !(nfsrv_stablefirst.nsf_flags & NFSNSF_UPDATEDONE))
5197 return (0);
5198 if (*haslockp == 0) {
5199 NFSUNLOCKSTATE();
5200 if (vp != NULL) {
5201 lktype = NFSVOPISLOCKED(vp);
5202 NFSVOPUNLOCK(vp);
5203 }
5204 NFSLOCKV4ROOTMUTEX();
5205 nfsv4_relref(&nfsv4rootfs_lock);
5206 do {
5207 gotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
5208 NFSV4ROOTLOCKMUTEXPTR, NULL);
5209 } while (!gotlock);
5210 NFSUNLOCKV4ROOTMUTEX();
5211 *haslockp = 1;
5212 if (vp != NULL) {
5213 NFSVOPLOCK(vp, lktype | LK_RETRY);
5214 if (VN_IS_DOOMED(vp))
5215 return (2);
5216 }
5217 return (1);
5218 }
5219 NFSUNLOCKSTATE();
5220
5221 /*
5222 * Ok, we can expire the conflicting client.
5223 */
5224 nfsrv_writestable(clp->lc_id, clp->lc_idlen, NFSNST_REVOKE, p);
5225 nfsrv_backupstable();
5226 nfsrv_cleanclient(clp, p);
5227 nfsrv_freedeleglist(&clp->lc_deleg);
5228 nfsrv_freedeleglist(&clp->lc_olddeleg);
5229 LIST_REMOVE(clp, lc_hash);
5230 nfsrv_zapclient(clp, p);
5231 return (1);
5232 }
5233
5234 /*
5235 * Resolve a delegation conflict.
5236 * Returns 0 to indicate the conflict was resolved without sleeping.
5237 * Return -1 to indicate that the caller should check for conflicts again.
5238 * Return > 0 for an error that should be returned, normally NFSERR_DELAY.
5239 *
5240 * Also, manipulate the nfsv4root_lock, as required. It isn't changed
5241 * for a return of 0, since there was no sleep and it could be required
5242 * later. It is released for a return of NFSERR_DELAY, since the caller
5243 * will return that error. It is released when a sleep was done waiting
5244 * for the delegation to be returned or expire (so that other nfsds can
5245 * handle ops). Then, it must be acquired for the write to stable storage.
5246 * (This function is somewhat similar to nfsrv_clientconflict(), but
5247 * the semantics differ in a couple of subtle ways. The return of 0
5248 * indicates the conflict was resolved without sleeping here, not
5249 * that the conflict can't be resolved and the handling of nfsv4root_lock
5250 * differs, as noted above.)
5251 * Unlocks State before returning a non-zero value.
5252 */
5253 static int
nfsrv_delegconflict(struct nfsstate * stp,int * haslockp,NFSPROC_T * p,vnode_t vp)5254 nfsrv_delegconflict(struct nfsstate *stp, int *haslockp, NFSPROC_T *p,
5255 vnode_t vp)
5256 {
5257 struct nfsclient *clp = stp->ls_clp;
5258 int gotlock, error, lktype = 0, retrycnt, zapped_clp;
5259 nfsv4stateid_t tstateid;
5260 fhandle_t tfh;
5261
5262 /*
5263 * If the conflict is with an old delegation...
5264 */
5265 if (stp->ls_flags & NFSLCK_OLDDELEG) {
5266 /*
5267 * You can delete it, if it has expired.
5268 */
5269 if (clp->lc_delegtime < NFSD_MONOSEC) {
5270 nfsrv_freedeleg(stp);
5271 NFSUNLOCKSTATE();
5272 error = -1;
5273 goto out;
5274 }
5275 NFSUNLOCKSTATE();
5276 /*
5277 * During this delay, the old delegation could expire or it
5278 * could be recovered by the client via an Open with
5279 * CLAIM_DELEGATE_PREV.
5280 * Release the nfsv4root_lock, if held.
5281 */
5282 if (*haslockp) {
5283 *haslockp = 0;
5284 NFSLOCKV4ROOTMUTEX();
5285 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5286 NFSUNLOCKV4ROOTMUTEX();
5287 }
5288 error = NFSERR_DELAY;
5289 goto out;
5290 }
5291
5292 /*
5293 * It's a current delegation, so:
5294 * - check to see if the delegation has expired
5295 * - if so, get the v4root lock and then expire it
5296 */
5297 if ((stp->ls_flags & NFSLCK_DELEGRECALL) == 0 || (stp->ls_lastrecall <
5298 NFSD_MONOSEC && clp->lc_expiry >= NFSD_MONOSEC &&
5299 stp->ls_delegtime >= NFSD_MONOSEC)) {
5300 /*
5301 * - do a recall callback, since not yet done
5302 * For now, never allow truncate to be set. To use
5303 * truncate safely, it must be guaranteed that the
5304 * Remove, Rename or Setattr with size of 0 will
5305 * succeed and that would require major changes to
5306 * the VFS/Vnode OPs.
5307 * Set the expiry time large enough so that it won't expire
5308 * until after the callback, then set it correctly, once
5309 * the callback is done. (The delegation will now time
5310 * out whether or not the Recall worked ok. The timeout
5311 * will be extended when ops are done on the delegation
5312 * stateid, up to the timelimit.)
5313 */
5314 if ((stp->ls_flags & NFSLCK_DELEGRECALL) == 0) {
5315 stp->ls_delegtime = NFSD_MONOSEC + (2 * nfsrv_lease) +
5316 NFSRV_LEASEDELTA;
5317 stp->ls_delegtimelimit = NFSD_MONOSEC + (6 *
5318 nfsrv_lease) + NFSRV_LEASEDELTA;
5319 stp->ls_flags |= NFSLCK_DELEGRECALL;
5320 }
5321 stp->ls_lastrecall = time_uptime + 1;
5322
5323 /*
5324 * Loop NFSRV_CBRETRYCNT times while the CBRecall replies
5325 * NFSERR_BADSTATEID or NFSERR_BADHANDLE. This is done
5326 * in order to try and avoid a race that could happen
5327 * when a CBRecall request passed the Open reply with
5328 * the delegation in it when transitting the network.
5329 * Since nfsrv_docallback will sleep, don't use stp after
5330 * the call.
5331 */
5332 NFSBCOPY((caddr_t)&stp->ls_stateid, (caddr_t)&tstateid,
5333 sizeof (tstateid));
5334 NFSBCOPY((caddr_t)&stp->ls_lfp->lf_fh, (caddr_t)&tfh,
5335 sizeof (tfh));
5336 NFSUNLOCKSTATE();
5337 if (*haslockp) {
5338 *haslockp = 0;
5339 NFSLOCKV4ROOTMUTEX();
5340 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5341 NFSUNLOCKV4ROOTMUTEX();
5342 }
5343 retrycnt = 0;
5344 do {
5345 error = nfsrv_docallback(clp, NFSV4OP_CBRECALL,
5346 &tstateid, 0, &tfh, NULL, NULL, 0, p);
5347 retrycnt++;
5348 } while ((error == NFSERR_BADSTATEID ||
5349 error == NFSERR_BADHANDLE) && retrycnt < NFSV4_CBRETRYCNT);
5350 error = NFSERR_DELAY;
5351 goto out;
5352 }
5353
5354 if (clp->lc_expiry >= NFSD_MONOSEC &&
5355 stp->ls_delegtime >= NFSD_MONOSEC) {
5356 NFSUNLOCKSTATE();
5357 /*
5358 * A recall has been done, but it has not yet expired.
5359 * So, RETURN_DELAY.
5360 */
5361 if (*haslockp) {
5362 *haslockp = 0;
5363 NFSLOCKV4ROOTMUTEX();
5364 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5365 NFSUNLOCKV4ROOTMUTEX();
5366 }
5367 error = NFSERR_DELAY;
5368 goto out;
5369 }
5370
5371 /*
5372 * If we don't yet have the lock, just get it and then return,
5373 * since we need that before deleting expired state, such as
5374 * this delegation.
5375 * When getting the lock, unlock the vnode, so other nfsds that
5376 * are in progress, won't get stuck waiting for the vnode lock.
5377 */
5378 if (*haslockp == 0) {
5379 NFSUNLOCKSTATE();
5380 if (vp != NULL) {
5381 lktype = NFSVOPISLOCKED(vp);
5382 NFSVOPUNLOCK(vp);
5383 }
5384 NFSLOCKV4ROOTMUTEX();
5385 nfsv4_relref(&nfsv4rootfs_lock);
5386 do {
5387 gotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
5388 NFSV4ROOTLOCKMUTEXPTR, NULL);
5389 } while (!gotlock);
5390 NFSUNLOCKV4ROOTMUTEX();
5391 *haslockp = 1;
5392 if (vp != NULL) {
5393 NFSVOPLOCK(vp, lktype | LK_RETRY);
5394 if (VN_IS_DOOMED(vp)) {
5395 *haslockp = 0;
5396 NFSLOCKV4ROOTMUTEX();
5397 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5398 NFSUNLOCKV4ROOTMUTEX();
5399 error = NFSERR_PERM;
5400 goto out;
5401 }
5402 }
5403 error = -1;
5404 goto out;
5405 }
5406
5407 NFSUNLOCKSTATE();
5408 /*
5409 * Ok, we can delete the expired delegation.
5410 * First, write the Revoke record to stable storage and then
5411 * clear out the conflict.
5412 * Since all other nfsd threads are now blocked, we can safely
5413 * sleep without the state changing.
5414 */
5415 nfsrv_writestable(clp->lc_id, clp->lc_idlen, NFSNST_REVOKE, p);
5416 nfsrv_backupstable();
5417 if (clp->lc_expiry < NFSD_MONOSEC) {
5418 nfsrv_cleanclient(clp, p);
5419 nfsrv_freedeleglist(&clp->lc_deleg);
5420 nfsrv_freedeleglist(&clp->lc_olddeleg);
5421 LIST_REMOVE(clp, lc_hash);
5422 zapped_clp = 1;
5423 } else {
5424 nfsrv_freedeleg(stp);
5425 zapped_clp = 0;
5426 }
5427 if (zapped_clp)
5428 nfsrv_zapclient(clp, p);
5429 error = -1;
5430
5431 out:
5432 NFSEXITCODE(error);
5433 return (error);
5434 }
5435
5436 /*
5437 * Check for a remove allowed, if remove is set to 1 and get rid of
5438 * delegations.
5439 */
5440 int
nfsrv_checkremove(vnode_t vp,int remove,struct nfsrv_descript * nd,nfsquad_t clientid,NFSPROC_T * p)5441 nfsrv_checkremove(vnode_t vp, int remove, struct nfsrv_descript *nd,
5442 nfsquad_t clientid, NFSPROC_T *p)
5443 {
5444 struct nfsclient *clp;
5445 struct nfsstate *stp;
5446 struct nfslockfile *lfp;
5447 int error, haslock = 0;
5448 fhandle_t nfh;
5449
5450 clp = NULL;
5451 /*
5452 * First, get the lock file structure.
5453 * (A return of -1 means no associated state, so remove ok.)
5454 */
5455 error = nfsrv_getlockfh(vp, NFSLCK_CHECK, NULL, &nfh, p);
5456 tryagain:
5457 NFSLOCKSTATE();
5458 if (error == 0 && clientid.qval != 0)
5459 error = nfsrv_getclient(clientid, CLOPS_RENEW, &clp, NULL,
5460 (nfsquad_t)((u_quad_t)0), 0, nd, p);
5461 if (!error)
5462 error = nfsrv_getlockfile(NFSLCK_CHECK, NULL, &lfp, &nfh, 0);
5463 if (error) {
5464 NFSUNLOCKSTATE();
5465 if (haslock) {
5466 NFSLOCKV4ROOTMUTEX();
5467 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5468 NFSUNLOCKV4ROOTMUTEX();
5469 }
5470 if (error == -1)
5471 error = 0;
5472 goto out;
5473 }
5474
5475 /*
5476 * Now, we must Recall any delegations.
5477 */
5478 error = nfsrv_cleandeleg(vp, lfp, clp, &haslock, p);
5479 if (error) {
5480 /*
5481 * nfsrv_cleandeleg() unlocks state for non-zero
5482 * return.
5483 */
5484 if (error == -1)
5485 goto tryagain;
5486 if (haslock) {
5487 NFSLOCKV4ROOTMUTEX();
5488 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5489 NFSUNLOCKV4ROOTMUTEX();
5490 }
5491 goto out;
5492 }
5493
5494 /*
5495 * Now, look for a conflicting open share.
5496 */
5497 if (remove) {
5498 /*
5499 * If the entry in the directory was the last reference to the
5500 * corresponding filesystem object, the object can be destroyed
5501 * */
5502 if(lfp->lf_usecount>1)
5503 LIST_FOREACH(stp, &lfp->lf_open, ls_file) {
5504 if (stp->ls_flags & NFSLCK_WRITEDENY) {
5505 error = NFSERR_FILEOPEN;
5506 break;
5507 }
5508 }
5509 }
5510
5511 NFSUNLOCKSTATE();
5512 if (haslock) {
5513 NFSLOCKV4ROOTMUTEX();
5514 nfsv4_unlock(&nfsv4rootfs_lock, 1);
5515 NFSUNLOCKV4ROOTMUTEX();
5516 }
5517
5518 out:
5519 NFSEXITCODE(error);
5520 return (error);
5521 }
5522
5523 /*
5524 * Clear out all delegations for the file referred to by lfp.
5525 * May return NFSERR_DELAY, if there will be a delay waiting for
5526 * delegations to expire.
5527 * Returns -1 to indicate it slept while recalling a delegation.
5528 * This function has the side effect of deleting the nfslockfile structure,
5529 * if it no longer has associated state and didn't have to sleep.
5530 * Unlocks State before a non-zero value is returned.
5531 */
5532 static int
nfsrv_cleandeleg(vnode_t vp,struct nfslockfile * lfp,struct nfsclient * clp,int * haslockp,NFSPROC_T * p)5533 nfsrv_cleandeleg(vnode_t vp, struct nfslockfile *lfp,
5534 struct nfsclient *clp, int *haslockp, NFSPROC_T *p)
5535 {
5536 struct nfsstate *stp, *nstp;
5537 int ret = 0;
5538
5539 stp = LIST_FIRST(&lfp->lf_deleg);
5540 while (stp != LIST_END(&lfp->lf_deleg)) {
5541 nstp = LIST_NEXT(stp, ls_file);
5542 if (stp->ls_clp != clp) {
5543 ret = nfsrv_delegconflict(stp, haslockp, p, vp);
5544 if (ret) {
5545 /*
5546 * nfsrv_delegconflict() unlocks state
5547 * when it returns non-zero.
5548 */
5549 goto out;
5550 }
5551 }
5552 stp = nstp;
5553 }
5554 out:
5555 NFSEXITCODE(ret);
5556 return (ret);
5557 }
5558
5559 /*
5560 * There are certain operations that, when being done outside of NFSv4,
5561 * require that any NFSv4 delegation for the file be recalled.
5562 * This function is to be called for those cases:
5563 * VOP_RENAME() - When a delegation is being recalled for any reason,
5564 * the client may have to do Opens against the server, using the file's
5565 * final component name. If the file has been renamed on the server,
5566 * that component name will be incorrect and the Open will fail.
5567 * VOP_REMOVE() - Theoretically, a client could Open a file after it has
5568 * been removed on the server, if there is a delegation issued to
5569 * that client for the file. I say "theoretically" since clients
5570 * normally do an Access Op before the Open and that Access Op will
5571 * fail with ESTALE. Note that NFSv2 and 3 don't even do Opens, so
5572 * they will detect the file's removal in the same manner. (There is
5573 * one case where RFC3530 allows a client to do an Open without first
5574 * doing an Access Op, which is passage of a check against the ACE
5575 * returned with a Write delegation, but current practice is to ignore
5576 * the ACE and always do an Access Op.)
5577 * Since the functions can only be called with an unlocked vnode, this
5578 * can't be done at this time.
5579 * VOP_ADVLOCK() - When a client holds a delegation, it can issue byte range
5580 * locks locally in the client, which are not visible to the server. To
5581 * deal with this, issuing of delegations for a vnode must be disabled
5582 * and all delegations for the vnode recalled. This is done via the
5583 * second function, using the VV_DISABLEDELEG vflag on the vnode.
5584 */
5585 void
nfsd_recalldelegation(vnode_t vp,NFSPROC_T * p)5586 nfsd_recalldelegation(vnode_t vp, NFSPROC_T *p)
5587 {
5588 time_t starttime;
5589 int error;
5590
5591 /*
5592 * First, check to see if the server is currently running and it has
5593 * been called for a regular file when issuing delegations.
5594 */
5595 if (newnfs_numnfsd == 0 || vp->v_type != VREG ||
5596 nfsrv_issuedelegs == 0)
5597 return;
5598
5599 KASSERT((NFSVOPISLOCKED(vp) != LK_EXCLUSIVE), ("vp %p is locked", vp));
5600 /*
5601 * First, get a reference on the nfsv4rootfs_lock so that an
5602 * exclusive lock cannot be acquired by another thread.
5603 */
5604 NFSLOCKV4ROOTMUTEX();
5605 nfsv4_getref(&nfsv4rootfs_lock, NULL, NFSV4ROOTLOCKMUTEXPTR, NULL);
5606 NFSUNLOCKV4ROOTMUTEX();
5607
5608 /*
5609 * Now, call nfsrv_checkremove() in a loop while it returns
5610 * NFSERR_DELAY. Return upon any other error or when timed out.
5611 */
5612 starttime = NFSD_MONOSEC;
5613 do {
5614 if (NFSVOPLOCK(vp, LK_EXCLUSIVE) == 0) {
5615 error = nfsrv_checkremove(vp, 0, NULL,
5616 (nfsquad_t)((u_quad_t)0), p);
5617 NFSVOPUNLOCK(vp);
5618 } else
5619 error = EPERM;
5620 if (error == NFSERR_DELAY) {
5621 if (NFSD_MONOSEC - starttime > NFS_REMOVETIMEO)
5622 break;
5623 /* Sleep for a short period of time */
5624 (void) nfs_catnap(PZERO, 0, "nfsremove");
5625 }
5626 } while (error == NFSERR_DELAY);
5627 NFSLOCKV4ROOTMUTEX();
5628 nfsv4_relref(&nfsv4rootfs_lock);
5629 NFSUNLOCKV4ROOTMUTEX();
5630 }
5631
5632 void
nfsd_disabledelegation(vnode_t vp,NFSPROC_T * p)5633 nfsd_disabledelegation(vnode_t vp, NFSPROC_T *p)
5634 {
5635
5636 #ifdef VV_DISABLEDELEG
5637 /*
5638 * First, flag issuance of delegations disabled.
5639 */
5640 atomic_set_long(&vp->v_vflag, VV_DISABLEDELEG);
5641 #endif
5642
5643 /*
5644 * Then call nfsd_recalldelegation() to get rid of all extant
5645 * delegations.
5646 */
5647 nfsd_recalldelegation(vp, p);
5648 }
5649
5650 /*
5651 * Check for conflicting locks, etc. and then get rid of delegations.
5652 * (At one point I thought that I should get rid of delegations for any
5653 * Setattr, since it could potentially disallow the I/O op (read or write)
5654 * allowed by the delegation. However, Setattr Ops that aren't changing
5655 * the size get a stateid of all 0s, so you can't tell if it is a delegation
5656 * for the same client or a different one, so I decided to only get rid
5657 * of delegations for other clients when the size is being changed.)
5658 * In general, a Setattr can disable NFS I/O Ops that are outstanding, such
5659 * as Write backs, even if there is no delegation, so it really isn't any
5660 * different?)
