/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * cachefs_max_idle is a global that is tunable. * This value decides how frequently or when the * cachefs_cnode_idleclean is run. * The default value is set to CFS_FS_MAXIDLE. * The tunable if set to X triggers a cleanup when * the number of idle cnodes reach X, and cleans up * (.25 * X) idle cnodes. */ int cachefs_max_idle = CFS_FS_MAXIDLE; struct kmem_cache *cachefs_cnode_cache = NULL; /* * Functions for cnode management. */ /* * Puts cnode on idle list. Only call from an async thread or no * locks held. */ /*ARGSUSED1*/ void cachefs_cnode_idle(struct vnode *vp, cred_t *cr) { cnode_t *cp = VTOC(vp); fscache_t *fscp = C_TO_FSCACHE(cp); int cleanidle; vnode_t *unldvp; cred_t *unlcred; char *unlname; int error; /* * The key to this routine is not to drop the vnode count * while on the idle list. This prevents this routine from * being called again by vn_rele on an inactive cnode. * Nothing bad happens if an "active" cnode is put on the idle * list. It eventually gets pulled off. * Also this routine is only called from a thread message sent * by cachefs_inactive(). It is not safe for this routine * to be the "inactive" entry point because of the dnlc. */ for (;;) { /* get access to the file system */ error = cachefs_cd_access(fscp, 0, 1); ASSERT(error == 0); /* get exclusive access to this cnode */ mutex_enter(&cp->c_statelock); /* done with this loop if not unlinking a file */ if (cp->c_unldvp == NULL) break; /* get unlink info out of the cnode */ unldvp = cp->c_unldvp; unlcred = cp->c_unlcred; unlname = cp->c_unlname; cp->c_unldvp = NULL; cp->c_unlcred = NULL; cp->c_unlname = NULL; mutex_exit(&cp->c_statelock); /* finish the remove operation */ if (fscp->fs_cdconnected == CFS_CD_CONNECTED) { error = cachefs_remove_connected(unldvp, unlname, unlcred, vp); } else { error = cachefs_remove_disconnected(unldvp, unlname, unlcred, vp); } /* reacquire cnode lock */ mutex_enter(&cp->c_statelock); /* if a timeout occurred */ if (CFS_TIMEOUT(fscp, error)) { /* restore cnode state */ if (cp->c_unldvp == NULL) { cp->c_unldvp = unldvp; cp->c_unlcred = unlcred; cp->c_unlname = unlname; if (fscp->fs_cdconnected == CFS_CD_CONNECTED) { mutex_exit(&cp->c_statelock); cachefs_cd_release(fscp); cachefs_cd_timedout(fscp); continue; } else { cp->c_flags |= CN_PENDRM; mutex_exit(&cp->c_statelock); goto out; } } } /* free up resources */ VN_RELE(unldvp); cachefs_kmem_free(unlname, MAXNAMELEN); crfree(unlcred); break; } ASSERT((cp->c_flags & CN_IDLE) == 0); /* * If we are going to destroy this cnode, * do it now instead of later. */ if (cp->c_flags & (CN_DESTROY | CN_STALE)) { mutex_exit(&cp->c_statelock); (void) cachefs_cnode_inactive(vp, cr); goto out; } /* * mark cnode as idle, put it on the idle list, and increment the * number of idle cnodes */ cp->c_flags |= CN_IDLE; mutex_enter(&fscp->fs_idlelock); cachefs_cnode_idleadd(cp); if ((fscp->fs_idlecnt > cachefs_max_idle) && (fscp->fs_idleclean == 0) && (fscp->fs_cdtransition == 0)) { fscp->fs_idleclean = 1; cleanidle = 1; } else { cleanidle = 0; } mutex_exit(&fscp->fs_idlelock); /* release cnode */ mutex_exit(&cp->c_statelock); /* if should reduce the number of idle cnodes */ if (cleanidle) { ASSERT(fscp->fs_idlecnt > 1); fscache_hold(fscp); cachefs_cnode_idleclean(fscp, 0); /* XXX race with cachefs_unmount() calling destroy */ fscache_rele(fscp); } out: /* release hold on the file system */ /* XXX unmount() could have called destroy after fscache_rele() */ cachefs_cd_release(fscp); } /* * Removes cnodes from the idle list and destroys them. */ void cachefs_cnode_idleclean(fscache_t *fscp, int unmount) { int remcnt; cnode_t *cp; mutex_enter(&fscp->fs_idlelock); /* determine number of cnodes to destroy */ if (unmount) { /* destroy all plus any that go idle while in this routine */ remcnt = fscp->fs_idlecnt * 2; } else { /* reduce to 75% of max allowed idle cnodes */ remcnt = (fscp->fs_idlecnt - cachefs_max_idle) + (cachefs_max_idle >> 2); } for (; remcnt > 0; remcnt--) { /* get cnode on back of idle list and hold it */ cp = fscp->fs_idleback; if (cp == NULL) break; VN_HOLD(CTOV(cp)); mutex_exit(&fscp->fs_idlelock); /* if the cnode is still on the idle list */ mutex_enter(&cp->c_statelock); if (cp->c_flags & CN_IDLE) { cp->c_flags &= ~CN_IDLE; /* remove cnode from the idle list */ mutex_enter(&fscp->fs_idlelock); cachefs_cnode_idlerem(cp); mutex_exit(&fscp->fs_idlelock); mutex_exit(&cp->c_statelock); /* destroy the cnode */ VN_RELE(CTOV(cp)); (void) cachefs_cnode_inactive(CTOV(cp), kcred); } else { /* cnode went active, just skip it */ mutex_exit(&cp->c_statelock); VN_RELE(CTOV(cp)); } mutex_enter(&fscp->fs_idlelock); } fscp->fs_idleclean = 0; mutex_exit(&fscp->fs_idlelock); } /* * This routine does the real work of inactivating a cachefs vnode. */ int cachefs_cnode_inactive(register struct vnode *vp, cred_t *cr) { cnode_t *cp; struct fscache *fscp; struct filegrp *fgp; cachefscache_t *cachep; struct cachefs_metadata *mdp; int meta_destroyed = 0; cp = VTOC(vp); fscp = C_TO_FSCACHE(cp); cachep = fscp->fs_cache; ASSERT(cachep != NULL); fgp = cp->c_filegrp; ASSERT((cp->c_flags & CN_IDLE) == 0); /* truncate the front file if necessary */ mutex_enter(&cp->c_statelock); if ((cp->c_flags & CN_NOCACHE) && (cp->c_metadata.md_flags & MD_FILE) && cp->c_metadata.md_frontblks) { ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_INVALIDATE) printf("c_cnode_inactive: invalidating %llu\n", (u_longlong_t)cp->c_id.cid_fileno); #endif /* * If the cnode is being populated, and we're not the * populating thread, then block until the pop