1 /* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
2 * vim:expandtab:shiftwidth=8:tabstop=8:
4 * Copyright (C) 2001 Cluster File Systems, Inc. <braam@clusterfs.com>
6 * This file is part of Lustre, http://www.lustre.org.
8 * Lustre is free software; you can redistribute it and/or
9 * modify it under the terms of version 2 of the GNU General Public
10 * License as published by the Free Software Foundation.
12 * Lustre is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
17 * You should have received a copy of the GNU General Public License
18 * along with Lustre; if not, write to the Free Software
19 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
21 * Basic Lustre library routines.
31 # include <asm/semaphore.h>
32 #include <linux/kp30.h> /* XXX just for LASSERT! */
34 #include <linux/portals_lib.h>
35 #include <linux/lustre_idl.h>
37 #if BITS_PER_LONG > 32
49 struct ptlrpc_request;
53 #include <linux/lustre_ha.h>
55 int target_handle_connect(struct ptlrpc_request *req);
56 int target_handle_disconnect(struct ptlrpc_request *req);
57 int client_obd_connect(struct lustre_handle *conn, struct obd_device *obd,
58 obd_uuid_t cluuid, struct recovd_obd *recovd,
59 ptlrpc_recovery_cb_t recover);
60 int client_obd_disconnect(struct lustre_handle *conn);
61 int client_obd_setup(struct obd_device *obddev, obd_count len, void *buf);
62 int client_obd_cleanup(struct obd_device * obddev);
63 struct client_obd *client_conn2cli(struct lustre_handle *conn);
65 int target_revoke_connection(struct recovd_data *rd, int phase);
70 struct task_struct *l_owner;
71 struct semaphore l_sem;
75 void l_lock_init(struct lustre_lock *);
76 void l_lock(struct lustre_lock *);
77 void l_unlock(struct lustre_lock *);
81 #define CB_PHASE_START 12
82 #define CB_PHASE_FINISH 13
85 * io_cb_data: io callback data merged into one struct to simplify
86 * memory managment. This may be turn out to be too simple.
89 typedef int (*brw_callback_t)(struct io_cb_data *, int err, int phase);
92 wait_queue_head_t waitq;
96 struct ptlrpc_bulk_desc *desc;
101 int ll_sync_io_cb(struct io_cb_data *data, int err, int phase);
102 struct io_cb_data *ll_init_cb(void);
107 void push_ctxt(struct obd_run_ctxt *save, struct obd_run_ctxt *new,
108 struct obd_ucred *cred);
109 void pop_ctxt(struct obd_run_ctxt *saved);
110 struct dentry *simple_mkdir(struct dentry *dir, char *name, int mode);
111 struct dentry *simple_mknod(struct dentry *dir, char *name, int mode);
112 int lustre_fread(struct file *file, char *str, int len, loff_t *off);
113 int lustre_fwrite(struct file *file, const char *str, int len, loff_t *off);
114 int lustre_fsync(struct file *file);
116 static inline void l_dput(struct dentry *de)
118 if (!de || IS_ERR(de))
120 shrink_dcache_parent(de);
121 LASSERT(atomic_read(&de->d_count) > 0);
125 static inline void ll_sleep(int t)
127 set_current_state(TASK_INTERRUPTIBLE);
128 schedule_timeout(t * HZ);
129 set_current_state(TASK_RUNNING);
133 /* FIXME: This needs to validate pointers and cookies */
134 static inline void *lustre_handle2object(struct lustre_handle *handle)
137 return (void *)(unsigned long)(handle->addr);
141 static inline void ldlm_object2handle(void *object, struct lustre_handle *handle)
143 handle->addr = (__u64)(unsigned long)object;
148 void statfs_pack(struct obd_statfs *osfs, struct statfs *sfs);
149 void statfs_unpack(struct statfs *sfs, struct obd_statfs *osfs);
