1 /* -*- mode: c; c-basic-offset: 8; indent-tabs-mode: nil; -*-
2 * vim:expandtab:shiftwidth=8:tabstop=8:
4 * Lustre Lite I/O page cache routines shared by different kernel revs
6 * Copyright (c) 2001-2003 Cluster File Systems, Inc.
8 * This file is part of Lustre, http://www.lustre.org.
10 * Lustre is free software; you can redistribute it and/or
11 * modify it under the terms of version 2 of the GNU General Public
12 * License as published by the Free Software Foundation.
14 * Lustre is distributed in the hope that it will be useful,
15 * but WITHOUT ANY WARRANTY; without even the implied warranty of
16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 * GNU General Public License for more details.
19 * You should have received a copy of the GNU General Public License
20 * along with Lustre; if not, write to the Free Software
21 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
23 #include <linux/autoconf.h>
24 #include <linux/kernel.h>
26 #include <linux/string.h>
27 #include <linux/stat.h>
28 #include <linux/errno.h>
29 #include <linux/smp_lock.h>
30 #include <linux/unistd.h>
31 #include <linux/version.h>
32 #include <asm/system.h>
33 #include <asm/uaccess.h>
36 #include <linux/stat.h>
37 #include <asm/uaccess.h>
39 #include <linux/pagemap.h>
40 #include <linux/smp_lock.h>
42 #define DEBUG_SUBSYSTEM S_LLITE
44 //#include <lustre_mdc.h>
45 #include <lustre_lite.h>
46 #include <obd_cksum.h>
47 #include "llite_internal.h"
48 #include <linux/lustre_compat25.h>
50 #ifndef list_for_each_prev_safe
51 #define list_for_each_prev_safe(pos, n, head) \
52 for (pos = (head)->prev, n = pos->prev; pos != (head); \
53 pos = n, n = pos->prev )
56 cfs_mem_cache_t *ll_async_page_slab = NULL;
57 size_t ll_async_page_slab_size = 0;
59 /* SYNCHRONOUS I/O to object storage for an inode */
60 static int ll_brw(int cmd, struct inode *inode, struct obdo *oa,
61 struct page *page, int flags)
63 struct ll_inode_info *lli = ll_i2info(inode);
64 struct lov_stripe_md *lsm = lli->lli_smd;
65 struct obd_info oinfo = { { { 0 } } };
71 pg.off = ((obd_off)page->index) << CFS_PAGE_SHIFT;
73 if ((cmd & OBD_BRW_WRITE) && (pg.off+CFS_PAGE_SIZE>i_size_read(inode)))
74 pg.count = i_size_read(inode) % CFS_PAGE_SIZE;
76 pg.count = CFS_PAGE_SIZE;
78 LL_CDEBUG_PAGE(D_PAGE, page, "%s %d bytes ino %lu at "LPU64"/"LPX64"\n",
79 cmd & OBD_BRW_WRITE ? "write" : "read", pg.count,
80 inode->i_ino, pg.off, pg.off);
82 CERROR("ZERO COUNT: ino %lu: size %p:%Lu(%p:%Lu) idx %lu off "
83 LPU64"\n", inode->i_ino, inode, i_size_read(inode),
84 page->mapping->host, i_size_read(page->mapping->host),
90 if (cmd & OBD_BRW_WRITE)
91 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_BRW_WRITE,
94 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_BRW_READ,
98 /* NB partial write, so we might not have CAPA_OPC_OSS_READ capa */
99 opc = cmd & OBD_BRW_WRITE ? CAPA_OPC_OSS_WRITE : CAPA_OPC_OSS_RW;
100 oinfo.oi_capa = ll_osscapa_get(inode, opc);
101 rc = obd_brw(cmd, ll_i2dtexp(inode), &oinfo, 1, &pg, NULL);
102 capa_put(oinfo.oi_capa);
104 obdo_to_inode(inode, oa, OBD_MD_FLBLOCKS);
106 CERROR("error from obd_brw: rc = %d\n", rc);
110 int ll_file_punch(struct inode * inode, loff_t new_size, int srvlock)
112 struct ll_inode_info *lli = ll_i2info(inode);
113 struct obd_info oinfo = { { { 0 } } };
118 CDEBUG(D_INFO, "calling punch for "LPX64" (new size %Lu=%#Lx)\n",
119 lli->lli_smd->lsm_object_id, i_size_read(inode), i_size_read(inode));
121 oinfo.oi_md = lli->lli_smd;
122 oinfo.oi_policy.l_extent.start = new_size;
123 oinfo.oi_policy.l_extent.end = OBD_OBJECT_EOF;
125 oa.o_id = lli->lli_smd->lsm_object_id;
126 oa.o_gr = lli->lli_smd->lsm_object_gr;
127 oa.o_valid = OBD_MD_FLID | OBD_MD_FLGROUP;
129 /* set OBD_MD_FLFLAGS in o_valid, only if we
130 * set OBD_FL_TRUNCLOCK, otherwise ost_punch
131 * and filter_setattr get confused, see the comment
133 oa.o_flags = OBD_FL_TRUNCLOCK;
134 oa.o_valid |= OBD_MD_FLFLAGS;
136 obdo_from_inode(&oa, inode, OBD_MD_FLTYPE | OBD_MD_FLMODE |
137 OBD_MD_FLATIME | OBD_MD_FLMTIME | OBD_MD_FLCTIME |
138 OBD_MD_FLFID | OBD_MD_FLGENER);
140 oinfo.oi_capa = ll_osscapa_get(inode, CAPA_OPC_OSS_TRUNC);
141 rc = obd_punch_rqset(ll_i2dtexp(inode), &oinfo, NULL);
142 ll_truncate_free_capa(oinfo.oi_capa);
144 CERROR("obd_truncate fails (%d) ino %lu\n", rc, inode->i_ino);
146 obdo_to_inode(inode, &oa, OBD_MD_FLSIZE | OBD_MD_FLBLOCKS |
147 OBD_MD_FLATIME | OBD_MD_FLMTIME | OBD_MD_FLCTIME);
151 /* this isn't where truncate starts. roughly:
152 * sys_truncate->ll_setattr_raw->vmtruncate->ll_truncate. setattr_raw grabs
153 * DLM lock on [size, EOF], i_mutex, ->lli_size_sem, and WRITE_I_ALLOC_SEM to
156 * must be called under ->lli_size_sem */
157 void ll_truncate(struct inode *inode)
159 struct ll_inode_info *lli = ll_i2info(inode);
160 int srvlock = !!(lli->lli_flags & LLIF_SRVLOCK);
163 CDEBUG(D_VFSTRACE, "VFS Op:inode=%lu/%u(%p) to %Lu=%#Lx\n",inode->i_ino,
164 inode->i_generation, inode, i_size_read(inode),
167 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_TRUNC, 1);
168 if (lli->lli_size_sem_owner != current) {
174 CDEBUG(D_INODE, "truncate on inode %lu with no objects\n",
179 LASSERT(atomic_read(&lli->lli_size_sem.count) <= 0);
185 /* XXX I'm pretty sure this is a hack to paper
186 * over a more fundamental race condition. */
187 lov_stripe_lock(lli->lli_smd);
188 inode_init_lvb(inode, &lvb);
189 rc = obd_merge_lvb(ll_i2dtexp(inode), lli->lli_smd, &lvb, 0);
190 if (lvb.lvb_size == i_size_read(inode) && rc == 0) {
191 CDEBUG(D_VFSTRACE, "skipping punch for obj "LPX64
192 ",%Lu=%#Lx\n", lli->lli_smd->lsm_object_id,
193 i_size_read(inode), i_size_read(inode));
194 lov_stripe_unlock(lli->lli_smd);
197 obd_adjust_kms(ll_i2dtexp(inode), lli->lli_smd,
198 i_size_read(inode), 1);
199 lov_stripe_unlock(lli->lli_smd);
202 if (unlikely((ll_i2sbi(inode)->ll_flags & LL_SBI_CHECKSUM) &&
203 (i_size_read(inode) & ~CFS_PAGE_MASK))) {
204 /* If the truncate leaves behind a partial page, update its
206 struct page *page = find_get_page(inode->i_mapping,
207 i_size_read(inode) >>
210 struct ll_async_page *llap = llap_cast_private(page);
212 char *kaddr = kmap_atomic(page, KM_USER0);
213 llap->llap_checksum =
214 init_checksum(OSC_DEFAULT_CKSUM);
215 llap->llap_checksum =
216 compute_checksum(llap->llap_checksum,
217 kaddr, CFS_PAGE_SIZE,
219 kunmap_atomic(kaddr, KM_USER0);
221 page_cache_release(page);
225 new_size = i_size_read(inode);
226 ll_inode_size_unlock(inode, 0);
228 ll_file_punch(inode, new_size, 0);
230 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_LOCKLESS_TRUNC, 1);
236 ll_inode_size_unlock(inode, 0);
239 int ll_prepare_write(struct file *file, struct page *page, unsigned from,
242 struct inode *inode = page->mapping->host;
243 struct ll_inode_info *lli = ll_i2info(inode);
244 struct lov_stripe_md *lsm = lli->lli_smd;
245 obd_off offset = ((obd_off)page->index) << CFS_PAGE_SHIFT;
246 struct obd_info oinfo = { { { 0 } } };
253 LASSERT(PageLocked(page));
