/* * SPDX-License-Identifier: BSD-3-Clause * * Copyright (c) 2022 Tomohiro Kusumi * Copyright (c) 2011-2022 The DragonFly Project. All rights reserved. * * This code is derived from software contributed to The DragonFly Project * by Matthew Dillon * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name of The DragonFly Project nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific, prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* #include #include #include #include #include #include #include #include #include #include #include #include #include #include */ #include "hammer2.h" TAILQ_HEAD(hammer2_mntlist, hammer2_dev); static struct hammer2_mntlist hammer2_mntlist; struct hammer2_pfslist hammer2_pfslist; struct hammer2_pfslist hammer2_spmplist; struct lock hammer2_mntlk; int hammer2_supported_version = HAMMER2_VOL_VERSION_DEFAULT; int hammer2_debug; int hammer2_aux_flags; int hammer2_xop_nthreads; int hammer2_xop_sgroups; int hammer2_xop_xgroups; int hammer2_xop_xbase; int hammer2_xop_mod; long hammer2_debug_inode; int hammer2_cluster_meta_read = 1; /* physical read-ahead */ int hammer2_cluster_data_read = 4; /* physical read-ahead */ int hammer2_cluster_write = 0; /* physical write clustering */ int hammer2_dedup_enable = 1; int hammer2_always_compress = 0; /* always try to compress */ int hammer2_flush_pipe = 100; int hammer2_dio_count; int hammer2_dio_limit = 256; int hammer2_bulkfree_tps = 5000; int hammer2_spread_workers; int hammer2_limit_saved_depth; long hammer2_chain_allocs; long hammer2_limit_saved_chains; long hammer2_limit_dirty_chains; long hammer2_limit_dirty_inodes; long hammer2_count_modified_chains; long hammer2_iod_file_read; long hammer2_iod_meta_read; long hammer2_iod_indr_read; long hammer2_iod_fmap_read; long hammer2_iod_volu_read; long hammer2_iod_file_write; long hammer2_iod_file_wembed; long hammer2_iod_file_wzero; long hammer2_iod_file_wdedup; long hammer2_iod_meta_write; long hammer2_iod_indr_write; long hammer2_iod_fmap_write; long hammer2_iod_volu_write; static long hammer2_iod_inode_creates; static long hammer2_iod_inode_deletes; long hammer2_process_icrc32; long hammer2_process_xxhash64; int hz; int ticks; int64_t vnode_count; MALLOC_DECLARE(M_HAMMER2_CBUFFER); MALLOC_DEFINE(M_HAMMER2_CBUFFER, "HAMMER2-compbuffer", "Buffer used for compression."); MALLOC_DECLARE(M_HAMMER2_DEBUFFER); MALLOC_DEFINE(M_HAMMER2_DEBUFFER, "HAMMER2-decompbuffer", "Buffer used for decompression."); SYSCTL_NODE(_vfs, OID_AUTO, hammer2, CTLFLAG_RW, 0, "HAMMER2 filesystem"); SYSCTL_INT(_vfs_hammer2, OID_AUTO, supported_version, CTLFLAG_RD, &hammer2_supported_version, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, aux_flags, CTLFLAG_RW, &hammer2_aux_flags, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, debug, CTLFLAG_RW, &hammer2_debug, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, debug_inode, CTLFLAG_RW, &hammer2_debug_inode, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, spread_workers, CTLFLAG_RW, &hammer2_spread_workers, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, cluster_meta_read, CTLFLAG_RW, &hammer2_cluster_meta_read, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, cluster_data_read, CTLFLAG_RW, &hammer2_cluster_data_read, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, cluster_write, CTLFLAG_RW, &hammer2_cluster_write, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, dedup_enable, CTLFLAG_RW, &hammer2_dedup_enable, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, always_compress, CTLFLAG_RW, &hammer2_always_compress, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, flush_pipe, CTLFLAG_RW, &hammer2_flush_pipe, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, bulkfree_tps, CTLFLAG_RW, &hammer2_bulkfree_tps, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, chain_allocs, CTLFLAG_RW, &hammer2_chain_allocs, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, limit_saved_chains, CTLFLAG_RW, &hammer2_limit_saved_chains, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, limit_saved_depth, CTLFLAG_RW, &hammer2_limit_saved_depth, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, limit_dirty_chains, CTLFLAG_RW, &hammer2_limit_dirty_chains, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, limit_dirty_inodes, CTLFLAG_RW, &hammer2_limit_dirty_inodes, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, count_modified_chains, CTLFLAG_RW, &hammer2_count_modified_chains, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, dio_count, CTLFLAG_RD, &hammer2_dio_count, 