5661 */
5662 int
nfsrv_checksetattr(vnode_t vp,struct nfsrv_descript * nd,nfsv4stateid_t * stateidp,struct nfsvattr * nvap,nfsattrbit_t * attrbitp,struct nfsexstuff * exp,NFSPROC_T * p)5663 nfsrv_checksetattr(vnode_t vp, struct nfsrv_descript *nd,
5664 nfsv4stateid_t *stateidp, struct nfsvattr *nvap, nfsattrbit_t *attrbitp,
5665 struct nfsexstuff *exp, NFSPROC_T *p)
5666 {
5667 struct nfsstate st, *stp = &st;
5668 struct nfslock lo, *lop = &lo;
5669 int error = 0;
5670 nfsquad_t clientid;
5671
5672 if (NFSISSET_ATTRBIT(attrbitp, NFSATTRBIT_SIZE)) {
5673 stp->ls_flags = (NFSLCK_CHECK | NFSLCK_WRITEACCESS);
5674 lop->lo_first = nvap->na_size;
5675 } else {
5676 stp->ls_flags = 0;
5677 lop->lo_first = 0;
5678 }
5679 if (NFSISSET_ATTRBIT(attrbitp, NFSATTRBIT_OWNER) ||
5680 NFSISSET_ATTRBIT(attrbitp, NFSATTRBIT_OWNERGROUP) ||
5681 NFSISSET_ATTRBIT(attrbitp, NFSATTRBIT_MODE) ||
5682 NFSISSET_ATTRBIT(attrbitp, NFSATTRBIT_ACL))
5683 stp->ls_flags |= NFSLCK_SETATTR;
5684 if (stp->ls_flags == 0)
5685 goto out;
5686 lop->lo_end = NFS64BITSSET;
5687 lop->lo_flags = NFSLCK_WRITE;
5688 stp->ls_ownerlen = 0;
5689 stp->ls_op = NULL;
5690 stp->ls_uid = nd->nd_cred->cr_uid;
5691 stp->ls_stateid.seqid = stateidp->seqid;
5692 clientid.lval[0] = stp->ls_stateid.other[0] = stateidp->other[0];
5693 clientid.lval[1] = stp->ls_stateid.other[1] = stateidp->other[1];
5694 stp->ls_stateid.other[2] = stateidp->other[2];
5695 error = nfsrv_lockctrl(vp, &stp, &lop, NULL, clientid,
5696 stateidp, exp, nd, p);
5697
5698 out:
5699 NFSEXITCODE2(error, nd);
5700 return (error);
5701 }
5702
5703 /*
5704 * Check for a write delegation and do a CBGETATTR if there is one, updating
5705 * the attributes, as required.
5706 * Should I return an error if I can't get the attributes? (For now, I'll
5707 * just return ok.
5708 */
5709 int
nfsrv_checkgetattr(struct nfsrv_descript * nd,vnode_t vp,struct nfsvattr * nvap,nfsattrbit_t * attrbitp,NFSPROC_T * p)5710 nfsrv_checkgetattr(struct nfsrv_descript *nd, vnode_t vp,
5711 struct nfsvattr *nvap, nfsattrbit_t *attrbitp, NFSPROC_T *p)
5712 {
5713 struct nfsstate *stp;
5714 struct nfslockfile *lfp;
5715 struct nfsclient *clp;
5716 struct nfsvattr nva;
5717 fhandle_t nfh;
5718 int error = 0;
5719 nfsattrbit_t cbbits;
5720 u_quad_t delegfilerev;
5721
5722 NFSCBGETATTR_ATTRBIT(attrbitp, &cbbits);
5723 if (!NFSNONZERO_ATTRBIT(&cbbits))
5724 goto out;
5725 if (nfsrv_writedelegcnt == 0)
5726 goto out;
5727
5728 /*
5729 * Get the lock file structure.
5730 * (A return of -1 means no associated state, so return ok.)
5731 */
5732 error = nfsrv_getlockfh(vp, NFSLCK_CHECK, NULL, &nfh, p);
5733 NFSLOCKSTATE();
5734 if (!error)
5735 error = nfsrv_getlockfile(NFSLCK_CHECK, NULL, &lfp, &nfh, 0);
5736 if (error) {
5737 NFSUNLOCKSTATE();
5738 if (error == -1)
5739 error = 0;
5740 goto out;
5741 }
5742
5743 /*
5744 * Now, look for a write delegation.
5745 */
5746 LIST_FOREACH(stp, &lfp->lf_deleg, ls_file) {
5747 if (stp->ls_flags & NFSLCK_DELEGWRITE)
5748 break;
5749 }
5750 if (stp == LIST_END(&lfp->lf_deleg)) {
5751 NFSUNLOCKSTATE();
5752 goto out;
5753 }
5754 clp = stp->ls_clp;
5755
5756 /* If the clientid is not confirmed, ignore the delegation. */
5757 if (clp->lc_flags & LCL_NEEDSCONFIRM) {
5758 NFSUNLOCKSTATE();
5759 goto out;
5760 }
5761
5762 delegfilerev = stp->ls_filerev;
5763 /*
5764 * If the Write delegation was issued as a part of this Compound RPC
5765 * or if we have an Implied Clientid (used in a previous Op in this
5766 * compound) and it is the client the delegation was issued to,
5767 * just return ok.
5768 * I also assume that it is from the same client iff the network
5769 * host IP address is the same as the callback address. (Not
5770 * exactly correct by the RFC, but avoids a lot of Getattr
5771 * callbacks.)
5772 */
5773 if (nd->nd_compref == stp->ls_compref ||
5774 ((nd->nd_flag & ND_IMPLIEDCLID) &&
5775 clp->lc_clientid.qval == nd->nd_clientid.qval) ||
5776 nfsaddr2_match(clp->lc_req.nr_nam, nd->nd_nam)) {
5777 NFSUNLOCKSTATE();
5778 goto out;
5779 }
5780
5781 /*
5782 * We are now done with the delegation state structure,
5783 * so the statelock can be released and we can now tsleep().
5784 */
5785
5786 /*
5787 * Now, we must do the CB Getattr callback, to see if Change or Size
5788 * has changed.
5789 */
5790 if (clp->lc_expiry >= NFSD_MONOSEC) {
5791 NFSUNLOCKSTATE();
5792 NFSVNO_ATTRINIT(&nva);
5793 nva.na_filerev = NFS64BITSSET;
5794 error = nfsrv_docallback(clp, NFSV4OP_CBGETATTR, NULL,
5795 0, &nfh, &nva, &cbbits, 0, p);
5796 if (!error) {
5797 if ((nva.na_filerev != NFS64BITSSET &&
5798 nva.na_filerev > delegfilerev) ||
5799 (NFSVNO_ISSETSIZE(&nva) &&
5800 nva.na_size != nvap->na_size)) {
5801 error = nfsvno_updfilerev(vp, nvap, nd, p);
5802 if (NFSVNO_ISSETSIZE(&nva))
5803 nvap->na_size = nva.na_size;
5804 }
5805 } else
5806 error = 0; /* Ignore callback errors for now. */
5807 } else {
5808 NFSUNLOCKSTATE();
5809 }
5810
5811 out:
5812 NFSEXITCODE2(error, nd);
5813 return (error);
5814 }
5815
5816 /*
5817 * This function looks for openowners that haven't had any opens for
5818 * a while and throws them away. Called by an nfsd when NFSNSF_NOOPENS
5819 * is set.
5820 */
5821 void
nfsrv_throwawayopens(NFSPROC_T * p)5822 nfsrv_throwawayopens(NFSPROC_T *p)
5823 {
5824 struct nfsclient *clp, *nclp;
5825 struct nfsstate *stp, *nstp;
5826 int i;
5827
5828 NFSLOCKSTATE();
5829 nfsrv_stablefirst.nsf_flags &= ~NFSNSF_NOOPENS;
5830 /*
5831 * For each client...
5832 */
5833 for (i = 0; i < nfsrv_clienthashsize; i++) {
5834 LIST_FOREACH_SAFE(clp, &nfsclienthash[i], lc_hash, nclp) {
5835 LIST_FOREACH_SAFE(stp, &clp->lc_open, ls_list, nstp) {
5836 if (LIST_EMPTY(&stp->ls_open) &&
5837 (stp->ls_noopens > NFSNOOPEN ||
5838 (nfsrv_openpluslock * 2) >
5839 nfsrv_v4statelimit))
5840 nfsrv_freeopenowner(stp, 0, p);
5841 }
5842 }
5843 }
5844 NFSUNLOCKSTATE();
5845 }
5846
5847 /*
5848 * This function checks to see if the credentials are the same.
5849 * Returns 1 for not same, 0 otherwise.
5850 */
5851 static int
nfsrv_notsamecredname(struct nfsrv_descript * nd,struct nfsclient * clp)5852 nfsrv_notsamecredname(struct nfsrv_descript *nd, struct nfsclient *clp)
5853 {
5854
5855 if (nd->nd_flag & ND_GSS) {
5856 if (!(clp->lc_flags & LCL_GSS))
5857 return (1);
5858 if (clp->lc_flags & LCL_NAME) {
5859 if (nd->nd_princlen != clp->lc_namelen ||
5860 NFSBCMP(nd->nd_principal, clp->lc_name,
5861 clp->lc_namelen))
5862 return (1);
5863 else
5864 return (0);
5865 }
5866 if (nd->nd_cred->cr_uid == clp->lc_uid)
5867 return (0);
5868 else
5869 return (1);
5870 } else if (clp->lc_flags & LCL_GSS)
5871 return (1);
5872 /*
5873 * For AUTH_SYS, allow the same uid or root. (This is underspecified
5874 * in RFC3530, which talks about principals, but doesn't say anything
5875 * about uids for AUTH_SYS.)
5876 */
5877 if (nd->nd_cred->cr_uid == clp->lc_uid || nd->nd_cred->cr_uid == 0)
5878 return (0);
5879 else
5880 return (1);
5881 }
5882
5883 /*
5884 * Calculate the lease expiry time.
5885 */
5886 static time_t
nfsrv_leaseexpiry(void)5887 nfsrv_leaseexpiry(void)
5888 {
5889
5890 if (nfsrv_stablefirst.nsf_eograce > NFSD_MONOSEC)
5891 return (NFSD_MONOSEC + 2 * (nfsrv_lease + NFSRV_LEASEDELTA));
5892 return (NFSD_MONOSEC + nfsrv_lease + NFSRV_LEASEDELTA);
5893 }
5894
5895 /*
5896 * Delay the delegation timeout as far as ls_delegtimelimit, as required.
5897 */
5898 static void
nfsrv_delaydelegtimeout(struct nfsstate * stp)5899 nfsrv_delaydelegtimeout(struct nfsstate *stp)
5900 {
5901
5902 if ((stp->ls_flags & NFSLCK_DELEGRECALL) == 0)
5903 return;
5904
5905 if ((stp->ls_delegtime + 15) > NFSD_MONOSEC &&
5906 stp->ls_delegtime < stp->ls_delegtimelimit) {
5907 stp->ls_delegtime += nfsrv_lease;
5908 if (stp->ls_delegtime > stp->ls_delegtimelimit)
5909 stp->ls_delegtime = stp->ls_delegtimelimit;
5910 }
5911 }
5912
5913 /*
5914 * This function checks to see if there is any other state associated
5915 * with the openowner for this Open.
5916 * It returns 1 if there is no other state, 0 otherwise.
5917 */
5918 static int
nfsrv_nootherstate(struct nfsstate * stp)5919 nfsrv_nootherstate(struct nfsstate *stp)
5920 {
5921 struct nfsstate *tstp;
5922
5923 LIST_FOREACH(tstp, &stp->ls_openowner->ls_open, ls_list) {
5924 if (tstp != stp || !LIST_EMPTY(&tstp->ls_lock))
5925 return (0);
5926 }
5927 return (1);
5928 }
5929
5930 /*
5931 * Create a list of lock deltas (changes to local byte range locking
5932 * that can be rolled back using the list) and apply the changes via
5933 * nfsvno_advlock(). Optionally, lock the list. It is expected that either
5934 * the rollback or update function will be called after this.
5935 * It returns an error (and rolls back, as required), if any nfsvno_advlock()
5936 * call fails. If it returns an error, it will unlock the list.
5937 */
5938 static int
nfsrv_locallock(vnode_t vp,struct nfslockfile * lfp,int flags,uint64_t first,uint64_t end,struct nfslockconflict * cfp,NFSPROC_T * p)5939 nfsrv_locallock(vnode_t vp, struct nfslockfile *lfp, int flags,
5940 uint64_t first, uint64_t end, struct nfslockconflict *cfp, NFSPROC_T *p)
5941 {
5942 struct nfslock *lop, *nlop;
5943 int error = 0;
5944
5945 /* Loop through the list of locks. */
5946 lop = LIST_FIRST(&lfp->lf_locallock);
5947 while (first < end && lop != NULL) {
5948 nlop = LIST_NEXT(lop, lo_lckowner);
5949 if (first >= lop->lo_end) {
5950 /* not there yet */
5951 lop = nlop;
5952 } else if (first < lop->lo_first) {
5953 /* new one starts before entry in list */
5954 if (end <= lop->lo_first) {
5955 /* no overlap between old and new */
5956 error = nfsrv_dolocal(vp, lfp, flags,
5957 NFSLCK_UNLOCK, first, end, cfp, p);
5958 if (error != 0)
5959 break;
5960 first = end;
5961 } else {
5962 /* handle fragment overlapped with new one */
5963 error = nfsrv_dolocal(vp, lfp, flags,
5964 NFSLCK_UNLOCK, first, lop->lo_first, cfp,
5965 p);
5966 if (error != 0)
5967 break;
5968 first = lop->lo_first;
5969 }
5970 } else {
5971 /* new one overlaps this entry in list */
5972 if (end <= lop->lo_end) {
5973 /* overlaps all of new one */
5974 error = nfsrv_dolocal(vp, lfp, flags,
5975 lop->lo_flags, first, end, cfp, p);
5976 if (error != 0)
5977 break;
5978 first = end;
5979 } else {
5980 /* handle fragment overlapped with new one */
5981 error = nfsrv_dolocal(vp, lfp, flags,
5982 lop->lo_flags, first, lop->lo_end, cfp, p);
5983 if (error != 0)
5984 break;
5985 first = lop->lo_end;
5986 lop = nlop;
5987 }
5988 }
5989 }
5990 if (first < end && error == 0)
5991 /* handle fragment past end of list */
5992 error = nfsrv_dolocal(vp, lfp, flags, NFSLCK_UNLOCK, first,
5993 end, cfp, p);
5994
5995 NFSEXITCODE(error);
5996 return (error);
5997 }
5998
5999 /*
6000 * Local lock unlock. Unlock all byte ranges that are no longer locked
6001 * by NFSv4. To do this, unlock any subranges of first-->end that
6002 * do not overlap with the byte ranges of any lock in the lfp->lf_lock
6003 * list. This list has all locks for the file held by other
6004 * <clientid, lockowner> tuples. The list is ordered by increasing
6005 * lo_first value, but may have entries that overlap each other, for
6006 * the case of read locks.
6007 */
6008 static void
nfsrv_localunlock(vnode_t vp,struct nfslockfile * lfp,uint64_t init_first,uint64_t init_end,NFSPROC_T * p)6009 nfsrv_localunlock(vnode_t vp, struct nfslockfile *lfp, uint64_t init_first,
6010 uint64_t init_end, NFSPROC_T *p)
6011 {
6012 struct nfslock *lop;
6013 uint64_t first, end, prevfirst __unused;
6014
6015 first = init_first;
6016 end = init_end;
6017 while (first < init_end) {
6018 /* Loop through all nfs locks, adjusting first and end */
6019 prevfirst = 0;
6020 LIST_FOREACH(lop, &lfp->lf_lock, lo_lckfile) {
6021 KASSERT(prevfirst <= lop->lo_first,
6022 ("nfsv4 locks out of order"));
6023 KASSERT(lop->lo_first < lop->lo_end,
6024 ("nfsv4 bogus lock"));
6025 prevfirst = lop->lo_first;
6026 if (first >= lop->lo_first &&
6027 first < lop->lo_end)
6028 /*
6029 * Overlaps with initial part, so trim
6030 * off that initial part by moving first past
6031 * it.
6032 */
6033 first = lop->lo_end;
6034 else if (end > lop->lo_first &&
6035 lop->lo_first > first) {
6036 /*
6037 * This lock defines the end of the
6038 * segment to unlock, so set end to the
6039 * start of it and break out of the loop.
6040 */
6041 end = lop->lo_first;
6042 break;
6043 }
6044 if (first >= end)
6045 /*
6046 * There is no segment left to do, so
6047 * break out of this loop and then exit
6048 * the outer while() since first will be set
6049 * to end, which must equal init_end here.
6050 */
6051 break;
6052 }
6053 if (first < end) {
6054 /* Unlock this segment */
6055 (void) nfsrv_dolocal(vp, lfp, NFSLCK_UNLOCK,
6056 NFSLCK_READ, first, end, NULL, p);
6057 nfsrv_locallock_commit(lfp, NFSLCK_UNLOCK,
6058 first, end);
6059 }
6060 /*
6061 * Now move past this segment and look for any further
6062 * segment in the range, if there is one.
6063 */
6064 first = end;
6065 end = init_end;
6066 }
6067 }
6068
6069 /*
6070 * Do the local lock operation and update the rollback list, as required.
6071 * Perform the rollback and return the error if nfsvno_advlock() fails.
6072 */
6073 static int
nfsrv_dolocal(vnode_t vp,struct nfslockfile * lfp,int flags,int oldflags,uint64_t first,uint64_t end,struct nfslockconflict * cfp,NFSPROC_T * p)6074 nfsrv_dolocal(vnode_t vp, struct nfslockfile *lfp, int flags, int oldflags,
6075 uint64_t first, uint64_t end, struct nfslockconflict *cfp, NFSPROC_T *p)
6076 {
6077 struct nfsrollback *rlp;
6078 int error = 0, ltype, oldltype;
6079
6080 if (flags & NFSLCK_WRITE)
6081 ltype = F_WRLCK;
6082 else if (flags & NFSLCK_READ)
6083 ltype = F_RDLCK;
6084 else
6085 ltype = F_UNLCK;
6086 if (oldflags & NFSLCK_WRITE)
6087 oldltype = F_WRLCK;
6088 else if (oldflags & NFSLCK_READ)
6089 oldltype = F_RDLCK;
6090 else
6091 oldltype = F_UNLCK;
6092 if (ltype == oldltype || (oldltype == F_WRLCK && ltype == F_RDLCK))
6093 /* nothing to do */
6094 goto out;
6095 error = nfsvno_advlock(vp, ltype, first, end, p);
6096 if (error != 0) {
6097 if (cfp != NULL) {
6098 cfp->cl_clientid.lval[0] = 0;
6099 cfp->cl_clientid.lval[1] = 0;
6100 cfp->cl_first = 0;
6101 cfp->cl_end = NFS64BITSSET;
6102 cfp->cl_flags = NFSLCK_WRITE;
6103 cfp->cl_ownerlen = 5;
6104 NFSBCOPY("LOCAL", cfp->cl_owner, 5);
6105 }
6106 nfsrv_locallock_rollback(vp, lfp, p);
6107 } else if (ltype != F_UNLCK) {
6108 rlp = malloc(sizeof (struct nfsrollback), M_NFSDROLLBACK,
6109 M_WAITOK);
6110 rlp->rlck_first = first;
6111 rlp->rlck_end = end;
6112 rlp->rlck_type = oldltype;
6113 LIST_INSERT_HEAD(&lfp->lf_rollback, rlp, rlck_list);
6114 }
6115
6116 out:
6117 NFSEXITCODE(error);
6118 return (error);
6119 }
6120
6121 /*
6122 * Roll back local lock changes and free up the rollback list.
6123 */
6124 static void
nfsrv_locallock_rollback(vnode_t vp,struct nfslockfile * lfp,NFSPROC_T * p)6125 nfsrv_locallock_rollback(vnode_t vp, struct nfslockfile *lfp, NFSPROC_T *p)
6126 {
6127 struct nfsrollback *rlp, *nrlp;
6128
6129 LIST_FOREACH_SAFE(rlp, &lfp->lf_rollback, rlck_list, nrlp) {
6130 (void) nfsvno_advlock(vp, rlp->rlck_type, rlp->rlck_first,
6131 rlp->rlck_end, p);
6132 free(rlp, M_NFSDROLLBACK);
6133 }
6134 LIST_INIT(&lfp->lf_rollback);
6135 }
6136
6137 /*
6138 * Update local lock list and delete rollback list (ie now committed to the
6139 * local locks). Most of the work is done by the internal function.
6140 */
6141 static void
nfsrv_locallock_commit(struct nfslockfile * lfp,int flags,uint64_t first,uint64_t end)6142 nfsrv_locallock_commit(struct nfslockfile *lfp, int flags, uint64_t first,
6143 uint64_t end)
6144 {
6145 struct nfsrollback *rlp, *nrlp;
6146 struct nfslock *new_lop, *other_lop;
6147
6148 new_lop = malloc(sizeof (struct nfslock), M_NFSDLOCK, M_WAITOK);
6149 if (flags & (NFSLCK_READ | NFSLCK_WRITE))
6150 other_lop = malloc(sizeof (struct nfslock), M_NFSDLOCK,
6151 M_WAITOK);
6152 else
6153 other_lop = NULL;
6154 new_lop->lo_flags = flags;
6155 new_lop->lo_first = first;
6156 new_lop->lo_end = end;
6157 nfsrv_updatelock(NULL, &new_lop, &other_lop, lfp);
6158 if (new_lop != NULL)
6159 free(new_lop, M_NFSDLOCK);
6160 if (other_lop != NULL)
6161 free(other_lop, M_NFSDLOCK);
6162
6163 /* and get rid of the rollback list */
6164 LIST_FOREACH_SAFE(rlp, &lfp->lf_rollback, rlck_list, nrlp)
6165 free(rlp, M_NFSDROLLBACK);
6166 LIST_INIT(&lfp->lf_rollback);
6167 }
6168
6169 /*
6170 * Lock the struct nfslockfile for local lock updating.