254 (void)llap_cast_private(page); /* assertion */
256 /* Check to see if we should return -EIO right away */
259 pga.count = CFS_PAGE_SIZE;
262 oa.o_mode = inode->i_mode;
263 oa.o_id = lsm->lsm_object_id;
264 oa.o_gr = lsm->lsm_object_gr;
265 oa.o_valid = OBD_MD_FLID | OBD_MD_FLMODE |
266 OBD_MD_FLTYPE | OBD_MD_FLGROUP;
267 obdo_from_inode(&oa, inode, OBD_MD_FLFID | OBD_MD_FLGENER);
271 rc = obd_brw(OBD_BRW_CHECK, ll_i2dtexp(inode), &oinfo, 1, &pga, NULL);
275 if (PageUptodate(page)) {
276 LL_CDEBUG_PAGE(D_PAGE, page, "uptodate\n");
280 /* We're completely overwriting an existing page, so _don't_ set it up
281 * to date until commit_write */
282 if (from == 0 && to == CFS_PAGE_SIZE) {
283 LL_CDEBUG_PAGE(D_PAGE, page, "full page write\n");
284 POISON_PAGE(page, 0x11);
288 /* If are writing to a new page, no need to read old data. The extent
289 * locking will have updated the KMS, and for our purposes here we can
290 * treat it like i_size. */
291 lov_stripe_lock(lsm);
292 inode_init_lvb(inode, &lvb);
293 obd_merge_lvb(ll_i2dtexp(inode), lsm, &lvb, 1);
294 lov_stripe_unlock(lsm);
295 if (lvb.lvb_size <= offset) {
296 char *kaddr = kmap_atomic(page, KM_USER0);
297 LL_CDEBUG_PAGE(D_PAGE, page, "kms "LPU64" <= offset "LPU64"\n",
298 lvb.lvb_size, offset);
299 memset(kaddr, 0, CFS_PAGE_SIZE);
300 kunmap_atomic(kaddr, KM_USER0);
301 GOTO(prepare_done, rc = 0);
304 /* XXX could be an async ocp read.. read-ahead? */
305 rc = ll_brw(OBD_BRW_READ, inode, &oa, page, 0);
307 /* bug 1598: don't clobber blksize */
308 oa.o_valid &= ~(OBD_MD_FLSIZE | OBD_MD_FLBLKSZ);
309 obdo_refresh_inode(inode, &oa, oa.o_valid);
315 SetPageUptodate(page);
320 static int ll_ap_make_ready(void *data, int cmd)
322 struct ll_async_page *llap;
326 llap = LLAP_FROM_COOKIE(data);
327 page = llap->llap_page;
329 LASSERTF(!(cmd & OBD_BRW_READ), "cmd %x page %p ino %lu index %lu\n", cmd, page,
330 page->mapping->host->i_ino, page->index);
332 /* we're trying to write, but the page is locked.. come back later */
333 if (TryLockPage(page))
336 LASSERT(!PageWriteback(page));
338 /* if we left PageDirty we might get another writepage call
339 * in the future. list walkers are bright enough
340 * to check page dirty so we can leave it on whatever list
341 * its on. XXX also, we're called with the cli list so if
342 * we got the page cache list we'd create a lock inversion
343 * with the removepage path which gets the page lock then the
345 LASSERTF(!PageWriteback(page),"cmd %x page %p ino %lu index %lu\n", cmd, page,
346 page->mapping->host->i_ino, page->index);
347 clear_page_dirty_for_io(page);
349 /* This actually clears the dirty bit in the radix tree.*/
350 set_page_writeback(page);
352 LL_CDEBUG_PAGE(D_PAGE, page, "made ready\n");
353 page_cache_get(page);
358 /* We have two reasons for giving llite the opportunity to change the
359 * write length of a given queued page as it builds the RPC containing
362 * 1) Further extending writes may have landed in the page cache
363 * since a partial write first queued this page requiring us
364 * to write more from the page cache. (No further races are possible, since
365 * by the time this is called, the page is locked.)
366 * 2) We might have raced with truncate and want to avoid performing
367 * write RPCs that are just going to be thrown away by the
368 * truncate's punch on the storage targets.
370 * The kms serves these purposes as it is set at both truncate and extending
373 static int ll_ap_refresh_count(void *data, int cmd)
375 struct ll_inode_info *lli;
376 struct ll_async_page *llap;
377 struct lov_stripe_md *lsm;
384 /* readpage queues with _COUNT_STABLE, shouldn't get here. */
385 LASSERT(cmd != OBD_BRW_READ);
387 llap = LLAP_FROM_COOKIE(data);
388 page = llap->llap_page;
389 inode = page->mapping->host;
390 lli = ll_i2info(inode);
393 lov_stripe_lock(lsm);
394 inode_init_lvb(inode, &lvb);
395 obd_merge_lvb(ll_i2dtexp(inode), lsm, &lvb, 1);
397 lov_stripe_unlock(lsm);
399 /* catch race with truncate */
400 if (((__u64)page->index << CFS_PAGE_SHIFT) >= kms)
403 /* catch sub-page write at end of file */
404 if (((__u64)page->index << CFS_PAGE_SHIFT) + CFS_PAGE_SIZE > kms)
405 return kms % CFS_PAGE_SIZE;
407 return CFS_PAGE_SIZE;
410 void ll_inode_fill_obdo(struct inode *inode, int cmd, struct obdo *oa)
412 struct lov_stripe_md *lsm;
413 obd_flag valid_flags;
415 lsm = ll_i2info(inode)->lli_smd;
417 oa->o_id = lsm->lsm_object_id;
418 oa->o_gr = lsm->lsm_object_gr;
419 oa->o_valid = OBD_MD_FLID | OBD_MD_FLGROUP;
420 valid_flags = OBD_MD_FLTYPE | OBD_MD_FLATIME;
421 if (cmd & OBD_BRW_WRITE) {
422 oa->o_valid |= OBD_MD_FLEPOCH;
423 oa->o_easize = ll_i2info(inode)->lli_ioepoch;
425 valid_flags |= OBD_MD_FLMTIME | OBD_MD_FLCTIME |
426 OBD_MD_FLUID | OBD_MD_FLGID |
427 OBD_MD_FLFID | OBD_MD_FLGENER;
430 obdo_from_inode(oa, inode, valid_flags);
433 static void ll_ap_fill_obdo(void *data, int cmd, struct obdo *oa)
435 struct ll_async_page *llap;
438 llap = LLAP_FROM_COOKIE(data);
439 ll_inode_fill_obdo(llap->llap_page->mapping->host, cmd, oa);
444 static void ll_ap_update_obdo(void *data, int cmd, struct obdo *oa,
447 struct ll_async_page *llap;
450 llap = LLAP_FROM_COOKIE(data);
451 obdo_from_inode(oa, llap->llap_page->mapping->host, valid);
456 static struct obd_capa *ll_ap_lookup_capa(void *data, int cmd)
458 struct ll_async_page *llap = LLAP_FROM_COOKIE(data);
459 int opc = cmd & OBD_BRW_WRITE ? CAPA_OPC_OSS_WRITE : CAPA_OPC_OSS_RW;
461 return ll_osscapa_get(llap->llap_page->mapping->host, opc);
464 static struct obd_async_page_ops ll_async_page_ops = {
465 .ap_make_ready = ll_ap_make_ready,
466 .ap_refresh_count = ll_ap_refresh_count,
467 .ap_fill_obdo = ll_ap_fill_obdo,
468 .ap_update_obdo = ll_ap_update_obdo,
469 .ap_completion = ll_ap_completion,
470 .ap_lookup_capa = ll_ap_lookup_capa,
473 struct ll_async_page *llap_cast_private(struct page *page)
475 struct ll_async_page *llap = (struct ll_async_page *)page_private(page);
477 LASSERTF(llap == NULL || llap->llap_magic == LLAP_MAGIC,
478 "page %p private %lu gave magic %d which != %d\n",
479 page, page_private(page), llap->llap_magic, LLAP_MAGIC);
484 /* Try to shrink the page cache for the @sbi filesystem by 1/@shrink_fraction.
486 * There is an llap attached onto every page in lustre, linked off @sbi.
487 * We add an llap to the list so we don't lose our place during list walking.
488 * If llaps in the list are being moved they will only move to the end
489 * of the LRU, and we aren't terribly interested in those pages here (we
490 * start at the beginning of the list where the least-used llaps are.
492 int llap_shrink_cache(struct ll_sb_info *sbi, int shrink_fraction)
494 struct ll_async_page *llap, dummy_llap = { .llap_magic = 0xd11ad11a };
495 unsigned long total, want, count = 0;
497 total = sbi->ll_async_page_count;
499 /* There can be a large number of llaps (600k or more in a large
500 * memory machine) so the VM 1/6 shrink ratio is likely too much.