0, ""); SYSCTL_INT(_vfs_hammer2, OID_AUTO, dio_limit, CTLFLAG_RW, &hammer2_dio_limit, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_file_read, CTLFLAG_RW, &hammer2_iod_file_read, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_meta_read, CTLFLAG_RW, &hammer2_iod_meta_read, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_indr_read, CTLFLAG_RW, &hammer2_iod_indr_read, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_fmap_read, CTLFLAG_RW, &hammer2_iod_fmap_read, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_volu_read, CTLFLAG_RW, &hammer2_iod_volu_read, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_file_write, CTLFLAG_RW, &hammer2_iod_file_write, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_file_wembed, CTLFLAG_RW, &hammer2_iod_file_wembed, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_file_wzero, CTLFLAG_RW, &hammer2_iod_file_wzero, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_file_wdedup, CTLFLAG_RW, &hammer2_iod_file_wdedup, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_meta_write, CTLFLAG_RW, &hammer2_iod_meta_write, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_indr_write, CTLFLAG_RW, &hammer2_iod_indr_write, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_fmap_write, CTLFLAG_RW, &hammer2_iod_fmap_write, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_volu_write, CTLFLAG_RW, &hammer2_iod_volu_write, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_inode_creates, CTLFLAG_RW, &hammer2_iod_inode_creates, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, iod_inode_deletes, CTLFLAG_RW, &hammer2_iod_inode_deletes, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, process_icrc32, CTLFLAG_RW, &hammer2_process_icrc32, 0, ""); SYSCTL_LONG(_vfs_hammer2, OID_AUTO, process_xxhash64, CTLFLAG_RW, &hammer2_process_xxhash64, 0, ""); /* static int hammer2_vfs_init(struct vfsconf *conf); static int hammer2_vfs_uninit(struct vfsconf *vfsp); static int hammer2_vfs_mount(struct mount *mp, char *path, caddr_t data, struct ucred *cred); static int hammer2_remount(hammer2_dev_t *, struct mount *, char *, struct ucred *); */ static int hammer2_recovery(hammer2_dev_t *hmp); /* static int hammer2_vfs_unmount(struct mount *mp, int mntflags); static int hammer2_vfs_root(struct mount *mp, struct vnode **vpp); */ static int hammer2_vfs_statfs(struct mount *mp, struct statfs *sbp, struct ucred *cred); static int hammer2_vfs_statvfs(struct mount *mp, struct statvfs *sbp, struct ucred *cred); /* static int hammer2_vfs_fhtovp(struct mount *mp, struct vnode *rootvp, struct fid *fhp, struct vnode **vpp); static int hammer2_vfs_vptofh(struct vnode *vp, struct fid *fhp); static int hammer2_vfs_checkexp(struct mount *mp, struct sockaddr *nam, int *exflagsp, struct ucred **credanonp); static int hammer2_vfs_modifying(struct mount *mp); */ static void hammer2_update_pmps(hammer2_dev_t *hmp); static void hammer2_mount_helper(struct mount *mp, hammer2_pfs_t *pmp); static void hammer2_unmount_helper(struct mount *mp, hammer2_pfs_t *pmp, hammer2_dev_t *hmp); static int hammer2_fixup_pfses(hammer2_dev_t *hmp); /* * HAMMER2 vfs operations. */ /* static struct vfsops hammer2_vfsops = { .vfs_flags = 0, .vfs_init = hammer2_vfs_init, .vfs_uninit = hammer2_vfs_uninit, .vfs_sync = hammer2_vfs_sync, .vfs_mount = hammer2_vfs_mount, .vfs_unmount = hammer2_vfs_unmount, .vfs_root = hammer2_vfs_root, .vfs_statfs = hammer2_vfs_statfs, .vfs_statvfs = hammer2_vfs_statvfs, .vfs_vget = hammer2_vfs_vget, .vfs_vptofh = hammer2_vfs_vptofh, .vfs_fhtovp = hammer2_vfs_fhtovp, .vfs_checkexp = hammer2_vfs_checkexp, .vfs_modifying = hammer2_vfs_modifying }; */ MALLOC_DEFINE(M_HAMMER2, "HAMMER2-mount", ""); VFS_SET(hammer2_vfsops, hammer2, VFCF_MPSAFE); MODULE_VERSION(hammer2, 1); int hammer2_vfs_init(void) { /* static struct objcache_malloc_args margs_read; static struct objcache_malloc_args margs_write; static struct objcache_malloc_args margs_vop; */ int error; int mod; error = 0; kmalloc_raise_limit(M_HAMMER2, 0); /* unlimited */ /* * hammer2_xop_nthreads must be a multiple of ncpus, * minimum 2 * ncpus. */ const int ncpus = 1; mod = ncpus; hammer2_xop_mod = mod; hammer2_xop_nthreads = mod * 2; /* while (hammer2_xop_nthreads / mod < HAMMER2_XOPGROUPS_MIN || hammer2_xop_nthreads < HAMMER2_XOPTHREADS_MIN) { hammer2_xop_nthreads += mod; } hammer2_xop_sgroups = hammer2_xop_nthreads / mod / 2; hammer2_xop_xgroups = hammer2_xop_nthreads / mod - hammer2_xop_sgroups; hammer2_xop_xbase = hammer2_xop_sgroups * mod; */ /* * A large DIO cache is needed to retain dedup enablement masks. * The bulkfree code clears related masks as part of the disk block * recycling algorithm, preventing it from being used for a later * dedup. * * NOTE: A large buffer cache can actually interfere with dedup * operation because we dedup based on media physical buffers * and not logical buffers. Try to make the DIO case large * enough to avoid this problem, but also cap it. */ const long nbuf = 100000; /* XXX */ hammer2_dio_limit = nbuf * 2; if (hammer2_dio_limit > 100000) hammer2_dio_limit = 100000; if (HAMMER2_BLOCKREF_BYTES != sizeof(struct hammer2_blockref)) error = EINVAL; if (HAMMER2_INODE_BYTES != sizeof(struct hammer2_inode_data)) error = EINVAL; if (HAMMER2_VOLUME_BYTES != sizeof(struct hammer2_volume_data)) error = EINVAL; if (error) { kprintf("HAMMER2 structure size mismatch; cannot continue.