150 void obd_statfs_pack(struct obd_statfs *tgt, struct obd_statfs *src);
152 obd_statfs_unpack(struct obd_statfs *tgt, struct obd_statfs *src)
154 obd_statfs_pack(tgt, src);
157 #include <linux/portals_lib.h>
162 #define OBD_IOCTL_VERSION 0x00010001
164 struct obd_ioctl_data {
166 uint32_t ioc_version;
173 struct obdo ioc_obdo1;
174 struct obdo ioc_obdo2;
179 uint32_t ____padding;
181 /* buffers the kernel will treat as user pointers */
187 /* two inline buffers */
188 uint32_t ioc_inllen1;
190 uint32_t ioc_inllen2;
192 uint32_t ioc_inllen3;
198 struct obd_ioctl_hdr {
200 uint32_t ioc_version;
203 static inline int obd_ioctl_packlen(struct obd_ioctl_data *data)
205 int len = size_round(sizeof(struct obd_ioctl_data));
206 len += size_round(data->ioc_inllen1);
207 len += size_round(data->ioc_inllen2);
208 len += size_round(data->ioc_inllen3);
213 static inline int obd_ioctl_is_invalid(struct obd_ioctl_data *data)
215 if (data->ioc_len > (1<<30)) {
216 printk("OBD ioctl: ioc_len larger than 1<<30\n");
219 if (data->ioc_inllen1 > (1<<30)) {
220 printk("OBD ioctl: ioc_inllen1 larger than 1<<30\n");
223 if (data->ioc_inllen2 > (1<<30)) {
224 printk("OBD ioctl: ioc_inllen2 larger than 1<<30\n");
228 if (data->ioc_inllen3 > (1<<30)) {
229 printk("OBD ioctl: ioc_inllen3 larger than 1<<30\n");
232 if (data->ioc_inlbuf1 && !data->ioc_inllen1) {
233 printk("OBD ioctl: inlbuf1 pointer but 0 length\n");
236 if (data->ioc_inlbuf2 && !data->ioc_inllen2) {
237 printk("OBD ioctl: inlbuf2 pointer but 0 length\n");
240 if (data->ioc_inlbuf3 && !data->ioc_inllen3) {
241 printk("OBD ioctl: inlbuf3 pointer but 0 length\n");
244 if (data->ioc_pbuf1 && !data->ioc_plen1) {
245 printk("OBD ioctl: pbuf1 pointer but 0 length\n");
248 if (data->ioc_pbuf2 && !data->ioc_plen2) {
249 printk("OBD ioctl: pbuf2 pointer but 0 length\n");
253 if (data->ioc_inllen1 && !data->ioc_inlbuf1) {
254 printk("OBD ioctl: inllen1 set but NULL pointer\n");
257 if (data->ioc_inllen2 && !data->ioc_inlbuf2) {
258 printk("OBD ioctl: inllen2 set but NULL pointer\n");
261 if (data->ioc_inllen3 && !data->ioc_inlbuf3) {
262 printk("OBD ioctl: inllen3 set but NULL pointer\n");
266 if (data->ioc_plen1 && !data->ioc_pbuf1) {
267 printk("OBD ioctl: plen1 set but NULL pointer\n");
270 if (data->ioc_plen2 && !data->ioc_pbuf2) {
271 printk("OBD ioctl: plen2 set but NULL pointer\n");
274 if (obd_ioctl_packlen(data) != data->ioc_len ) {
275 printk("OBD ioctl: packlen exceeds ioc_len\n");
279 if (data->ioc_inllen1 &&
280 data->ioc_bulk[data->ioc_inllen1 - 1] != '\0') {
281 printk("OBD ioctl: inlbuf1 not 0 terminated\n");
284 if (data->ioc_inllen2 &&
285 data->ioc_bulk[size_round(data->ioc_inllen1) + data->ioc_inllen2 - 1] != '\0') {
286 printk("OBD ioctl: inlbuf2 not 0 terminated\n");
289 if (data->ioc_inllen3 &&
290 data->ioc_bulk[size_round(data->ioc_inllen1) + size_round(data->ioc_inllen2)
291 + data->ioc_inllen3 - 1] != '\0') {
292 printk("OBD ioctl: inlbuf3 not 0 terminated\n");
300 static inline int obd_ioctl_pack(struct obd_ioctl_data *data, char **pbuf,
304 struct obd_ioctl_data *overlay;
305 data->ioc_len = obd_ioctl_packlen(data);
306 data->ioc_version = OBD_IOCTL_VERSION;
308 if (*pbuf && obd_ioctl_packlen(data) > max)
311 *pbuf = malloc(data->ioc_len);
315 overlay = (struct obd_ioctl_data *)*pbuf;
316 memcpy(*pbuf, data, sizeof(*data));
318 ptr = overlay->ioc_bulk;
319 if (data->ioc_inlbuf1)
320 LOGL(data->ioc_inlbuf1, data->ioc_inllen1, ptr);