6171 */
6172 static void
nfsrv_locklf(struct nfslockfile * lfp)6173 nfsrv_locklf(struct nfslockfile *lfp)
6174 {
6175 int gotlock;
6176
6177 /* lf_usecount ensures *lfp won't be free'd */
6178 lfp->lf_usecount++;
6179 do {
6180 gotlock = nfsv4_lock(&lfp->lf_locallock_lck, 1, NULL,
6181 NFSSTATEMUTEXPTR, NULL);
6182 } while (gotlock == 0);
6183 lfp->lf_usecount--;
6184 }
6185
6186 /*
6187 * Unlock the struct nfslockfile after local lock updating.
6188 */
6189 static void
nfsrv_unlocklf(struct nfslockfile * lfp)6190 nfsrv_unlocklf(struct nfslockfile *lfp)
6191 {
6192
6193 nfsv4_unlock(&lfp->lf_locallock_lck, 0);
6194 }
6195
6196 /*
6197 * Clear out all state for the NFSv4 server.
6198 * Must be called by a thread that can sleep when no nfsds are running.
6199 */
6200 void
nfsrv_throwawayallstate(NFSPROC_T * p)6201 nfsrv_throwawayallstate(NFSPROC_T *p)
6202 {
6203 struct nfsclient *clp, *nclp;
6204 struct nfslockfile *lfp, *nlfp;
6205 int i;
6206
6207 /*
6208 * For each client, clean out the state and then free the structure.
6209 */
6210 for (i = 0; i < nfsrv_clienthashsize; i++) {
6211 LIST_FOREACH_SAFE(clp, &nfsclienthash[i], lc_hash, nclp) {
6212 nfsrv_cleanclient(clp, p);
6213 nfsrv_freedeleglist(&clp->lc_deleg);
6214 nfsrv_freedeleglist(&clp->lc_olddeleg);
6215 free(clp->lc_stateid, M_NFSDCLIENT);
6216 free(clp, M_NFSDCLIENT);
6217 }
6218 }
6219
6220 /*
6221 * Also, free up any remaining lock file structures.
6222 */
6223 for (i = 0; i < nfsrv_lockhashsize; i++) {
6224 LIST_FOREACH_SAFE(lfp, &nfslockhash[i], lf_hash, nlfp) {
6225 printf("nfsd unload: fnd a lock file struct\n");
6226 nfsrv_freenfslockfile(lfp);
6227 }
6228 }
6229
6230 /* And get rid of the deviceid structures and layouts. */
6231 nfsrv_freealllayoutsanddevids();
6232 }
6233
6234 /*
6235 * Check the sequence# for the session and slot provided as an argument.
6236 * Also, renew the lease if the session will return NFS_OK.
6237 */
6238 int
nfsrv_checksequence(struct nfsrv_descript * nd,uint32_t sequenceid,uint32_t * highest_slotidp,uint32_t * target_highest_slotidp,int cache_this,uint32_t * sflagsp,NFSPROC_T * p)6239 nfsrv_checksequence(struct nfsrv_descript *nd, uint32_t sequenceid,
6240 uint32_t *highest_slotidp, uint32_t *target_highest_slotidp, int cache_this,
6241 uint32_t *sflagsp, NFSPROC_T *p)
6242 {
6243 struct nfsdsession *sep;
6244 struct nfssessionhash *shp;
6245 int error;
6246
6247 shp = NFSSESSIONHASH(nd->nd_sessionid);
6248 NFSLOCKSESSION(shp);
6249 sep = nfsrv_findsession(nd->nd_sessionid);
6250 if (sep == NULL) {
6251 NFSUNLOCKSESSION(shp);
6252 return (NFSERR_BADSESSION);
6253 }
6254 error = nfsv4_seqsession(sequenceid, nd->nd_slotid, *highest_slotidp,
6255 sep->sess_slots, NULL, NFSV4_SLOTS - 1);
6256 if (error != 0) {
6257 NFSUNLOCKSESSION(shp);
6258 return (error);
6259 }
6260 if (cache_this != 0)
6261 nd->nd_flag |= ND_SAVEREPLY;
6262 /* Renew the lease. */
6263 sep->sess_clp->lc_expiry = nfsrv_leaseexpiry();
6264 nd->nd_clientid.qval = sep->sess_clp->lc_clientid.qval;
6265 nd->nd_flag |= ND_IMPLIEDCLID;
6266
6267 /* Save maximum request and reply sizes. */
6268 nd->nd_maxreq = sep->sess_maxreq;
6269 nd->nd_maxresp = sep->sess_maxresp;
6270
6271 *sflagsp = 0;
6272 if (sep->sess_clp->lc_req.nr_client == NULL ||
6273 (sep->sess_clp->lc_flags & LCL_CBDOWN) != 0)
6274 *sflagsp |= NFSV4SEQ_CBPATHDOWN;
6275 NFSUNLOCKSESSION(shp);
6276 if (error == NFSERR_EXPIRED) {
6277 *sflagsp |= NFSV4SEQ_EXPIREDALLSTATEREVOKED;
6278 error = 0;
6279 } else if (error == NFSERR_ADMINREVOKED) {
6280 *sflagsp |= NFSV4SEQ_ADMINSTATEREVOKED;
6281 error = 0;
6282 }
6283 *highest_slotidp = *target_highest_slotidp = NFSV4_SLOTS - 1;
6284 return (0);
6285 }
6286
6287 /*
6288 * Check/set reclaim complete for this session/clientid.
6289 */
6290 int
nfsrv_checkreclaimcomplete(struct nfsrv_descript * nd,int onefs)6291 nfsrv_checkreclaimcomplete(struct nfsrv_descript *nd, int onefs)
6292 {
6293 struct nfsdsession *sep;
6294 struct nfssessionhash *shp;
6295 int error = 0;
6296
6297 shp = NFSSESSIONHASH(nd->nd_sessionid);
6298 NFSLOCKSTATE();
6299 NFSLOCKSESSION(shp);
6300 sep = nfsrv_findsession(nd->nd_sessionid);
6301 if (sep == NULL) {
6302 NFSUNLOCKSESSION(shp);
6303 NFSUNLOCKSTATE();
6304 return (NFSERR_BADSESSION);
6305 }
6306
6307 if (onefs != 0)
6308 sep->sess_clp->lc_flags |= LCL_RECLAIMONEFS;
6309 /* Check to see if reclaim complete has already happened. */
6310 else if ((sep->sess_clp->lc_flags & LCL_RECLAIMCOMPLETE) != 0)
6311 error = NFSERR_COMPLETEALREADY;
6312 else {
6313 sep->sess_clp->lc_flags |= LCL_RECLAIMCOMPLETE;
6314 nfsrv_markreclaim(sep->sess_clp);
6315 }
6316 NFSUNLOCKSESSION(shp);
6317 NFSUNLOCKSTATE();
6318 return (error);
6319 }
6320
6321 /*
6322 * Cache the reply in a session slot.
6323 */
6324 void
nfsrv_cache_session(struct nfsrv_descript * nd,struct mbuf ** m)6325 nfsrv_cache_session(struct nfsrv_descript *nd, struct mbuf **m)
6326 {
6327 struct nfsdsession *sep;
6328 struct nfssessionhash *shp;
6329 char *buf, *cp;
6330 #ifdef INET
6331 struct sockaddr_in *sin;
6332 #endif
6333 #ifdef INET6
6334 struct sockaddr_in6 *sin6;
6335 #endif
6336
6337 shp = NFSSESSIONHASH(nd->nd_sessionid);
6338 NFSLOCKSESSION(shp);
6339 sep = nfsrv_findsession(nd->nd_sessionid);
6340 if (sep == NULL) {
6341 NFSUNLOCKSESSION(shp);
6342 if ((nfsrv_stablefirst.nsf_flags & NFSNSF_GRACEOVER) != 0) {
6343 buf = malloc(INET6_ADDRSTRLEN, M_TEMP, M_WAITOK);
6344 switch (nd->nd_nam->sa_family) {
6345 #ifdef INET
6346 case AF_INET:
6347 sin = (struct sockaddr_in *)nd->nd_nam;
6348 cp = inet_ntop(sin->sin_family,
6349 &sin->sin_addr.s_addr, buf,
6350 INET6_ADDRSTRLEN);
6351 break;
6352 #endif
6353 #ifdef INET6
6354 case AF_INET6:
6355 sin6 = (struct sockaddr_in6 *)nd->nd_nam;
6356 cp = inet_ntop(sin6->sin6_family,
6357 &sin6->sin6_addr, buf, INET6_ADDRSTRLEN);
6358 break;
6359 #endif
6360 default:
6361 cp = NULL;
6362 }
6363 if (cp != NULL)
6364 printf("nfsrv_cache_session: no session "
6365 "IPaddr=%s\n", cp);
6366 else
6367 printf("nfsrv_cache_session: no session\n");
6368 free(buf, M_TEMP);
6369 }
6370 m_freem(*m);
6371 return;
6372 }
6373 nfsv4_seqsess_cacherep(nd->nd_slotid, sep->sess_slots, nd->nd_repstat,
6374 m);
6375 NFSUNLOCKSESSION(shp);
6376 }
6377
6378 /*
6379 * Search for a session that matches the sessionid.
6380 */
6381 static struct nfsdsession *
nfsrv_findsession(uint8_t * sessionid)6382 nfsrv_findsession(uint8_t *sessionid)
6383 {
6384 struct nfsdsession *sep;
6385 struct nfssessionhash *shp;
6386
6387 shp = NFSSESSIONHASH(sessionid);
6388 LIST_FOREACH(sep, &shp->list, sess_hash) {
6389 if (!NFSBCMP(sessionid, sep->sess_sessionid, NFSX_V4SESSIONID))
6390 break;
6391 }
6392 return (sep);
6393 }
6394
6395 /*
6396 * Destroy a session.
6397 */
6398 int
nfsrv_destroysession(struct nfsrv_descript * nd,uint8_t * sessionid)6399 nfsrv_destroysession(struct nfsrv_descript *nd, uint8_t *sessionid)
6400 {
6401 int error, igotlock, samesess;
6402
6403 samesess = 0;
6404 if (!NFSBCMP(sessionid, nd->nd_sessionid, NFSX_V4SESSIONID) &&
6405 (nd->nd_flag & ND_HASSEQUENCE) != 0) {
6406 samesess = 1;
6407 if ((nd->nd_flag & ND_LASTOP) == 0)
6408 return (NFSERR_BADSESSION);
6409 }
6410
6411 /* Lock out other nfsd threads */
6412 NFSLOCKV4ROOTMUTEX();
6413 nfsv4_relref(&nfsv4rootfs_lock);
6414 do {
6415 igotlock = nfsv4_lock(&nfsv4rootfs_lock, 1, NULL,
6416 NFSV4ROOTLOCKMUTEXPTR, NULL);
6417 } while (igotlock == 0);
6418 NFSUNLOCKV4ROOTMUTEX();
6419
6420 error = nfsrv_freesession(NULL, sessionid);
6421 if (error == 0 && samesess != 0)
6422 nd->nd_flag &= ~ND_HASSEQUENCE;
6423
6424 NFSLOCKV4ROOTMUTEX();
6425 nfsv4_unlock(&nfsv4rootfs_lock, 1);
6426 NFSUNLOCKV4ROOTMUTEX();
6427 return (error);
6428 }
6429
6430 /*
6431 * Bind a connection to a session.
6432 * For now, only certain variants are supported, since the current session
6433 * structure can only handle a single backchannel entry, which will be
6434 * applied to all connections if it is set.
6435 */
6436 int
nfsrv_bindconnsess(struct nfsrv_descript * nd,uint8_t * sessionid,int * foreaftp)6437 nfsrv_bindconnsess(struct nfsrv_descript *nd, uint8_t *sessionid, int *foreaftp)
6438 {
6439 struct nfssessionhash *shp;
6440 struct nfsdsession *sep;
6441 struct nfsclient *clp;
6442 SVCXPRT *savxprt;
6443 int error;
6444
6445 error = 0;
6446 savxprt = NULL;
6447 shp = NFSSESSIONHASH(sessionid);
6448 NFSLOCKSTATE();
6449 NFSLOCKSESSION(shp);
6450 sep = nfsrv_findsession(sessionid);
6451 if (sep != NULL) {
6452 clp = sep->sess_clp;
6453 if (*foreaftp == NFSCDFC4_BACK ||
6454 *foreaftp == NFSCDFC4_BACK_OR_BOTH ||
6455 *foreaftp == NFSCDFC4_FORE_OR_BOTH) {
6456 /* Try to set up a backchannel. */
6457 if (clp->lc_req.nr_client == NULL) {
6458 NFSD_DEBUG(2, "nfsrv_bindconnsess: acquire "
6459 "backchannel\n");
6460 clp->lc_req.nr_client = (struct __rpc_client *)
6461 clnt_bck_create(nd->nd_xprt->xp_socket,
6462 sep->sess_cbprogram, NFSV4_CBVERS);
6463 }
6464 if (clp->lc_req.nr_client != NULL) {
6465 NFSD_DEBUG(2, "nfsrv_bindconnsess: set up "
6466 "backchannel\n");
6467 savxprt = sep->sess_cbsess.nfsess_xprt;
6468 SVC_ACQUIRE(nd->nd_xprt);
6469 CLNT_ACQUIRE(clp->lc_req.nr_client);
6470 nd->nd_xprt->xp_p2 = clp->lc_req.nr_client;
6471 /* Disable idle timeout. */
6472 nd->nd_xprt->xp_idletimeout = 0;
6473 sep->sess_cbsess.nfsess_xprt = nd->nd_xprt;
6474 sep->sess_crflags |= NFSV4CRSESS_CONNBACKCHAN;
6475 clp->lc_flags |= LCL_DONEBINDCONN |
6476 LCL_NEEDSCBNULL;
6477 clp->lc_flags &= ~LCL_CBDOWN;
6478 if (*foreaftp == NFSCDFS4_BACK)
6479 *foreaftp = NFSCDFS4_BACK;
6480 else
6481 *foreaftp = NFSCDFS4_BOTH;
6482 } else if (*foreaftp != NFSCDFC4_BACK) {
6483 NFSD_DEBUG(2, "nfsrv_bindconnsess: can't set "
6484 "up backchannel\n");
6485 sep->sess_crflags &= ~NFSV4CRSESS_CONNBACKCHAN;
6486 clp->lc_flags |= LCL_DONEBINDCONN;
6487 *foreaftp = NFSCDFS4_FORE;
6488 } else {
6489 error = NFSERR_NOTSUPP;
6490 printf("nfsrv_bindconnsess: Can't add "
6491 "backchannel\n");
6492 }
6493 } else {
6494 NFSD_DEBUG(2, "nfsrv_bindconnsess: Set forechannel\n");
6495 clp->lc_flags |= LCL_DONEBINDCONN;
6496 *foreaftp = NFSCDFS4_FORE;
6497 }
6498 } else
6499 error = NFSERR_BADSESSION;
6500 NFSUNLOCKSESSION(shp);
6501 NFSUNLOCKSTATE();
6502 if (savxprt != NULL)
6503 SVC_RELEASE(savxprt);
6504 return (error);
6505 }
6506
6507 /*
6508 * Free up a session structure.
6509 */
6510 static int
nfsrv_freesession(struct nfsdsession * sep,uint8_t * sessionid)6511 nfsrv_freesession(struct nfsdsession *sep, uint8_t *sessionid)
6512 {
6513 struct nfssessionhash *shp;
6514 int i;
6515
6516 NFSLOCKSTATE();
6517 if (sep == NULL) {
6518 shp = NFSSESSIONHASH(sessionid);
6519 NFSLOCKSESSION(shp);
6520 sep = nfsrv_findsession(sessionid);
6521 } else {
6522 shp = NFSSESSIONHASH(sep->sess_sessionid);
6523 NFSLOCKSESSION(shp);
6524 }
6525 if (sep != NULL) {
6526 sep->sess_refcnt--;
6527 if (sep->sess_refcnt > 0) {
6528 NFSUNLOCKSESSION(shp);
6529 NFSUNLOCKSTATE();
6530 return (NFSERR_BACKCHANBUSY);
6531 }
6532 LIST_REMOVE(sep, sess_hash);
6533 LIST_REMOVE(sep, sess_list);
6534 }
6535 NFSUNLOCKSESSION(shp);
6536 NFSUNLOCKSTATE();
6537 if (sep == NULL)
6538 return (NFSERR_BADSESSION);
6539 for (i = 0; i < NFSV4_SLOTS; i++)
6540 if (sep->sess_slots[i].nfssl_reply != NULL)
6541 m_freem(sep->sess_slots[i].nfssl_reply);
6542 if (sep->sess_cbsess.nfsess_xprt != NULL)
6543 SVC_RELEASE(sep->sess_cbsess.nfsess_xprt);
6544 free(sep, M_NFSDSESSION);
6545 return (0);
6546 }
6547
6548 /*
6549 * Free a stateid.
6550 * RFC5661 says that it should fail when there are associated opens, locks
6551 * or delegations. Since stateids represent opens, I don't see how you can
6552 * free an open stateid (it will be free'd when closed), so this function
6553 * only works for lock stateids (freeing the lock_owner) or delegations.
6554 */
6555 int
nfsrv_freestateid(struct nfsrv_descript * nd,nfsv4stateid_t * stateidp,NFSPROC_T * p)6556 nfsrv_freestateid(struct nfsrv_descript *nd, nfsv4stateid_t *stateidp,
6557 NFSPROC_T *p)
6558 {
6559 struct nfsclient *clp;
6560 struct nfsstate *stp;
6561 int error;
6562
6563 NFSLOCKSTATE();
6564 /*
6565 * Look up the stateid
6566 */
6567 error = nfsrv_getclient((nfsquad_t)((u_quad_t)0), CLOPS_RENEW, &clp,
6568 NULL, (nfsquad_t)((u_quad_t)0), 0, nd, p);
6569 if (error == 0) {
6570 /* First, check for a delegation. */
6571 LIST_FOREACH(stp, &clp->lc_deleg, ls_list) {
6572 if (!NFSBCMP(stp->ls_stateid.other, stateidp->other,
6573 NFSX_STATEIDOTHER))
6574 break;
6575 }
6576 if (stp != NULL) {
6577 nfsrv_freedeleg(stp);
6578 NFSUNLOCKSTATE();
6579 return (error);
6580 }
6581 }
6582 /* Not a delegation, try for a lock_owner. */
6583 if (error == 0)
6584 error = nfsrv_getstate(clp, stateidp, 0, &stp);
6585 if (error == 0 && ((stp->ls_flags & (NFSLCK_OPEN | NFSLCK_DELEGREAD |
6586 NFSLCK_DELEGWRITE)) != 0 || (stp->ls_flags & NFSLCK_LOCK) == 0))
6587 /* Not a lock_owner stateid. */
6588 error = NFSERR_LOCKSHELD;
6589 if (error == 0 && !LIST_EMPTY(&stp->ls_lock))
6590 error = NFSERR_LOCKSHELD;
6591 if (error == 0)
6592 nfsrv_freelockowner(stp, NULL, 0, p);
6593 NFSUNLOCKSTATE();
6594 return (error);
6595 }
6596
6597 /*
6598 * Test a stateid.
6599 */
6600 int
nfsrv_teststateid(struct nfsrv_descript * nd,nfsv4stateid_t * stateidp,NFSPROC_T * p)6601 nfsrv_teststateid(struct nfsrv_descript *nd, nfsv4stateid_t *stateidp,
6602 NFSPROC_T *p)
6603 {
6604 struct nfsclient *clp;
6605 struct nfsstate *stp;
6606 int error;
6607
6608 NFSLOCKSTATE();
6609 /*
6610 * Look up the stateid
6611 */
6612 error = nfsrv_getclient((nfsquad_t)((u_quad_t)0), CLOPS_RENEW, &clp,
6613 NULL, (nfsquad_t)((u_quad_t)0), 0, nd, p);
6614 if (error == 0)
6615 error = nfsrv_getstate(clp, stateidp, 0, &stp);
6616 if (error == 0 && stateidp->seqid != 0 &&
6617 SEQ_LT(stateidp->seqid, stp->ls_stateid.seqid))
6618 error = NFSERR_OLDSTATEID;
6619 NFSUNLOCKSTATE();
6620 return (error);
6621 }
6622
6623 /*
6624 * Generate the xdr for an NFSv4.1 CBSequence Operation.