\n"); return (error); } #if 0 margs_read.objsize = 65536; margs_read.mtype = M_HAMMER2_DEBUFFER; margs_write.objsize = 32768; margs_write.mtype = M_HAMMER2_CBUFFER; margs_vop.objsize = sizeof(hammer2_xop_t); margs_vop.mtype = M_HAMMER2; /* * Note thaht for the XOPS cache we want backing store allocations * to use M_ZERO. This is not allowed in objcache_get() (to avoid * confusion), so use the backing store function that does it. This * means that initial XOPS objects are zerod but REUSED objects are * not. So we are responsible for cleaning the object up sufficiently * for our needs before objcache_put()ing it back (typically just the * FIFO indices). */ cache_buffer_read = objcache_create(margs_read.mtype->ks_shortdesc, 0, 1, NULL, NULL, NULL, objcache_malloc_alloc, objcache_malloc_free, &margs_read); cache_buffer_write = objcache_create(margs_write.mtype->ks_shortdesc, 0, 1, NULL, NULL, NULL, objcache_malloc_alloc, objcache_malloc_free, &margs_write); cache_xops = objcache_create(margs_vop.mtype->ks_shortdesc, 0, 1, NULL, NULL, NULL, objcache_malloc_alloc_zero, objcache_malloc_free, &margs_vop); #endif lockinit(&hammer2_mntlk, "mntlk", 0, 0); TAILQ_INIT(&hammer2_mntlist); TAILQ_INIT(&hammer2_pfslist); TAILQ_INIT(&hammer2_spmplist); const int maxvnodes = 100000; /* XXX */ hammer2_limit_dirty_chains = maxvnodes / 10; if (hammer2_limit_dirty_chains > HAMMER2_LIMIT_DIRTY_CHAINS) hammer2_limit_dirty_chains = HAMMER2_LIMIT_DIRTY_CHAINS; if (hammer2_limit_dirty_chains < 1000) hammer2_limit_dirty_chains = 1000; hammer2_limit_dirty_inodes = maxvnodes / 25; if (hammer2_limit_dirty_inodes < 100) hammer2_limit_dirty_inodes = 100; if (hammer2_limit_dirty_inodes > HAMMER2_LIMIT_DIRTY_INODES) hammer2_limit_dirty_inodes = HAMMER2_LIMIT_DIRTY_INODES; hammer2_limit_saved_chains = hammer2_limit_dirty_chains * 5; return (error); } int hammer2_vfs_uninit(void) { /* objcache_destroy(cache_buffer_read); objcache_destroy(cache_buffer_write); objcache_destroy(cache_xops); */ return 0; } /* * Core PFS allocator. Used to allocate or reference the pmp structure * for PFS cluster mounts and the spmp structure for media (hmp) structures. * The pmp can be passed in or loaded by this function using the chain and * inode data. * * pmp->modify_tid tracks new modify_tid transaction ids for front-end * transactions. Note that synchronization does not use this field. * (typically frontend operations and synchronization cannot run on the * same PFS node at the same time). * * XXX check locking */ hammer2_pfs_t * hammer2_pfsalloc(hammer2_chain_t *chain, const hammer2_inode_data_t *ripdata, hammer2_dev_t *force_local) { hammer2_pfs_t *pmp; hammer2_inode_t *iroot; int count; int i; int j; pmp = NULL; /* * Locate or create the PFS based on the cluster id. If ripdata * is NULL this is a spmp which is unique and is always allocated. * * If the device is mounted in local mode all PFSs are considered * independent and not part of any cluster (for debugging only). */ if (ripdata) { TAILQ_FOREACH(pmp, &hammer2_pfslist, mntentry) { if (force_local != pmp->force_local) continue; if (force_local == NULL && bcmp(&pmp->pfs_clid, &ripdata->meta.pfs_clid, sizeof(pmp->pfs_clid)) == 0) { break; } else if (force_local && pmp->pfs_names[0] && strcmp(pmp->pfs_names[0], ripdata->filename) == 0) { break; } } } if (pmp == NULL) { pmp = kmalloc(sizeof(*pmp), M_HAMMER2, M_WAITOK | M_ZERO); pmp->force_local = force_local; hammer2_trans_manage_init(pmp); kmalloc_create_obj(&pmp->minode, "HAMMER2-inodes", sizeof(struct hammer2_inode)); lockinit(&pmp->lock, "pfslk", 0, 0); hammer2_spin_init(&pmp->inum_spin, "hm2pfsalloc_inum"); hammer2_spin_init(&pmp->xop_spin, "h2xop"); hammer2_spin_init(&pmp->lru_spin, "h2lru"); RB_INIT(&pmp->inum_tree); TAILQ_INIT(&pmp->syncq); TAILQ_INIT(&pmp->depq); TAILQ_INIT(&pmp->lru_list); hammer2_spin_init(&pmp->list_spin, "h2pfsalloc_list"); /* * Save the last media transaction id for the flusher. Set * initial */ if (ripdata) { pmp->pfs_clid = ripdata->meta.pfs_clid; TAILQ_INSERT_TAIL(&hammer2_pfslist, pmp, mntentry); } else { pmp->flags |= HAMMER2_PMPF_SPMP; TAILQ_INSERT_TAIL(&hammer2_spmplist, pmp, mntentry); } /* * The synchronization thread may start too early, make * sure it stays frozen until we are ready to let it go. * XXX */ /* pmp->primary_thr.flags = HAMMER2_THREAD_FROZEN | HAMMER2_THREAD_REMASTER; */ } /* * Create the PFS's root inode and any missing XOP helper threads. */ if ((iroot = pmp->iroot) == NULL) { iroot = hammer2_inode_get(pmp, NULL, 1, -1); if (ripdata) iroot->meta = ripdata->meta; pmp->iroot = iroot; hammer2_inode_ref(iroot); hammer2_inode_unlock(iroot); } /* * Stop here if no chain is passed in. */ if (chain == NULL) goto done; /* * When a chain is passed in we must add it to the PFS's root * inode, update pmp->pfs_types[], and update the syncronization * threads. * * When forcing local mode, mark the PFS as a MASTER regardless. * * At the moment empty spots can develop due to removals or failures. * Ultimately we want to re-fill these spots but doing so might * confused running code. XXX */ hammer2_inode_ref(iroot); hammer2_mtx_ex(&iroot->lock); j = iroot->cluster.nchains; if (j == HAMMER2_MAXCLUSTER) { kprintf("hammer2_pfsalloc: cluster full!