321 if (data->ioc_inlbuf2)
322 LOGL(data->ioc_inlbuf2, data->ioc_inllen2, ptr);
323 if (data->ioc_inlbuf3)
324 LOGL(data->ioc_inlbuf3, data->ioc_inllen3, ptr);
325 if (obd_ioctl_is_invalid(overlay))
333 #include <linux/obd_support.h>
335 /* buffer MUST be at least the size of obd_ioctl_hdr */
336 static inline int obd_ioctl_getdata(char **buf, int *len, void *arg)
338 struct obd_ioctl_hdr hdr;
339 struct obd_ioctl_data *data;
344 err = copy_from_user(&hdr, (void *)arg, sizeof(hdr));
350 if (hdr.ioc_version != OBD_IOCTL_VERSION) {
351 printk("OBD: version mismatch kernel vs application\n");
355 if (hdr.ioc_len > 8192) {
356 printk("OBD: user buffer exceeds 8192 max buffer\n");
360 if (hdr.ioc_len < sizeof(struct obd_ioctl_data)) {
361 printk("OBD: user buffer too small for ioctl\n");
365 OBD_ALLOC(*buf, hdr.ioc_len);
367 CERROR("Cannot allocate control buffer of len %d\n",
372 data = (struct obd_ioctl_data *)*buf;
374 err = copy_from_user(*buf, (void *)arg, hdr.ioc_len);
380 if (obd_ioctl_is_invalid(data)) {
381 printk("OBD: ioctl not correctly formatted\n");
385 if (data->ioc_inllen1) {
386 data->ioc_inlbuf1 = &data->ioc_bulk[0];
389 if (data->ioc_inllen2) {
390 data->ioc_inlbuf2 = &data->ioc_bulk[0] + size_round(data->ioc_inllen1);
393 if (data->ioc_inllen3) {
394 data->ioc_inlbuf3 = &data->ioc_bulk[0] + size_round(data->ioc_inllen1) +
395 size_round(data->ioc_inllen2);
403 #define OBD_IOC_CREATE _IOR ('f', 101, long)
404 #define OBD_IOC_SETUP _IOW ('f', 102, long)
405 #define OBD_IOC_CLEANUP _IO ('f', 103 )
406 #define OBD_IOC_DESTROY _IOW ('f', 104, long)
407 #define OBD_IOC_PREALLOCATE _IOWR('f', 105, long)
408 #define OBD_IOC_DEC_USE_COUNT _IO ('f', 106 )
409 #define OBD_IOC_SETATTR _IOW ('f', 107, long)
410 #define OBD_IOC_GETATTR _IOR ('f', 108, long)
411 #define OBD_IOC_READ _IOWR('f', 109, long)
412 #define OBD_IOC_WRITE _IOWR('f', 110, long)
413 #define OBD_IOC_CONNECT _IOR ('f', 111, long)
414 #define OBD_IOC_DISCONNECT _IOW ('f', 112, long)
415 #define OBD_IOC_STATFS _IOWR('f', 113, long)
416 #define OBD_IOC_SYNC _IOR ('f', 114, long)
417 #define OBD_IOC_READ2 _IOWR('f', 115, long)
418 #define OBD_IOC_FORMAT _IOWR('f', 116, long)
419 #define OBD_IOC_PARTITION _IOWR('f', 117, long)
420 #define OBD_IOC_ATTACH _IOWR('f', 118, long)
421 #define OBD_IOC_DETACH _IOWR('f', 119, long)
422 #define OBD_IOC_COPY _IOWR('f', 120, long)
423 #define OBD_IOC_MIGR _IOWR('f', 121, long)
424 #define OBD_IOC_PUNCH _IOWR('f', 122, long)
425 #define OBD_IOC_DEVICE _IOWR('f', 123, long)
426 #define OBD_IOC_MODULE_DEBUG _IOWR('f', 124, long)
427 #define OBD_IOC_BRW_READ _IOWR('f', 125, long)
428 #define OBD_IOC_BRW_WRITE _IOWR('f', 126, long)
429 #define OBD_IOC_NAME2DEV _IOWR('f', 127, long)
430 #define OBD_IOC_NEWDEV _IOWR('f', 128, long)
431 #define OBD_IOC_LIST _IOWR('f', 129, long)
432 #define OBD_IOC_UUID2DEV _IOWR('f', 130, long)
434 #define OBD_IOC_RECOVD_NEWCONN _IOWR('f', 131, long)
435 #define OBD_IOC_LOV_CONFIG _IOWR('f', 132, long)
437 #define OBD_IOC_DEC_FS_USE_COUNT _IO ('f', 133 )
439 #define OBD_IOC_OPEN _IOWR('f', 134, long)
440 #define OBD_IOC_CLOSE _IOWR('f', 135, long)
442 #define OBD_IOC_RECOVD_FAILCONN _IOWR('f', 136, long)
445 * l_wait_event is a flexible sleeping function, permitting simple caller
446 * configuration of interrupt and timeout sensitivity along with actions to
447 * be performed in the event of either exception.