6625 */
6626 static int
nfsv4_setcbsequence(struct nfsrv_descript * nd,struct nfsclient * clp,int dont_replycache,struct nfsdsession ** sepp,int * slotposp)6627 nfsv4_setcbsequence(struct nfsrv_descript *nd, struct nfsclient *clp,
6628 int dont_replycache, struct nfsdsession **sepp, int *slotposp)
6629 {
6630 struct nfsdsession *sep;
6631 uint32_t *tl, slotseq = 0;
6632 int maxslot;
6633 uint8_t sessionid[NFSX_V4SESSIONID];
6634 int error;
6635
6636 error = nfsv4_getcbsession(clp, sepp);
6637 if (error != 0)
6638 return (error);
6639 sep = *sepp;
6640 (void)nfsv4_sequencelookup(NULL, &sep->sess_cbsess, slotposp, &maxslot,
6641 &slotseq, sessionid);
6642 KASSERT(maxslot >= 0, ("nfsv4_setcbsequence neg maxslot"));
6643
6644 /* Build the Sequence arguments. */
6645 NFSM_BUILD(tl, uint32_t *, NFSX_V4SESSIONID + 5 * NFSX_UNSIGNED);
6646 bcopy(sessionid, tl, NFSX_V4SESSIONID);
6647 tl += NFSX_V4SESSIONID / NFSX_UNSIGNED;
6648 nd->nd_slotseq = tl;
6649 *tl++ = txdr_unsigned(slotseq);
6650 *tl++ = txdr_unsigned(*slotposp);
6651 *tl++ = txdr_unsigned(maxslot);
6652 if (dont_replycache == 0)
6653 *tl++ = newnfs_true;
6654 else
6655 *tl++ = newnfs_false;
6656 *tl = 0; /* No referring call list, for now. */
6657 nd->nd_flag |= ND_HASSEQUENCE;
6658 return (0);
6659 }
6660
6661 /*
6662 * Get a session for the callback.
6663 */
6664 static int
nfsv4_getcbsession(struct nfsclient * clp,struct nfsdsession ** sepp)6665 nfsv4_getcbsession(struct nfsclient *clp, struct nfsdsession **sepp)
6666 {
6667 struct nfsdsession *sep;
6668
6669 NFSLOCKSTATE();
6670 LIST_FOREACH(sep, &clp->lc_session, sess_list) {
6671 if ((sep->sess_crflags & NFSV4CRSESS_CONNBACKCHAN) != 0)
6672 break;
6673 }
6674 if (sep == NULL) {
6675 NFSUNLOCKSTATE();
6676 return (NFSERR_BADSESSION);
6677 }
6678 sep->sess_refcnt++;
6679 *sepp = sep;
6680 NFSUNLOCKSTATE();
6681 return (0);
6682 }
6683
6684 /*
6685 * Free up all backchannel xprts. This needs to be done when the nfsd threads
6686 * exit, since those transports will all be going away.
6687 * This is only called after all the nfsd threads are done performing RPCs,
6688 * so locking shouldn't be an issue.
6689 */
6690 void
nfsrv_freeallbackchannel_xprts(void)6691 nfsrv_freeallbackchannel_xprts(void)
6692 {
6693 struct nfsdsession *sep;
6694 struct nfsclient *clp;
6695 SVCXPRT *xprt;
6696 int i;
6697
6698 for (i = 0; i < nfsrv_clienthashsize; i++) {
6699 LIST_FOREACH(clp, &nfsclienthash[i], lc_hash) {
6700 LIST_FOREACH(sep, &clp->lc_session, sess_list) {
6701 xprt = sep->sess_cbsess.nfsess_xprt;
6702 sep->sess_cbsess.nfsess_xprt = NULL;
6703 if (xprt != NULL)
6704 SVC_RELEASE(xprt);
6705 }
6706 }
6707 }
6708 }
6709
6710 /*
6711 * Do a layout commit. Actually just call nfsrv_updatemdsattr().
6712 * I have no idea if the rest of these arguments will ever be useful?
6713 */
6714 int
nfsrv_layoutcommit(struct nfsrv_descript * nd,vnode_t vp,int layouttype,int hasnewoff,uint64_t newoff,uint64_t offset,uint64_t len,int hasnewmtime,struct timespec * newmtimep,int reclaim,nfsv4stateid_t * stateidp,int maxcnt,char * layp,int * hasnewsizep,uint64_t * newsizep,struct ucred * cred,NFSPROC_T * p)6715 nfsrv_layoutcommit(struct nfsrv_descript *nd, vnode_t vp, int layouttype,
6716 int hasnewoff, uint64_t newoff, uint64_t offset, uint64_t len,
6717 int hasnewmtime, struct timespec *newmtimep, int reclaim,
6718 nfsv4stateid_t *stateidp, int maxcnt, char *layp, int *hasnewsizep,
6719 uint64_t *newsizep, struct ucred *cred, NFSPROC_T *p)
6720 {
6721 struct nfsvattr na;
6722 int error;
6723
6724 error = nfsrv_updatemdsattr(vp, &na, p);
6725 if (error == 0) {
6726 *hasnewsizep = 1;
6727 *newsizep = na.na_size;
6728 }
6729 return (error);
6730 }
6731
6732 /*
6733 * Try and get a layout.
6734 */
6735 int
nfsrv_layoutget(struct nfsrv_descript * nd,vnode_t vp,struct nfsexstuff * exp,int layouttype,int * iomode,uint64_t * offset,uint64_t * len,uint64_t minlen,nfsv4stateid_t * stateidp,int maxcnt,int * retonclose,int * layoutlenp,char * layp,struct ucred * cred,NFSPROC_T * p)6736 nfsrv_layoutget(struct nfsrv_descript *nd, vnode_t vp, struct nfsexstuff *exp,
6737 int layouttype, int *iomode, uint64_t *offset, uint64_t *len,
6738 uint64_t minlen, nfsv4stateid_t *stateidp, int maxcnt, int *retonclose,
6739 int *layoutlenp, char *layp, struct ucred *cred, NFSPROC_T *p)
6740 {
6741 struct nfslayouthash *lhyp;
6742 struct nfslayout *lyp;
6743 char *devid;
6744 fhandle_t fh, *dsfhp;
6745 int error, mirrorcnt;
6746
6747 if (nfsrv_devidcnt == 0)
6748 return (NFSERR_UNKNLAYOUTTYPE);
6749
6750 if (*offset != 0)
6751 printf("nfsrv_layoutget: off=%ju len=%ju\n", (uintmax_t)*offset,
6752 (uintmax_t)*len);
6753 error = nfsvno_getfh(vp, &fh, p);
6754 NFSD_DEBUG(4, "layoutget getfh=%d\n", error);
6755 if (error != 0)
6756 return (error);
6757
6758 /*
6759 * For now, all layouts are for entire files.
6760 * Only issue Read/Write layouts if requested for a non-readonly fs.
6761 */
6762 if (NFSVNO_EXRDONLY(exp)) {
6763 if (*iomode == NFSLAYOUTIOMODE_RW)
6764 return (NFSERR_LAYOUTTRYLATER);
6765 *iomode = NFSLAYOUTIOMODE_READ;
6766 }
6767 if (*iomode != NFSLAYOUTIOMODE_RW)
6768 *iomode = NFSLAYOUTIOMODE_READ;
6769
6770 /*
6771 * Check to see if a write layout can be issued for this file.
6772 * This is used during mirror recovery to avoid RW layouts being
6773 * issued for a file while it is being copied to the recovered
6774 * mirror.
6775 */
6776 if (*iomode == NFSLAYOUTIOMODE_RW && nfsrv_dontlayout(&fh) != 0)
6777 return (NFSERR_LAYOUTTRYLATER);
6778
6779 *retonclose = 0;
6780 *offset = 0;
6781 *len = UINT64_MAX;
6782
6783 /* First, see if a layout already exists and return if found. */
6784 lhyp = NFSLAYOUTHASH(&fh);
6785 NFSLOCKLAYOUT(lhyp);
6786 error = nfsrv_findlayout(&nd->nd_clientid, &fh, layouttype, p, &lyp);
6787 NFSD_DEBUG(4, "layoutget findlay=%d\n", error);
6788 /*
6789 * Not sure if the seqid must be the same, so I won't check it.
6790 */
6791 if (error == 0 && (stateidp->other[0] != lyp->lay_stateid.other[0] ||
6792 stateidp->other[1] != lyp->lay_stateid.other[1] ||
6793 stateidp->other[2] != lyp->lay_stateid.other[2])) {
6794 if ((lyp->lay_flags & NFSLAY_CALLB) == 0) {
6795 NFSUNLOCKLAYOUT(lhyp);
6796 NFSD_DEBUG(1, "ret bad stateid\n");
6797 return (NFSERR_BADSTATEID);
6798 }
6799 /*
6800 * I believe we get here because there is a race between
6801 * the client processing the CBLAYOUTRECALL and the layout
6802 * being deleted here on the server.
6803 * The client has now done a LayoutGet with a non-layout
6804 * stateid, as it would when there is no layout.
6805 * As such, free this layout and set error == NFSERR_BADSTATEID
6806 * so the code below will create a new layout structure as
6807 * would happen if no layout was found.
6808 * "lyp" will be set before being used below, but set it NULL
6809 * as a safety belt.
6810 */
6811 nfsrv_freelayout(&lhyp->list, lyp);
6812 lyp = NULL;
6813 error = NFSERR_BADSTATEID;
6814 }
6815 if (error == 0) {
6816 if (lyp->lay_layoutlen > maxcnt) {
6817 NFSUNLOCKLAYOUT(lhyp);
6818 NFSD_DEBUG(1, "ret layout too small\n");
6819 return (NFSERR_TOOSMALL);
6820 }
6821 if (*iomode == NFSLAYOUTIOMODE_RW) {
6822 if ((lyp->lay_flags & NFSLAY_NOSPC) != 0) {
6823 NFSUNLOCKLAYOUT(lhyp);
6824 NFSD_DEBUG(1, "ret layout nospace\n");
6825 return (NFSERR_NOSPC);
6826 }
6827 lyp->lay_flags |= NFSLAY_RW;
6828 } else
6829 lyp->lay_flags |= NFSLAY_READ;
6830 NFSBCOPY(lyp->lay_xdr, layp, lyp->lay_layoutlen);
6831 *layoutlenp = lyp->lay_layoutlen;
6832 if (++lyp->lay_stateid.seqid == 0)
6833 lyp->lay_stateid.seqid = 1;
6834 stateidp->seqid = lyp->lay_stateid.seqid;
6835 NFSUNLOCKLAYOUT(lhyp);
6836 NFSD_DEBUG(4, "ret fnd layout\n");
6837 return (0);
6838 }
6839 NFSUNLOCKLAYOUT(lhyp);
6840
6841 /* Find the device id and file handle. */
6842 dsfhp = malloc(sizeof(fhandle_t) * NFSDEV_MAXMIRRORS, M_TEMP, M_WAITOK);
6843 devid = malloc(NFSX_V4DEVICEID * NFSDEV_MAXMIRRORS, M_TEMP, M_WAITOK);
6844 error = nfsrv_dsgetdevandfh(vp, p, &mirrorcnt, dsfhp, devid);
6845 NFSD_DEBUG(4, "layoutget devandfh=%d\n", error);
6846 if (error == 0) {
6847 if (layouttype == NFSLAYOUT_NFSV4_1_FILES) {
6848 if (NFSX_V4FILELAYOUT > maxcnt)
6849 error = NFSERR_TOOSMALL;
6850 else
6851 lyp = nfsrv_filelayout(nd, *iomode, &fh, dsfhp,
6852 devid, vp->v_mount->mnt_stat.f_fsid);
6853 } else {
6854 if (NFSX_V4FLEXLAYOUT(mirrorcnt) > maxcnt)
6855 error = NFSERR_TOOSMALL;
6856 else
6857 lyp = nfsrv_flexlayout(nd, *iomode, mirrorcnt,
6858 &fh, dsfhp, devid,
6859 vp->v_mount->mnt_stat.f_fsid);
6860 }
6861 }
6862 free(dsfhp, M_TEMP);
6863 free(devid, M_TEMP);
6864 if (error != 0)
6865 return (error);
6866
6867 /*
6868 * Now, add this layout to the list.
6869 */
6870 error = nfsrv_addlayout(nd, &lyp, stateidp, layp, layoutlenp, p);
6871 NFSD_DEBUG(4, "layoutget addl=%d\n", error);
6872 /*
6873 * The lyp will be set to NULL by nfsrv_addlayout() if it
6874 * linked the new structure into the lists.
6875 */
6876 free(lyp, M_NFSDSTATE);
6877 return (error);
6878 }
6879
6880 /*
6881 * Generate a File Layout.
6882 */
6883 static struct nfslayout *
nfsrv_filelayout(struct nfsrv_descript * nd,int iomode,fhandle_t * fhp,fhandle_t * dsfhp,char * devid,fsid_t fs)6884 nfsrv_filelayout(struct nfsrv_descript *nd, int iomode, fhandle_t *fhp,
6885 fhandle_t *dsfhp, char *devid, fsid_t fs)
6886 {
6887 uint32_t *tl;
6888 struct nfslayout *lyp;
6889 uint64_t pattern_offset;
6890
6891 lyp = malloc(sizeof(struct nfslayout) + NFSX_V4FILELAYOUT, M_NFSDSTATE,
6892 M_WAITOK | M_ZERO);
6893 lyp->lay_type = NFSLAYOUT_NFSV4_1_FILES;
6894 if (iomode == NFSLAYOUTIOMODE_RW)
6895 lyp->lay_flags = NFSLAY_RW;
6896 else
6897 lyp->lay_flags = NFSLAY_READ;
6898 NFSBCOPY(fhp, &lyp->lay_fh, sizeof(*fhp));
6899 lyp->lay_clientid.qval = nd->nd_clientid.qval;
6900 lyp->lay_fsid = fs;
6901 NFSBCOPY(devid, lyp->lay_deviceid, NFSX_V4DEVICEID);
6902
6903 /* Fill in the xdr for the files layout. */
6904 tl = (uint32_t *)lyp->lay_xdr;
6905 NFSBCOPY(devid, tl, NFSX_V4DEVICEID); /* Device ID. */
6906 tl += (NFSX_V4DEVICEID / NFSX_UNSIGNED);
6907
6908 /* Set the stripe size to the maximum I/O size. */
6909 *tl++ = txdr_unsigned(nfs_srvmaxio & NFSFLAYUTIL_STRIPE_MASK);
6910 *tl++ = 0; /* 1st stripe index. */
6911 pattern_offset = 0;
6912 txdr_hyper(pattern_offset, tl); tl += 2; /* Pattern offset. */
6913 *tl++ = txdr_unsigned(1); /* 1 file handle. */
6914 *tl++ = txdr_unsigned(NFSX_V4PNFSFH);
6915 NFSBCOPY(dsfhp, tl, sizeof(*dsfhp));
6916 lyp->lay_layoutlen = NFSX_V4FILELAYOUT;
6917 return (lyp);
6918 }
6919
6920 #define FLEX_OWNERID "999"
6921 #define FLEX_UID0 "0"
6922 /*
6923 * Generate a Flex File Layout.
6924 * The FLEX_OWNERID can be any string of 3 decimal digits. Although this
6925 * string goes on the wire, it isn't supposed to be used by the client,
6926 * since this server uses tight coupling.
6927 * Although not recommended by the spec., if vfs.nfsd.flexlinuxhack=1 use
6928 * a string of "0". This works around the Linux Flex File Layout driver bug
6929 * which uses the synthetic uid/gid strings for the "tightly coupled" case.
6930 */
6931 static struct nfslayout *
nfsrv_flexlayout(struct nfsrv_descript * nd,int iomode,int mirrorcnt,fhandle_t * fhp,fhandle_t * dsfhp,char * devid,fsid_t fs)6932 nfsrv_flexlayout(struct nfsrv_descript *nd, int iomode, int mirrorcnt,
6933 fhandle_t *fhp, fhandle_t *dsfhp, char *devid, fsid_t fs)
6934 {
6935 uint32_t *tl;
6936 struct nfslayout *lyp;
6937 uint64_t lenval;
6938 int i;
6939
6940 lyp = malloc(sizeof(struct nfslayout) + NFSX_V4FLEXLAYOUT(mirrorcnt),
6941 M_NFSDSTATE, M_WAITOK | M_ZERO);
6942 lyp->lay_type = NFSLAYOUT_FLEXFILE;
6943 if (iomode == NFSLAYOUTIOMODE_RW)
6944 lyp->lay_flags = NFSLAY_RW;
6945 else
6946 lyp->lay_flags = NFSLAY_READ;
6947 NFSBCOPY(fhp, &lyp->lay_fh, sizeof(*fhp));
6948 lyp->lay_clientid.qval = nd->nd_clientid.qval;
6949 lyp->lay_fsid = fs;
6950 lyp->lay_mirrorcnt = mirrorcnt;
6951 NFSBCOPY(devid, lyp->lay_deviceid, NFSX_V4DEVICEID);
6952
6953 /* Fill in the xdr for the files layout. */
6954 tl = (uint32_t *)lyp->lay_xdr;
6955 lenval = 0;
6956 txdr_hyper(lenval, tl); tl += 2; /* Stripe unit. */
6957 *tl++ = txdr_unsigned(mirrorcnt); /* # of mirrors. */
6958 for (i = 0; i < mirrorcnt; i++) {
6959 *tl++ = txdr_unsigned(1); /* One stripe. */
6960 NFSBCOPY(devid, tl, NFSX_V4DEVICEID); /* Device ID. */
6961 tl += (NFSX_V4DEVICEID / NFSX_UNSIGNED);
6962 devid += NFSX_V4DEVICEID;
6963 *tl++ = txdr_unsigned(1); /* Efficiency. */
6964 *tl++ = 0; /* Proxy Stateid. */
6965 *tl++ = 0x55555555;
6966 *tl++ = 0x55555555;
6967 *tl++ = 0x55555555;
6968 *tl++ = txdr_unsigned(1); /* 1 file handle. */
6969 *tl++ = txdr_unsigned(NFSX_V4PNFSFH);
6970 NFSBCOPY(dsfhp, tl, sizeof(*dsfhp));
6971 tl += (NFSM_RNDUP(NFSX_V4PNFSFH) / NFSX_UNSIGNED);
6972 dsfhp++;
6973 if (nfsrv_flexlinuxhack != 0) {
6974 *tl++ = txdr_unsigned(strlen(FLEX_UID0));
6975 *tl = 0; /* 0 pad string. */
6976 NFSBCOPY(FLEX_UID0, tl++, strlen(FLEX_UID0));
6977 *tl++ = txdr_unsigned(strlen(FLEX_UID0));
6978 *tl = 0; /* 0 pad string. */
6979 NFSBCOPY(FLEX_UID0, tl++, strlen(FLEX_UID0));
6980 } else {
6981 *tl++ = txdr_unsigned(strlen(FLEX_OWNERID));
6982 NFSBCOPY(FLEX_OWNERID, tl++, NFSX_UNSIGNED);
6983 *tl++ = txdr_unsigned(strlen(FLEX_OWNERID));
6984 NFSBCOPY(FLEX_OWNERID, tl++, NFSX_UNSIGNED);
6985 }
6986 }
6987 *tl++ = txdr_unsigned(0); /* ff_flags. */
6988 *tl = txdr_unsigned(60); /* Status interval hint. */
6989 lyp->lay_layoutlen = NFSX_V4FLEXLAYOUT(mirrorcnt);
6990 return (lyp);
6991 }
6992
6993 /*
6994 * Parse and process Flex File errors returned via LayoutReturn.
6995 */
6996 static void
nfsrv_flexlayouterr(struct nfsrv_descript * nd,uint32_t * layp,int maxcnt,NFSPROC_T * p)6997 nfsrv_flexlayouterr(struct nfsrv_descript *nd, uint32_t *layp, int maxcnt,
6998 NFSPROC_T *p)
6999 {
7000 uint32_t *tl;
7001 int cnt, errcnt, i, j, opnum, stat;
7002 char devid[NFSX_V4DEVICEID];
7003
7004 tl = layp;
7005 maxcnt -= NFSX_UNSIGNED;
7006 if (maxcnt > 0)
7007 cnt = fxdr_unsigned(int, *tl++);
7008 else
7009 cnt = 0;
7010 NFSD_DEBUG(4, "flexlayouterr cnt=%d\n", cnt);
7011 for (i = 0; i < cnt; i++) {
7012 maxcnt -= NFSX_STATEID + 2 * NFSX_HYPER +
7013 NFSX_UNSIGNED;
7014 if (maxcnt <= 0)
7015 break;
7016 /* Skip offset, length and stateid for now. */
7017 tl += (4 + NFSX_STATEID / NFSX_UNSIGNED);
7018 errcnt = fxdr_unsigned(int, *tl++);
7019 NFSD_DEBUG(4, "flexlayouterr errcnt=%d\n", errcnt);
7020 for (j = 0; j < errcnt; j++) {
7021 maxcnt -= NFSX_V4DEVICEID + 2 * NFSX_UNSIGNED;
7022 if (maxcnt < 0)
7023 break;
7024 NFSBCOPY(tl, devid, NFSX_V4DEVICEID);
7025 tl += (NFSX_V4DEVICEID / NFSX_UNSIGNED);
7026 stat = fxdr_unsigned(int, *tl++);
7027 opnum = fxdr_unsigned(int, *tl++);
7028 NFSD_DEBUG(4, "flexlayouterr op=%d stat=%d\n", opnum,
7029 stat);
7030 /*
7031 * Except for NFSERR_ACCES, NFSERR_STALE and
7032 * NFSERR_NOSPC errors, disable the mirror.