\n"); /* XXX fatal error? */ } else { KKASSERT(chain->pmp == NULL); chain->pmp = pmp; hammer2_chain_ref(chain); iroot->cluster.array[j].chain = chain; if (force_local) pmp->pfs_types[j] = HAMMER2_PFSTYPE_MASTER; else pmp->pfs_types[j] = ripdata->meta.pfs_type; pmp->pfs_names[j] = kstrdup(ripdata->filename, M_HAMMER2); pmp->pfs_hmps[j] = chain->hmp; hammer2_spin_ex(&pmp->inum_spin); pmp->pfs_iroot_blocksets[j] = chain->data->ipdata.u.blockset; hammer2_spin_unex(&pmp->inum_spin); /* * If the PFS is already mounted we must account * for the mount_count here. */ if (pmp->mp) ++chain->hmp->mount_count; /* * May have to fixup dirty chain tracking. Previous * pmp was NULL so nothing to undo. */ if (chain->flags & HAMMER2_CHAIN_MODIFIED) hammer2_pfs_memory_inc(pmp); ++j; } iroot->cluster.nchains = j; /* * Update nmasters from any PFS inode which is part of the cluster. * It is possible that this will result in a value which is too * high. MASTER PFSs are authoritative for pfs_nmasters and will * override this value later on. * * (This informs us of masters that might not currently be * discoverable by this mount). */ if (ripdata && pmp->pfs_nmasters < ripdata->meta.pfs_nmasters) { pmp->pfs_nmasters = ripdata->meta.pfs_nmasters; } /* * Count visible masters. Masters are usually added with * ripdata->meta.pfs_nmasters set to 1. This detects when there * are more (XXX and must update the master inodes). */ count = 0; for (i = 0; i < iroot->cluster.nchains; ++i) { if (pmp->pfs_types[i] == HAMMER2_PFSTYPE_MASTER) ++count; } if (pmp->pfs_nmasters < count) pmp->pfs_nmasters = count; /* * Create missing synchronization and support threads. * * Single-node masters (including snapshots) have nothing to * synchronize and do not require this thread. * * Multi-node masters or any number of soft masters, slaves, copy, * or other PFS types need the thread. * * Each thread is responsible for its particular cluster index. * We use independent threads so stalls or mismatches related to * any given target do not affect other targets. */ for (i = 0; i < iroot->cluster.nchains; ++i) { /* * Single-node masters (including snapshots) have nothing * to synchronize and will make direct xops support calls, * thus they do not require this thread. * * Note that there can be thousands of snapshots. We do not * want to create thousands of threads. */ if (pmp->pfs_nmasters <= 1 && pmp->pfs_types[i] == HAMMER2_PFSTYPE_MASTER) { continue; } /* * Sync support thread */ /* if (pmp->sync_thrs[i].td == NULL) { hammer2_thr_create(&pmp->sync_thrs[i], pmp, NULL, "h2nod", i, -1, hammer2_primary_sync_thread); } */ } /* * Create missing Xop threads * * NOTE: We create helper threads for all mounted PFSs or any * PFSs with 2+ nodes (so the sync thread can update them, * even if not mounted). */ if (pmp->mp || iroot->cluster.nchains >= 2) hammer2_xop_helper_create(pmp); hammer2_mtx_unlock(&iroot->lock); hammer2_inode_drop(iroot); done: return pmp; } /* * Deallocate an element of a probed PFS. If destroying and this is a * MASTER, adjust nmasters. * * This function does not physically destroy the PFS element in its device * under the super-root (see hammer2_ioctl_pfs_delete()). */ void hammer2_pfsdealloc(hammer2_pfs_t *pmp, int clindex, int destroying) { hammer2_inode_t *iroot; hammer2_chain_t *chain; int j; /* * Cleanup our reference on iroot. iroot is (should) not be needed * by the flush code. */ iroot = pmp->iroot; if (iroot) { /* * Stop synchronizing * * XXX flush after acquiring the iroot lock. * XXX clean out the cluster index from all inode structures. */ hammer2_thr_delete(&pmp->sync_thrs[clindex]); /* * Remove the cluster index from the group. If destroying * the PFS and this is a master, adjust pfs_nmasters. */ hammer2_mtx_ex(&iroot->lock); chain = iroot->cluster.array[clindex].chain; iroot->cluster.array[clindex].chain = NULL; switch(pmp->pfs_types[clindex]) { case HAMMER2_PFSTYPE_MASTER: if (destroying && pmp->pfs_nmasters > 0) --pmp->pfs_nmasters; /* XXX adjust ripdata->meta.pfs_nmasters */ break; default: break; } pmp->pfs_types[clindex] = HAMMER2_PFSTYPE_NONE; hammer2_mtx_unlock(&iroot->lock); /* * Release the chain. */ if (chain) { atomic_set_int(&chain->flags, HAMMER2_CHAIN_RELEASE); hammer2_chain_drop(chain); } /* * Terminate all XOP threads for the cluster index. */ if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) { hammer2_thr_delete( &pmp->xop_groups[j].thrs[clindex]); } } } } /* * Destroy a PFS, typically only occurs after the last mount on a device * has gone away. */ static void hammer2_pfsfree(hammer2_pfs_t *pmp) { hammer2_inode_t *iroot; hammer2_chain_t *chain; int chains_still_present = 0; int i; //int j; /* * Cleanup our reference on iroot. iroot is (should) not be needed * by the flush code. */ if (pmp->flags & HAMMER2_PMPF_SPMP) TAILQ_REMOVE(&hammer2_spmplist, pmp, mntentry); else