501 * Since we are freeing pages also, we don't necessarily want to
502 * shrink so much. Limit to 40MB of pages + llaps per call. */
503 if (shrink_fraction == 0)
504 want = sbi->ll_async_page_count - sbi->ll_async_page_max + 32;
506 want = (total + shrink_fraction - 1) / shrink_fraction;
508 if (want > 40 << (20 - CFS_PAGE_SHIFT))
509 want = 40 << (20 - CFS_PAGE_SHIFT);
511 CDEBUG(D_CACHE, "shrinking %lu of %lu pages (1/%d)\n",
512 want, total, shrink_fraction);
514 spin_lock(&sbi->ll_lock);
515 list_add(&dummy_llap.llap_pglist_item, &sbi->ll_pglist);
517 while (--total >= 0 && count < want) {
521 if (unlikely(need_resched())) {
522 spin_unlock(&sbi->ll_lock);
524 spin_lock(&sbi->ll_lock);
527 llap = llite_pglist_next_llap(sbi,&dummy_llap.llap_pglist_item);
528 list_del_init(&dummy_llap.llap_pglist_item);
532 page = llap->llap_page;
533 LASSERT(page != NULL);
535 list_add(&dummy_llap.llap_pglist_item, &llap->llap_pglist_item);
537 /* Page needs/undergoing IO */
538 if (TryLockPage(page)) {
539 LL_CDEBUG_PAGE(D_PAGE, page, "can't lock\n");
543 keep = (llap->llap_write_queued || PageDirty(page) ||
544 PageWriteback(page) || (!PageUptodate(page) &&
545 llap->llap_origin != LLAP_ORIGIN_READAHEAD));
547 LL_CDEBUG_PAGE(D_PAGE, page,"%s LRU page: %s%s%s%s%s origin %s\n",
548 keep ? "keep" : "drop",
549 llap->llap_write_queued ? "wq " : "",
550 PageDirty(page) ? "pd " : "",
551 PageUptodate(page) ? "" : "!pu ",
552 PageWriteback(page) ? "wb" : "",
553 llap->llap_defer_uptodate ? "" : "!du",
554 llap_origins[llap->llap_origin]);
556 /* If page is dirty or undergoing IO don't discard it */
562 page_cache_get(page);
563 spin_unlock(&sbi->ll_lock);
565 if (page->mapping != NULL) {
566 ll_teardown_mmaps(page->mapping,
567 (__u64)page->index << CFS_PAGE_SHIFT,
568 ((__u64)page->index << CFS_PAGE_SHIFT)|
570 if (!PageDirty(page) && !page_mapped(page)) {
571 ll_ra_accounting(llap, page->mapping);
572 ll_truncate_complete_page(page);
575 LL_CDEBUG_PAGE(D_PAGE, page, "Not dropping page"
583 page_cache_release(page);
585 spin_lock(&sbi->ll_lock);
587 list_del(&dummy_llap.llap_pglist_item);
588 spin_unlock(&sbi->ll_lock);
590 CDEBUG(D_CACHE, "shrank %lu/%lu and left %lu unscanned\n",
596 static struct ll_async_page *llap_from_page_with_lockh(struct page *page,
598 struct lustre_handle *lockh)
600 struct ll_async_page *llap;
601 struct obd_export *exp;
602 struct inode *inode = page->mapping->host;
603 struct ll_sb_info *sbi;
608 static int triggered;
611 LL_CDEBUG_PAGE(D_ERROR, page, "Bug 10047. Wrong anon "
613 libcfs_debug_dumpstack(NULL);
616 RETURN(ERR_PTR(-EINVAL));
618 sbi = ll_i2sbi(inode);
619 LASSERT(ll_async_page_slab);
620 LASSERTF(origin < LLAP__ORIGIN_MAX, "%u\n", origin);
622 llap = llap_cast_private(page);
624 /* move to end of LRU list, except when page is just about to
626 if (origin != LLAP_ORIGIN_REMOVEPAGE) {
627 spin_lock(&sbi->ll_lock);
628 sbi->ll_pglist_gen++;
629 list_del_init(&llap->llap_pglist_item);
630 list_add_tail(&llap->llap_pglist_item, &sbi->ll_pglist);
631 spin_unlock(&sbi->ll_lock);
636 exp = ll_i2dtexp(page->mapping->host);
638 RETURN(ERR_PTR(-EINVAL));
640 /* limit the number of lustre-cached pages */
641 if (sbi->ll_async_page_count >= sbi->ll_async_page_max)
642 llap_shrink_cache(sbi, 0);
644 OBD_SLAB_ALLOC(llap, ll_async_page_slab, CFS_ALLOC_STD,
645 ll_async_page_slab_size);
647 RETURN(ERR_PTR(-ENOMEM));
648 llap->llap_magic = LLAP_MAGIC;
649 llap->llap_cookie = (void *)llap + size_round(sizeof(*llap));
651 /* XXX: for bug 11270 - check for lockless origin here! */
652 if (origin == LLAP_ORIGIN_LOCKLESS_IO)
653 llap->llap_nocache = 1;
655 rc = obd_prep_async_page(exp, ll_i2info(inode)->lli_smd, NULL, page,
656 (obd_off)page->index << CFS_PAGE_SHIFT,
657 &ll_async_page_ops, llap, &llap->llap_cookie,
658 llap->llap_nocache, lockh);
660 OBD_SLAB_FREE(llap, ll_async_page_slab,
661 ll_async_page_slab_size);
665 CDEBUG(D_CACHE, "llap %p page %p cookie %p obj off "LPU64"\n", llap,
666 page, llap->llap_cookie, (obd_off)page->index << CFS_PAGE_SHIFT);
667 /* also zeroing the PRIVBITS low order bitflags */
668 __set_page_ll_data(page, llap);
669 llap->llap_page = page;
670 spin_lock(&sbi->ll_lock);
671 sbi->ll_pglist_gen++;
672 sbi->ll_async_page_count++;
673 list_add_tail(&llap->llap_pglist_item, &sbi->ll_pglist);
674 INIT_LIST_HEAD(&llap->llap_pending_write);
675 spin_unlock(&sbi->ll_lock);
678 if (unlikely(sbi->ll_flags & LL_SBI_CHECKSUM)) {
680 char *kaddr = kmap_atomic(page, KM_USER0);
681 csum = init_checksum(OSC_DEFAULT_CKSUM);
682 csum = compute_checksum(csum, kaddr, CFS_PAGE_SIZE,
684 kunmap_atomic(kaddr, KM_USER0);
685 if (origin == LLAP_ORIGIN_READAHEAD ||
686 origin == LLAP_ORIGIN_READPAGE ||
687 origin == LLAP_ORIGIN_LOCKLESS_IO) {
688 llap->llap_checksum = 0;
689 } else if (origin == LLAP_ORIGIN_COMMIT_WRITE ||
690 llap->llap_checksum == 0) {
691 llap->llap_checksum = csum;
692 CDEBUG(D_PAGE, "page %p cksum %x\n", page, csum);
693 } else if (llap->llap_checksum == csum) {
694 /* origin == LLAP_ORIGIN_WRITEPAGE */
695 CDEBUG(D_PAGE, "page %p cksum %x confirmed\n",
698 /* origin == LLAP_ORIGIN_WRITEPAGE */
699 LL_CDEBUG_PAGE(D_ERROR, page, "old cksum %x != new "
700 "%x!\n", llap->llap_checksum, csum);
704 llap->llap_origin = origin;
708 struct ll_async_page *llap_from_page(struct page *page,
711 return llap_from_page_with_lockh(page, origin, NULL);
714 static int queue_or_sync_write(struct obd_export *exp, struct inode *inode,
715 struct ll_async_page *llap,
716 unsigned to, obd_flag async_flags)
718 unsigned long size_index = i_size_read(inode) >> CFS_PAGE_SHIFT;
719 struct obd_io_group *oig;
720 struct ll_sb_info *sbi = ll_i2sbi(inode);
721 int rc, noquot = llap->llap_ignore_quota ? OBD_BRW_NOQUOTA : 0;
724 /* _make_ready only sees llap once we've unlocked the page */
725 llap->llap_write_queued = 1;
726 rc = obd_queue_async_io(exp, ll_i2info(inode)->lli_smd, NULL,
727 llap->llap_cookie, OBD_BRW_WRITE | noquot,
728 0, 0, 0, async_flags);
730 LL_CDEBUG_PAGE(D_PAGE, llap->llap_page, "write queued\n");
734 llap->llap_write_queued = 0;
735 /* Do not pass llap here as it is sync write. */
736 llap_write_pending(inode, NULL);
742 /* make full-page requests if we are not at EOF (bug 4410) */
743 if (to != CFS_PAGE_SIZE && llap->llap_page->index < size_index) {
744 LL_CDEBUG_PAGE(D_PAGE, llap->llap_page,
745 "sync write before EOF: size_index %lu, to %d\n",
748 } else if (to != CFS_PAGE_SIZE && llap->llap_page->index == size_index) {
749 int size_to = i_size_read(inode) & ~CFS_PAGE_MASK;
750 LL_CDEBUG_PAGE(D_PAGE, llap->llap_page,
751 "sync write at EOF: size_index %lu, to %d/%d\n",
752 size_index, to, size_to);
757 /* compare the checksum once before the page leaves llite */
758 if (unlikely((sbi->ll_flags & LL_SBI_CHECKSUM) &&
759 llap->llap_checksum != 0)) {