7033 */
7034 if (stat != NFSERR_ACCES && stat != NFSERR_STALE &&
7035 stat != NFSERR_NOSPC)
7036 nfsrv_delds(devid, p);
7037
7038 /* For NFSERR_NOSPC, mark all devids and layouts. */
7039 if (stat == NFSERR_NOSPC)
7040 nfsrv_marknospc(devid, true);
7041 }
7042 }
7043 }
7044
7045 /*
7046 * This function removes all flex file layouts which has a mirror with
7047 * a device id that matches the argument.
7048 * Called when the DS represented by the device id has failed.
7049 */
7050 void
nfsrv_flexmirrordel(char * devid,NFSPROC_T * p)7051 nfsrv_flexmirrordel(char *devid, NFSPROC_T *p)
7052 {
7053 uint32_t *tl;
7054 struct nfslayout *lyp, *nlyp;
7055 struct nfslayouthash *lhyp;
7056 struct nfslayouthead loclyp;
7057 int i, j;
7058
7059 NFSD_DEBUG(4, "flexmirrordel\n");
7060 /* Move all layouts found onto a local list. */
7061 TAILQ_INIT(&loclyp);
7062 for (i = 0; i < nfsrv_layouthashsize; i++) {
7063 lhyp = &nfslayouthash[i];
7064 NFSLOCKLAYOUT(lhyp);
7065 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp) {
7066 if (lyp->lay_type == NFSLAYOUT_FLEXFILE &&
7067 lyp->lay_mirrorcnt > 1) {
7068 NFSD_DEBUG(4, "possible match\n");
7069 tl = lyp->lay_xdr;
7070 tl += 3;
7071 for (j = 0; j < lyp->lay_mirrorcnt; j++) {
7072 tl++;
7073 if (NFSBCMP(devid, tl, NFSX_V4DEVICEID)
7074 == 0) {
7075 /* Found one. */
7076 NFSD_DEBUG(4, "fnd one\n");
7077 TAILQ_REMOVE(&lhyp->list, lyp,
7078 lay_list);
7079 TAILQ_INSERT_HEAD(&loclyp, lyp,
7080 lay_list);
7081 break;
7082 }
7083 tl += (NFSX_V4DEVICEID / NFSX_UNSIGNED +
7084 NFSM_RNDUP(NFSX_V4PNFSFH) /
7085 NFSX_UNSIGNED + 11 * NFSX_UNSIGNED);
7086 }
7087 }
7088 }
7089 NFSUNLOCKLAYOUT(lhyp);
7090 }
7091
7092 /* Now, try to do a Layout recall for each one found. */
7093 TAILQ_FOREACH_SAFE(lyp, &loclyp, lay_list, nlyp) {
7094 NFSD_DEBUG(4, "do layout recall\n");
7095 /*
7096 * The layout stateid.seqid needs to be incremented
7097 * before doing a LAYOUT_RECALL callback.
7098 */
7099 if (++lyp->lay_stateid.seqid == 0)
7100 lyp->lay_stateid.seqid = 1;
7101 nfsrv_recalllayout(lyp->lay_clientid, &lyp->lay_stateid,
7102 &lyp->lay_fh, lyp, 1, lyp->lay_type, p);
7103 nfsrv_freelayout(&loclyp, lyp);
7104 }
7105 }
7106
7107 /*
7108 * Do a recall callback to the client for this layout.
7109 */
7110 static int
nfsrv_recalllayout(nfsquad_t clid,nfsv4stateid_t * stateidp,fhandle_t * fhp,struct nfslayout * lyp,int changed,int laytype,NFSPROC_T * p)7111 nfsrv_recalllayout(nfsquad_t clid, nfsv4stateid_t *stateidp, fhandle_t *fhp,
7112 struct nfslayout *lyp, int changed, int laytype, NFSPROC_T *p)
7113 {
7114 struct nfsclient *clp;
7115 int error;
7116
7117 NFSD_DEBUG(4, "nfsrv_recalllayout\n");
7118 error = nfsrv_getclient(clid, 0, &clp, NULL, (nfsquad_t)((u_quad_t)0),
7119 0, NULL, p);
7120 NFSD_DEBUG(4, "aft nfsrv_getclient=%d\n", error);
7121 if (error != 0) {
7122 printf("nfsrv_recalllayout: getclient err=%d\n", error);
7123 return (error);
7124 }
7125 if ((clp->lc_flags & LCL_NFSV41) != 0) {
7126 error = nfsrv_docallback(clp, NFSV4OP_CBLAYOUTRECALL,
7127 stateidp, changed, fhp, NULL, NULL, laytype, p);
7128 /* If lyp != NULL, handle an error return here. */
7129 if (error != 0 && lyp != NULL) {
7130 NFSDRECALLLOCK();
7131 /*
7132 * Mark it returned, since no layout recall
7133 * has been done.
7134 * All errors seem to be non-recoverable, although
7135 * NFSERR_NOMATCHLAYOUT is a normal event.
7136 */
7137 if ((lyp->lay_flags & NFSLAY_RECALL) != 0) {
7138 lyp->lay_flags |= NFSLAY_RETURNED;
7139 wakeup(lyp);
7140 }
7141 NFSDRECALLUNLOCK();
7142 if (error != NFSERR_NOMATCHLAYOUT)
7143 printf("nfsrv_recalllayout: err=%d\n", error);
7144 }
7145 } else
7146 printf("nfsrv_recalllayout: clp not NFSv4.1\n");
7147 return (error);
7148 }
7149
7150 /*
7151 * Find a layout to recall when we exceed our high water mark.
7152 */
7153 void
nfsrv_recalloldlayout(NFSPROC_T * p)7154 nfsrv_recalloldlayout(NFSPROC_T *p)
7155 {
7156 struct nfslayouthash *lhyp;
7157 struct nfslayout *lyp;
7158 nfsquad_t clientid;
7159 nfsv4stateid_t stateid;
7160 fhandle_t fh;
7161 int error, laytype = 0, ret;
7162
7163 lhyp = &nfslayouthash[arc4random() % nfsrv_layouthashsize];
7164 NFSLOCKLAYOUT(lhyp);
7165 TAILQ_FOREACH_REVERSE(lyp, &lhyp->list, nfslayouthead, lay_list) {
7166 if ((lyp->lay_flags & NFSLAY_CALLB) == 0) {
7167 lyp->lay_flags |= NFSLAY_CALLB;
7168 /*
7169 * The layout stateid.seqid needs to be incremented
7170 * before doing a LAYOUT_RECALL callback.
7171 */
7172 if (++lyp->lay_stateid.seqid == 0)
7173 lyp->lay_stateid.seqid = 1;
7174 clientid = lyp->lay_clientid;
7175 stateid = lyp->lay_stateid;
7176 NFSBCOPY(&lyp->lay_fh, &fh, sizeof(fh));
7177 laytype = lyp->lay_type;
7178 break;
7179 }
7180 }
7181 NFSUNLOCKLAYOUT(lhyp);
7182 if (lyp != NULL) {
7183 error = nfsrv_recalllayout(clientid, &stateid, &fh, NULL, 0,
7184 laytype, p);
7185 if (error != 0 && error != NFSERR_NOMATCHLAYOUT)
7186 NFSD_DEBUG(4, "recallold=%d\n", error);
7187 if (error != 0) {
7188 NFSLOCKLAYOUT(lhyp);
7189 /*
7190 * Since the hash list was unlocked, we need to
7191 * find it again.
7192 */
7193 ret = nfsrv_findlayout(&clientid, &fh, laytype, p,
7194 &lyp);
7195 if (ret == 0 &&
7196 (lyp->lay_flags & NFSLAY_CALLB) != 0 &&
7197 lyp->lay_stateid.other[0] == stateid.other[0] &&
7198 lyp->lay_stateid.other[1] == stateid.other[1] &&
7199 lyp->lay_stateid.other[2] == stateid.other[2]) {
7200 /*
7201 * The client no longer knows this layout, so
7202 * it can be free'd now.
7203 */
7204 if (error == NFSERR_NOMATCHLAYOUT)
7205 nfsrv_freelayout(&lhyp->list, lyp);
7206 else {
7207 /*
7208 * Leave it to be tried later by
7209 * clearing NFSLAY_CALLB and moving
7210 * it to the head of the list, so it
7211 * won't be tried again for a while.
7212 */
7213 lyp->lay_flags &= ~NFSLAY_CALLB;
7214 TAILQ_REMOVE(&lhyp->list, lyp,
7215 lay_list);
7216 TAILQ_INSERT_HEAD(&lhyp->list, lyp,
7217 lay_list);
7218 }
7219 }
7220 NFSUNLOCKLAYOUT(lhyp);
7221 }
7222 }
7223 }
7224
7225 /*
7226 * Try and return layout(s).
7227 */
7228 int
nfsrv_layoutreturn(struct nfsrv_descript * nd,vnode_t vp,int layouttype,int iomode,uint64_t offset,uint64_t len,int reclaim,int kind,nfsv4stateid_t * stateidp,int maxcnt,uint32_t * layp,int * fndp,struct ucred * cred,NFSPROC_T * p)7229 nfsrv_layoutreturn(struct nfsrv_descript *nd, vnode_t vp,
7230 int layouttype, int iomode, uint64_t offset, uint64_t len, int reclaim,
7231 int kind, nfsv4stateid_t *stateidp, int maxcnt, uint32_t *layp, int *fndp,
7232 struct ucred *cred, NFSPROC_T *p)
7233 {
7234 struct nfsvattr na;
7235 struct nfslayouthash *lhyp;
7236 struct nfslayout *lyp;
7237 fhandle_t fh;
7238 int error = 0;
7239
7240 *fndp = 0;
7241 if (kind == NFSV4LAYOUTRET_FILE) {
7242 error = nfsvno_getfh(vp, &fh, p);
7243 if (error == 0) {
7244 error = nfsrv_updatemdsattr(vp, &na, p);
7245 if (error != 0)
7246 printf("nfsrv_layoutreturn: updatemdsattr"
7247 " failed=%d\n", error);
7248 }
7249 if (error == 0) {
7250 if (reclaim == newnfs_true) {
7251 error = nfsrv_checkgrace(NULL, NULL,
7252 NFSLCK_RECLAIM);
7253 if (error != NFSERR_NOGRACE)
7254 error = 0;
7255 return (error);
7256 }
7257 lhyp = NFSLAYOUTHASH(&fh);
7258 NFSDRECALLLOCK();
7259 NFSLOCKLAYOUT(lhyp);
7260 error = nfsrv_findlayout(&nd->nd_clientid, &fh,
7261 layouttype, p, &lyp);
7262 NFSD_DEBUG(4, "layoutret findlay=%d\n", error);
7263 if (error == 0 &&
7264 stateidp->other[0] == lyp->lay_stateid.other[0] &&
7265 stateidp->other[1] == lyp->lay_stateid.other[1] &&
7266 stateidp->other[2] == lyp->lay_stateid.other[2]) {
7267 NFSD_DEBUG(4, "nfsrv_layoutreturn: stateid %d"
7268 " %x %x %x laystateid %d %x %x %x"
7269 " off=%ju len=%ju flgs=0x%x\n",
7270 stateidp->seqid, stateidp->other[0],
7271 stateidp->other[1], stateidp->other[2],
7272 lyp->lay_stateid.seqid,
7273 lyp->lay_stateid.other[0],
7274 lyp->lay_stateid.other[1],
7275 lyp->lay_stateid.other[2],
7276 (uintmax_t)offset, (uintmax_t)len,
7277 lyp->lay_flags);
7278 if (++lyp->lay_stateid.seqid == 0)
7279 lyp->lay_stateid.seqid = 1;
7280 stateidp->seqid = lyp->lay_stateid.seqid;
7281 if (offset == 0 && len == UINT64_MAX) {
7282 if ((iomode & NFSLAYOUTIOMODE_READ) !=
7283 0)
7284 lyp->lay_flags &= ~NFSLAY_READ;
7285 if ((iomode & NFSLAYOUTIOMODE_RW) != 0)
7286 lyp->lay_flags &= ~NFSLAY_RW;
7287 if ((lyp->lay_flags & (NFSLAY_READ |
7288 NFSLAY_RW)) == 0)
7289 nfsrv_freelayout(&lhyp->list,
7290 lyp);
7291 else
7292 *fndp = 1;
7293 } else
7294 *fndp = 1;
7295 }
7296 NFSUNLOCKLAYOUT(lhyp);
7297 /* Search the nfsrv_recalllist for a match. */
7298 TAILQ_FOREACH(lyp, &nfsrv_recalllisthead, lay_list) {
7299 if (NFSBCMP(&lyp->lay_fh, &fh,
7300 sizeof(fh)) == 0 &&
7301 lyp->lay_clientid.qval ==
7302 nd->nd_clientid.qval &&
7303 stateidp->other[0] ==
7304 lyp->lay_stateid.other[0] &&
7305 stateidp->other[1] ==
7306 lyp->lay_stateid.other[1] &&
7307 stateidp->other[2] ==
7308 lyp->lay_stateid.other[2]) {
7309 lyp->lay_flags |= NFSLAY_RETURNED;
7310 wakeup(lyp);
7311 error = 0;
7312 }
7313 }
7314 NFSDRECALLUNLOCK();
7315 }
7316 if (layouttype == NFSLAYOUT_FLEXFILE && layp != NULL)
7317 nfsrv_flexlayouterr(nd, layp, maxcnt, p);
7318 } else if (kind == NFSV4LAYOUTRET_FSID)
7319 nfsrv_freelayouts(&nd->nd_clientid,
7320 &vp->v_mount->mnt_stat.f_fsid, layouttype, iomode);
7321 else if (kind == NFSV4LAYOUTRET_ALL)
7322 nfsrv_freelayouts(&nd->nd_clientid, NULL, layouttype, iomode);
7323 else
7324 error = NFSERR_INVAL;
7325 if (error == -1)
7326 error = 0;
7327 return (error);
7328 }
7329
7330 /*
7331 * Look for an existing layout.
7332 */
7333 static int
nfsrv_findlayout(nfsquad_t * clientidp,fhandle_t * fhp,int laytype,NFSPROC_T * p,struct nfslayout ** lypp)7334 nfsrv_findlayout(nfsquad_t *clientidp, fhandle_t *fhp, int laytype,
7335 NFSPROC_T *p, struct nfslayout **lypp)
7336 {
7337 struct nfslayouthash *lhyp;
7338 struct nfslayout *lyp;
7339 int ret;
7340
7341 *lypp = NULL;
7342 ret = 0;
7343 lhyp = NFSLAYOUTHASH(fhp);
7344 TAILQ_FOREACH(lyp, &lhyp->list, lay_list) {
7345 if (NFSBCMP(&lyp->lay_fh, fhp, sizeof(*fhp)) == 0 &&
7346 lyp->lay_clientid.qval == clientidp->qval &&
7347 lyp->lay_type == laytype)
7348 break;
7349 }
7350 if (lyp != NULL)
7351 *lypp = lyp;
7352 else
7353 ret = -1;
7354 return (ret);
7355 }
7356
7357 /*
7358 * Add the new layout, as required.
7359 */
7360 static int
nfsrv_addlayout(struct nfsrv_descript * nd,struct nfslayout ** lypp,nfsv4stateid_t * stateidp,char * layp,int * layoutlenp,NFSPROC_T * p)7361 nfsrv_addlayout(struct nfsrv_descript *nd, struct nfslayout **lypp,
7362 nfsv4stateid_t *stateidp, char *layp, int *layoutlenp, NFSPROC_T *p)
7363 {
7364 struct nfsclient *clp;
7365 struct nfslayouthash *lhyp;
7366 struct nfslayout *lyp, *nlyp;
7367 fhandle_t *fhp;
7368 int error;
7369
7370 KASSERT((nd->nd_flag & ND_IMPLIEDCLID) != 0,
7371 ("nfsrv_layoutget: no nd_clientid\n"));
7372 lyp = *lypp;
7373 fhp = &lyp->lay_fh;
7374 NFSLOCKSTATE();
7375 error = nfsrv_getclient((nfsquad_t)((u_quad_t)0), CLOPS_RENEW, &clp,
7376 NULL, (nfsquad_t)((u_quad_t)0), 0, nd, p);
7377 if (error != 0) {
7378 NFSUNLOCKSTATE();
7379 return (error);
7380 }
7381 lyp->lay_stateid.seqid = stateidp->seqid = 1;
7382 lyp->lay_stateid.other[0] = stateidp->other[0] =
7383 clp->lc_clientid.lval[0];
7384 lyp->lay_stateid.other[1] = stateidp->other[1] =
7385 clp->lc_clientid.lval[1];
7386 lyp->lay_stateid.other[2] = stateidp->other[2] =
7387 nfsrv_nextstateindex(clp);
7388 NFSUNLOCKSTATE();
7389
7390 lhyp = NFSLAYOUTHASH(fhp);
7391 NFSLOCKLAYOUT(lhyp);
7392 TAILQ_FOREACH(nlyp, &lhyp->list, lay_list) {
7393 if (NFSBCMP(&nlyp->lay_fh, fhp, sizeof(*fhp)) == 0 &&
7394 nlyp->lay_clientid.qval == nd->nd_clientid.qval)
7395 break;
7396 }
7397 if (nlyp != NULL) {
7398 /* A layout already exists, so use it. */
7399 nlyp->lay_flags |= (lyp->lay_flags & (NFSLAY_READ | NFSLAY_RW));
7400 NFSBCOPY(nlyp->lay_xdr, layp, nlyp->lay_layoutlen);
7401 *layoutlenp = nlyp->lay_layoutlen;
7402 if (++nlyp->lay_stateid.seqid == 0)
7403 nlyp->lay_stateid.seqid = 1;
7404 stateidp->seqid = nlyp->lay_stateid.seqid;
7405 stateidp->other[0] = nlyp->lay_stateid.other[0];
7406 stateidp->other[1] = nlyp->lay_stateid.other[1];
7407 stateidp->other[2] = nlyp->lay_stateid.other[2];
7408 NFSUNLOCKLAYOUT(lhyp);
7409 return (0);
7410 }
7411
7412 /* Insert the new layout in the lists. */
7413 *lypp = NULL;
7414 atomic_add_int(&nfsrv_layoutcnt, 1);
7415 nfsstatsv1.srvlayouts++;
7416 NFSBCOPY(lyp->lay_xdr, layp, lyp->lay_layoutlen);
7417 *layoutlenp = lyp->lay_layoutlen;
7418 TAILQ_INSERT_HEAD(&lhyp->list, lyp, lay_list);
7419 NFSUNLOCKLAYOUT(lhyp);
7420 return (0);
7421 }
7422
7423 /*
7424 * Get the devinfo for a deviceid.
7425 */
7426 int
nfsrv_getdevinfo(char * devid,int layouttype,uint32_t * maxcnt,uint32_t * notify,int * devaddrlen,char ** devaddr)7427 nfsrv_getdevinfo(char *devid, int layouttype, uint32_t *maxcnt,
7428 uint32_t *notify, int *devaddrlen, char **devaddr)
7429 {
7430 struct nfsdevice *ds;
7431
7432 if ((layouttype != NFSLAYOUT_NFSV4_1_FILES && layouttype !=
7433 NFSLAYOUT_FLEXFILE) ||
7434 (nfsrv_maxpnfsmirror > 1 && layouttype == NFSLAYOUT_NFSV4_1_FILES))
7435 return (NFSERR_UNKNLAYOUTTYPE);
7436
7437 /*
7438 * Now, search for the device id. Note that the structures won't go
7439 * away, but the order changes in the list. As such, the lock only
7440 * needs to be held during the search through the list.
7441 */
7442 NFSDDSLOCK();
7443 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
7444 if (NFSBCMP(devid, ds->nfsdev_deviceid, NFSX_V4DEVICEID) == 0 &&
7445 ds->nfsdev_nmp != NULL)
7446 break;
7447 }
7448 NFSDDSUNLOCK();
7449 if (ds == NULL)
7450 return (NFSERR_NOENT);
7451
7452 /* If the correct nfsdev_XXXXaddrlen is > 0, we have the device info. */
7453 *devaddrlen = 0;
7454 if (layouttype == NFSLAYOUT_NFSV4_1_FILES) {
7455 *devaddrlen = ds->nfsdev_fileaddrlen;
7456 *devaddr = ds->nfsdev_fileaddr;
7457 } else if (layouttype == NFSLAYOUT_FLEXFILE) {
7458 *devaddrlen = ds->nfsdev_flexaddrlen;
7459 *devaddr = ds->nfsdev_flexaddr;
7460 }
7461 if (*devaddrlen == 0)
7462 return (NFSERR_UNKNLAYOUTTYPE);
7463
7464 /*
7465 * The XDR overhead is 3 unsigned values: layout_type,
7466 * length_of_address and notify bitmap.