TAILQ_REMOVE(&hammer2_pfslist, pmp, mntentry); /* * Cleanup chains remaining on LRU list. */ hammer2_spin_ex(&pmp->lru_spin); while ((chain = TAILQ_FIRST(&pmp->lru_list)) != NULL) { KKASSERT(chain->flags & HAMMER2_CHAIN_ONLRU); atomic_add_int(&pmp->lru_count, -1); atomic_clear_int(&chain->flags, HAMMER2_CHAIN_ONLRU); TAILQ_REMOVE(&pmp->lru_list, chain, lru_node); hammer2_chain_ref(chain); hammer2_spin_unex(&pmp->lru_spin); atomic_set_int(&chain->flags, HAMMER2_CHAIN_RELEASE); hammer2_chain_drop(chain); hammer2_spin_ex(&pmp->lru_spin); } hammer2_spin_unex(&pmp->lru_spin); /* * Clean up iroot */ iroot = pmp->iroot; if (iroot) { for (i = 0; i < iroot->cluster.nchains; ++i) { /* hammer2_thr_delete(&pmp->sync_thrs[i]); if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) hammer2_thr_delete( &pmp->xop_groups[j].thrs[i]); } */ chain = iroot->cluster.array[i].chain; if (chain && !RB_EMPTY(&chain->core.rbtree)) { kprintf("hammer2: Warning pmp %p still " "has active chains\n", pmp); chains_still_present = 1; } } KASSERT(iroot->refs == 1, ("PMP->IROOT %p REFS WRONG %d", iroot, iroot->refs)); /* ref for iroot */ hammer2_inode_drop(iroot); pmp->iroot = NULL; } /* * Free remaining pmp resources */ if (chains_still_present) { kprintf("hammer2: cannot free pmp %p, still in use\n", pmp); } else { /* * In makefs HAMMER2, all inodes must be gone at this point. * XXX vnode_count may not be 0 at this point. */ assert(hammer2_pfs_inode_count(pmp) == 0); kmalloc_destroy_obj(&pmp->minode); kfree(pmp, M_HAMMER2); } } /* * Remove all references to hmp from the pfs list. Any PFS which becomes * empty is terminated and freed. * * XXX inefficient. */ static void hammer2_pfsfree_scan(hammer2_dev_t *hmp, int which) { hammer2_pfs_t *pmp; hammer2_inode_t *iroot; hammer2_chain_t *rchain; int i; //int j; struct hammer2_pfslist *wlist; if (which == 0) wlist = &hammer2_pfslist; else wlist = &hammer2_spmplist; again: TAILQ_FOREACH(pmp, wlist, mntentry) { if ((iroot = pmp->iroot) == NULL) continue; /* * Determine if this PFS is affected. If it is we must * freeze all management threads and lock its iroot. * * Freezing a management thread forces it idle, operations * in-progress will be aborted and it will have to start * over again when unfrozen, or exit if told to exit. */ for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_hmps[i] == hmp) break; } if (i == HAMMER2_MAXCLUSTER) continue; hammer2_vfs_sync_pmp(pmp, MNT_WAIT); /* * Make sure all synchronization threads are locked * down. */ /* for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_hmps[i] == NULL) continue; hammer2_thr_freeze_async(&pmp->sync_thrs[i]); if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) { hammer2_thr_freeze_async( &pmp->xop_groups[j].thrs[i]); } } } for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_hmps[i] == NULL) continue; hammer2_thr_freeze(&pmp->sync_thrs[i]); if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) { hammer2_thr_freeze( &pmp->xop_groups[j].thrs[i]); } } } */ /* * Lock the inode and clean out matching chains. * Note that we cannot use hammer2_inode_lock_*() * here because that would attempt to validate the * cluster that we are in the middle of ripping * apart. * * WARNING! We are working directly on the inodes * embedded cluster. */ hammer2_mtx_ex(&iroot->lock); /* * Remove the chain from matching elements of the PFS. */ for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_hmps[i] != hmp) continue; /* hammer2_thr_delete(&pmp->sync_thrs[i]); if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) { hammer2_thr_delete( &pmp->xop_groups[j].thrs[i]); } } */ rchain = iroot->cluster.array[i].chain; iroot->cluster.array[i].chain = NULL; pmp->pfs_types[i] = 0; if (pmp->pfs_names[i]) { kfree(pmp->pfs_names[i], M_HAMMER2); pmp->pfs_names[i] = NULL; } if (rchain) { hammer2_chain_drop(rchain); /* focus hint */ if (iroot->cluster.focus == rchain) iroot->cluster.focus = NULL; } pmp->pfs_hmps[i] = NULL; } hammer2_mtx_unlock(&iroot->lock); /* * Cleanup trailing chains. Gaps may remain. */ for (i = HAMMER2_MAXCLUSTER - 1; i >= 0; --i) { if (pmp->pfs_hmps[i]) break; } iroot->cluster.nchains = i + 1; /* * If the PMP has no elements remaining we can destroy it. * (this will transition management threads from frozen->exit). */ if (iroot->cluster.nchains == 0) { /* * If this was the hmp's spmp, we need to clean * a little more stuff out. */ if (hmp->spmp == pmp) { hmp->spmp = NULL; hmp->vchain.pmp = NULL; hmp->fchain.pmp = NULL; } /* * Free the pmp and restart the loop */ KKASSERT(TAILQ_EMPTY(&pmp->syncq)); KKASSERT(TAILQ_EMPTY(&pmp->depq)); hammer2_pfsfree(pmp); goto again; } /* * If elements still remain we need to set the REMASTER * flag and unfreeze it. */ for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_hmps[i] == NULL) continue; /* hammer2_thr_remaster(&pmp->sync_thrs[i]); hammer2_thr_unfreeze(&pmp->sync_thrs[i]); if (pmp->xop_groups) { for (j = 0; j < hammer2_xop_nthreads; ++j) { hammer2_thr_remaster( &pmp->xop_groups[j].thrs[i]); hammer2_thr_unfreeze( &pmp->xop_groups[j].thrs[i]); } } */ } } } /* * Mount or remount HAMMER2 fileystem from physical media * * mountroot * mp mount point structure * path NULL * data * cred * * mount * mp mount point structure * path path to mount point * data pointer to argument structure in user space * volume volume path (device@LABEL form) * hflags user mount flags * cred user credentials * * RETURNS: 0 Success * !0 error number */ int hammer2_vfs_mount(struct vnode *makefs_devvp, struct mount *mp, const char *label, const struct hammer2_mount_info *mi) { struct hammer2_mount_info info = *mi; hammer2_pfs_t *pmp; hammer2_pfs_t *spmp; hammer2_dev_t *hmp, *hmp_tmp; hammer2_dev_t *force_local; hammer2_key_t key_next; hammer2_key_t key_dummy; hammer2_key_t lhc; hammer2_chain_t *parent; hammer2_chain_t *chain; const hammer2_inode_data_t *ripdata; hammer2_devvp_list_t devvpl; hammer2_devvp_t *e, *e_tmp; char *devstr; int ronly = ((mp->mnt_flag & MNT_RDONLY) != 0); int error; int i; hmp = NULL; pmp = NULL; devstr = NULL; kprintf("hammer2_mount: device=\"%s\" label=\"%s\" rdonly=%d\n", devstr, label, ronly); /* * Initialize all device vnodes. */ TAILQ_INIT(&devvpl); error = hammer2_init_devvp(makefs_devvp, &devvpl); if (error) { kprintf("hammer2: failed to initialize devvp in %s\n", devstr); hammer2_cleanup_devvp(&devvpl); return error; } /* * Determine if the device has already been mounted. After this * check hmp will be non-NULL if we are doing the second or more * hammer2 mounts from the same device. */ lockmgr(&hammer2_mntlk, LK_EXCLUSIVE); if (!TAILQ_EMPTY(&devvpl)) { /* * Match the device. Due to the way devfs works, * we may not be able to directly match the vnode pointer, * so also check to see if the underlying device matches. */ TAILQ_FOREACH(hmp_tmp, &hammer2_mntlist, mntentry) { TAILQ_FOREACH(e_tmp, &hmp_tmp->devvpl, entry) { int devvp_found = 0; TAILQ_FOREACH(e, &devvpl, entry) { KKASSERT(e->devvp); if (e_tmp->devvp == e->devvp) devvp_found = 1; /* if (e_tmp->devvp->v_rdev && e_tmp->devvp->v_rdev == e->devvp->v_rdev) devvp_found = 1; */ } if (!devvp_found) goto next_hmp; } hmp = hmp_tmp; kprintf("hammer2_mount: hmp=%p matched\n", hmp); break; next_hmp: continue; } /* * If no match this may be a fresh H2 mount, make sure * the device is not mounted on anything else. */ if (hmp == NULL) { TAILQ_FOREACH(e, &devvpl, entry) { struct vnode *devvp = e->devvp; KKASSERT(devvp); error = vfs_mountedon(devvp); if (error) { kprintf("hammer2_mount: %s mounted %d\n", e->path, error); hammer2_cleanup_devvp(&devvpl); lockmgr(&hammer2_mntlk, LK_RELEASE); return error; } } } } else { /* * Match the label to a pmp already probed. */ TAILQ_FOREACH(pmp, &hammer2_pfslist, mntentry) { for (i = 0; i < HAMMER2_MAXCLUSTER; ++i) { if (pmp->pfs_names[i] && strcmp(pmp->pfs_names[i], label) == 0) { hmp = pmp->pfs_hmps[i]; break; } } if (hmp) break; } if (hmp == NULL) { kprintf("hammer2_mount: PFS label \"%s\" not found\n", label); hammer2_cleanup_devvp(&devvpl); lockmgr(&hammer2_mntlk, LK_RELEASE); return ENOENT; } } /* * Open the device if this isn't a secondary mount and construct * the H2 device mount (hmp). */ if (hmp == NULL) { hammer2_chain_t *schain; hammer2_xop_head_t xop; /* * Now open the device */ KKASSERT(!TAILQ_EMPTY(&devvpl)); if (error == 0) { error = hammer2_open_devvp(&devvpl, ronly); if (error) { hammer2_close_devvp(&devvpl, ronly); hammer2_cleanup_devvp(&devvpl); lockmgr(&hammer2_mntlk, LK_RELEASE); return error; } } /* * Construct volumes and link with device vnodes. */ hmp = kmalloc(sizeof(*hmp), M_HAMMER2, M_WAITOK | M_ZERO); hmp->devvp = NULL; error = hammer2_init_vfsvolumes(mp, &devvpl, hmp->volumes, &hmp->voldata, &hmp->volhdrno, &hmp->devvp); if (error) { hammer2_close_devvp(&devvpl, ronly); hammer2_cleanup_devvp(&devvpl); lockmgr(&hammer2_mntlk, LK_RELEASE); kfree(hmp, M_HAMMER2); return error; } if (!hmp->devvp) { kprintf("hammer2: failed to initialize root volume\n"); hammer2_unmount_helper(mp, NULL, hmp); lockmgr(&hammer2_mntlk, LK_RELEASE); hammer2_vfs_unmount(mp, MNT_FORCE); return EINVAL; } ksnprintf(hmp->devrepname, sizeof(hmp->devrepname), "%s", devstr); hmp->ronly = ronly; hmp->hflags = info.hflags & HMNT2_DEVFLAGS; kmalloc_create_obj(&hmp->mchain, "HAMMER2-chains", sizeof(struct hammer2_chain)); kmalloc_create_obj(&hmp->mio, "HAMMER2-dio", sizeof(struct hammer2_io)); kmalloc_create(&hmp->mmsg, "HAMMER2-msg"); TAILQ_INSERT_TAIL(&hammer2_mntlist, hmp, mntentry); RB_INIT(&hmp->iotree); hammer2_spin_init(&hmp->io_spin, "h2mount_io"); hammer2_spin_init(&hmp->list_spin, "h2mount_list"); lockinit(&hmp->vollk, "h2vol", 0, 0); lockinit(&hmp->bulklk, "h2bulk", 0, 0); lockinit(&hmp->bflock, "h2bflk", 0, 0); /* * vchain setup. vchain.data is embedded. * vchain.refs is initialized and will never drop to 0. * * NOTE! voldata is not yet loaded. */ hmp->vchain.hmp = hmp; hmp->vchain.refs = 1; hmp->vchain.data = (void *)&hmp->voldata; hmp->vchain.bref.type = HAMMER2_BREF_TYPE_VOLUME; hmp->vchain.bref.data_off = 0 | HAMMER2_PBUFRADIX; hmp->vchain.bref.mirror_tid = hmp->voldata.mirror_tid; hammer2_chain_core_init(&hmp->vchain); /* * fchain setup. fchain.data is embedded. * fchain.refs is initialized and will never drop to 0. * * The data is not used but needs to be initialized to * pass assertion muster. We use this chain primarily * as a placeholder for the freemap's top-level radix tree * so it does not interfere with the volume's topology * radix tree. */ hmp->fchain.hmp = hmp; hmp->fchain.refs = 1; hmp->fchain.data = (void *)&hmp->voldata.freemap_blockset; hmp->fchain.bref.type = HAMMER2_BREF_TYPE_FREEMAP; hmp->fchain.bref.data_off = 0 | HAMMER2_PBUFRADIX; hmp->fchain.bref.mirror_tid = hmp->voldata.freemap_tid; hmp->fchain.bref.methods = HAMMER2_ENC_CHECK(HAMMER2_CHECK_FREEMAP) | HAMMER2_ENC_COMP(HAMMER2_COMP_NONE); hammer2_chain_core_init(&hmp->fchain); /* * Initialize volume header related fields. */ KKASSERT(hmp->voldata.magic == HAMMER2_VOLUME_ID_HBO || hmp->voldata.magic == HAMMER2_VOLUME_ID_ABO); hmp->volsync = hmp->voldata; hmp->free_reserved = hmp->voldata.allocator_size / 20; /* * Must use hmp instead of volume header for these two * in order to handle volume versions transparently. */ if (hmp->voldata.version >= HAMMER2_VOL_VERSION_MULTI_VOLUMES) { hmp->nvolumes = hmp->voldata.nvolumes; hmp->total_size = hmp->voldata.total_size; } else { hmp->nvolumes = 1; hmp->total_size = hmp->voldata.volu_size; } KKASSERT(hmp->nvolumes > 0); /* * Move devvpl entries to hmp. */ TAILQ_INIT(&hmp->devvpl); while ((e = TAILQ_FIRST(&devvpl)) != NULL) { TAILQ_REMOVE(&devvpl, e, entry); TAILQ_INSERT_TAIL(&hmp->devvpl, e, entry); } KKASSERT(TAILQ_EMPTY(&devvpl)); KKASSERT(!TAILQ_EMPTY(&hmp->devvpl)); /* * Really important to get these right or the flush and * teardown code will get confused. */ hmp->spmp = hammer2_pfsalloc(NULL, NULL, NULL); spmp = hmp->spmp; spmp->pfs_hmps[0] = hmp; /* * Dummy-up vchain and fchain's modify_tid. mirror_tid * is inherited from the volume header. */ hmp->vchain.bref.mirror_tid = hmp->voldata.mirror_tid; hmp->vchain.bref.modify_tid = hmp->vchain.bref.mirror_tid; hmp->vchain.pmp = spmp; hmp->fchain.bref.mirror_tid = hmp->voldata.freemap_tid; hmp->fchain.bref.modify_tid = hmp->fchain.bref.mirror_tid; hmp->fchain.pmp = spmp; /* * First locate the super-root inode, which is key 0 * relative to the volume header's blockset. * * Then locate the root inode by scanning the directory keyspace * represented by the label. */ parent = hammer2_chain_lookup_init(&hmp->vchain, 0); schain = hammer2_chain_lookup(&parent, &key_dummy, HAMMER2_SROOT_KEY, HAMMER2_SROOT_KEY, &error, 0); hammer2_chain_lookup_done(parent); if (schain == NULL) { kprintf("hammer2_mount: invalid super-root\n"); hammer2_unmount_helper(mp, NULL, hmp); lockmgr(&hammer2_mntlk, LK_RELEASE); hammer2_vfs_unmount(mp, MNT_FORCE); return EINVAL; } if (schain->error) { kprintf("hammer2_mount: error %s reading super-root\n", hammer2_error_str(schain->error)); hammer2_chain_unlock(schain); hammer2_chain_drop(schain); schain = NULL; hammer2_unmount_helper(mp, NULL, hmp); lockmgr(&hammer2_mntlk, LK_RELEASE); hammer2_vfs_unmount(mp, MNT_FORCE); return EINVAL; } /* * The super-root always uses an inode_tid of 1 when * creating PFSs. */ spmp->inode_tid = 1; spmp->modify_tid = schain->bref.modify_tid + 1; /* * Sanity-check schain's pmp and finish initialization. * Any chain belonging to the super-root topology should * have a NULL pmp (not even set to spmp). */ ripdata = &schain->data->ipdata; KKASSERT(schain->pmp == NULL); spmp->pfs_clid = ripdata->meta.pfs_clid; /* * Replace the dummy spmp->iroot with a real one. It's * easier to just do a wholesale replacement than to try * to update the chain and fixup the iroot fields. * * The returned inode is locked with the supplied cluster. */ hammer2_dummy_xop_from_chain(&xop, schain); hammer2_inode_drop(spmp->iroot); spmp->iroot = NULL; spmp->iroot = hammer2_inode_get(spmp, &xop, -1, -1); spmp->spmp_hmp = hmp; spmp->pfs_types[0] = ripdata->meta.pfs_type; spmp->pfs_hmps[0] = hmp; hammer2_inode_ref(spmp->iroot); hammer2_inode_unlock(spmp->iroot); hammer2_cluster_unlock(&xop.cluster); hammer2_chain_drop(schain); /* do not call hammer2_cluster_drop() on an embedded cluster */ schain = NULL; /* now invalid */ /* leave spmp->iroot with one ref */ if (!hmp->ronly) { error = hammer2_recovery(hmp); if (error == 0) error |= hammer2_fixup_pfses(hmp); /* XXX do something with error */ } hammer2_update_pmps(hmp); hammer2_iocom_init(hmp); hammer2_bulkfree_init(hmp); /* * Ref the cluster management messaging descriptor. The mount * program deals with the other end of the communications pipe. * * Root mounts typically do not supply one. */ /* if (info.cluster_fd >= 0) { fp = holdfp(curthread, info.cluster_fd, -1); if (fp) { hammer2_cluster_reconnect(hmp, fp); } else { kprintf("hammer2_mount: bad cluster_fd!