761 struct page *page = llap->llap_page;
762 char *kaddr = kmap_atomic(page, KM_USER0);
763 csum = init_checksum(OSC_DEFAULT_CKSUM);
764 csum = compute_checksum(csum, kaddr, CFS_PAGE_SIZE,
766 kunmap_atomic(kaddr, KM_USER0);
767 if (llap->llap_checksum == csum) {
768 CDEBUG(D_PAGE, "page %p cksum %x confirmed\n",
771 CERROR("page %p old cksum %x != new cksum %x!\n",
772 page, llap->llap_checksum, csum);
776 rc = obd_queue_group_io(exp, ll_i2info(inode)->lli_smd, NULL, oig,
777 llap->llap_cookie, OBD_BRW_WRITE | noquot,
778 0, to, 0, ASYNC_READY | ASYNC_URGENT |
779 ASYNC_COUNT_STABLE | ASYNC_GROUP_SYNC);
783 rc = obd_trigger_group_io(exp, ll_i2info(inode)->lli_smd, NULL, oig);
789 if (!rc && async_flags & ASYNC_READY) {
790 unlock_page(llap->llap_page);
791 if (PageWriteback(llap->llap_page)) {
792 end_page_writeback(llap->llap_page);
796 if (rc == 0 && llap_write_complete(inode, llap))
797 ll_queue_done_writing(inode, 0);
799 LL_CDEBUG_PAGE(D_PAGE, llap->llap_page, "sync write returned %d\n", rc);
807 /* update our write count to account for i_size increases that may have
808 * happened since we've queued the page for io. */
810 /* be careful not to return success without setting the page Uptodate or
811 * the next pass through prepare_write will read in stale data from disk. */
812 int ll_commit_write(struct file *file, struct page *page, unsigned from,
815 struct ll_file_data *fd = LUSTRE_FPRIVATE(file);
816 struct inode *inode = page->mapping->host;
817 struct ll_inode_info *lli = ll_i2info(inode);
818 struct lov_stripe_md *lsm = lli->lli_smd;
819 struct obd_export *exp;
820 struct ll_async_page *llap;
822 struct lustre_handle *lockh = NULL;
826 SIGNAL_MASK_ASSERT(); /* XXX BUG 1511 */
827 LASSERT(inode == file->f_dentry->d_inode);
828 LASSERT(PageLocked(page));
830 CDEBUG(D_INODE, "inode %p is writing page %p from %d to %d at %lu\n",
831 inode, page, from, to, page->index);
833 if (fd->fd_flags & LL_FILE_GROUP_LOCKED)
834 lockh = &fd->fd_cwlockh;
836 llap = llap_from_page_with_lockh(page, LLAP_ORIGIN_COMMIT_WRITE, lockh);
838 RETURN(PTR_ERR(llap));
840 exp = ll_i2dtexp(inode);
844 llap->llap_ignore_quota = capable(CAP_SYS_RESOURCE);
847 * queue a write for some time in the future the first time we
850 * This is different from what other file systems do: they usually
851 * just mark page (and some of its buffers) dirty and rely on
852 * balance_dirty_pages() to start a write-back. Lustre wants write-back
853 * to be started earlier for the following reasons:
855 * (1) with a large number of clients we need to limit the amount
856 * of cached data on the clients a lot;
858 * (2) large compute jobs generally want compute-only then io-only
859 * and the IO should complete as quickly as possible;
861 * (3) IO is batched up to the RPC size and is async until the
862 * client max cache is hit
863 * (/proc/fs/lustre/osc/OSC.../max_dirty_mb)
866 if (!PageDirty(page)) {
867 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_DIRTY_MISSES, 1);
869 rc = queue_or_sync_write(exp, inode, llap, to, 0);
873 ll_stats_ops_tally(ll_i2sbi(inode), LPROC_LL_DIRTY_HITS, 1);
876 /* put the page in the page cache, from now on ll_removepage is
877 * responsible for cleaning up the llap.
878 * only set page dirty when it's queued to be write out */
879 if (llap->llap_write_queued)
880 set_page_dirty(page);
883 size = (((obd_off)page->index) << CFS_PAGE_SHIFT) + to;
884 ll_inode_size_lock(inode, 0);
886 lov_stripe_lock(lsm);
887 obd_adjust_kms(exp, lsm, size, 0);
888 lov_stripe_unlock(lsm);
889 if (size > i_size_read(inode))
890 i_size_write(inode, size);
891 SetPageUptodate(page);
892 } else if (size > i_size_read(inode)) {
893 /* this page beyond the pales of i_size, so it can't be
894 * truncated in ll_p_r_e during lock revoking. we must
895 * teardown our book-keeping here. */
898 ll_inode_size_unlock(inode, 0);
902 static unsigned long ll_ra_count_get(struct ll_sb_info *sbi, unsigned long len)
904 struct ll_ra_info *ra = &sbi->ll_ra_info;
908 spin_lock(&sbi->ll_lock);
909 ret = min(ra->ra_max_pages - ra->ra_cur_pages, len);
910 ra->ra_cur_pages += ret;
911 spin_unlock(&sbi->ll_lock);
916 static void ll_ra_count_put(struct ll_sb_info *sbi, unsigned long len)
918 struct ll_ra_info *ra = &sbi->ll_ra_info;
919 spin_lock(&sbi->ll_lock);
920 LASSERTF(ra->ra_cur_pages >= len, "r_c_p %lu len %lu\n",
921 ra->ra_cur_pages, len);
922 ra->ra_cur_pages -= len;
923 spin_unlock(&sbi->ll_lock);
926 /* called for each page in a completed rpc.*/
927 int ll_ap_completion(void *data, int cmd, struct obdo *oa, int rc)
929 struct ll_async_page *llap;
934 llap = LLAP_FROM_COOKIE(data);
935 page = llap->llap_page;
936 LASSERT(PageLocked(page));
937 LASSERT(CheckWriteback(page,cmd));
939 LL_CDEBUG_PAGE(D_PAGE, page, "completing cmd %d with %d\n", cmd, rc);
941 if (cmd & OBD_BRW_READ && llap->llap_defer_uptodate)
942 ll_ra_count_put(ll_i2sbi(page->mapping->host), 1);
945 if (cmd & OBD_BRW_READ) {
946 if (!llap->llap_defer_uptodate)
947 SetPageUptodate(page);
949 llap->llap_write_queued = 0;
951 ClearPageError(page);
953 if (cmd & OBD_BRW_READ) {
954 llap->llap_defer_uptodate = 0;
958 set_bit(AS_ENOSPC, &page->mapping->flags);
960 set_bit(AS_EIO, &page->mapping->flags);
965 if (cmd & OBD_BRW_WRITE) {
966 /* Only rc == 0, write succeed, then this page could be deleted
967 * from the pending_writing list
969 if (rc == 0 && llap_write_complete(page->mapping->host, llap))
970 ll_queue_done_writing(page->mapping->host, 0);
973 if (PageWriteback(page)) {
974 end_page_writeback(page);
976 page_cache_release(page);
981 static void __ll_put_llap(struct page *page)
983 struct inode *inode = page->mapping->host;
984 struct obd_export *exp;
985 struct ll_async_page *llap;
986 struct ll_sb_info *sbi = ll_i2sbi(inode);
990 exp = ll_i2dtexp(inode);
992 CERROR("page %p ind %lu gave null export\n", page, page->index);
997 llap = llap_from_page(page, LLAP_ORIGIN_REMOVEPAGE);
999 CERROR("page %p ind %lu couldn't find llap: %ld\n", page,
1000 page->index, PTR_ERR(llap));
1005 if (llap_write_complete(inode, llap))
1006 ll_queue_done_writing(inode, 0);
1008 rc = obd_teardown_async_page(exp, ll_i2info(inode)->lli_smd, NULL,
1011 CERROR("page %p ind %lu failed: %d\n", page, page->index, rc);
1013 /* this unconditional free is only safe because the page lock
1014 * is providing exclusivity to memory pressure/truncate/writeback..*/
1015 __clear_page_ll_data(page);
1017 spin_lock(&sbi->ll_lock);
1018 if (!list_empty(&llap->llap_pglist_item))
1019 list_del_init(&llap->llap_pglist_item);
1020 sbi->ll_pglist_gen++;
1021 sbi->ll_async_page_count--;
1022 spin_unlock(&sbi->ll_lock);
1023 OBD_SLAB_FREE(llap, ll_async_page_slab, ll_async_page_slab_size);
1027 /* the kernel calls us here when a page is unhashed from the page cache.