7467 * If the notify array is changed to not all zeros, the
7468 * count of unsigned values must be increased.
7469 */
7470 if (*maxcnt > 0 && *maxcnt < NFSM_RNDUP(*devaddrlen) +
7471 3 * NFSX_UNSIGNED) {
7472 *maxcnt = NFSM_RNDUP(*devaddrlen) + 3 * NFSX_UNSIGNED;
7473 return (NFSERR_TOOSMALL);
7474 }
7475 return (0);
7476 }
7477
7478 /*
7479 * Free a list of layout state structures.
7480 */
7481 static void
nfsrv_freelayoutlist(nfsquad_t clientid)7482 nfsrv_freelayoutlist(nfsquad_t clientid)
7483 {
7484 struct nfslayouthash *lhyp;
7485 struct nfslayout *lyp, *nlyp;
7486 int i;
7487
7488 for (i = 0; i < nfsrv_layouthashsize; i++) {
7489 lhyp = &nfslayouthash[i];
7490 NFSLOCKLAYOUT(lhyp);
7491 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp) {
7492 if (lyp->lay_clientid.qval == clientid.qval)
7493 nfsrv_freelayout(&lhyp->list, lyp);
7494 }
7495 NFSUNLOCKLAYOUT(lhyp);
7496 }
7497 }
7498
7499 /*
7500 * Free up a layout.
7501 */
7502 static void
nfsrv_freelayout(struct nfslayouthead * lhp,struct nfslayout * lyp)7503 nfsrv_freelayout(struct nfslayouthead *lhp, struct nfslayout *lyp)
7504 {
7505
7506 NFSD_DEBUG(4, "Freelayout=%p\n", lyp);
7507 atomic_add_int(&nfsrv_layoutcnt, -1);
7508 nfsstatsv1.srvlayouts--;
7509 TAILQ_REMOVE(lhp, lyp, lay_list);
7510 free(lyp, M_NFSDSTATE);
7511 }
7512
7513 /*
7514 * Free up a device id.
7515 */
7516 void
nfsrv_freeonedevid(struct nfsdevice * ds)7517 nfsrv_freeonedevid(struct nfsdevice *ds)
7518 {
7519 int i;
7520
7521 atomic_add_int(&nfsrv_devidcnt, -1);
7522 vrele(ds->nfsdev_dvp);
7523 for (i = 0; i < nfsrv_dsdirsize; i++)
7524 if (ds->nfsdev_dsdir[i] != NULL)
7525 vrele(ds->nfsdev_dsdir[i]);
7526 free(ds->nfsdev_fileaddr, M_NFSDSTATE);
7527 free(ds->nfsdev_flexaddr, M_NFSDSTATE);
7528 free(ds->nfsdev_host, M_NFSDSTATE);
7529 free(ds, M_NFSDSTATE);
7530 }
7531
7532 /*
7533 * Free up a device id and its mirrors.
7534 */
7535 static void
nfsrv_freedevid(struct nfsdevice * ds)7536 nfsrv_freedevid(struct nfsdevice *ds)
7537 {
7538
7539 TAILQ_REMOVE(&nfsrv_devidhead, ds, nfsdev_list);
7540 nfsrv_freeonedevid(ds);
7541 }
7542
7543 /*
7544 * Free all layouts and device ids.
7545 * Done when the nfsd threads are shut down since there may be a new
7546 * modified device id list created when the nfsd is restarted.
7547 */
7548 void
nfsrv_freealllayoutsanddevids(void)7549 nfsrv_freealllayoutsanddevids(void)
7550 {
7551 struct nfsdontlist *mrp, *nmrp;
7552 struct nfslayout *lyp, *nlyp;
7553
7554 /* Get rid of the deviceid structures. */
7555 nfsrv_freealldevids();
7556 TAILQ_INIT(&nfsrv_devidhead);
7557 nfsrv_devidcnt = 0;
7558
7559 /* Get rid of all layouts. */
7560 nfsrv_freealllayouts();
7561
7562 /* Get rid of any nfsdontlist entries. */
7563 LIST_FOREACH_SAFE(mrp, &nfsrv_dontlisthead, nfsmr_list, nmrp)
7564 free(mrp, M_NFSDSTATE);
7565 LIST_INIT(&nfsrv_dontlisthead);
7566 nfsrv_dontlistlen = 0;
7567
7568 /* Free layouts in the recall list. */
7569 TAILQ_FOREACH_SAFE(lyp, &nfsrv_recalllisthead, lay_list, nlyp)
7570 nfsrv_freelayout(&nfsrv_recalllisthead, lyp);
7571 TAILQ_INIT(&nfsrv_recalllisthead);
7572 }
7573
7574 /*
7575 * Free layouts that match the arguments.
7576 */
7577 static void
nfsrv_freelayouts(nfsquad_t * clid,fsid_t * fs,int laytype,int iomode)7578 nfsrv_freelayouts(nfsquad_t *clid, fsid_t *fs, int laytype, int iomode)
7579 {
7580 struct nfslayouthash *lhyp;
7581 struct nfslayout *lyp, *nlyp;
7582 int i;
7583
7584 for (i = 0; i < nfsrv_layouthashsize; i++) {
7585 lhyp = &nfslayouthash[i];
7586 NFSLOCKLAYOUT(lhyp);
7587 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp) {
7588 if (clid->qval != lyp->lay_clientid.qval)
7589 continue;
7590 if (fs != NULL && fsidcmp(fs, &lyp->lay_fsid) != 0)
7591 continue;
7592 if (laytype != lyp->lay_type)
7593 continue;
7594 if ((iomode & NFSLAYOUTIOMODE_READ) != 0)
7595 lyp->lay_flags &= ~NFSLAY_READ;
7596 if ((iomode & NFSLAYOUTIOMODE_RW) != 0)
7597 lyp->lay_flags &= ~NFSLAY_RW;
7598 if ((lyp->lay_flags & (NFSLAY_READ | NFSLAY_RW)) == 0)
7599 nfsrv_freelayout(&lhyp->list, lyp);
7600 }
7601 NFSUNLOCKLAYOUT(lhyp);
7602 }
7603 }
7604
7605 /*
7606 * Free all layouts for the argument file.
7607 */
7608 void
nfsrv_freefilelayouts(fhandle_t * fhp)7609 nfsrv_freefilelayouts(fhandle_t *fhp)
7610 {
7611 struct nfslayouthash *lhyp;
7612 struct nfslayout *lyp, *nlyp;
7613
7614 lhyp = NFSLAYOUTHASH(fhp);
7615 NFSLOCKLAYOUT(lhyp);
7616 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp) {
7617 if (NFSBCMP(&lyp->lay_fh, fhp, sizeof(*fhp)) == 0)
7618 nfsrv_freelayout(&lhyp->list, lyp);
7619 }
7620 NFSUNLOCKLAYOUT(lhyp);
7621 }
7622
7623 /*
7624 * Free all layouts.
7625 */
7626 static void
nfsrv_freealllayouts(void)7627 nfsrv_freealllayouts(void)
7628 {
7629 struct nfslayouthash *lhyp;
7630 struct nfslayout *lyp, *nlyp;
7631 int i;
7632
7633 for (i = 0; i < nfsrv_layouthashsize; i++) {
7634 lhyp = &nfslayouthash[i];
7635 NFSLOCKLAYOUT(lhyp);
7636 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp)
7637 nfsrv_freelayout(&lhyp->list, lyp);
7638 NFSUNLOCKLAYOUT(lhyp);
7639 }
7640 }
7641
7642 /*
7643 * Look up the mount path for the DS server.
7644 */
7645 static int
nfsrv_setdsserver(char * dspathp,char * mdspathp,NFSPROC_T * p,struct nfsdevice ** dsp)7646 nfsrv_setdsserver(char *dspathp, char *mdspathp, NFSPROC_T *p,
7647 struct nfsdevice **dsp)
7648 {
7649 struct nameidata nd;
7650 struct nfsdevice *ds;
7651 struct mount *mp;
7652 int error, i;
7653 char *dsdirpath;
7654 size_t dsdirsize;
7655
7656 NFSD_DEBUG(4, "setdssrv path=%s\n", dspathp);
7657 *dsp = NULL;
7658 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF, UIO_SYSSPACE,
7659 dspathp, p);
7660 error = namei(&nd);
7661 NFSD_DEBUG(4, "lookup=%d\n", error);
7662 if (error != 0)
7663 return (error);
7664 if (nd.ni_vp->v_type != VDIR) {
7665 vput(nd.ni_vp);
7666 NFSD_DEBUG(4, "dspath not dir\n");
7667 return (ENOTDIR);
7668 }
7669 if (strcmp(nd.ni_vp->v_mount->mnt_vfc->vfc_name, "nfs") != 0) {
7670 vput(nd.ni_vp);
7671 NFSD_DEBUG(4, "dspath not an NFS mount\n");
7672 return (ENXIO);
7673 }
7674
7675 /*
7676 * Allocate a DS server structure with the NFS mounted directory
7677 * vnode reference counted, so that a non-forced dismount will
7678 * fail with EBUSY.
7679 * This structure is always linked into the list, even if an error
7680 * is being returned. The caller will free the entire list upon
7681 * an error return.
7682 */
7683 *dsp = ds = malloc(sizeof(*ds) + nfsrv_dsdirsize * sizeof(vnode_t),
7684 M_NFSDSTATE, M_WAITOK | M_ZERO);
7685 ds->nfsdev_dvp = nd.ni_vp;
7686 ds->nfsdev_nmp = VFSTONFS(nd.ni_vp->v_mount);
7687 NFSVOPUNLOCK(nd.ni_vp);
7688
7689 dsdirsize = strlen(dspathp) + 16;
7690 dsdirpath = malloc(dsdirsize, M_TEMP, M_WAITOK);
7691 /* Now, create the DS directory structures. */
7692 for (i = 0; i < nfsrv_dsdirsize; i++) {
7693 snprintf(dsdirpath, dsdirsize, "%s/ds%d", dspathp, i);
7694 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF,
7695 UIO_SYSSPACE, dsdirpath, p);
7696 error = namei(&nd);
7697 NFSD_DEBUG(4, "dsdirpath=%s lookup=%d\n", dsdirpath, error);
7698 if (error != 0)
7699 break;
7700 if (nd.ni_vp->v_type != VDIR) {
7701 vput(nd.ni_vp);
7702 error = ENOTDIR;
7703 NFSD_DEBUG(4, "dsdirpath not a VDIR\n");
7704 break;
7705 }
7706 if (strcmp(nd.ni_vp->v_mount->mnt_vfc->vfc_name, "nfs") != 0) {
7707 vput(nd.ni_vp);
7708 error = ENXIO;
7709 NFSD_DEBUG(4, "dsdirpath not an NFS mount\n");
7710 break;
7711 }
7712 ds->nfsdev_dsdir[i] = nd.ni_vp;
7713 NFSVOPUNLOCK(nd.ni_vp);
7714 }
7715 free(dsdirpath, M_TEMP);
7716
7717 if (strlen(mdspathp) > 0) {
7718 /*
7719 * This DS stores file for a specific MDS exported file
7720 * system.
7721 */
7722 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF,
7723 UIO_SYSSPACE, mdspathp, p);
7724 error = namei(&nd);
7725 NFSD_DEBUG(4, "mds lookup=%d\n", error);
7726 if (error != 0)
7727 goto out;
7728 if (nd.ni_vp->v_type != VDIR) {
7729 vput(nd.ni_vp);
7730 error = ENOTDIR;
7731 NFSD_DEBUG(4, "mdspath not dir\n");
7732 goto out;
7733 }
7734 mp = nd.ni_vp->v_mount;
7735 if ((mp->mnt_flag & MNT_EXPORTED) == 0) {
7736 vput(nd.ni_vp);
7737 error = ENXIO;
7738 NFSD_DEBUG(4, "mdspath not an exported fs\n");
7739 goto out;
7740 }
7741 ds->nfsdev_mdsfsid = mp->mnt_stat.f_fsid;
7742 ds->nfsdev_mdsisset = 1;
7743 vput(nd.ni_vp);
7744 }
7745
7746 out:
7747 TAILQ_INSERT_TAIL(&nfsrv_devidhead, ds, nfsdev_list);
7748 atomic_add_int(&nfsrv_devidcnt, 1);
7749 return (error);
7750 }
7751
7752 /*
7753 * Look up the mount path for the DS server and delete it.
7754 */
7755 int
nfsrv_deldsserver(int op,char * dspathp,NFSPROC_T * p)7756 nfsrv_deldsserver(int op, char *dspathp, NFSPROC_T *p)
7757 {
7758 struct mount *mp;
7759 struct nfsmount *nmp;
7760 struct nfsdevice *ds;
7761 int error;
7762
7763 NFSD_DEBUG(4, "deldssrv path=%s\n", dspathp);
7764 /*
7765 * Search for the path in the mount list. Avoid looking the path
7766 * up, since this mount point may be hung, with associated locked
7767 * vnodes, etc.
7768 * Set NFSMNTP_CANCELRPCS so that any forced dismount will be blocked
7769 * until this completes.
7770 * As noted in the man page, this should be done before any forced
7771 * dismount on the mount point, but at least the handshake on
7772 * NFSMNTP_CANCELRPCS should make it safe.
7773 */
7774 error = 0;
7775 ds = NULL;
7776 nmp = NULL;
7777 mtx_lock(&mountlist_mtx);
7778 TAILQ_FOREACH(mp, &mountlist, mnt_list) {
7779 if (strcmp(mp->mnt_stat.f_mntonname, dspathp) == 0 &&
7780 strcmp(mp->mnt_stat.f_fstypename, "nfs") == 0 &&
7781 mp->mnt_data != NULL) {
7782 nmp = VFSTONFS(mp);
7783 NFSLOCKMNT(nmp);
7784 if ((nmp->nm_privflag & (NFSMNTP_FORCEDISM |
7785 NFSMNTP_CANCELRPCS)) == 0) {
7786 nmp->nm_privflag |= NFSMNTP_CANCELRPCS;
7787 NFSUNLOCKMNT(nmp);
7788 } else {
7789 NFSUNLOCKMNT(nmp);
7790 nmp = NULL;
7791 }
7792 break;
7793 }
7794 }
7795 mtx_unlock(&mountlist_mtx);
7796
7797 if (nmp != NULL) {
7798 ds = nfsrv_deldsnmp(op, nmp, p);
7799 NFSD_DEBUG(4, "deldsnmp=%p\n", ds);
7800 if (ds != NULL) {
7801 nfsrv_killrpcs(nmp);
7802 NFSD_DEBUG(4, "aft killrpcs\n");
7803 } else
7804 error = ENXIO;
7805 NFSLOCKMNT(nmp);
7806 nmp->nm_privflag &= ~NFSMNTP_CANCELRPCS;
7807 wakeup(nmp);
7808 NFSUNLOCKMNT(nmp);
7809 } else
7810 error = EINVAL;
7811 return (error);
7812 }
7813
7814 /*
7815 * Search for and remove a DS entry which matches the "nmp" argument.
7816 * The nfsdevice structure pointer is returned so that the caller can
7817 * free it via nfsrv_freeonedevid().
7818 * For the forced case, do not try to do LayoutRecalls, since the server
7819 * must be shut down now anyhow.
7820 */
7821 struct nfsdevice *
nfsrv_deldsnmp(int op,struct nfsmount * nmp,NFSPROC_T * p)7822 nfsrv_deldsnmp(int op, struct nfsmount *nmp, NFSPROC_T *p)
7823 {
7824 struct nfsdevice *fndds;
7825
7826 NFSD_DEBUG(4, "deldsdvp\n");
7827 NFSDDSLOCK();
7828 if (op == PNFSDOP_FORCEDELDS)
7829 fndds = nfsv4_findmirror(nmp);
7830 else
7831 fndds = nfsrv_findmirroredds(nmp);
7832 if (fndds != NULL)
7833 nfsrv_deleteds(fndds);
7834 NFSDDSUNLOCK();
7835 if (fndds != NULL) {
7836 if (op != PNFSDOP_FORCEDELDS)
7837 nfsrv_flexmirrordel(fndds->nfsdev_deviceid, p);
7838 printf("pNFS server: mirror %s failed\n", fndds->nfsdev_host);
7839 }
7840 return (fndds);
7841 }
7842
7843 /*
7844 * Similar to nfsrv_deldsnmp(), except that the DS is indicated by deviceid.
7845 * This function also calls nfsrv_killrpcs() to unblock RPCs on the mount
7846 * point.
7847 * Also, returns an error instead of the nfsdevice found.
7848 */
7849 int
nfsrv_delds(char * devid,NFSPROC_T * p)7850 nfsrv_delds(char *devid, NFSPROC_T *p)
7851 {
7852 struct nfsdevice *ds, *fndds;
7853 struct nfsmount *nmp;
7854 int fndmirror;
7855
7856 NFSD_DEBUG(4, "delds\n");
7857 /*
7858 * Search the DS server list for a match with devid.
7859 * Remove the DS entry if found and there is a mirror.
7860 */
7861 fndds = NULL;
7862 nmp = NULL;
7863 fndmirror = 0;
7864 NFSDDSLOCK();
7865 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
7866 if (NFSBCMP(ds->nfsdev_deviceid, devid, NFSX_V4DEVICEID) == 0 &&
7867 ds->nfsdev_nmp != NULL) {
7868 NFSD_DEBUG(4, "fnd main ds\n");
7869 fndds = ds;
7870 break;
7871 }
7872 }
7873 if (fndds == NULL) {
7874 NFSDDSUNLOCK();
7875 return (ENXIO);
7876 }
7877 if (fndds->nfsdev_mdsisset == 0 && nfsrv_faildscnt > 0)
7878 fndmirror = 1;
7879 else if (fndds->nfsdev_mdsisset != 0) {
7880 /* For the fsid is set case, search for a mirror. */
7881 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
7882 if (ds != fndds && ds->nfsdev_nmp != NULL &&
7883 ds->nfsdev_mdsisset != 0 &&
7884 fsidcmp(&ds->nfsdev_mdsfsid,
7885 &fndds->nfsdev_mdsfsid) == 0) {
7886 fndmirror = 1;
7887 break;
7888 }
7889 }
7890 }
7891 if (fndmirror != 0) {
7892 nmp = fndds->nfsdev_nmp;
7893 NFSLOCKMNT(nmp);
7894 if ((nmp->nm_privflag & (NFSMNTP_FORCEDISM |
7895 NFSMNTP_CANCELRPCS)) == 0) {
7896 nmp->nm_privflag |= NFSMNTP_CANCELRPCS;
7897 NFSUNLOCKMNT(nmp);
7898 nfsrv_deleteds(fndds);
7899 } else {
7900 NFSUNLOCKMNT(nmp);
7901 nmp = NULL;
7902 }
7903 }
7904 NFSDDSUNLOCK();
7905 if (nmp != NULL) {
7906 nfsrv_flexmirrordel(fndds->nfsdev_deviceid, p);
7907 printf("pNFS server: mirror %s failed\n", fndds->nfsdev_host);
7908 nfsrv_killrpcs(nmp);
7909 NFSLOCKMNT(nmp);
7910 nmp->nm_privflag &= ~NFSMNTP_CANCELRPCS;
7911 wakeup(nmp);
7912 NFSUNLOCKMNT(nmp);
7913 return (0);
7914 }
7915 return (ENXIO);
7916 }
7917
7918 /*
7919 * Mark a DS as disabled by setting nfsdev_nmp = NULL.
7920 */
7921 static void
nfsrv_deleteds(struct nfsdevice * fndds)7922 nfsrv_deleteds(struct nfsdevice *fndds)
7923 {
7924
7925 NFSD_DEBUG(4, "deleteds: deleting a mirror\n");
7926 fndds->nfsdev_nmp = NULL;
7927 if (fndds->nfsdev_mdsisset == 0)
7928 nfsrv_faildscnt--;
7929 }
7930
7931 /*
7932 * Fill in the addr structures for the File and Flex File layouts.