thread * completes. If we are the pop thread, then we may come in * here, but not to nuke the directory cnode at a critical * juncture. */ while ((cp->c_flags & CN_ASYNC_POP_WORKING) && (cp->c_popthrp != curthread)) cv_wait(&cp->c_popcv, &cp->c_statelock); cachefs_inval_object(cp); } mutex_exit(&cp->c_statelock); for (;;) { /* see if vnode is really inactive */ mutex_enter(&vp->v_lock); ASSERT(vp->v_count > 0); if (vp->v_count > 1) { /* * It's impossible for us to be cnode_inactive for * the root cnode _unless_ we are being called from * cachefs_unmount (where inactive is called * explictly). If the count is not 1, there is * still an outstanding reference to the root cnode, * and we return EBUSY; this allows cachefs_unmount * to fail. */ if (cp->c_flags & CN_ROOT) { mutex_exit(&vp->v_lock); return (EBUSY); } cp->c_ipending = 0; vp->v_count--; /* release our hold from vn_rele */ mutex_exit(&vp->v_lock); return (0); } mutex_exit(&vp->v_lock); /* get rid of any pages, do not care if cannot be pushed */ if (vn_has_cached_data(vp)) { ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); (void) cachefs_putpage_common(vp, (offset_t)0, 0, B_INVAL | B_FORCE, cr); } /* if need to sync metadata, the call is a no op for NFSv4 */ if ((cp->c_flags & (CN_UPDATED | CN_DESTROY)) == CN_UPDATED) { (void) cachefs_sync_metadata(cp); continue; } break; } /* * Lock out possible race with makecachefsnode. * Makecachefsnode will fix up the rl/active list stuff to * be correct when it gets to run. * We have to do the rl/active stuff while the cnode is on the hash * list to sync actions on the rl/active list. */ mutex_enter(&fgp->fg_cnodelock); mutex_enter(&cp->c_statelock); /* see if vnode is still inactive */ mutex_enter(&vp->v_lock); ASSERT(vp->v_count > 0); if (vp->v_count > 1) { cp->c_ipending = 0; vp->v_count--; mutex_exit(&vp->v_lock); mutex_exit(&cp->c_statelock); mutex_exit(&fgp->fg_cnodelock); #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_INVALIDATE) printf("cachefs_cnode_inactive: %u vp %p\n", vp->v_count, vp); #endif return (0); } mutex_exit(&vp->v_lock); /* check for race with remove */ if (cp->c_unldvp) { mutex_exit(&cp->c_statelock); mutex_exit(&fgp->fg_cnodelock); /* this causes cachefs_inactive to be called again */ VN_RELE(vp); return (0); } /* if any pages left, really get rid of them */ if (vn_has_cached_data(vp)) { ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); (void) pvn_vplist_dirty(vp, 0, NULL, B_INVAL | B_TRUNC, cr); } ASSERT(vp->v_count == 1); mdp = &cp->c_metadata; /* if we can (and should) destroy the front file and metadata */ if ((cp->c_flags & (CN_DESTROY | CN_STALE)) && (fgp->fg_flags & CFS_FG_WRITE) && !CFS_ISFS_BACKFS_NFSV4(fscp)) { if (mdp->md_rlno) { cachefs_removefrontfile(mdp, &cp->c_id, fgp); cachefs_rlent_moveto(cachep, CACHEFS_RL_FREE, mdp->md_rlno, 0); mdp->md_rlno = 0; mdp->md_rltype = CACHEFS_RL_NONE; } if ((cp->c_flags & CN_ALLOC_PENDING) == 0) { (void) filegrp_destroy_metadata(fgp, &cp->c_id); meta_destroyed = 1; } } /* else put the front file on the gc list */ else if (mdp->md_rlno && (fgp->fg_flags & CFS_FG_WRITE) && (cp->c_metadata.md_rltype == CACHEFS_RL_ACTIVE)) { #ifdef CFSDEBUG cachefs_rlent_verify(cachep, CACHEFS_RL_ACTIVE, mdp->md_rlno); #endif /* CFSDEBUG */ ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); cachefs_rlent_moveto(cachep, CACHEFS_RL_GC, mdp->md_rlno, mdp->md_frontblks); mdp->md_rltype = CACHEFS_RL_GC; cp->c_flags |= CN_UPDATED; } /* if idlelist pointer(s) not null, remove from idle list */ if ((cp->c_idlefront != NULL) || (cp->c_idleback != NULL)) { mutex_enter(&fscp->fs_idlelock); cachefs_cnode_idlerem(cp); mutex_exit(&fscp->fs_idlelock); } /* remove from the filegrp list prior to releasing the cnode lock */ cachefs_cnode_listrem(cp); mutex_exit(&cp->c_statelock); if (! meta_destroyed) (void) cachefs_sync_metadata(cp); mutex_exit(&fgp->fg_cnodelock); if (cp->c_cred != NULL) { crfree(cp->c_cred); cp->c_cred = NULL; } if (cp->c_frontvp) VN_RELE(cp->c_frontvp); if (cp->c_backvp) VN_RELE(cp->c_backvp); if (cp->c_acldirvp) VN_RELE(cp->c_acldirvp); rw_destroy(&cp->c_rwlock); mutex_destroy(&cp->c_statelock); cv_destroy(&cp->c_popcv); mutex_destroy(&cp->c_iomutex); cv_destroy(&cp->c_iocv); /* free up cnode memory */ vn_invalid(cp->c_vnode); vn_free(cp->c_vnode); kmem_cache_free(cachefs_cnode_cache, cp); filegrp_rele(fgp); (void) fscache_cnodecnt(fscp, -1); return (0); } /* * Add a cnode to the filegrp list. */ void cachefs_cnode_listadd(struct cnode *cp) { filegrp_t *fgp = cp->c_filegrp; ASSERT(MUTEX_HELD(&fgp->fg_cnodelock)); ASSERT(cp->c_next == NULL); cp->c_next = fgp->fg_cnodelist; fgp->fg_cnodelist = cp; } /* * Remove a cnode from the filegrp list. */ void cachefs_cnode_listrem(struct cnode *cp) { filegrp_t *fgp = cp->c_filegrp; struct cnode **headpp; #ifdef CFSDEBUG int found = 0; #endif ASSERT(MUTEX_HELD(&fgp->fg_cnodelock)); ASSERT(cp->c_idleback == NULL); ASSERT(cp->c_idlefront == NULL); for (headpp = &fgp->fg_cnodelist; *headpp != NULL; headpp = &(*headpp)->c_next) { if (*headpp == cp) { *headpp = cp->c_next; cp->c_next = NULL; #ifdef CFSDEBUG found++; #endif break; } } #ifdef CFSDEBUG ASSERT(found); #endif } /* * Add a cnode to the front of the fscache idle list. */ void cachefs_cnode_idleadd(struct cnode *cp) { fscache_t *fscp = C_TO_FSCACHE(cp); ASSERT(MUTEX_HELD(&cp->c_statelock)); ASSERT(MUTEX_HELD(&fscp->fs_idlelock)); /* put cnode on the front of the idle list */ cp->c_idlefront = fscp->fs_idlefront; cp->c_idleback = NULL; if (fscp->fs_idlefront) fscp->fs_idlefront->c_idleback = cp; else { ASSERT(fscp->fs_idleback == NULL); fscp->fs_idleback = cp; } fscp->fs_idlefront = cp; fscp->fs_idlecnt++; } /* * Remove a cnode from the fscache idle list. */ void cachefs_cnode_idlerem(struct cnode *cp) { fscache_t *fscp = C_TO_FSCACHE(cp); ASSERT(MUTEX_HELD(&cp->c_statelock)); ASSERT(MUTEX_HELD(&fscp->fs_idlelock)); if (cp->c_idlefront == NULL) { ASSERT(fscp->fs_idleback == cp); fscp->fs_idleback = cp->c_idleback; if (fscp->fs_idleback != NULL) fscp->fs_idleback->c_idlefront = NULL; } else { cp->c_idlefront->c_idleback = cp->c_idleback; } if (cp->c_idleback == NULL) { ASSERT(fscp->fs_idlefront == cp); fscp->fs_idlefront = cp->c_idlefront; if (fscp->fs_idlefront != NULL) fscp->fs_idlefront->c_idleback = NULL; } else { cp->c_idleback->c_idlefront = cp->c_idlefront; cp->c_idleback = NULL; } cp->c_idlefront = NULL; fscp->fs_idlecnt--; ASSERT(fscp->fs_idlecnt >= 0); } /* * Search the cnode list of the input file group, looking for a cnode which * matches the supplied file ident fileno. * * Returns: * *cpp = NULL, if no valid matching cnode is found * *cpp = address of cnode with matching fileno, with c_statelock held * return status is 0 if no cnode found, or if found & cookies match * return status is 1 if a cnode was found, but the cookies don't match * * Note: must grab the c_statelock for each cnode, or its state could * change while we're processing it. Also, if a cnode is found, must return * with c_statelock still held, so that the cnode state cannot change until * the calling routine releases the lock. */ int cachefs_cnode_find(filegrp_t *fgp, cfs_cid_t *cidp, fid_t *cookiep, struct cnode **cpp, struct vnode *backvp, vattr_t *vap) { struct cnode *cp; int badcookie = 0; uint32_t is_nfsv4; #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) cmn_err(CE_NOTE, "cachefs_cnode_find: fileno %llu fgp %p\n", (u_longlong_t)cidp->cid_fileno, (void *)fgp); #endif ASSERT(MUTEX_HELD(&fgp->fg_cnodelock)); *cpp = NULL; is_nfsv4 = CFS_ISFS_BACKFS_NFSV4(fgp->fg_fscp); /* * Cookie should be filled unless disconnected operation or * backfilesystem is NFSv4 */ if (cookiep == NULL && !CFS_ISFS_SNR(fgp->fg_fscp) && !CFS_ISFS_BACKFS_NFSV4(fgp->fg_fscp)) { goto out; } for (cp = fgp->fg_cnodelist; cp != NULL; cp = cp->c_next) { mutex_enter(&cp->c_statelock); if ((cidp->cid_fileno != cp->c_id.cid_fileno && (is_nfsv4 == FALSE || cp->c_backvp != backvp)) || (cp->c_flags & (CN_STALE | CN_DESTROY))) { mutex_exit(&cp->c_statelock); continue; } /* * Having found a non stale, non destroy pending cnode with * matching fileno, will be exiting the for loop, after * determining return status */ *cpp = cp; if ((cookiep != NULL) && ((cookiep->fid_len != cp->c_cookie.fid_len) || (bcmp((caddr_t)cookiep->fid_data, (caddr_t)&cp->c_cookie.fid_data, cookiep->fid_len)) != 0)) { #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_GENERAL) { cmn_err(CE_NOTE, "cachefs: dup fileno %llu, cp %p\n", (u_longlong_t)cidp->cid_fileno, (void *)cp); } #endif badcookie = 1; } /* * For NFSv4 since there is no fid, add a check to * ensure the backvp and vap matches that in the cnode. * If it doesn't then someone tried to use a stale cnode. */ if (is_nfsv4) { if (backvp && backvp != cp->c_backvp || vap && vap->va_type != cp->c_attr.va_type || cidp->cid_fileno != cp->c_id.cid_fileno) { CFS_DPRINT_BACKFS_NFSV4(C_TO_FSCACHE(cp), ("cachefs_cnode_find (nfsv4): stale cnode " "cnode %p, backvp %p, new-backvp %p, vap %p " "fileno=%llx cp-fileno=%llx\n", cp, cp->c_backvp, backvp, vap, cidp->cid_fileno, cp->c_id.cid_fileno)); badcookie = 1; } } break; } out: #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) cmn_err(CE_NOTE, "cachefs_cnode_find: cp %p\n", (void *)*cpp); #endif return (badcookie); } /* * We have to initialize the cnode contents. Fill in the contents from the * cache (attrcache file), from the info passed in, whatever it takes. */ static int cachefs_cnode_init(cfs_cid_t *cidp, cnode_t *cp, fscache_t *fscp, filegrp_t *fgp, fid_t *cookiep, vattr_t *vap, vnode_t *backvp, int flag, cred_t *cr) { int error = 0; int slotfound; vnode_t *vp; int null_cookie; cachefscache_t *cachep = fscp->fs_cache; bzero(cp, sizeof (cnode_t)); cp->c_vnode = vn_alloc(KM_SLEEP); vp = CTOV(cp); vp->v_data = (caddr_t)cp; rw_init(&cp->c_rwlock, NULL, RW_DEFAULT, NULL); mutex_init(&cp->c_statelock, NULL, MUTEX_DEFAULT, NULL); cv_init(&cp->c_popcv, NULL, CV_DEFAULT, NULL); mutex_init(&cp->c_iomutex, NULL, MUTEX_DEFAULT, NULL); cv_init(&cp->c_iocv, NULL, CV_DEFAULT, NULL); vn_setops(vp, cachefs_getvnodeops()); cp->c_id = *cidp; if (backvp != NULL) { cp->c_backvp = backvp; VN_HOLD(backvp); } cp->c_flags |= flag; filegrp_hold(fgp); cp->c_filegrp = fgp; if (cookiep) cp->c_cookie = *cookiep; mutex_enter(&cp->c_statelock); /* * if nocache is set then ignore anything cached for this file, * if nfsv4 flag is set, then create the cnode but don't do * any caching. */ if (cp->c_flags & CN_NOCACHE || CFS_ISFS_BACKFS_NFSV4(fscp)) { /* * this case only happens while booting without a cache * or if NFSv4 is the backfilesystem */ ASSERT(!CFS_ISFS_SNR(fscp)); ASSERT(fscp->fs_cdconnected == CFS_CD_CONNECTED); if (cookiep || CFS_ISFS_BACKFS_NFSV4(fscp)) { error = CFSOP_INIT_COBJECT(fscp, cp, vap, cr); if (error) goto out; cp->c_flags |= CN_UPDATED | CN_ALLOC_PENDING; ASSERT(cp->c_attr.va_type != 0); VN_SET_VFS_TYPE_DEV(vp, fscp->fs_cfsvfsp, cp->c_attr.va_type, cp->c_attr.va_rdev); cachefs_cnode_setlocalstats(cp); } else error = ESTALE; goto out; } /* * see if there's a slot for this filegrp/cid fileno * if not, and there's no cookie info, nothing can be done, but if * there's cookie data indicate we need to create a