1028 * the page will be locked and the kernel is holding a spinlock, so
1029 * we need to be careful. we're just tearing down our book-keeping
1031 void ll_removepage(struct page *page)
1033 struct ll_async_page *llap = llap_cast_private(page);
1036 LASSERT(!in_interrupt());
1038 /* sync pages or failed read pages can leave pages in the page
1039 * cache that don't have our data associated with them anymore */
1040 if (page_private(page) == 0) {
1045 LASSERT(!llap->llap_lockless_io_page);
1046 LASSERT(!llap->llap_nocache);
1047 LL_CDEBUG_PAGE(D_PAGE, page, "being evicted\n");
1048 __ll_put_llap(page);
1052 static int ll_issue_page_read(struct obd_export *exp,
1053 struct ll_async_page *llap,
1054 struct obd_io_group *oig, int defer)
1056 struct page *page = llap->llap_page;
1059 page_cache_get(page);
1060 llap->llap_defer_uptodate = defer;
1061 llap->llap_ra_used = 0;
1062 rc = obd_queue_group_io(exp, ll_i2info(page->mapping->host)->lli_smd,
1063 NULL, oig, llap->llap_cookie, OBD_BRW_READ, 0,
1064 CFS_PAGE_SIZE, 0, ASYNC_COUNT_STABLE |
1065 ASYNC_READY | ASYNC_URGENT);
1067 LL_CDEBUG_PAGE(D_ERROR, page, "read queue failed: rc %d\n", rc);
1068 page_cache_release(page);
1073 static void ll_ra_stats_inc_unlocked(struct ll_ra_info *ra, enum ra_stat which)
1075 LASSERTF(which >= 0 && which < _NR_RA_STAT, "which: %u\n", which);
1076 ra->ra_stats[which]++;
1079 static void ll_ra_stats_inc(struct address_space *mapping, enum ra_stat which)
1081 struct ll_sb_info *sbi = ll_i2sbi(mapping->host);
1082 struct ll_ra_info *ra = &ll_i2sbi(mapping->host)->ll_ra_info;
1084 spin_lock(&sbi->ll_lock);
1085 ll_ra_stats_inc_unlocked(ra, which);
1086 spin_unlock(&sbi->ll_lock);
1089 void ll_ra_accounting(struct ll_async_page *llap, struct address_space *mapping)
1091 if (!llap->llap_defer_uptodate || llap->llap_ra_used)
1094 ll_ra_stats_inc(mapping, RA_STAT_DISCARDED);
1097 #define RAS_CDEBUG(ras) \
1099 "lrp %lu cr %lu cp %lu ws %lu wl %lu nra %lu r %lu ri %lu" \
1100 "csr %lu sf %lu sp %lu sl %lu \n", \
1101 ras->ras_last_readpage, ras->ras_consecutive_requests, \
1102 ras->ras_consecutive_pages, ras->ras_window_start, \
1103 ras->ras_window_len, ras->ras_next_readahead, \
1104 ras->ras_requests, ras->ras_request_index, \
1105 ras->ras_consecutive_stride_requests, ras->ras_stride_offset, \
1106 ras->ras_stride_pages, ras->ras_stride_length)
1108 static int index_in_window(unsigned long index, unsigned long point,
1109 unsigned long before, unsigned long after)
1111 unsigned long start = point - before, end = point + after;
1118 return start <= index && index <= end;
1121 static struct ll_readahead_state *ll_ras_get(struct file *f)
1123 struct ll_file_data *fd;
1125 fd = LUSTRE_FPRIVATE(f);
1129 void ll_ra_read_in(struct file *f, struct ll_ra_read *rar)
1131 struct ll_readahead_state *ras;
1133 ras = ll_ras_get(f);
1135 spin_lock(&ras->ras_lock);
1136 ras->ras_requests++;
1137 ras->ras_request_index = 0;
1138 ras->ras_consecutive_requests++;
1139 rar->lrr_reader = current;
1141 list_add(&rar->lrr_linkage, &ras->ras_read_beads);
1142 spin_unlock(&ras->ras_lock);
1145 void ll_ra_read_ex(struct file *f, struct ll_ra_read *rar)
1147 struct ll_readahead_state *ras;
1149 ras = ll_ras_get(f);
1151 spin_lock(&ras->ras_lock);
1152 list_del_init(&rar->lrr_linkage);
1153 spin_unlock(&ras->ras_lock);
1156 static struct ll_ra_read *ll_ra_read_get_locked(struct ll_readahead_state *ras)
1158 struct ll_ra_read *scan;
1160 list_for_each_entry(scan, &ras->ras_read_beads, lrr_linkage) {
1161 if (scan->lrr_reader == current)
1167 struct ll_ra_read *ll_ra_read_get(struct file *f)
1169 struct ll_readahead_state *ras;
1170 struct ll_ra_read *bead;
1172 ras = ll_ras_get(f);
1174 spin_lock(&ras->ras_lock);
1175 bead = ll_ra_read_get_locked(ras);
1176 spin_unlock(&ras->ras_lock);
1180 static int ll_read_ahead_page(struct obd_export *exp, struct obd_io_group *oig,
1181 int index, struct address_space *mapping)
1183 struct ll_async_page *llap;
1185 unsigned int gfp_mask = 0;
1188 gfp_mask = GFP_HIGHUSER & ~__GFP_WAIT;
1190 gfp_mask |= __GFP_NOWARN;
1192 page = grab_cache_page_nowait_gfp(mapping, index, gfp_mask);
1194 ll_ra_stats_inc(mapping, RA_STAT_FAILED_GRAB_PAGE);
1195 CDEBUG(D_READA, "g_c_p_n failed\n");
1199 /* Check if page was truncated or reclaimed */
1200 if (page->mapping != mapping) {
1201 ll_ra_stats_inc(mapping, RA_STAT_WRONG_GRAB_PAGE);
1202 CDEBUG(D_READA, "g_c_p_n returned invalid page\n");
1203 GOTO(unlock_page, rc = 0);
1206 /* we do this first so that we can see the page in the /proc
1208 llap = llap_from_page(page, LLAP_ORIGIN_READAHEAD);
1209 if (IS_ERR(llap) || llap->llap_defer_uptodate) {
1210 if (PTR_ERR(llap) == -ENOLCK) {
1211 ll_ra_stats_inc(mapping, RA_STAT_FAILED_MATCH);
1212 CDEBUG(D_READA | D_PAGE,
1213 "Adding page to cache failed index "
1215 CDEBUG(D_READA, "nolock page\n");
1216 GOTO(unlock_page, rc = -ENOLCK);
1218 CDEBUG(D_READA, "read-ahead page\n");
1219 GOTO(unlock_page, rc = 0);
1222 /* skip completed pages */
1223 if (Page_Uptodate(page))
1224 GOTO(unlock_page, rc = 0);
1226 /* bail out when we hit the end of the lock. */
1227 rc = ll_issue_page_read(exp, llap, oig, 1);
1229 LL_CDEBUG_PAGE(D_READA | D_PAGE, page, "started read-ahead\n");
1234 LL_CDEBUG_PAGE(D_READA | D_PAGE, page, "skipping read-ahead\n");
1236 page_cache_release(page);
1240 /* ra_io_arg will be filled in the beginning of ll_readahead with
1241 * ras_lock, then the following ll_read_ahead_pages will read RA
1242 * pages according to this arg, all the items in this structure are
1243 * counted by page index.
1246 unsigned long ria_start; /* start offset of read-ahead*/
1247 unsigned long ria_end; /* end offset of read-ahead*/
1248 /* If stride read pattern is detected, ria_stoff means where
1249 * stride read is started. Note: for normal read-ahead, the
1250 * value here is meaningless, and also it will not be accessed*/
1252 /* ria_length and ria_pages are the length and pages length in the
1253 * stride I/O mode. And they will also be used to check whether
1254 * it is stride I/O read-ahead in the read-ahead pages*/
1255 unsigned long ria_length;
1256 unsigned long ria_pages;
1259 #define RIA_DEBUG(ria) \
1260 CDEBUG(D_READA, "rs %lu re %lu ro %lu rl %lu rp %lu\n", \
1261 ria->ria_start, ria->ria_end, ria->ria_stoff, ria->ria_length,\
1264 #define RAS_INCREASE_STEP (1024 * 1024 >> CFS_PAGE_SHIFT)
1266 static inline int stride_io_mode(struct ll_readahead_state *ras)
1268 return ras->ras_consecutive_stride_requests > 1;
1271 /* The function calculates how much pages will be read in
1272 * [off, off + length], which will be read by stride I/O mode,
1273 * stride_offset = st_off, stride_lengh = st_len,
1274 * stride_pages = st_pgs
1276 static unsigned long
1277 stride_pg_count(pgoff_t st_off, unsigned long st_len, unsigned long st_pgs,
1278 unsigned long off, unsigned length)
1280 unsigned long cont_len = st_off > off ? st_off - off : 0;
1281 unsigned long stride_len = length + off > st_off ?
1282 length + off + 1 - st_off : 0;
1283 unsigned long left, pg_count;
1285 if (st_len == 0 || length == 0)
1288 left = do_div(stride_len, st_len);
1289 left = min(left, st_pgs);
1291 pg_count = left + stride_len * st_pgs + cont_len;
1293 LASSERT(pg_count >= left);
1295 CDEBUG(D_READA, "st_off %lu, st_len %lu st_pgs %lu off %lu length %u"
1296 "pgcount %lu\n", st_off, st_len, st_pgs, off, length, pg_count);
1301 static int ria_page_count(struct ra_io_arg *ria)
1303 __u64 length = ria->ria_end >= ria->ria_start ?