7933 */
7934 static void
nfsrv_allocdevid(struct nfsdevice * ds,char * addr,char * dnshost)7935 nfsrv_allocdevid(struct nfsdevice *ds, char *addr, char *dnshost)
7936 {
7937 uint32_t *tl;
7938 char *netprot;
7939 int addrlen;
7940 static uint64_t new_devid = 0;
7941
7942 if (strchr(addr, ':') != NULL)
7943 netprot = "tcp6";
7944 else
7945 netprot = "tcp";
7946
7947 /* Fill in the device id. */
7948 NFSBCOPY(&nfsdev_time, ds->nfsdev_deviceid, sizeof(nfsdev_time));
7949 new_devid++;
7950 NFSBCOPY(&new_devid, &ds->nfsdev_deviceid[sizeof(nfsdev_time)],
7951 sizeof(new_devid));
7952
7953 /*
7954 * Fill in the file addr (actually the nfsv4_file_layout_ds_addr4
7955 * as defined in RFC5661) in XDR.
7956 */
7957 addrlen = NFSM_RNDUP(strlen(addr)) + NFSM_RNDUP(strlen(netprot)) +
7958 6 * NFSX_UNSIGNED;
7959 NFSD_DEBUG(4, "hn=%s addr=%s netprot=%s\n", dnshost, addr, netprot);
7960 ds->nfsdev_fileaddrlen = addrlen;
7961 tl = malloc(addrlen, M_NFSDSTATE, M_WAITOK | M_ZERO);
7962 ds->nfsdev_fileaddr = (char *)tl;
7963 *tl++ = txdr_unsigned(1); /* One stripe with index 0. */
7964 *tl++ = 0;
7965 *tl++ = txdr_unsigned(1); /* One multipath list */
7966 *tl++ = txdr_unsigned(1); /* with one entry in it. */
7967 /* The netaddr for this one entry. */
7968 *tl++ = txdr_unsigned(strlen(netprot));
7969 NFSBCOPY(netprot, tl, strlen(netprot));
7970 tl += (NFSM_RNDUP(strlen(netprot)) / NFSX_UNSIGNED);
7971 *tl++ = txdr_unsigned(strlen(addr));
7972 NFSBCOPY(addr, tl, strlen(addr));
7973
7974 /*
7975 * Fill in the flex file addr (actually the ff_device_addr4
7976 * as defined for Flexible File Layout) in XDR.
7977 */
7978 addrlen = NFSM_RNDUP(strlen(addr)) + NFSM_RNDUP(strlen(netprot)) +
7979 14 * NFSX_UNSIGNED;
7980 ds->nfsdev_flexaddrlen = addrlen;
7981 tl = malloc(addrlen, M_NFSDSTATE, M_WAITOK | M_ZERO);
7982 ds->nfsdev_flexaddr = (char *)tl;
7983 *tl++ = txdr_unsigned(1); /* One multipath entry. */
7984 /* The netaddr for this one entry. */
7985 *tl++ = txdr_unsigned(strlen(netprot));
7986 NFSBCOPY(netprot, tl, strlen(netprot));
7987 tl += (NFSM_RNDUP(strlen(netprot)) / NFSX_UNSIGNED);
7988 *tl++ = txdr_unsigned(strlen(addr));
7989 NFSBCOPY(addr, tl, strlen(addr));
7990 tl += (NFSM_RNDUP(strlen(addr)) / NFSX_UNSIGNED);
7991 *tl++ = txdr_unsigned(2); /* Two NFS Versions. */
7992 *tl++ = txdr_unsigned(NFS_VER4); /* NFSv4. */
7993 *tl++ = txdr_unsigned(NFSV42_MINORVERSION); /* Minor version 2. */
7994 *tl++ = txdr_unsigned(nfs_srvmaxio); /* DS max rsize. */
7995 *tl++ = txdr_unsigned(nfs_srvmaxio); /* DS max wsize. */
7996 *tl++ = newnfs_true; /* Tightly coupled. */
7997 *tl++ = txdr_unsigned(NFS_VER4); /* NFSv4. */
7998 *tl++ = txdr_unsigned(NFSV41_MINORVERSION); /* Minor version 1. */
7999 *tl++ = txdr_unsigned(nfs_srvmaxio); /* DS max rsize. */
8000 *tl++ = txdr_unsigned(nfs_srvmaxio); /* DS max wsize. */
8001 *tl = newnfs_true; /* Tightly coupled. */
8002
8003 ds->nfsdev_hostnamelen = strlen(dnshost);
8004 ds->nfsdev_host = malloc(ds->nfsdev_hostnamelen + 1, M_NFSDSTATE,
8005 M_WAITOK);
8006 NFSBCOPY(dnshost, ds->nfsdev_host, ds->nfsdev_hostnamelen + 1);
8007 }
8008
8009 /*
8010 * Create the device id list.
8011 * Return 0 if the nfsd threads are to run and ENXIO if the "-p" argument
8012 * is misconfigured.
8013 */
8014 int
nfsrv_createdevids(struct nfsd_nfsd_args * args,NFSPROC_T * p)8015 nfsrv_createdevids(struct nfsd_nfsd_args *args, NFSPROC_T *p)
8016 {
8017 struct nfsdevice *ds;
8018 char *addrp, *dnshostp, *dspathp, *mdspathp;
8019 int error, i;
8020
8021 addrp = args->addr;
8022 dnshostp = args->dnshost;
8023 dspathp = args->dspath;
8024 mdspathp = args->mdspath;
8025 nfsrv_maxpnfsmirror = args->mirrorcnt;
8026 if (addrp == NULL || dnshostp == NULL || dspathp == NULL ||
8027 mdspathp == NULL)
8028 return (0);
8029
8030 /*
8031 * Loop around for each nul-terminated string in args->addr,
8032 * args->dnshost, args->dnspath and args->mdspath.
8033 */
8034 while (addrp < (args->addr + args->addrlen) &&
8035 dnshostp < (args->dnshost + args->dnshostlen) &&
8036 dspathp < (args->dspath + args->dspathlen) &&
8037 mdspathp < (args->mdspath + args->mdspathlen)) {
8038 error = nfsrv_setdsserver(dspathp, mdspathp, p, &ds);
8039 if (error != 0) {
8040 /* Free all DS servers. */
8041 nfsrv_freealldevids();
8042 nfsrv_devidcnt = 0;
8043 return (ENXIO);
8044 }
8045 nfsrv_allocdevid(ds, addrp, dnshostp);
8046 addrp += (strlen(addrp) + 1);
8047 dnshostp += (strlen(dnshostp) + 1);
8048 dspathp += (strlen(dspathp) + 1);
8049 mdspathp += (strlen(mdspathp) + 1);
8050 }
8051 if (nfsrv_devidcnt < nfsrv_maxpnfsmirror) {
8052 /* Free all DS servers. */
8053 nfsrv_freealldevids();
8054 nfsrv_devidcnt = 0;
8055 nfsrv_maxpnfsmirror = 1;
8056 return (ENXIO);
8057 }
8058 /* We can fail at most one less DS than the mirror level. */
8059 nfsrv_faildscnt = nfsrv_maxpnfsmirror - 1;
8060
8061 /*
8062 * Allocate the nfslayout hash table now, since this is a pNFS server.
8063 * Make it 1% of the high water mark and at least 100.
8064 */
8065 if (nfslayouthash == NULL) {
8066 nfsrv_layouthashsize = nfsrv_layouthighwater / 100;
8067 if (nfsrv_layouthashsize < 100)
8068 nfsrv_layouthashsize = 100;
8069 nfslayouthash = mallocarray(nfsrv_layouthashsize,
8070 sizeof(struct nfslayouthash), M_NFSDSESSION, M_WAITOK |
8071 M_ZERO);
8072 for (i = 0; i < nfsrv_layouthashsize; i++) {
8073 mtx_init(&nfslayouthash[i].mtx, "nfslm", NULL, MTX_DEF);
8074 TAILQ_INIT(&nfslayouthash[i].list);
8075 }
8076 }
8077 return (0);
8078 }
8079
8080 /*
8081 * Free all device ids.
8082 */
8083 static void
nfsrv_freealldevids(void)8084 nfsrv_freealldevids(void)
8085 {
8086 struct nfsdevice *ds, *nds;
8087
8088 TAILQ_FOREACH_SAFE(ds, &nfsrv_devidhead, nfsdev_list, nds)
8089 nfsrv_freedevid(ds);
8090 }
8091
8092 /*
8093 * Check to see if there is a Read/Write Layout plus either:
8094 * - A Write Delegation
8095 * or
8096 * - An Open with Write_access.
8097 * Return 1 if this is the case and 0 otherwise.
8098 * This function is used by nfsrv_proxyds() to decide if doing a Proxy
8099 * Getattr RPC to the Data Server (DS) is necessary.
8100 */
8101 #define NFSCLIDVECSIZE 6
8102 int
nfsrv_checkdsattr(vnode_t vp,NFSPROC_T * p)8103 nfsrv_checkdsattr(vnode_t vp, NFSPROC_T *p)
8104 {
8105 fhandle_t fh, *tfhp;
8106 struct nfsstate *stp;
8107 struct nfslayout *lyp;
8108 struct nfslayouthash *lhyp;
8109 struct nfslockhashhead *hp;
8110 struct nfslockfile *lfp;
8111 nfsquad_t clid[NFSCLIDVECSIZE];
8112 int clidcnt, ret;
8113
8114 ret = nfsvno_getfh(vp, &fh, p);
8115 if (ret != 0)
8116 return (0);
8117
8118 /* First check for a Read/Write Layout. */
8119 clidcnt = 0;
8120 lhyp = NFSLAYOUTHASH(&fh);
8121 NFSLOCKLAYOUT(lhyp);
8122 TAILQ_FOREACH(lyp, &lhyp->list, lay_list) {
8123 if (NFSBCMP(&lyp->lay_fh, &fh, sizeof(fh)) == 0 &&
8124 ((lyp->lay_flags & NFSLAY_RW) != 0 ||
8125 ((lyp->lay_flags & NFSLAY_READ) != 0 &&
8126 nfsrv_pnfsatime != 0))) {
8127 if (clidcnt < NFSCLIDVECSIZE)
8128 clid[clidcnt].qval = lyp->lay_clientid.qval;
8129 clidcnt++;
8130 }
8131 }
8132 NFSUNLOCKLAYOUT(lhyp);
8133 if (clidcnt == 0) {
8134 /* None found, so return 0. */
8135 return (0);
8136 }
8137
8138 /* Get the nfslockfile for this fh. */
8139 NFSLOCKSTATE();
8140 hp = NFSLOCKHASH(&fh);
8141 LIST_FOREACH(lfp, hp, lf_hash) {
8142 tfhp = &lfp->lf_fh;
8143 if (NFSVNO_CMPFH(&fh, tfhp))
8144 break;
8145 }
8146 if (lfp == NULL) {
8147 /* None found, so return 0. */
8148 NFSUNLOCKSTATE();
8149 return (0);
8150 }
8151
8152 /* Now, look for a Write delegation for this clientid. */
8153 LIST_FOREACH(stp, &lfp->lf_deleg, ls_file) {
8154 if ((stp->ls_flags & NFSLCK_DELEGWRITE) != 0 &&
8155 nfsrv_fndclid(clid, stp->ls_clp->lc_clientid, clidcnt) != 0)
8156 break;
8157 }
8158 if (stp != NULL) {
8159 /* Found one, so return 1. */
8160 NFSUNLOCKSTATE();
8161 return (1);
8162 }
8163
8164 /* No Write delegation, so look for an Open with Write_access. */
8165 LIST_FOREACH(stp, &lfp->lf_open, ls_file) {
8166 KASSERT((stp->ls_flags & NFSLCK_OPEN) != 0,
8167 ("nfsrv_checkdsattr: Non-open in Open list\n"));
8168 if ((stp->ls_flags & NFSLCK_WRITEACCESS) != 0 &&
8169 nfsrv_fndclid(clid, stp->ls_clp->lc_clientid, clidcnt) != 0)
8170 break;
8171 }
8172 NFSUNLOCKSTATE();
8173 if (stp != NULL)
8174 return (1);
8175 return (0);
8176 }
8177
8178 /*
8179 * Look for a matching clientid in the vector. Return 1 if one might match.
8180 */
8181 static int
nfsrv_fndclid(nfsquad_t * clidvec,nfsquad_t clid,int clidcnt)8182 nfsrv_fndclid(nfsquad_t *clidvec, nfsquad_t clid, int clidcnt)
8183 {
8184 int i;
8185
8186 /* If too many for the vector, return 1 since there might be a match. */
8187 if (clidcnt > NFSCLIDVECSIZE)
8188 return (1);
8189
8190 for (i = 0; i < clidcnt; i++)
8191 if (clidvec[i].qval == clid.qval)
8192 return (1);
8193 return (0);
8194 }
8195
8196 /*
8197 * Check the don't list for "vp" and see if issuing an rw layout is allowed.
8198 * Return 1 if issuing an rw layout isn't allowed, 0 otherwise.
8199 */
8200 static int
nfsrv_dontlayout(fhandle_t * fhp)8201 nfsrv_dontlayout(fhandle_t *fhp)
8202 {
8203 struct nfsdontlist *mrp;
8204 int ret;
8205
8206 if (nfsrv_dontlistlen == 0)
8207 return (0);
8208 ret = 0;
8209 NFSDDONTLISTLOCK();
8210 LIST_FOREACH(mrp, &nfsrv_dontlisthead, nfsmr_list) {
8211 if (NFSBCMP(fhp, &mrp->nfsmr_fh, sizeof(*fhp)) == 0 &&
8212 (mrp->nfsmr_flags & NFSMR_DONTLAYOUT) != 0) {
8213 ret = 1;
8214 break;
8215 }
8216 }
8217 NFSDDONTLISTUNLOCK();
8218 return (ret);
8219 }
8220
8221 #define PNFSDS_COPYSIZ 65536
8222 /*
8223 * Create a new file on a DS and copy the contents of an extant DS file to it.
8224 * This can be used for recovery of a DS file onto a recovered DS.
8225 * The steps are:
8226 * - When called, the MDS file's vnode is locked, blocking LayoutGet operations.
8227 * - Disable issuing of read/write layouts for the file via the nfsdontlist,
8228 * so that they will be disabled after the MDS file's vnode is unlocked.
8229 * - Set up the nfsrv_recalllist so that recall of read/write layouts can
8230 * be done.
8231 * - Unlock the MDS file's vnode, so that the client(s) can perform proxied
8232 * writes, LayoutCommits and LayoutReturns for the file when completing the
8233 * LayoutReturn requested by the LayoutRecall callback.
8234 * - Issue a LayoutRecall callback for all read/write layouts and wait for
8235 * them to be returned. (If the LayoutRecall callback replies
8236 * NFSERR_NOMATCHLAYOUT, they are gone and no LayoutReturn is needed.)
8237 * - Exclusively lock the MDS file's vnode. This ensures that no proxied
8238 * writes are in progress or can occur during the DS file copy.
8239 * It also blocks Setattr operations.
8240 * - Create the file on the recovered mirror.
8241 * - Copy the file from the operational DS.
8242 * - Copy any ACL from the MDS file to the new DS file.
8243 * - Set the modify time of the new DS file to that of the MDS file.
8244 * - Update the extended attribute for the MDS file.
8245 * - Enable issuing of rw layouts by deleting the nfsdontlist entry.
8246 * - The caller will unlock the MDS file's vnode allowing operations
8247 * to continue normally, since it is now on the mirror again.
8248 */
8249 int
nfsrv_copymr(vnode_t vp,vnode_t fvp,vnode_t dvp,struct nfsdevice * ds,struct pnfsdsfile * pf,struct pnfsdsfile * wpf,int mirrorcnt,struct ucred * cred,NFSPROC_T * p)8250 nfsrv_copymr(vnode_t vp, vnode_t fvp, vnode_t dvp, struct nfsdevice *ds,
8251 struct pnfsdsfile *pf, struct pnfsdsfile *wpf, int mirrorcnt,
8252 struct ucred *cred, NFSPROC_T *p)
8253 {
8254 struct nfsdontlist *mrp, *nmrp;
8255 struct nfslayouthash *lhyp;
8256 struct nfslayout *lyp, *nlyp;
8257 struct nfslayouthead thl;
8258 struct mount *mp, *tvmp;
8259 struct acl *aclp;
8260 struct vattr va;
8261 struct timespec mtime;
8262 fhandle_t fh;
8263 vnode_t tvp;
8264 off_t rdpos, wrpos;
8265 ssize_t aresid;
8266 char *dat;
8267 int didprintf, ret, retacl, xfer;
8268
8269 ASSERT_VOP_LOCKED(fvp, "nfsrv_copymr fvp");
8270 ASSERT_VOP_LOCKED(vp, "nfsrv_copymr vp");
8271 /*
8272 * Allocate a nfsdontlist entry and set the NFSMR_DONTLAYOUT flag
8273 * so that no more RW layouts will get issued.
8274 */
8275 ret = nfsvno_getfh(vp, &fh, p);
8276 if (ret != 0) {
8277 NFSD_DEBUG(4, "nfsrv_copymr: getfh=%d\n", ret);
8278 return (ret);
8279 }
8280 nmrp = malloc(sizeof(*nmrp), M_NFSDSTATE, M_WAITOK);
8281 nmrp->nfsmr_flags = NFSMR_DONTLAYOUT;
8282 NFSBCOPY(&fh, &nmrp->nfsmr_fh, sizeof(fh));
8283 NFSDDONTLISTLOCK();
8284 LIST_FOREACH(mrp, &nfsrv_dontlisthead, nfsmr_list) {
8285 if (NFSBCMP(&fh, &mrp->nfsmr_fh, sizeof(fh)) == 0)
8286 break;
8287 }
8288 if (mrp == NULL) {
8289 LIST_INSERT_HEAD(&nfsrv_dontlisthead, nmrp, nfsmr_list);
8290 mrp = nmrp;
8291 nmrp = NULL;
8292 nfsrv_dontlistlen++;
8293 NFSD_DEBUG(4, "nfsrv_copymr: in dontlist\n");
8294 } else {
8295 NFSDDONTLISTUNLOCK();
8296 free(nmrp, M_NFSDSTATE);
8297 NFSD_DEBUG(4, "nfsrv_copymr: dup dontlist\n");
8298 return (ENXIO);
8299 }
8300 NFSDDONTLISTUNLOCK();
8301
8302 /*
8303 * Search for all RW layouts for this file. Move them to the
8304 * recall list, so they can be recalled and their return noted.
8305 */
8306 lhyp = NFSLAYOUTHASH(&fh);
8307 NFSDRECALLLOCK();
8308 NFSLOCKLAYOUT(lhyp);
8309 TAILQ_FOREACH_SAFE(lyp, &lhyp->list, lay_list, nlyp) {
8310 if (NFSBCMP(&lyp->lay_fh, &fh, sizeof(fh)) == 0 &&
8311 (lyp->lay_flags & NFSLAY_RW) != 0) {
8312 TAILQ_REMOVE(&lhyp->list, lyp, lay_list);
8313 TAILQ_INSERT_HEAD(&nfsrv_recalllisthead, lyp, lay_list);
8314 lyp->lay_trycnt = 0;
8315 }
8316 }
8317 NFSUNLOCKLAYOUT(lhyp);
8318 NFSDRECALLUNLOCK();
8319
8320 ret = 0;
8321 mp = tvmp = NULL;
8322 didprintf = 0;
8323 TAILQ_INIT(&thl);
8324 /* Unlock the MDS vp, so that a LayoutReturn can be done on it. */
8325 NFSVOPUNLOCK(vp);
8326 /* Now, do a recall for all layouts not yet recalled. */
8327 tryagain:
8328 NFSDRECALLLOCK();
8329 TAILQ_FOREACH(lyp, &nfsrv_recalllisthead, lay_list) {
8330 if (NFSBCMP(&lyp->lay_fh, &fh, sizeof(fh)) == 0 &&
8331 (lyp->lay_flags & NFSLAY_RECALL) == 0) {
8332 lyp->lay_flags |= NFSLAY_RECALL;
8333 /*
8334 * The layout stateid.seqid needs to be incremented
8335 * before doing a LAYOUT_RECALL callback.
8336 */
8337 if (++lyp->lay_stateid.seqid == 0)
8338 lyp->lay_stateid.seqid = 1;
8339 NFSDRECALLUNLOCK();
8340 nfsrv_recalllayout(lyp->lay_clientid, &lyp->lay_stateid,
8341 &lyp->lay_fh, lyp, 0, lyp->lay_type, p);
8342 NFSD_DEBUG(4, "nfsrv_copymr: recalled layout\n");
8343 goto tryagain;
8344 }
8345 }
8346
8347 /* Now wait for them to be returned. */
8348 tryagain2:
8349 TAILQ_FOREACH(lyp, &nfsrv_recalllisthead, lay_list) {
8350 if (NFSBCMP(&lyp->lay_fh, &fh, sizeof(fh)) == 0) {
8351 if ((lyp->lay_flags & NFSLAY_RETURNED) != 0) {
8352 TAILQ_REMOVE(&nfsrv_recalllisthead, lyp,
8353 lay_list);
8354 TAILQ_INSERT_HEAD(&thl, lyp, lay_list);
8355 NFSD_DEBUG(4,
8356 "nfsrv_copymr: layout returned\n");
8357 } else {
8358 lyp->lay_trycnt++;
8359 ret = mtx_sleep(lyp, NFSDRECALLMUTEXPTR,
8360 PVFS | PCATCH, "nfsmrl", hz);
8361 NFSD_DEBUG(4, "nfsrv_copymr: aft sleep=%d\n",
8362 ret);
8363 if (ret == EINTR || ret == ERESTART)
8364 break;
8365 if ((lyp->lay_flags & NFSLAY_RETURNED) == 0) {
8366 /*
8367 * Give up after 60sec and return
8368 * ENXIO, failing the copymr.