metadata slot. */ slotfound = cachefs_cid_inuse(cp->c_filegrp, cidp); if (slotfound == 0) { if (cookiep == NULL) { error = ENOENT; goto out; } cp->c_flags |= CN_ALLOC_PENDING; } else { /* * if a slot was found, then increment the slot in use count * and try to read the metadata. */ cp->c_filegrp->fg_header->ach_count++; error = filegrp_read_metadata(cp->c_filegrp, cidp, &cp->c_metadata); } /* * if there wasn't a slot, or an attempt to read it results in ENOENT, * then init the cache object, create the vnode, etc... */ if ((slotfound == 0) || (error == ENOENT)) { error = CFSOP_INIT_COBJECT(fscp, cp, vap, cr); if (error) goto out; ASSERT(cp->c_attr.va_type != 0); VN_SET_VFS_TYPE_DEV(vp, fscp->fs_cfsvfsp, cp->c_attr.va_type, cp->c_attr.va_rdev); cp->c_metadata.md_rltype = CACHEFS_RL_NONE; } else if (error == 0) { /* slot found, no error occurred on the metadata read */ cp->c_size = cp->c_attr.va_size; if ((cachep->c_flags & CACHE_CHECK_RLTYPE) && (cp->c_metadata.md_rlno != 0) && (cp->c_metadata.md_rltype == CACHEFS_RL_ACTIVE)) { rl_entry_t rl, *rlp; mutex_enter(&cachep->c_contentslock); error = cachefs_rl_entry_get(cachep, cp->c_metadata.md_rlno, &rlp); if (error) { mutex_exit(&cachep->c_contentslock); goto out; } rl = *rlp; mutex_exit(&cachep->c_contentslock); if (cp->c_metadata.md_rltype != rl.rl_current) { cp->c_flags |= CN_UPDATED; cp->c_metadata.md_rltype = rl.rl_current; } } /* * If no cookie is specified, or if this is a local file, * accept the one in the metadata. */ null_cookie = 0; if ((cookiep == NULL) || (cp->c_id.cid_flags & CFS_CID_LOCAL)) { cookiep = &cp->c_metadata.md_cookie; null_cookie = 1; } /* if cookies do not match, reset the metadata */ if ((cookiep->fid_len != cp->c_cookie.fid_len) || (bcmp(&cookiep->fid_data, &cp->c_cookie.fid_data, (size_t)cookiep->fid_len) != 0)) { cp->c_cookie = *cookiep; cp->c_flags |= CN_UPDATED; cp->c_metadata.md_timestamp.tv_sec = 0; /* clear all but the front file bit */ cp->c_metadata.md_flags &= MD_FILE; error = CFSOP_INIT_COBJECT(fscp, cp, vap, cr); ASSERT(cp->c_attr.va_type != 0); VN_SET_VFS_TYPE_DEV(vp, fscp->fs_cfsvfsp, cp->c_attr.va_type, cp->c_attr.va_rdev); } /* else if the consistency type changed, fix it up */ else if (cp->c_metadata.md_consttype != fscp->fs_consttype) { ASSERT(cp->c_attr.va_type != 0); VN_SET_VFS_TYPE_DEV(vp, fscp->fs_cfsvfsp, cp->c_attr.va_type, cp->c_attr.va_rdev); CFSOP_CONVERT_COBJECT(fscp, cp, cr); if (!null_cookie) { error = CFSOP_CHECK_COBJECT(fscp, cp, C_BACK_CHECK, cr); } } /* else check the consistency of the data */ else { ASSERT(cp->c_attr.va_type != 0); VN_SET_VFS_TYPE_DEV(vp, fscp->fs_cfsvfsp, cp->c_attr.va_type, cp->c_attr.va_rdev); if (!null_cookie) { error = CFSOP_CHECK_COBJECT(fscp, cp, 0, cr); } } } else { goto out; } cachefs_cnode_setlocalstats(cp); out: mutex_exit(&cp->c_statelock); if (error) { if (cp->c_frontvp) VN_RELE(cp->c_frontvp); if (cp->c_backvp) VN_RELE(cp->c_backvp); if (cp->c_acldirvp) VN_RELE(cp->c_acldirvp); filegrp_rele(fgp); rw_destroy(&cp->c_rwlock); mutex_destroy(&cp->c_statelock); cv_destroy(&cp->c_popcv); mutex_destroy(&cp->c_iomutex); cv_destroy(&cp->c_iocv); } return (error); } /* * Finds the cnode for the specified fileno and fid. * Creates the cnode if it does not exist. * The cnode is returned held. */ int cachefs_cnode_make(cfs_cid_t *cidp, fscache_t *fscp, fid_t *cookiep, vattr_t *vap, vnode_t *backvp, cred_t *cr, int flag, cnode_t **cpp) { struct cnode *cp; int error; struct filegrp *fgp; struct cachefs_metadata *mdp; fid_t cookie; #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) printf("cachefs_cnode_make: ENTER fileno %llu\n", (u_longlong_t)cidp->cid_fileno); #endif /* get the file group that owns this file */ mutex_enter(&fscp->fs_fslock); fgp = filegrp_list_find(fscp, cidp); if (fgp == NULL) { fgp = filegrp_create(fscp, cidp); filegrp_list_add(fscp, fgp); } filegrp_hold(fgp); mutex_exit(&fscp->fs_fslock); /* grab the cnode list lock */ mutex_enter(&fgp->fg_cnodelock); if ((fgp->fg_flags & CFS_FG_READ) == 0) flag |= CN_NOCACHE; error = 0; cp = NULL; /* look for the cnode on the cnode list */ error = cachefs_cnode_find(fgp, cidp, cookiep, &cp, backvp, vap); /* * If there already is a cnode with this cid but a different cookie, * (or backvp) we're not going to be using the one we found. */ if (error && CFS_ISFS_BACKFS_NFSV4(fscp)) { ASSERT(MUTEX_HELD(&cp->c_statelock)); cachefs_cnode_stale(cp); mutex_exit(&cp->c_statelock); cp = NULL; error = 0; } else if (error) { ASSERT(cp); ASSERT(cookiep); mutex_exit(&cp->c_statelock); /* * If backvp is NULL then someone tried to use * a stale cookie. */ if (backvp == NULL) { mutex_exit(&fgp->fg_cnodelock); error = ESTALE; goto out; } /* verify the backvp */ error = cachefs_getcookie(backvp, &cookie, NULL, cr, TRUE); if (error || ((cookiep->fid_len != cookie.fid_len) || (bcmp(&cookiep->fid_data, cookie.fid_data, (size_t)cookiep->fid_len) != 0))) { mutex_exit(&fgp->fg_cnodelock); error = ESTALE; goto out; } /* make the old cnode give up its front file resources */ VN_HOLD(CTOV(cp)); (void) cachefs_sync_metadata(cp); mutex_enter(&cp->c_statelock); mdp = &cp->c_metadata; if (mdp->md_rlno) { /* XXX sam: should this assert be NOCACHE? */ /* XXX sam: maybe we should handle NOFILL as no-op */ ASSERT((fscp->fs_cache->c_flags & CACHE_NOFILL) == 0); /* if modified in the cache, move to lost+found */ if ((cp->c_attr.va_type == VREG) && (cp->c_metadata.md_rltype == CACHEFS_RL_MODIFIED)) { error = cachefs_cnode_lostfound(cp, NULL); if (error) { mutex_exit(&cp->c_statelock); VN_RELE(CTOV(cp)); mutex_exit(&fgp->fg_cnodelock); error = ESTALE; goto