1304 ria->ria_end - ria->ria_start + 1 : 0;
1306 return stride_pg_count(ria->ria_stoff, ria->ria_length,
1307 ria->ria_pages, ria->ria_start,
1311 /*Check whether the index is in the defined ra-window */
1312 static int ras_inside_ra_window(unsigned long idx, struct ra_io_arg *ria)
1314 /* If ria_length == ria_pages, it means non-stride I/O mode,
1315 * idx should always inside read-ahead window in this case
1316 * For stride I/O mode, just check whether the idx is inside
1318 return ria->ria_length == 0 || ria->ria_length == ria->ria_pages ||
1319 (idx - ria->ria_stoff) % ria->ria_length < ria->ria_pages;
1322 static int ll_read_ahead_pages(struct obd_export *exp,
1323 struct obd_io_group *oig,
1324 struct ra_io_arg *ria,
1325 unsigned long *reserved_pages,
1326 struct address_space *mapping,
1327 unsigned long *ra_end)
1329 int rc, count = 0, stride_ria;
1330 unsigned long page_idx;
1332 LASSERT(ria != NULL);
1335 stride_ria = ria->ria_length > ria->ria_pages && ria->ria_pages > 0;
1336 for (page_idx = ria->ria_start; page_idx <= ria->ria_end &&
1337 *reserved_pages > 0; page_idx++) {
1338 if (ras_inside_ra_window(page_idx, ria)) {
1339 /* If the page is inside the read-ahead window*/
1340 rc = ll_read_ahead_page(exp, oig, page_idx, mapping);
1342 (*reserved_pages)--;
1344 } else if (rc == -ENOLCK)
1346 } else if (stride_ria) {
1347 /* If it is not in the read-ahead window, and it is
1348 * read-ahead mode, then check whether it should skip
1351 /* FIXME: This assertion only is valid when it is for
1352 * forward read-ahead, it will be fixed when backward
1353 * read-ahead is implemented */
1354 LASSERTF(page_idx > ria->ria_stoff, "since %lu in the"
1355 " gap of ra window,it should bigger than stride"
1356 " offset %lu \n", page_idx, ria->ria_stoff);
1358 offset = page_idx - ria->ria_stoff;
1359 offset = offset % (ria->ria_length);
1360 if (offset > ria->ria_pages) {
1361 page_idx += ria->ria_length - offset;
1362 CDEBUG(D_READA, "i %lu skip %lu \n", page_idx,
1363 ria->ria_length - offset);
1372 static int ll_readahead(struct ll_readahead_state *ras,
1373 struct obd_export *exp, struct address_space *mapping,
1374 struct obd_io_group *oig, int flags)
1376 unsigned long start = 0, end = 0, reserved;
1377 unsigned long ra_end, len;
1378 struct inode *inode;
1379 struct lov_stripe_md *lsm;
1380 struct ll_ra_read *bead;
1382 struct ra_io_arg ria = { 0 };
1387 inode = mapping->host;
1388 lsm = ll_i2info(inode)->lli_smd;
1390 lov_stripe_lock(lsm);
1391 inode_init_lvb(inode, &lvb);
1392 obd_merge_lvb(ll_i2dtexp(inode), lsm, &lvb, 1);
1394 lov_stripe_unlock(lsm);
1396 ll_ra_stats_inc(mapping, RA_STAT_ZERO_LEN);
1400 spin_lock(&ras->ras_lock);
1401 bead = ll_ra_read_get_locked(ras);
1402 /* Enlarge the RA window to encompass the full read */
1403 if (bead != NULL && ras->ras_window_start + ras->ras_window_len <
1404 bead->lrr_start + bead->lrr_count) {
1405 ras->ras_window_len = bead->lrr_start + bead->lrr_count -
1406 ras->ras_window_start;
1408 /* Reserve a part of the read-ahead window that we'll be issuing */
1409 if (ras->ras_window_len) {
1410 start = ras->ras_next_readahead;
1411 end = ras->ras_window_start + ras->ras_window_len - 1;
1414 /* Truncate RA window to end of file */
1415 end = min(end, (unsigned long)((kms - 1) >> CFS_PAGE_SHIFT));
1416 ras->ras_next_readahead = max(end, end + 1);
1419 ria.ria_start = start;
1421 /* If stride I/O mode is detected, get stride window*/
1422 if (stride_io_mode(ras)) {
1423 ria.ria_length = ras->ras_stride_length;
1424 ria.ria_pages = ras->ras_stride_pages;
1426 spin_unlock(&ras->ras_lock);
1429 ll_ra_stats_inc(mapping, RA_STAT_ZERO_WINDOW);
1432 len = ria_page_count(&ria);
1436 reserved = ll_ra_count_get(ll_i2sbi(inode), len);
1438 if (reserved < end - start + 1)
1439 ll_ra_stats_inc(mapping, RA_STAT_MAX_IN_FLIGHT);
1441 CDEBUG(D_READA, "reserved page %lu \n", reserved);
1443 ret = ll_read_ahead_pages(exp, oig, &ria, &reserved, mapping, &ra_end);
1445 LASSERTF(reserved >= 0, "reserved %lu\n", reserved);
1447 ll_ra_count_put(ll_i2sbi(inode), reserved);
1449 if (ra_end == end + 1 && ra_end == (kms >> CFS_PAGE_SHIFT))
1450 ll_ra_stats_inc(mapping, RA_STAT_EOF);
1452 /* if we didn't get to the end of the region we reserved from
1453 * the ras we need to go back and update the ras so that the
1454 * next read-ahead tries from where we left off. we only do so
1455 * if the region we failed to issue read-ahead on is still ahead
1456 * of the app and behind the next index to start read-ahead from */
1457 CDEBUG(D_READA, "ra_end %lu end %lu stride end %lu \n",
1458 ra_end, end, ria.ria_end);
1460 if (ra_end != (end + 1)) {
1461 spin_lock(&ras->ras_lock);
1462 if (ra_end < ras->ras_next_readahead &&
1463 index_in_window(ra_end, ras->ras_window_start, 0,
1464 ras->ras_window_len)) {
1465 ras->ras_next_readahead = ra_end;
1468 spin_unlock(&ras->ras_lock);
1474 static void ras_set_start(struct ll_readahead_state *ras, unsigned long index)
1476 ras->ras_window_start = index & (~(RAS_INCREASE_STEP - 1));
1479 /* called with the ras_lock held or from places where it doesn't matter */
1480 static void ras_reset(struct ll_readahead_state *ras, unsigned long index)
1482 ras->ras_last_readpage = index;
1483 ras->ras_consecutive_requests = 0;
1484 ras->ras_consecutive_pages = 0;
1485 ras->ras_window_len = 0;
1486 ras_set_start(ras, index);
1487 ras->ras_next_readahead = max(ras->ras_window_start, index);
1492 /* called with the ras_lock held or from places where it doesn't matter */
1493 static void ras_stride_reset(struct ll_readahead_state *ras)
1495 ras->ras_consecutive_stride_requests = 0;
1499 void ll_readahead_init(struct inode *inode, struct ll_readahead_state *ras)
1501 spin_lock_init(&ras->ras_lock);
1503 ras->ras_requests = 0;
1504 INIT_LIST_HEAD(&ras->ras_read_beads);
1507 /* Check whether the read request is in the stride window.
1508 * If it is in the stride window, return 1, otherwise return 0.
1509 * and also update stride_gap and stride_pages.
1511 static int index_in_stride_window(unsigned long index,
1512 struct ll_readahead_state *ras,
1513 struct inode *inode)
1515 int stride_gap = index - ras->ras_last_readpage - 1;
1517 LASSERT(stride_gap != 0);
1519 if (ras->ras_consecutive_pages == 0)
1522 /*Otherwise check the stride by itself */
1523 if ((ras->ras_stride_length - ras->ras_stride_pages) == stride_gap &&
1524 ras->ras_consecutive_pages == ras->ras_stride_pages)
1527 if (stride_gap >= 0) {
1529 * only set stride_pages, stride_length if
1530 * it is forward reading ( stride_gap > 0)
1532 ras->ras_stride_pages = ras->ras_consecutive_pages;
1533 ras->ras_stride_length = stride_gap + ras->ras_consecutive_pages;
1536 * If stride_gap < 0,(back_forward reading),
1537 * reset the stride_pages/length.
1538 * FIXME:back_ward stride I/O read.