8369 * This layout will remain on the
8370 * recalllist. It can only be cleared
8371 * by restarting the nfsd.
8372 * This seems the safe way to handle
8373 * it, since it cannot be safely copied
8374 * with an outstanding RW layout.
8375 */
8376 if (lyp->lay_trycnt >= 60) {
8377 ret = ENXIO;
8378 break;
8379 }
8380 if (didprintf == 0) {
8381 printf("nfsrv_copymr: layout "
8382 "not returned\n");
8383 didprintf = 1;
8384 }
8385 }
8386 }
8387 goto tryagain2;
8388 }
8389 }
8390 NFSDRECALLUNLOCK();
8391 /* We can now get rid of the layouts that have been returned. */
8392 TAILQ_FOREACH_SAFE(lyp, &thl, lay_list, nlyp)
8393 nfsrv_freelayout(&thl, lyp);
8394
8395 /*
8396 * Do the vn_start_write() calls here, before the MDS vnode is
8397 * locked and the tvp is created (locked) in the NFS file system
8398 * that dvp is in.
8399 * For tvmp, this probably isn't necessary, since it will be an
8400 * NFS mount and they are not suspendable at this time.
8401 */
8402 if (ret == 0)
8403 ret = vn_start_write(vp, &mp, V_WAIT | PCATCH);
8404 if (ret == 0) {
8405 tvmp = dvp->v_mount;
8406 ret = vn_start_write(NULL, &tvmp, V_WAIT | PCATCH);
8407 }
8408
8409 /*
8410 * LK_EXCLUSIVE lock the MDS vnode, so that any
8411 * proxied writes through the MDS will be blocked until we have
8412 * completed the copy and update of the extended attributes.
8413 * This will also ensure that any attributes and ACL will not be
8414 * changed until the copy is complete.
8415 */
8416 NFSVOPLOCK(vp, LK_EXCLUSIVE | LK_RETRY);
8417 if (ret == 0 && VN_IS_DOOMED(vp)) {
8418 NFSD_DEBUG(4, "nfsrv_copymr: lk_exclusive doomed\n");
8419 ret = ESTALE;
8420 }
8421
8422 /* Create the data file on the recovered DS. */
8423 if (ret == 0)
8424 ret = nfsrv_createdsfile(vp, &fh, pf, dvp, ds, cred, p, &tvp);
8425
8426 /* Copy the DS file, if created successfully. */
8427 if (ret == 0) {
8428 /*
8429 * Get any NFSv4 ACL on the MDS file, so that it can be set
8430 * on the new DS file.
8431 */
8432 aclp = acl_alloc(M_WAITOK | M_ZERO);
8433 retacl = VOP_GETACL(vp, ACL_TYPE_NFS4, aclp, cred, p);
8434 if (retacl != 0 && retacl != ENOATTR)
8435 NFSD_DEBUG(1, "nfsrv_copymr: vop_getacl=%d\n", retacl);
8436 dat = malloc(PNFSDS_COPYSIZ, M_TEMP, M_WAITOK);
8437 /* Malloc a block of 0s used to check for holes. */
8438 if (nfsrv_zeropnfsdat == NULL)
8439 nfsrv_zeropnfsdat = malloc(PNFSDS_COPYSIZ, M_TEMP,
8440 M_WAITOK | M_ZERO);
8441 rdpos = wrpos = 0;
8442 ret = VOP_GETATTR(fvp, &va, cred);
8443 aresid = 0;
8444 while (ret == 0 && aresid == 0) {
8445 ret = vn_rdwr(UIO_READ, fvp, dat, PNFSDS_COPYSIZ,
8446 rdpos, UIO_SYSSPACE, IO_NODELOCKED, cred, NULL,
8447 &aresid, p);
8448 xfer = PNFSDS_COPYSIZ - aresid;
8449 if (ret == 0 && xfer > 0) {
8450 rdpos += xfer;
8451 /*
8452 * Skip the write for holes, except for the
8453 * last block.
8454 */
8455 if (xfer < PNFSDS_COPYSIZ || rdpos ==
8456 va.va_size || NFSBCMP(dat,
8457 nfsrv_zeropnfsdat, PNFSDS_COPYSIZ) != 0)
8458 ret = vn_rdwr(UIO_WRITE, tvp, dat, xfer,
8459 wrpos, UIO_SYSSPACE, IO_NODELOCKED,
8460 cred, NULL, NULL, p);
8461 if (ret == 0)
8462 wrpos += xfer;
8463 }
8464 }
8465
8466 /* If there is an ACL and the copy succeeded, set the ACL. */
8467 if (ret == 0 && retacl == 0) {
8468 ret = VOP_SETACL(tvp, ACL_TYPE_NFS4, aclp, cred, p);
8469 /*
8470 * Don't consider these as errors, since VOP_GETACL()
8471 * can return an ACL when they are not actually
8472 * supported. For example, for UFS, VOP_GETACL()
8473 * will return a trivial ACL based on the uid/gid/mode
8474 * when there is no ACL on the file.
8475 * This case should be recognized as a trivial ACL
8476 * by UFS's VOP_SETACL() and succeed, but...
8477 */
8478 if (ret == ENOATTR || ret == EOPNOTSUPP || ret == EPERM)
8479 ret = 0;
8480 }
8481
8482 if (ret == 0)
8483 ret = VOP_FSYNC(tvp, MNT_WAIT, p);
8484
8485 /* Set the DS data file's modify time that of the MDS file. */
8486 if (ret == 0)
8487 ret = VOP_GETATTR(vp, &va, cred);
8488 if (ret == 0) {
8489 mtime = va.va_mtime;
8490 VATTR_NULL(&va);
8491 va.va_mtime = mtime;
8492 ret = VOP_SETATTR(tvp, &va, cred);
8493 }
8494
8495 vput(tvp);
8496 acl_free(aclp);
8497 free(dat, M_TEMP);
8498 }
8499 if (tvmp != NULL)
8500 vn_finished_write(tvmp);
8501
8502 /* Update the extended attributes for the newly created DS file. */
8503 if (ret == 0)
8504 ret = vn_extattr_set(vp, IO_NODELOCKED,
8505 EXTATTR_NAMESPACE_SYSTEM, "pnfsd.dsfile",
8506 sizeof(*wpf) * mirrorcnt, (char *)wpf, p);
8507 if (mp != NULL)
8508 vn_finished_write(mp);
8509
8510 /* Get rid of the dontlist entry, so that Layouts can be issued. */
8511 NFSDDONTLISTLOCK();
8512 LIST_REMOVE(mrp, nfsmr_list);
8513 NFSDDONTLISTUNLOCK();
8514 free(mrp, M_NFSDSTATE);
8515 return (ret);
8516 }
8517
8518 /*
8519 * Create a data storage file on the recovered DS.
8520 */
8521 static int
nfsrv_createdsfile(vnode_t vp,fhandle_t * fhp,struct pnfsdsfile * pf,vnode_t dvp,struct nfsdevice * ds,struct ucred * cred,NFSPROC_T * p,vnode_t * tvpp)8522 nfsrv_createdsfile(vnode_t vp, fhandle_t *fhp, struct pnfsdsfile *pf,
8523 vnode_t dvp, struct nfsdevice *ds, struct ucred *cred, NFSPROC_T *p,
8524 vnode_t *tvpp)
8525 {
8526 struct vattr va, nva;
8527 int error;
8528
8529 /* Make data file name based on FH. */
8530 error = VOP_GETATTR(vp, &va, cred);
8531 if (error == 0) {
8532 /* Set the attributes for "vp" to Setattr the DS vp. */
8533 VATTR_NULL(&nva);
8534 nva.va_uid = va.va_uid;
8535 nva.va_gid = va.va_gid;
8536 nva.va_mode = va.va_mode;
8537 nva.va_size = 0;
8538 VATTR_NULL(&va);
8539 va.va_type = VREG;
8540 va.va_mode = nva.va_mode;
8541 NFSD_DEBUG(4, "nfsrv_dscreatefile: dvp=%p pf=%p\n", dvp, pf);
8542 error = nfsrv_dscreate(dvp, &va, &nva, fhp, pf, NULL,
8543 pf->dsf_filename, cred, p, tvpp);
8544 }
8545 return (error);
8546 }
8547
8548 /*
8549 * Look up the MDS file shared locked, and then get the extended attribute
8550 * to find the extant DS file to be copied to the new mirror.
8551 * If successful, *vpp is set to the MDS file's vp and *nvpp is
8552 * set to a DS data file for the MDS file, both exclusively locked.
8553 * The "buf" argument has the pnfsdsfile structure from the MDS file
8554 * in it and buflen is set to its length.
8555 */
8556 int
nfsrv_mdscopymr(char * mdspathp,char * dspathp,char * curdspathp,char * buf,int * buflenp,char * fname,NFSPROC_T * p,struct vnode ** vpp,struct vnode ** nvpp,struct pnfsdsfile ** pfp,struct nfsdevice ** dsp,struct nfsdevice ** fdsp)8557 nfsrv_mdscopymr(char *mdspathp, char *dspathp, char *curdspathp, char *buf,
8558 int *buflenp, char *fname, NFSPROC_T *p, struct vnode **vpp,
8559 struct vnode **nvpp, struct pnfsdsfile **pfp, struct nfsdevice **dsp,
8560 struct nfsdevice **fdsp)
8561 {
8562 struct nameidata nd;
8563 struct vnode *vp, *curvp;
8564 struct pnfsdsfile *pf;
8565 struct nfsmount *nmp, *curnmp;
8566 int dsdir, error, mirrorcnt, ippos;
8567
8568 vp = NULL;
8569 curvp = NULL;
8570 curnmp = NULL;
8571 *dsp = NULL;
8572 *fdsp = NULL;
8573 if (dspathp == NULL && curdspathp != NULL)
8574 return (EPERM);
8575
8576 /*
8577 * Look up the MDS file shared locked. The lock will be upgraded
8578 * to an exclusive lock after any rw layouts have been returned.
8579 */
8580 NFSD_DEBUG(4, "mdsopen path=%s\n", mdspathp);
8581 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF, UIO_SYSSPACE,
8582 mdspathp, p);
8583 error = namei(&nd);
8584 NFSD_DEBUG(4, "lookup=%d\n", error);
8585 if (error != 0)
8586 return (error);
8587 if (nd.ni_vp->v_type != VREG) {
8588 vput(nd.ni_vp);
8589 NFSD_DEBUG(4, "mdspath not reg\n");
8590 return (EISDIR);
8591 }
8592 vp = nd.ni_vp;
8593
8594 if (curdspathp != NULL) {
8595 /*
8596 * Look up the current DS path and find the nfsdev structure for
8597 * it.
8598 */
8599 NFSD_DEBUG(4, "curmdsdev path=%s\n", curdspathp);
8600 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF,
8601 UIO_SYSSPACE, curdspathp, p);
8602 error = namei(&nd);
8603 NFSD_DEBUG(4, "ds lookup=%d\n", error);
8604 if (error != 0) {
8605 vput(vp);
8606 return (error);
8607 }
8608 if (nd.ni_vp->v_type != VDIR) {
8609 vput(nd.ni_vp);
8610 vput(vp);
8611 NFSD_DEBUG(4, "curdspath not dir\n");
8612 return (ENOTDIR);
8613 }
8614 if (strcmp(nd.ni_vp->v_mount->mnt_vfc->vfc_name, "nfs") != 0) {
8615 vput(nd.ni_vp);
8616 vput(vp);
8617 NFSD_DEBUG(4, "curdspath not an NFS mount\n");
8618 return (ENXIO);
8619 }
8620 curnmp = VFSTONFS(nd.ni_vp->v_mount);
8621
8622 /* Search the nfsdev list for a match. */
8623 NFSDDSLOCK();
8624 *fdsp = nfsv4_findmirror(curnmp);
8625 NFSDDSUNLOCK();
8626 if (*fdsp == NULL)
8627 curnmp = NULL;
8628 if (curnmp == NULL) {
8629 vput(nd.ni_vp);
8630 vput(vp);
8631 NFSD_DEBUG(4, "mdscopymr: no current ds\n");
8632 return (ENXIO);
8633 }
8634 curvp = nd.ni_vp;
8635 }
8636
8637 if (dspathp != NULL) {
8638 /* Look up the nfsdev path and find the nfsdev structure. */
8639 NFSD_DEBUG(4, "mdsdev path=%s\n", dspathp);
8640 NDINIT(&nd, LOOKUP, FOLLOW | LOCKSHARED | LOCKLEAF,
8641 UIO_SYSSPACE, dspathp, p);
8642 error = namei(&nd);
8643 NFSD_DEBUG(4, "ds lookup=%d\n", error);
8644 if (error != 0) {
8645 vput(vp);
8646 if (curvp != NULL)
8647 vput(curvp);
8648 return (error);
8649 }
8650 if (nd.ni_vp->v_type != VDIR || nd.ni_vp == curvp) {
8651 vput(nd.ni_vp);
8652 vput(vp);
8653 if (curvp != NULL)
8654 vput(curvp);
8655 NFSD_DEBUG(4, "dspath not dir\n");
8656 if (nd.ni_vp == curvp)
8657 return (EPERM);
8658 return (ENOTDIR);
8659 }
8660 if (strcmp(nd.ni_vp->v_mount->mnt_vfc->vfc_name, "nfs") != 0) {
8661 vput(nd.ni_vp);
8662 vput(vp);
8663 if (curvp != NULL)
8664 vput(curvp);
8665 NFSD_DEBUG(4, "dspath not an NFS mount\n");
8666 return (ENXIO);
8667 }
8668 nmp = VFSTONFS(nd.ni_vp->v_mount);
8669
8670 /*
8671 * Search the nfsdevice list for a match. If curnmp == NULL,
8672 * this is a recovery and there must be a mirror.
8673 */
8674 NFSDDSLOCK();
8675 if (curnmp == NULL)
8676 *dsp = nfsrv_findmirroredds(nmp);
8677 else
8678 *dsp = nfsv4_findmirror(nmp);
8679 NFSDDSUNLOCK();
8680 if (*dsp == NULL) {
8681 vput(nd.ni_vp);
8682 vput(vp);
8683 if (curvp != NULL)
8684 vput(curvp);
8685 NFSD_DEBUG(4, "mdscopymr: no ds\n");
8686 return (ENXIO);
8687 }
8688 } else {
8689 nd.ni_vp = NULL;
8690 nmp = NULL;
8691 }
8692
8693 /*
8694 * Get a vp for an available DS data file using the extended
8695 * attribute on the MDS file.
8696 * If there is a valid entry for the new DS in the extended attribute
8697 * on the MDS file (as checked via the nmp argument),
8698 * nfsrv_dsgetsockmnt() returns EEXIST, so no copying will occur.
8699 */
8700 error = nfsrv_dsgetsockmnt(vp, 0, buf, buflenp, &mirrorcnt, p,
8701 NULL, NULL, NULL, fname, nvpp, &nmp, curnmp, &ippos, &dsdir);
8702 if (curvp != NULL)
8703 vput(curvp);
8704 if (nd.ni_vp == NULL) {
8705 if (error == 0 && nmp != NULL) {
8706 /* Search the nfsdev list for a match. */
8707 NFSDDSLOCK();
8708 *dsp = nfsrv_findmirroredds(nmp);
8709 NFSDDSUNLOCK();
8710 }
8711 if (error == 0 && (nmp == NULL || *dsp == NULL)) {
8712 if (nvpp != NULL && *nvpp != NULL) {
8713 vput(*nvpp);
8714 *nvpp = NULL;
8715 }
8716 error = ENXIO;
8717 }
8718 } else
8719 vput(nd.ni_vp);
8720
8721 /*
8722 * When dspathp != NULL and curdspathp == NULL, this is a recovery
8723 * and is only allowed if there is a 0.0.0.0 IP address entry.
8724 * When curdspathp != NULL, the ippos will be set to that entry.
8725 */
8726 if (error == 0 && dspathp != NULL && ippos == -1) {
8727 if (nvpp != NULL && *nvpp != NULL) {
8728 vput(*nvpp);
8729 *nvpp = NULL;
8730 }
8731 error = ENXIO;
8732 }
8733 if (error == 0) {
8734 *vpp = vp;
8735
8736 pf = (struct pnfsdsfile *)buf;
8737 if (ippos == -1) {
8738 /* If no zeroip pnfsdsfile, add one. */
8739 ippos = *buflenp / sizeof(*pf);
8740 *buflenp += sizeof(*pf);
8741 pf += ippos;
8742 pf->dsf_dir = dsdir;
8743 strlcpy(pf->dsf_filename, fname,
8744 sizeof(pf->dsf_filename));
8745 } else
8746 pf += ippos;
8747 *pfp = pf;
8748 } else
8749 vput(vp);
8750 return (error);
8751 }
8752
8753 /*
8754 * Search for a matching pnfsd mirror device structure, base on the nmp arg.
8755 * Return one if found, NULL otherwise.
8756 */
8757 static struct nfsdevice *
nfsrv_findmirroredds(struct nfsmount * nmp)8758 nfsrv_findmirroredds(struct nfsmount *nmp)
8759 {
8760 struct nfsdevice *ds, *fndds;
8761 int fndmirror;
8762
8763 mtx_assert(NFSDDSMUTEXPTR, MA_OWNED);
8764 /*
8765 * Search the DS server list for a match with nmp.
8766 * Remove the DS entry if found and there is a mirror.
8767 */
8768 fndds = NULL;
8769 fndmirror = 0;
8770 if (nfsrv_devidcnt == 0)
8771 return (fndds);
8772 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
8773 if (ds->nfsdev_nmp == nmp) {
8774 NFSD_DEBUG(4, "nfsrv_findmirroredds: fnd main ds\n");
8775 fndds = ds;
8776 break;
8777 }
8778 }
8779 if (fndds == NULL)
8780 return (fndds);
8781 if (fndds->nfsdev_mdsisset == 0 && nfsrv_faildscnt > 0)
8782 fndmirror = 1;
8783 else if (fndds->nfsdev_mdsisset != 0) {
8784 /* For the fsid is set case, search for a mirror. */
8785 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
8786 if (ds != fndds && ds->nfsdev_nmp != NULL &&
8787 ds->nfsdev_mdsisset != 0 &&
8788 fsidcmp(&ds->nfsdev_mdsfsid,
8789 &fndds->nfsdev_mdsfsid) == 0) {
8790 fndmirror = 1;
8791 break;
8792 }
8793 }
8794 }
8795 if (fndmirror == 0) {
8796 NFSD_DEBUG(4, "nfsrv_findmirroredds: no mirror for DS\n");
8797 return (NULL);
8798 }
8799 return (fndds);
8800 }
8801
8802 /*
8803 * Mark the appropriate devid and all associated layout as "out of space".
8804 */
8805 void
nfsrv_marknospc(char * devid,bool setit)8806 nfsrv_marknospc(char *devid, bool setit)
8807 {
8808 struct nfsdevice *ds;
8809 struct nfslayout *lyp;
8810 struct nfslayouthash *lhyp;
8811 int i;
8812
8813 NFSDDSLOCK();
8814 TAILQ_FOREACH(ds, &nfsrv_devidhead, nfsdev_list) {
8815 if (NFSBCMP(ds->nfsdev_deviceid, devid, NFSX_V4DEVICEID) == 0) {
8816 NFSD_DEBUG(1, "nfsrv_marknospc: devid %d\n", setit);
8817 ds->nfsdev_nospc = setit;
8818 }
8819 }
8820 NFSDDSUNLOCK();
8821
8822 for (i = 0; i < nfsrv_layouthashsize; i++) {
8823 lhyp = &nfslayouthash[i];
8824 NFSLOCKLAYOUT(lhyp);
8825 TAILQ_FOREACH(lyp, &lhyp->list, lay_list) {
8826 if (NFSBCMP(lyp->lay_deviceid, devid,
8827 NFSX_V4DEVICEID) == 0) {
8828 NFSD_DEBUG(1, "nfsrv_marknospc: layout %d\n",
8829 setit);
8830 if (setit)
8831 lyp->lay_flags |= NFSLAY_NOSPC;
8832 else
8833 lyp->lay_flags &= ~NFSLAY_NOSPC;
8834 }
8835 }
8836 NFSUNLOCKLAYOUT(lhyp);
8837 }
8838 }
8839