out; } } /* else nuke the front file */ else { cachefs_cnode_stale(cp); } } else { cachefs_cnode_stale(cp); } mutex_exit(&cp->c_statelock); VN_RELE(CTOV(cp)); cp = NULL; error = 0; } /* if the cnode does not exist */ if (cp == NULL) { /* XXX should we drop all locks for this? */ cp = kmem_cache_alloc(cachefs_cnode_cache, KM_SLEEP); error = cachefs_cnode_init(cidp, cp, fscp, fgp, cookiep, vap, backvp, flag, cr); if (error) { mutex_exit(&fgp->fg_cnodelock); vn_free(cp->c_vnode); kmem_cache_free(cachefs_cnode_cache, cp); goto out; } if (cp->c_metadata.md_rlno && (cp->c_metadata.md_rltype == CACHEFS_RL_GC) && ((fscp->fs_cache->c_flags & CACHE_NOFILL) == 0)) { #ifdef CFSDEBUG cachefs_rlent_verify(fscp->fs_cache, CACHEFS_RL_GC, cp->c_metadata.md_rlno); #endif /* CFSDEBUG */ cachefs_rlent_moveto(fscp->fs_cache, CACHEFS_RL_ACTIVE, cp->c_metadata.md_rlno, cp->c_metadata.md_frontblks); cp->c_metadata.md_rltype = CACHEFS_RL_ACTIVE; cp->c_flags |= CN_UPDATED; } cachefs_cnode_listadd(cp); vn_exists(cp->c_vnode); mutex_exit(&fgp->fg_cnodelock); (void) fscache_cnodecnt(fscp, 1); } /* else if the cnode exists */ else { VN_HOLD(CTOV(cp)); /* remove from idle list if on it */ if (cp->c_flags & CN_IDLE) { cp->c_flags &= ~CN_IDLE; mutex_enter(&fscp->fs_idlelock); cachefs_cnode_idlerem(cp); mutex_exit(&fscp->fs_idlelock); VN_RELE(CTOV(cp)); cp->c_ipending = 0; } mutex_exit(&cp->c_statelock); mutex_exit(&fgp->fg_cnodelock); } /* * Assertion to ensure the cnode matches * the backvp and attribute type information. */ ASSERT((CFS_ISFS_BACKFS_NFSV4(fscp) == 0) || ((cp->c_backvp == backvp) && (cp->c_attr.va_type == vap->va_type))); out: *cpp = ((error == 0) ? cp : NULL); filegrp_rele(fgp); #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) printf("cachefs_cnode_make: EXIT cp %p, error %d\n", (void *)*cpp, error); #endif return (error); } /* * cachefs_cid_inuse() * * returns nonzero if a cid has any data in the cache; either a cnode * or metadata. */ int cachefs_cid_inuse(filegrp_t *fgp, cfs_cid_t *cidp) { cnode_t *cp; int status = 0; ASSERT(MUTEX_HELD(&fgp->fg_cnodelock)); /* * Since we don't care about the cookie data, we don't care about any * status that find might return. */ cp = NULL; (void) cachefs_cnode_find(fgp, cidp, NULL, &cp, NULL, NULL); if (cp != NULL) { mutex_exit(&cp->c_statelock); status = 1; return (status); } /* * Don't want to use filegrp_read_metadata, since it will return * ENOENT if the metadata slot exists but hasn't been written to yet. * That condition still counts as the slot (metadata) being in use. * Instead, as long as the filegrp attrcache has been created and * there's a slot assigned for this cid, then the metadata is in use. */ if (((fgp->fg_flags & CFS_FG_ALLOC_ATTR) == 0) && (filegrp_cid_to_slot(fgp, cidp) != 0)) status = 1; return (status); } /* * cachefs_fileno_inuse() * * returns nonzero if a fileno is known to the cache, as either a * local or a normal file. */ int cachefs_fileno_inuse(fscache_t *fscp, ino64_t fileno) { cfs_cid_t cid; filegrp_t *fgp; int known = 0; ASSERT(MUTEX_HELD(&fscp->fs_fslock)); cid.cid_fileno = fileno; /* if there's no filegrp for this cid range, then there's no data */ fgp = filegrp_list_find(fscp, &cid); if (fgp == NULL) return (known); filegrp_hold(fgp); mutex_enter(&fgp->fg_cnodelock); cid.cid_flags = CFS_CID_LOCAL; if (cachefs_cid_inuse(fgp, &cid)) { known = 1; goto out; } cid.cid_flags = 0; if (cachefs_cid_inuse(fgp, &cid)) known = 1; out: mutex_exit(&fgp->fg_cnodelock); filegrp_rele(fgp); return (known); } /* * Creates a cnode from an unused inode in the cache. * The cnode is returned held. */ int cachefs_cnode_create(fscache_t *fscp, vattr_t *vap, int flag, cnode_t **cpp) { struct cnode *cp; int error, found; struct filegrp *fgp; cfs_cid_t cid, cid2; ASSERT(CFS_ISFS_SNR(fscp)); ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); cid.cid_flags = CFS_CID_LOCAL; cid2.cid_flags = 0; /* find an unused local file in the cache */ for (;;) { mutex_enter(&fscp->fs_fslock); /* make sure we did not wrap */ fscp->fs_info.fi_localfileno++; if (fscp->fs_info.fi_localfileno == 0) fscp->fs_info.fi_localfileno = 3; cid.cid_fileno = fscp->fs_info.fi_localfileno; fscp->fs_flags |= CFS_FS_DIRTYINFO; /* avoid fileno conflict in non-local space */ cid2.cid_fileno = cid.cid_fileno; fgp = filegrp_list_find(fscp, &cid2); if (fgp != NULL) { filegrp_hold(fgp); mutex_enter(&fgp->fg_cnodelock); found = cachefs_cid_inuse(fgp, &cid2); mutex_exit(&fgp->fg_cnodelock); filegrp_rele(fgp); if (found) { mutex_exit(&fscp->fs_fslock); continue; } } /* get the file group that owns this fileno */ fgp = filegrp_list_find(fscp, &cid); if (fgp == NULL) { fgp = filegrp_create(fscp, &cid); filegrp_list_add(fscp, fgp); } /* see if there is any room left in this file group */ mutex_enter(&fgp->fg_mutex); if (fgp->fg_header && (fgp->fg_header->ach_count == fscp->fs_info.fi_fgsize)) { /* no more room, set up for the next file group */ fscp->fs_info.fi_localfileno = fgp->fg_id.cid_fileno + fscp->fs_info.fi_fgsize; mutex_exit(&fgp->fg_mutex); mutex_exit(&fscp->fs_fslock); continue; } mutex_exit(&fgp->fg_mutex); filegrp_hold(fgp); mutex_exit(&fscp->fs_fslock); ASSERT((fgp->fg_flags & (CFS_FG_READ | CFS_FG_WRITE)) == (CFS_FG_READ | CFS_FG_WRITE)); /* grab the cnode list lock */ mutex_enter(&fgp->fg_cnodelock); if ((fgp->fg_flags & CFS_FG_READ) == 0) flag |= CN_NOCACHE; /* keep looking if a cnode or metadata exist for this fileno */ if (cachefs_cid_inuse(fgp, &cid)) { mutex_exit(&fgp->fg_cnodelock); filegrp_rele(fgp); #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) cmn_err(CE_NOTE, "cachefs_cnode_create: " "fileno %llu exists.