1541 ras->ras_stride_pages = 0;
1542 ras->ras_stride_length = 0;
1549 static unsigned long
1550 stride_page_count(struct ll_readahead_state *ras, unsigned long len)
1552 return stride_pg_count(ras->ras_stride_offset, ras->ras_stride_length,
1553 ras->ras_stride_pages, ras->ras_stride_offset,
1557 /* Stride Read-ahead window will be increased inc_len according to
1558 * stride I/O pattern */
1559 static void ras_stride_increase_window(struct ll_readahead_state *ras,
1560 struct ll_ra_info *ra,
1561 unsigned long inc_len)
1563 unsigned long left, step, window_len;
1564 unsigned long stride_len;
1566 LASSERT(ras->ras_stride_length > 0);
1568 stride_len = ras->ras_window_start + ras->ras_window_len -
1569 ras->ras_stride_offset;
1571 LASSERTF(stride_len >= 0, "window_start %lu, window_len %lu"
1572 " stride_offset %lu\n", ras->ras_window_start,
1573 ras->ras_window_len, ras->ras_stride_offset);
1575 left = stride_len % ras->ras_stride_length;
1577 window_len = ras->ras_window_len - left;
1579 if (left < ras->ras_stride_pages)
1582 left = ras->ras_stride_pages + inc_len;
1584 LASSERT(ras->ras_stride_pages != 0);
1586 step = left / ras->ras_stride_pages;
1587 left %= ras->ras_stride_pages;
1589 window_len += step * ras->ras_stride_length + left;
1591 if (stride_page_count(ras, window_len) <= ra->ra_max_pages)
1592 ras->ras_window_len = window_len;
1597 /* Set stride I/O read-ahead window start offset */
1598 static void ras_set_stride_offset(struct ll_readahead_state *ras)
1600 unsigned long window_len = ras->ras_next_readahead -
1601 ras->ras_window_start;
1604 LASSERT(ras->ras_stride_length != 0);
1606 left = window_len % ras->ras_stride_length;
1608 ras->ras_stride_offset = ras->ras_next_readahead - left;
1613 static void ras_update(struct ll_sb_info *sbi, struct inode *inode,
1614 struct ll_readahead_state *ras, unsigned long index,
1617 struct ll_ra_info *ra = &sbi->ll_ra_info;
1618 int zero = 0, stride_zero = 0, stride_detect = 0, ra_miss = 0;
1621 spin_lock(&sbi->ll_lock);
1622 spin_lock(&ras->ras_lock);
1624 ll_ra_stats_inc_unlocked(ra, hit ? RA_STAT_HIT : RA_STAT_MISS);
1626 /* reset the read-ahead window in two cases. First when the app seeks
1627 * or reads to some other part of the file. Secondly if we get a
1628 * read-ahead miss that we think we've previously issued. This can
1629 * be a symptom of there being so many read-ahead pages that the VM is
1630 * reclaiming it before we get to it. */
1631 if (!index_in_window(index, ras->ras_last_readpage, 8, 8)) {
1633 ll_ra_stats_inc_unlocked(ra, RA_STAT_DISTANT_READPAGE);
1634 /* check whether it is in stride I/O mode*/
1635 if (!index_in_stride_window(index, ras, inode))
1637 } else if (!hit && ras->ras_window_len &&
1638 index < ras->ras_next_readahead &&
1639 index_in_window(index, ras->ras_window_start, 0,
1640 ras->ras_window_len)) {
1643 /* If it hits read-ahead miss and the stride I/O is still
1644 * not detected, reset stride stuff to re-detect the whole
1645 * stride I/O mode to avoid complication */
1646 if (!stride_io_mode(ras))
1648 ll_ra_stats_inc_unlocked(ra, RA_STAT_MISS_IN_WINDOW);
1651 /* On the second access to a file smaller than the tunable
1652 * ra_max_read_ahead_whole_pages trigger RA on all pages in the
1653 * file up to ra_max_pages. This is simply a best effort and
1654 * only occurs once per open file. Normal RA behavior is reverted
1655 * to for subsequent IO. The mmap case does not increment
1656 * ras_requests and thus can never trigger this behavior. */
1657 if (ras->ras_requests == 2 && !ras->ras_request_index) {
1660 kms_pages = (i_size_read(inode) + CFS_PAGE_SIZE - 1) >>
1663 CDEBUG(D_READA, "kmsp "LPU64" mwp %lu mp %lu\n", kms_pages,
1664 ra->ra_max_read_ahead_whole_pages, ra->ra_max_pages);
1667 kms_pages <= ra->ra_max_read_ahead_whole_pages) {
1668 ras->ras_window_start = 0;
1669 ras->ras_last_readpage = 0;
1670 ras->ras_next_readahead = 0;
1671 ras->ras_window_len = min(ra->ra_max_pages,
1672 ra->ra_max_read_ahead_whole_pages);
1673 GOTO(out_unlock, 0);
1678 /* If it is discontinuous read, check
1679 * whether it is stride I/O mode*/
1681 ras_reset(ras, index);
1682 ras->ras_consecutive_pages++;
1683 ras_stride_reset(ras);
1685 GOTO(out_unlock, 0);
1687 /* The read is still in stride window or
1688 * it hits read-ahead miss */
1690 /* If ra-window miss is hitted, which probably means VM
1691 * pressure, and some read-ahead pages were reclaimed.So
1692 * the length of ra-window will not increased, but also
1693 * not reset to avoid redetecting the stride I/O mode.*/
1694 ras->ras_consecutive_requests = 0;
1696 ras->ras_consecutive_pages = 0;
1697 if (++ras->ras_consecutive_stride_requests > 1)
1702 } else if (ras->ras_consecutive_stride_requests > 1) {
1703 /* If this is contiguous read but in stride I/O mode
1704 * currently, check whether stride step still is valid,
1705 * if invalid, it will reset the stride ra window*/
1706 if (ras->ras_consecutive_pages + 1 > ras->ras_stride_pages)
1707 ras_stride_reset(ras);
1710 ras->ras_last_readpage = index;
1711 ras->ras_consecutive_pages++;
1712 ras_set_start(ras, index);
1713 ras->ras_next_readahead = max(ras->ras_window_start,
1714 ras->ras_next_readahead);
1717 /* Trigger RA in the mmap case where ras_consecutive_requests
1718 * is not incremented and thus can't be used to trigger RA */
1719 if (!ras->ras_window_len && ras->ras_consecutive_pages == 4) {
1720 ras->ras_window_len = RAS_INCREASE_STEP;
1721 GOTO(out_unlock, 0);
1724 /* Initially reset the stride window offset to next_readahead*/
1725 if (ras->ras_consecutive_stride_requests == 2 && stride_detect)
1726 ras_set_stride_offset(ras);
1728 /* The initial ras_window_len is set to the request size. To avoid
1729 * uselessly reading and discarding pages for random IO the window is
1730 * only increased once per consecutive request received. */
1731 if ((ras->ras_consecutive_requests > 1 &&
1732 !ras->ras_request_index) || stride_detect) {
1733 if (stride_io_mode(ras))
1734 ras_stride_increase_window(ras, ra, RAS_INCREASE_STEP);
1736 ras->ras_window_len = min(ras->ras_window_len +
1743 ras->ras_request_index++;
1744 spin_unlock(&ras->ras_lock);
1745 spin_unlock(&sbi->ll_lock);
1749 int ll_writepage(struct page *page)
1751 struct inode *inode = page->mapping->host;
1752 struct ll_inode_info *lli = ll_i2info(inode);
1753 struct obd_export *exp;
1754 struct ll_async_page *llap;
1758 LASSERT(PageLocked(page));
1760 exp = ll_i2dtexp(inode);
1762 GOTO(out, rc = -EINVAL);
1764 llap = llap_from_page(page, LLAP_ORIGIN_WRITEPAGE);
1766 GOTO(out, rc = PTR_ERR(llap));
1768 LASSERT(!llap->llap_nocache);
1769 LASSERT(!PageWriteback(page));
1770 set_page_writeback(page);
1772 page_cache_get(page);
1773 if (llap->llap_write_queued) {
1774 LL_CDEBUG_PAGE(D_PAGE, page, "marking urgent\n");
1775 rc = obd_set_async_flags(exp, lli->lli_smd, NULL,
1777 ASYNC_READY | ASYNC_URGENT);
1779 rc = queue_or_sync_write(exp, inode, llap, CFS_PAGE_SIZE,
1780 ASYNC_READY | ASYNC_URGENT);
1783 page_cache_release(page);
1786 if (!lli->lli_async_rc)
1787 lli->lli_async_rc = rc;
1788 /* re-dirty page on error so it retries write */
1789 if (PageWriteback(page)) {
1790 end_page_writeback(page);
1792 /* resend page only for not started IO*/
1793 if (!PageError(page))
1794 ll_redirty_page(page);
1801 * for now we do our readpage the same on both 2.4 and 2.5. The kernel's
1802 * read-ahead assumes it is valid to issue readpage all the way up to
1803 * i_size, but our dlm locks make that not the case. We disable the
1804 * kernel's read-ahead and do our own by walking ahead in the page cache
1805 * checking for dlm lock coverage. the main difference between 2.4 and
1806 * 2.6 is how read-ahead gets batched and issued, but we're using our own,
1807 * so they look the same.