449 * Common usage looks like this:
451 * struct l_wait_info lwi = LWI_TIMEOUT_INTR(timeout, timeout_handler,
452 * intr_handler, callback_data);
453 * rc = l_wait_event(waitq, condition, &lwi);
455 * (LWI_TIMEOUT and LWI_INTR macros are available for timeout- and
456 * interrupt-only variants, respectively.)
458 * If a timeout is specified, the timeout_handler will be invoked in the event
459 * that the timeout expires before the process is awakened. (Note that any
460 * waking of the process will restart the timeout, even if the condition is
461 * not satisfied and the process immediately returns to sleep. This might be
462 * considered a bug.) If the timeout_handler returns non-zero, l_wait_event
463 * will return -ETIMEDOUT and the caller will continue. If the handler returns
464 * zero instead, the process will go back to sleep until it is awakened by the
465 * waitq or some similar mechanism, or an interrupt occurs (if the caller has
466 * asked for interrupts to be detected). The timeout will only fire once, so
467 * callers should take care that a timeout_handler which returns zero will take
468 * future steps to awaken the process. N.B. that these steps must include making
469 * the provided condition become true.
471 * If the interrupt flag (lwi_signals) is non-zero, then the process will be
472 * interruptible, and will be awakened by any "killable" signal (SIGTERM,
473 * SIGKILL or SIGINT). If a timeout is also specified, then the process will
474 * only become interruptible _after_ the timeout has expired, though it can be
475 * awakened by a signal that was delivered before the timeout and is still
476 * pending when the timeout expires. If a timeout is not specified, the process
477 * will be interruptible at all times during l_wait_event.
482 int (*lwi_on_timeout)(void *);
484 int (*lwi_on_signal)(void *); /* XXX return is ignored for now */
488 #define LWI_TIMEOUT(time, cb, data) \
489 ((struct l_wait_info) { \
491 lwi_on_timeout: cb, \
495 #define LWI_INTR(cb, data) \
496 ((struct l_wait_info) { \
502 #define LWI_TIMEOUT_INTR(time, time_cb, sig_cb, data) \
503 ((struct l_wait_info) { \
505 lwi_on_timeout: time_cb, \
507 lwi_on_signal: sig_cb, \
511 /* XXX this should be one mask-check */
512 #define l_killable_pending(task) \
513 (sigismember(&(task->pending.signal), SIGKILL) || \
514 sigismember(&(task->pending.signal), SIGINT) || \
515 sigismember(&(task->pending.signal), SIGTERM))
517 #define __l_wait_event(wq, condition, info, ret) \
519 wait_queue_t __wait; \
521 int __timed_out = 0; \
522 init_waitqueue_entry(&__wait, current); \
524 add_wait_queue(&wq, &__wait); \
525 if (info->lwi_signals && !info->lwi_timeout) \
526 __state = TASK_INTERRUPTIBLE; \
528 __state = TASK_UNINTERRUPTIBLE; \
530 set_current_state(__state); \
533 if (__state == TASK_INTERRUPTIBLE && l_killable_pending(current)) {\
534 CERROR("lwe: interrupt\n"); \
535 if (info->lwi_on_signal) \
536 info->lwi_on_signal(info->lwi_cb_data); \
540 if (info->lwi_timeout && !__timed_out) { \
541 if (schedule_timeout(info->lwi_timeout) == 0) { \
542 CERROR("lwe: timeout\n"); \
544 if (!info->lwi_on_timeout || \
545 info->lwi_on_timeout(info->lwi_cb_data)) { \
549 /* We'll take signals after a timeout. */ \
550 if (info->lwi_signals) { \
551 __state = TASK_INTERRUPTIBLE; \
552 /* Check for a pending interrupt. */ \
553 if (info->lwi_signals && l_killable_pending(current)) {\
554 CERROR("lwe: pending interrupt\n"); \
555 if (info->lwi_on_signal) \
556 info->lwi_on_signal(info->lwi_cb_data); \
566 current->state = TASK_RUNNING; \
567 remove_wait_queue(&wq, &__wait); \
570 #define l_wait_event(wq, condition, info) \
573 struct l_wait_info *__info = (info); \
575 __l_wait_event(wq, condition, __info, __ret); \
579 #endif /* _LUSTRE_LIB_H */