\n", (u_longlong_t)cid.cid_fileno); #endif continue; } break; } vap->va_nodeid = cid.cid_fileno; /* create space for the cnode */ cp = kmem_cache_alloc(cachefs_cnode_cache, KM_SLEEP); /* set up the cnode */ error = cachefs_cnode_init(&cid, cp, fscp, fgp, &cp->c_cookie, vap, NULL, flag, kcred); if (error) { mutex_exit(&fgp->fg_cnodelock); vn_free(cp->c_vnode); kmem_cache_free(cachefs_cnode_cache, cp); goto out; } /* save copy of fileno that is returned to the user */ cp->c_metadata.md_flags |= MD_LOCALFILENO; cp->c_metadata.md_localfileno = cid.cid_fileno; cp->c_flags |= CN_UPDATED; cachefs_cnode_listadd(cp); mutex_exit(&fgp->fg_cnodelock); (void) fscache_cnodecnt(fscp, 1); out: *cpp = ((error == 0) ? cp : NULL); filegrp_rele(fgp); return (error); } /* * Moves the cnode to its new location in the cache. * Before calling this routine other steps must be taken * to ensure that other file system routines that operate * on cnodes do not run. */ void cachefs_cnode_move(cnode_t *cp) { fscache_t *fscp = C_TO_FSCACHE(cp); cfs_cid_t cid; filegrp_t *fgp; filegrp_t *ofgp = cp->c_filegrp; struct cachefs_metadata *mdp; cnode_t *xcp; char oname[CFS_FRONTFILE_NAME_SIZE]; char nname[CFS_FRONTFILE_NAME_SIZE]; int ffnuke = 0; int error; ASSERT(CFS_ISFS_SNR(fscp)); ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); ASSERT(cp->c_id.cid_flags & CFS_CID_LOCAL); ASSERT(cp->c_attr.va_nodeid != 0); /* construct the cid of the new file location */ cid.cid_fileno = cp->c_attr.va_nodeid; cid.cid_flags = 0; /* see if there already is a file occupying our slot */ error = cachefs_cnode_make(&cid, fscp, NULL, NULL, NULL, kcred, 0, &xcp); if (error == 0) { mutex_enter(&xcp->c_statelock); cachefs_cnode_stale(xcp); mutex_exit(&xcp->c_statelock); VN_RELE(CTOV(xcp)); xcp = NULL; error = 0; } /* get the file group that this file is moving to */ mutex_enter(&fscp->fs_fslock); fgp = filegrp_list_find(fscp, &cid); if (fgp == NULL) { fgp = filegrp_create(fscp, &cid); filegrp_list_add(fscp, fgp); } filegrp_hold(fgp); mutex_exit(&fscp->fs_fslock); /* XXX fix to not have to create metadata to hold rl slot */ /* get a metadata slot in the new file group */ if (fgp->fg_flags & CFS_FG_ALLOC_ATTR) { (void) filegrp_allocattr(fgp); } /* XXX can fix create_metadata to call allocattr if necessary? */ error = filegrp_create_metadata(fgp, &cp->c_metadata, &cid); if (error) ffnuke = 1; if ((ffnuke == 0) && filegrp_ffhold(fgp)) ffnuke = 1; /* move the front file to the new file group */ if ((ffnuke == 0) && (cp->c_metadata.md_flags & MD_FILE)) { make_ascii_name(&cp->c_id, oname); make_ascii_name(&cid, nname); error = VOP_RENAME(ofgp->fg_dirvp, oname, fgp->fg_dirvp, nname, kcred, NULL, 0); if (error) { ffnuke = 1; #ifdef CFSDEBUG if (error != ENOSPC) { CFS_DEBUG(CFSDEBUG_CNODE) printf("cachefs: cnode_move " "1: error %d\n", error); } #endif } } /* remove the file from the old file group */ mutex_enter(&ofgp->fg_cnodelock); mutex_enter(&cp->c_statelock); if (cp->c_frontvp) { VN_RELE(cp->c_frontvp); cp->c_frontvp = NULL; } if (cp->c_acldirvp) { VN_RELE(cp->c_acldirvp); cp->c_acldirvp = NULL; } mdp = &cp->c_metadata; if (mdp->md_rlno) { if (ffnuke) { cachefs_removefrontfile(mdp, &cp->c_id, ofgp); cachefs_rlent_moveto(fscp->fs_cache, CACHEFS_RL_FREE, mdp->md_rlno, 0); mdp->md_rlno = 0; mdp->md_rltype = CACHEFS_RL_NONE; } else { filegrp_ffrele(ofgp); } } if (ffnuke) mdp->md_flags &= ~MD_PACKED; if ((cp->c_flags & CN_ALLOC_PENDING) == 0) { (void) filegrp_destroy_metadata(ofgp, &cp->c_id); cp->c_flags |= CN_ALLOC_PENDING; } cachefs_cnode_listrem(cp); cp->c_filegrp = NULL; mutex_exit(&cp->c_statelock); mutex_exit(&ofgp->fg_cnodelock); /* add the cnode to the new file group */ mutex_enter(&fgp->fg_cnodelock); mutex_enter(&cp->c_statelock); cp->c_id = cid; cp->c_filegrp = fgp; cp->c_flags |= CN_UPDATED; mutex_exit(&cp->c_statelock); cachefs_cnode_listadd(cp); if (mdp->md_rlno) cachefs_rl_changefileno(fscp->fs_cache, mdp->md_rlno, cp->c_id.cid_fileno); mutex_exit(&fgp->fg_cnodelock); filegrp_rele(ofgp); } /* * Syncs out the specified cnode. * Only called via cnode_traverse from fscache_sync */ void cachefs_cnode_sync(cnode_t *cp) { vnode_t *vp = CTOV(cp); int error = 0; fscache_t *fscp = C_TO_FSCACHE(cp); int held = 0; if (cp->c_flags & (CN_STALE | CN_DESTROY)) return; if (fscp->fs_backvfsp && fscp->fs_backvfsp->vfs_flag & VFS_RDONLY) return; for (;;) { /* get (or renew) access to the file system */ if (held) { cachefs_cd_release(fscp); held = 0; } /* * Getting file system access for reading is really cheating. * However we are getting called from sync so we do not * want to hang up if the cachefsd is not running. */ error = cachefs_cd_access(fscp, 0, 0); if (error) break; held = 1; /* if a regular file, write out the pages */ if ((vp->v_type == VREG) && vn_has_cached_data(vp)) { ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); error = cachefs_putpage_common(vp, (offset_t)0, 0, 0, kcred); if (CFS_TIMEOUT(fscp, error)) { if (fscp->fs_cdconnected == CFS_CD_CONNECTED) { cachefs_cd_release(fscp); held = 0; cachefs_cd_timedout(fscp); continue; } else { /* cannot push, give up */ break; } } /* clear the cnode error if putpage worked */ if ((error == 0) && cp->c_error) { mutex_enter(&cp->c_statelock); cp->c_error = 0; mutex_exit(&cp->c_statelock); } if (error) break; } /* if connected, sync the backvp */ if ((fscp->fs_cdconnected == CFS_CD_CONNECTED) && cp->c_backvp) { mutex_enter(&cp->c_statelock); if (cp->c_backvp) { error = VOP_FSYNC(cp->c_backvp, FSYNC, kcred, NULL); if (CFS_TIMEOUT(fscp, error)) { mutex_exit(&cp->c_statelock); cachefs_cd_release(fscp); held = 0; cachefs_cd_timedout(fscp); continue; } else if (error && (error != EINTR)) cp->c_error = error; } mutex_exit(&cp->c_statelock); } /* sync the metadata and the front file to the front fs */ (void) cachefs_sync_metadata(cp); break; } if (held) cachefs_cd_release(fscp); } /* * Moves the specified file to the lost+found directory for the * cached file system. * Invalidates cached data and attributes. * Returns 0 or an error if could not perform operation. */ int cachefs_cnode_lostfound(cnode_t *cp, char *rname) { int error = 0; fscache_t *fscp; cachefscache_t *cachep; char oname[CFS_FRONTFILE_NAME_SIZE]; filegrp_t *fgp; char *namep, *strp; char *namebuf = NULL; vnode_t *nvp; int index; int len; fscp = C_TO_FSCACHE(cp); cachep = fscp->fs_cache; ASSERT(MUTEX_HELD(&cp->c_statelock)); ASSERT((cachep->c_flags & (CACHE_NOCACHE|CACHE_NOFILL)) == 0); ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); fgp = cp->c_filegrp; /* set up the file group if necessary */ if (fgp->fg_flags & CFS_FG_ALLOC_ATTR) { error = filegrp_allocattr(fgp); if (error) goto out; } ASSERT(fgp->fg_dirvp); namebuf = cachefs_kmem_alloc(MAXNAMELEN * 2, KM_SLEEP); if ((cp->c_attr.va_type != VREG) || (cp->c_metadata.md_rltype != CACHEFS_RL_MODIFIED) || ((cp->c_metadata.md_flags & MD_POPULATED) == 0) || ((cp->c_metadata.md_flags & MD_FILE) == 0) || (cp->c_metadata.md_rlno == 0)) { #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_CNODE) printf("cachefs_cnode_lostfound cp %p cannot save\n", (void *)cp); #endif error = EINVAL; goto out; } /* lock out other users of the lost+found directory */ mutex_enter(&cachep->c_contentslock); /* find a name we can use in lost+found */ if (rname) namep = rname; else namep = "lostfile"; error = VOP_LOOKUP(cachep->c_lostfoundvp, namep, &nvp, NULL, 0, NULL, kcred, NULL, NULL, NULL); if (error == 0) VN_RELE(nvp); if (error != ENOENT) { #define MAXTRIES 1000 strp = namep; for (index = 0; index < MAXTRIES; index++) { (void) sprintf(namebuf, "%s.%" PRIx64, strp, gethrestime_sec() * cp->c_id.cid_fileno * index); len = (int)strlen(namebuf) + 1; if (len > MAXNAMELEN) namep = &namebuf[len - MAXNAMELEN]; else namep = namebuf; error = VOP_LOOKUP(cachep->c_lostfoundvp, namep, &nvp, NULL, 0, NULL, kcred, NULL, NULL, NULL); if (error == 0) VN_RELE(nvp); if (error == ENOENT) break; } if (index == MAXTRIES) { error = EIO; mutex_exit(&cachep->c_contentslock); goto out; } } /* get the name of the front file */ make_ascii_name(&cp->c_id, oname); /* rename the file into the lost+found directory */ error = VOP_RENAME(fgp->fg_dirvp, oname, cachep->c_lostfoundvp, namep, kcred, NULL, 0); if (error) { mutex_exit(&cachep->c_contentslock); goto out; } mutex_exit(&cachep->c_contentslock); /* copy out the new name */ if (rname) (void) strcpy(rname, namep); out: /* clean up */ cachefs_cnode_stale(cp); if (namebuf) cachefs_kmem_free(namebuf, MAXNAMELEN * 2); #if 0 /* XXX until we can put filesystem in read-only mode */ if (error) { /* XXX put file system in read-only mode */ } #endif return (error); } /* * Traverses the list of cnodes on the fscache and calls the * specified routine with the held cnode. */ void cachefs_cnode_traverse(fscache_t *fscp, void (*routinep)(cnode_t *)) { filegrp_t *fgp, *ofgp; cnode_t *cp, *ocp; int index; /* lock the fscache while we traverse the file groups */ mutex_enter(&fscp->fs_fslock); /* for each bucket of file groups */ for (index = 0; index < CFS_FS_FGP_BUCKET_SIZE; index++) { ofgp = NULL; /* for each file group in a bucket */ for (fgp = fscp->fs_filegrp[index]; fgp != NULL; fgp = fgp->fg_next) { /* hold the file group */ filegrp_hold(fgp); /* drop fscache lock so others can use it */ mutex_exit(&fscp->fs_fslock); /* drop hold on previous file group */ if (ofgp) filegrp_rele(ofgp); ofgp = fgp; /* lock the cnode list while we traverse it */ mutex_enter(&fgp->fg_cnodelock); ocp = NULL; /* for each cnode in this file group */ for (cp = fgp->fg_cnodelist; cp != NULL; cp = cp->c_next) { /* hold the cnode */ VN_HOLD(CTOV(cp)); /* drop cnode list lock so others can use it */ mutex_exit(&fgp->fg_cnodelock); /* drop hold on previous cnode */ if (ocp) { VN_RELE(CTOV(ocp)); } ocp = cp; /* * Execute routine for this cnode. * At this point no locks are held. */ (routinep)(cp); /* reacquire the cnode list lock */ mutex_enter(&fgp->fg_cnodelock); } /* drop cnode list lock */ mutex_exit(&fgp->fg_cnodelock); /* drop hold on last cnode */ if (ocp) { VN_RELE(CTOV(ocp)); } /* reacquire the fscache lock */ mutex_enter(&fscp->fs_fslock); } /* drop hold on last file group */ if (ofgp) filegrp_rele(ofgp); } mutex_exit(&fscp->fs_fslock); } void cachefs_cnode_disable_caching(struct cnode *cp) { mutex_enter(&cp->c_statelock); cp->c_flags |= CN_NOCACHE; if (cp->c_frontvp != NULL) { VN_RELE(cp->c_frontvp); cp->c_frontvp = NULL; } mutex_exit(&cp->c_statelock); } #define TIMEMATCH(a, b) ((a)->tv_sec == (b)->tv_sec && \ (a)->tv_nsec == (b)->tv_nsec) static void cnode_enable_caching(struct cnode *cp) { struct vnode *iovp; struct filegrp *fgp; struct cachefs_metadata md; cachefscache_t *cachep = C_TO_FSCACHE(cp)->fs_cache; int error; ASSERT((cachep->c_flags & (CACHE_NOFILL | CACHE_NOCACHE)) == 0); ASSERT(CFS_ISFS_BACKFS_NFSV4(C_TO_FSCACHE(cp)) == 0); iovp = NULL; if (CTOV(cp)->v_type == VREG) iovp = cp->c_backvp; if (iovp) { (void) VOP_PUTPAGE(iovp, (offset_t)0, (uint_t)0, B_INVAL, kcred, NULL); } mutex_enter(&cp->c_statelock); if (cp->c_backvp) { VN_RELE(cp->c_backvp); cp->c_backvp = NULL; } fgp = cp->c_filegrp; ASSERT(fgp); error = filegrp_read_metadata(fgp, &cp->c_id, &md); if (error == 0) { if ((cachep->c_flags & CACHE_CHECK_RLTYPE) && (md.md_rlno != 0) && (md.md_rltype == CACHEFS_RL_ACTIVE)) { rl_entry_t *rlp, rl; mutex_enter(&cachep->c_contentslock); error = cachefs_rl_entry_get(cachep, md.md_rlno, &rlp); if (error) { mutex_exit(&cachep->c_contentslock); goto out; } rl = *rlp; mutex_exit(&cachep->c_contentslock); if (rl.rl_current != md.md_rltype) { md.md_rltype = rl.rl_current; cp->c_flags |= CN_UPDATED; } } /* * A rudimentary consistency check * here. If the cookie and mtime * from the cnode match those from the * cache metadata, we assume for now that * the cached data is OK. */ if (bcmp(&md.md_cookie.fid_data, &cp->c_cookie.fid_data, (size_t)cp->c_cookie.fid_len) == 0 && TIMEMATCH(&cp->c_attr.va_mtime, &md.md_vattr.va_mtime)) { cp->c_metadata = md; } else { /* * Here we're skeptical about the validity of * the front file. * We'll keep the attributes already present in * the cnode, and bring along the parts of the * metadata that we need to eventually nuke this * bogus front file -- in inactive or getfrontfile, * whichever comes first... */ if (cp->c_frontvp != NULL) { VN_RELE(cp->c_frontvp); cp->c_frontvp = NULL; } cp->c_metadata.md_flags = md.md_flags; cp->c_metadata.md_flags |= MD_NEEDATTRS; cp->c_metadata.md_rlno = md.md_rlno; cp->c_metadata.md_rltype = md.md_rltype; cp->c_metadata.md_consttype = md.md_consttype; cp->c_metadata.md_fid = md.md_fid; cp->c_metadata.md_frontblks = md.md_frontblks; cp->c_metadata.md_timestamp.tv_sec = 0; cp->c_metadata.md_timestamp.tv_nsec = 0; bzero(&cp->c_metadata.md_allocinfo, cp->c_metadata.md_allocents * sizeof (struct cachefs_allocmap)); cp->c_metadata.md_allocents = 0; cp->c_metadata.md_flags &= ~MD_POPULATED; if ((cp->c_metadata.md_rlno != 0) && (cp->c_metadata.md_rltype == CACHEFS_RL_PACKED)) { cachefs_rlent_moveto(cachep, CACHEFS_RL_PACKED_PENDING, cp->c_metadata.md_rlno, cp->c_metadata.md_frontblks); cp->c_metadata.md_rltype = CACHEFS_RL_PACKED_PENDING; } cp->c_flags |= CN_UPDATED; #ifdef CFSDEBUG CFS_DEBUG(CFSDEBUG_GENERAL) { printf( "fileno %lld ignores cached data due " "to cookie and/or mtime mismatch\n", (longlong_t)cp->c_id.cid_fileno); } #endif } if (cp->c_metadata.md_rltype == CACHEFS_RL_GC) { cachefs_rlent_moveto(cachep, CACHEFS_RL_ACTIVE, cp->c_metadata.md_rlno, cp->c_metadata.md_frontblks); cp->c_metadata.md_rltype = CACHEFS_RL_ACTIVE; cp->c_flags |= CN_UPDATED; } } out: cp->c_flags &= ~CN_NOCACHE; mutex_exit(&cp->c_statelock); (void) cachefs_pack_common(CTOV(cp), kcred); } void cachefs_enable_caching(struct fscache *fscp) { /* * This function is only called when a remount occurs, * with "nocache" and "nofill" options configured * (currently these aren't supported). Since this * function can write into the cache, make sure that * its not in use with NFSv4. */ if (CFS_ISFS_BACKFS_NFSV4(fscp)) return; /* * set up file groups so we can read them. Note that general * users (makecfsnode) will *not* start using them (i.e., all * newly created cnodes will be NOCACHE) * until we "enable_caching_rw" below. */ mutex_enter(&fscp->fs_fslock); filegrp_list_enable_caching_ro(fscp); mutex_exit(&fscp->fs_fslock); cachefs_cnode_traverse(fscp, cnode_enable_caching); /* enable general use of the filegrps */ mutex_enter(&fscp->fs_fslock); filegrp_list_enable_caching_rw(fscp); mutex_exit(&fscp->fs_fslock); } /* * This function makes a cnode stale by performing the following tasks: * 1) remove the front file * 2) Remove any resource file entries * 3) Remove any metadata entry from the attrcache file * 4) Set the stale bit in the cnode flags field */ void cachefs_cnode_stale(cnode_t *cp) { fscache_t *fscp = C_TO_FSCACHE(cp); struct cachefs_metadata *mdp; ASSERT(MUTEX_HELD(&cp->c_statelock)); /* * Remove a metadata entry if the file exists */ mdp = &cp->c_metadata; if (mdp->md_rlno) { ASSERT(CFS_ISFS_BACKFS_NFSV4(fscp) == 0); /* * destroy the frontfile */ cachefs_removefrontfile(mdp, &cp->c_id, cp->c_filegrp); /* * Remove resource file entry */ cachefs_rlent_moveto(fscp->fs_cache, CACHEFS_RL_FREE, mdp->md_rlno, 0); mdp->md_rlno = 0; mdp->md_rltype = CACHEFS_RL_NONE; } /* * Remove attrcache metadata */ if (CFS_ISFS_BACKFS_NFSV4(fscp) == 0) (void) filegrp_destroy_metadata(cp->c_filegrp, &cp->c_id); mdp->md_flags = 0; if (cp->c_frontvp) { VN_RELE(cp->c_frontvp); cp->c_frontvp = NULL; } /* * For NFSv4 need to hang on to the backvp until vn_rele() * frees this cnode. */ if (cp->c_backvp && !CFS_ISFS_BACKFS_NFSV4(fscp)) { VN_RELE(cp->c_backvp); cp->c_backvp = NULL; } if (cp->c_acldirvp) { VN_RELE(cp->c_acldirvp); cp->c_acldirvp = NULL; } cp->c_flags |= CN_STALE | CN_ALLOC_PENDING | CN_NOCACHE; } /* * Sets up the local attributes in the metadata from the attributes. */ void cachefs_cnode_setlocalstats(cnode_t *cp) { fscache_t *fscp = C_TO_FSCACHE(cp); cachefs_metadata_t *mdp = &cp->c_metadata; ASSERT(MUTEX_HELD(&cp->c_statelock)); /* allow over writing of local attributes if a remount occurred */ if (fscp->fs_info.fi_resettimes != mdp->md_resettimes) { mdp->md_flags &= ~(MD_LOCALCTIME | MD_LOCALMTIME); mdp->md_resettimes = fscp->fs_info.fi_resettimes; } if (fscp->fs_info.fi_resetfileno != mdp->md_resetfileno) { mdp->md_flags &= ~MD_LOCALFILENO; mdp->md_resetfileno = fscp->fs_info.fi_resetfileno; } /* overwrite old fileno and timestamps if not local versions */ if ((mdp->md_flags & MD_LOCALFILENO) == 0) mdp->md_localfileno = mdp->md_vattr.va_nodeid; if ((mdp->md_flags & MD_LOCALCTIME) == 0) mdp->md_localctime = mdp->md_vattr.va_ctime; if ((mdp->md_flags & MD_LOCALMTIME) == 0) mdp->md_localmtime = mdp->md_vattr.va_mtime; cp->c_flags |= CN_UPDATED; }