1809 int ll_readpage(struct file *filp, struct page *page)
1811 struct ll_file_data *fd = LUSTRE_FPRIVATE(filp);
1812 struct inode *inode = page->mapping->host;
1813 struct obd_export *exp;
1814 struct ll_async_page *llap;
1815 struct obd_io_group *oig = NULL;
1816 struct lustre_handle *lockh = NULL;
1820 LASSERT(PageLocked(page));
1821 LASSERT(!PageUptodate(page));
1822 CDEBUG(D_VFSTRACE, "VFS Op:inode=%lu/%u(%p),offset=%Lu=%#Lx\n",
1823 inode->i_ino, inode->i_generation, inode,
1824 (((loff_t)page->index) << CFS_PAGE_SHIFT),
1825 (((loff_t)page->index) << CFS_PAGE_SHIFT));
1826 LASSERT(atomic_read(&filp->f_dentry->d_inode->i_count) > 0);
1828 if (!ll_i2info(inode)->lli_smd) {
1829 /* File with no objects - one big hole */
1830 /* We use this just for remove_from_page_cache that is not
1831 * exported, we'd make page back up to date. */
1832 ll_truncate_complete_page(page);
1833 clear_page(kmap(page));
1835 SetPageUptodate(page);
1840 rc = oig_init(&oig);
1844 exp = ll_i2dtexp(inode);
1846 GOTO(out, rc = -EINVAL);
1848 if (fd->fd_flags & LL_FILE_GROUP_LOCKED)
1849 lockh = &fd->fd_cwlockh;
1851 llap = llap_from_page_with_lockh(page, LLAP_ORIGIN_READPAGE, lockh);
1853 if (PTR_ERR(llap) == -ENOLCK) {
1854 CWARN("ino %lu page %lu (%llu) not covered by "
1855 "a lock (mmap?). check debug logs.\n",
1856 inode->i_ino, page->index,
1857 (long long)page->index << PAGE_CACHE_SHIFT);
1859 GOTO(out, rc = PTR_ERR(llap));
1862 if (ll_i2sbi(inode)->ll_ra_info.ra_max_pages)
1863 ras_update(ll_i2sbi(inode), inode, &fd->fd_ras, page->index,
1864 llap->llap_defer_uptodate);
1867 if (llap->llap_defer_uptodate) {
1868 /* This is the callpath if we got the page from a readahead */
1869 llap->llap_ra_used = 1;
1870 rc = ll_readahead(&fd->fd_ras, exp, page->mapping, oig,
1873 obd_trigger_group_io(exp, ll_i2info(inode)->lli_smd,
1875 LL_CDEBUG_PAGE(D_PAGE, page, "marking uptodate from defer\n");
1876 SetPageUptodate(page);
1878 GOTO(out_oig, rc = 0);
1881 rc = ll_issue_page_read(exp, llap, oig, 0);
1885 LL_CDEBUG_PAGE(D_PAGE, page, "queued readpage\n");
1886 /* We have just requested the actual page we want, see if we can tack
1887 * on some readahead to that page's RPC before it is sent. */
1888 if (ll_i2sbi(inode)->ll_ra_info.ra_max_pages)
1889 ll_readahead(&fd->fd_ras, exp, page->mapping, oig,
1892 rc = obd_trigger_group_io(exp, ll_i2info(inode)->lli_smd, NULL, oig);
1903 static void ll_file_put_pages(struct page **pages, int numpages)
1909 for (i = 0, pp = pages; i < numpages; i++, pp++) {
1911 LL_CDEBUG_PAGE(D_PAGE, (*pp), "free\n");
1913 if (page_private(*pp))
1914 CERROR("the llap wasn't freed\n");
1915 (*pp)->mapping = NULL;
1916 if (page_count(*pp) != 1)
1917 CERROR("page %p, flags %#lx, count %i, private %p\n",
1918 (*pp), (unsigned long)(*pp)->flags, page_count(*pp),
1919 (void*)page_private(*pp));
1920 __free_pages(*pp, 0);
1923 OBD_FREE(pages, numpages * sizeof(struct page*));
1927 static struct page **ll_file_prepare_pages(int numpages, struct inode *inode,
1928 unsigned long first)
1930 struct page **pages;
1935 OBD_ALLOC(pages, sizeof(struct page *) * numpages);
1937 RETURN(ERR_PTR(-ENOMEM));
1938 for (i = 0; i < numpages; i++) {
1940 struct ll_async_page *llap;
1942 page = alloc_pages(GFP_HIGHUSER, 0);
1944 GOTO(err, rc = -ENOMEM);
1946 /* llap_from_page needs page index and mapping to be set */
1947 page->index = first++;
1948 page->mapping = inode->i_mapping;
1949 llap = llap_from_page(page, LLAP_ORIGIN_LOCKLESS_IO);
1951 GOTO(err, rc = PTR_ERR(llap));
1952 llap->llap_lockless_io_page = 1;
1956 ll_file_put_pages(pages, numpages);
1957 RETURN(ERR_PTR(rc));
1960 static ssize_t ll_file_copy_pages(struct page **pages, int numpages,
1961 char *buf, loff_t pos, size_t count, int rw)
1965 int updatechecksum = ll_i2sbi(pages[0]->mapping->host)->ll_flags &
1969 for (i = 0; i < numpages; i++) {
1970 unsigned offset, bytes, left;
1973 vaddr = kmap(pages[i]);
1974 offset = pos & (CFS_PAGE_SIZE - 1);
1975 bytes = min_t(unsigned, CFS_PAGE_SIZE - offset, count);
1976 LL_CDEBUG_PAGE(D_PAGE, pages[i], "op = %s, addr = %p, "
1977 "buf = %p, bytes = %u\n",
1978 (rw == WRITE) ? "CFU" : "CTU",
1979 vaddr + offset, buf, bytes);
1981 left = copy_from_user(vaddr + offset, buf, bytes);
1982 if (updatechecksum) {
1983 struct ll_async_page *llap;
1985 llap = llap_cast_private(pages[i]);
1986 llap->llap_checksum = crc32_le(0, vaddr,
1990 left = copy_to_user(buf, vaddr + offset, bytes);
2007 static int ll_file_oig_pages(struct inode * inode, struct page **pages,
2008 int numpages, loff_t pos, size_t count, int rw)
2010 struct obd_io_group *oig;
2011 struct ll_inode_info *lli = ll_i2info(inode);
2012 struct obd_export *exp;
2013 loff_t org_pos = pos;
2019 exp = ll_i2dtexp(inode);
2022 rc = oig_init(&oig);
2025 brw_flags = OBD_BRW_SRVLOCK;
2026 if (capable(CAP_SYS_RESOURCE))
2027 brw_flags |= OBD_BRW_NOQUOTA;
2029 for (i = 0; i < numpages; i++) {
2030 struct ll_async_page *llap;
2031 unsigned from, bytes;
2033 from = pos & (CFS_PAGE_SIZE - 1);
2034 bytes = min_t(unsigned, CFS_PAGE_SIZE - from,
2035 count - pos + org_pos);
2036 llap = llap_cast_private(pages[i]);
2039 lock_page(pages[i]);
2041 LL_CDEBUG_PAGE(D_PAGE, pages[i], "offset "LPU64","
2042 " from %u, bytes = %u\n",
2044 LASSERTF(pos >> CFS_PAGE_SHIFT == pages[i]->index,
2045 "wrong page index %lu (%lu)\n",
2047 (unsigned long)(pos >> CFS_PAGE_SHIFT));
2048 rc = obd_queue_group_io(exp, lli->lli_smd, NULL, oig,
2051 OBD_BRW_WRITE:OBD_BRW_READ,
2052 from, bytes, brw_flags,
2053 ASYNC_READY | ASYNC_URGENT |
2054 ASYNC_COUNT_STABLE | ASYNC_GROUP_SYNC);
2061 rc = obd_trigger_group_io(exp, lli->lli_smd, NULL, oig);
2067 unlock_page(pages[i]);
2072 ssize_t ll_file_lockless_io(struct file *file, char *buf, size_t count,
2073 loff_t *ppos, int rw)
2076 struct inode *inode = file->f_dentry->d_inode;
2080 unsigned long first, last;
2086 ll_inode_size_lock(inode, 0);
2087 isize = i_size_read(inode);
2088 ll_inode_size_unlock(inode, 0);
2091 if (*ppos + count >= isize)
2092 count -= *ppos + count - isize;
2096 rc = generic_write_checks(file, ppos, &count, 0);
2099 rc = remove_suid(file->f_dentry);
2104 first = pos >> CFS_PAGE_SHIFT;
2105 last = (pos + count - 1) >> CFS_PAGE_SHIFT;
2106 max_pages = PTLRPC_MAX_BRW_PAGES *
2107 ll_i2info(inode)->lli_smd->lsm_stripe_count;
2108 CDEBUG(D_INFO, "%u, stripe_count = %u\n",
2109 PTLRPC_MAX_BRW_PAGES /* max_pages_per_rpc */,
2110 ll_i2info(inode)->lli_smd->lsm_stripe_count);
2112 while (first <= last && rc >= 0) {
2114 struct page **pages;
2115 size_t bytes = count - amount;
2117 pages_for_io = min_t(int, last - first + 1, max_pages);
2118 pages = ll_file_prepare_pages(pages_for_io, inode, first);
2119 if (IS_ERR(pages)) {
2120 rc = PTR_ERR(pages);
2124 rc = ll_file_copy_pages(pages, pages_for_io, buf,
2125 pos + amount, bytes, rw);
2127 GOTO(put_pages, rc);
2130 rc = ll_file_oig_pages(inode, pages, pages_for_io,
2131 pos + amount, bytes, rw);
2133 GOTO(put_pages, rc);
2135 rc = ll_file_copy_pages(pages, pages_for_io, buf,
2136 pos + amount, bytes, rw);
2138 GOTO(put_pages, rc);
2144 ll_file_put_pages(pages, pages_for_io);
2145 first += pages_for_io;
2146 /* a short read/write check */
2147 if (pos + amount < ((loff_t)first << CFS_PAGE_SHIFT))
2150 /* NOTE: don't update i_size and KMS in absence of LDLM locks even
2151 * write makes the file large */
2152 file_accessed(file);
2153 if (rw == READ && amount < count && rc == 0) {
2154 unsigned long not_cleared;
2156 not_cleared = clear_user(buf, count - amount);
2157 amount = count - not_cleared;
2162 lprocfs_counter_add(ll_i2sbi(inode)->ll_stats,
2164 LPROC_LL_LOCKLESS_WRITE :
2165 LPROC_LL_LOCKLESS_READ,