\n"); } } */ } else { spmp = hmp->spmp; if (info.hflags & HMNT2_DEVFLAGS) { kprintf("hammer2_mount: Warning: mount flags pertaining " "to the whole device may only be specified " "on the first mount of the device: %08x\n", info.hflags & HMNT2_DEVFLAGS); } } /* * Force local mount (disassociate all PFSs from their clusters). * Used primarily for debugging. */ force_local = (hmp->hflags & HMNT2_LOCAL) ? hmp : NULL; /* * Lookup the mount point under the media-localized super-root. * Scanning hammer2_pfslist doesn't help us because it represents * PFS cluster ids which can aggregate several named PFSs together. * * cluster->pmp will incorrectly point to spmp and must be fixed * up later on. */ hammer2_inode_lock(spmp->iroot, 0); parent = hammer2_inode_chain(spmp->iroot, 0, HAMMER2_RESOLVE_ALWAYS); lhc = hammer2_dirhash(label, strlen(label)); chain = hammer2_chain_lookup(&parent, &key_next, lhc, lhc + HAMMER2_DIRHASH_LOMASK, &error, 0); while (chain) { if (chain->bref.type == HAMMER2_BREF_TYPE_INODE && strcmp(label, chain->data->ipdata.filename) == 0) { break; } chain = hammer2_chain_next(&parent, chain, &key_next, key_next, lhc + HAMMER2_DIRHASH_LOMASK, &error, 0); } if (parent) { hammer2_chain_unlock(parent); hammer2_chain_drop(parent); } hammer2_inode_unlock(spmp->iroot); /* * PFS could not be found? */ if (chain == NULL) { hammer2_unmount_helper(mp, NULL, hmp); lockmgr(&hammer2_mntlk, LK_RELEASE); hammer2_vfs_unmount(mp, MNT_FORCE); if (error) { kprintf("hammer2_mount: PFS label I/O error\n"); return EINVAL; } else { kprintf("hammer2_mount: PFS label \"%s\" not found\n", label); return ENOENT; } } /* * Acquire the pmp structure (it should have already been allocated * via hammer2_update_pmps() so do not pass cluster in to add to * available chains). * * Check if the cluster has already been mounted. A cluster can * only be mounted once, use null mounts to mount additional copies. */ if (chain->error) { kprintf("hammer2_mount: PFS label I/O error\n"); } else { ripdata = &chain->data->ipdata; pmp = hammer2_pfsalloc(NULL, ripdata, force_local); } hammer2_chain_unlock(chain); hammer2_chain_drop(chain); /* * Finish the mount */ kprintf("hammer2_mount: hmp=%p pmp=%p\n", hmp, pmp); if (pmp->mp) { kprintf("hammer2_mount: PFS already mounted!\n"); hammer2_unmount_helper(mp, NULL, hmp); lockmgr(&hammer2_mntlk, LK_RELEASE); hammer2_vfs_unmount(mp, MNT_FORCE); return EBUSY; } pmp->hflags = info.hflags; mp->mnt_flag |= MNT_LOCAL; mp->mnt_kern_flag |= MNTK_ALL_MPSAFE; /* all entry pts are SMP */ mp->mnt_kern_flag |= MNTK_THR_SYNC; /* new vsyncscan semantics */ /* * required mount structure initializations */ mp->mnt_stat.f_iosize = HAMMER2_PBUFSIZE; mp->mnt_stat.f_bsize = HAMMER2_PBUFSIZE; mp->mnt_vstat.f_frsize = HAMMER2_PBUFSIZE; mp->mnt_vstat.f_bsize = HAMMER2_PBUFSIZE; /* * Optional fields */ mp->mnt_iosize_max = MAXPHYS; /* * Connect up mount pointers. */ hammer2_mount_helper(mp, pmp); lockmgr(&hammer2_mntlk, LK_RELEASE); #if 0 /* * Finish setup */ vfs_getnewfsid(mp); vfs_add_vnodeops(mp, &hammer2_vnode_vops, &mp->mnt_vn_norm_ops); vfs_add_vnodeops(mp, &hammer2_spec_vops, &mp->mnt_vn_spec_ops); vfs_add_vnodeops(mp, &hammer2_fifo_vops, &mp->mnt_vn_fifo_ops); if (path) { copyinstr(info.volume, mp->mnt_stat.f_mntfromname, MNAMELEN - 1, &size); bzero(mp->mnt_stat.f_mntfromname + size, MNAMELEN - size); } /* else root mount, already in there */ bzero(mp->mnt_stat.f_mntonname, sizeof(mp->mnt_stat.f_mntonname)); if (path) { copyinstr(path, mp->mnt_stat.f_mntonname, sizeof(mp->mnt_stat.f_mntonname) - 1, &size); } else { /* root mount */ mp->mnt_stat.f_mntonname[0] = '/'; } #endif /* * Initial statfs to prime mnt_stat. */ hammer2_vfs_statfs(mp, &mp->mnt_stat, NULL); hammer2_vfs_statvfs(mp, &mp->mnt_vstat, NULL); return 0; } /* * Scan PFSs under the super-root and create hammer2_pfs structures. */ static void hammer2_update_pmps(hammer2_dev_t *hmp) { const hammer2_inode_data_t *ripdata; hammer2_chain_t *parent; hammer2_chain_t *chain; hammer2_dev_t *force_local; hammer2_pfs_t *spmp; hammer2_key_t key_next; int error; /* * Force local mount (disassociate all PFSs from their clusters). * Used primarily for debugging. */ force_local = (hmp->hflags & HMNT2_LOCAL) ? hmp : NULL; /* * Lookup mount point under the media-localized super-root. * * cluster->pmp will incorrectly point to spmp and must be fixed * up later on. */ spmp = hmp->spmp; hammer2_inode_lock(spmp->iroot, 0); parent = hammer2_inode_chain(spmp->iroot, 0, HAMMER2_RESOLVE_ALWAYS); chain = hammer2_chain_lookup(&parent, &key_next, HAMMER2_KEY_MIN, HAMMER2_KEY_MAX, &error, 0); while (chain) { if (chain->error) { kprintf("I/O error scanning PFS labels\n"); } else if (chain->bref.type != HAMMER2_BREF_TYPE_INODE) { kprintf("Non inode chain type %d under super-root\n", chain->bref.type); } else { ripdata = &chain->data->ipdata; hammer2_pfsalloc(chain, ripdata, force_local); } chain = hammer2_chain_next(&parent, chain, &key_next, key_next, HAMMER2_KEY_MAX, &error, 0); } if (parent) { hammer2_chain_unlock(parent); hammer2_chain_drop(parent); } hammer2_inode_unlock(spmp->iroot); } #if 0 static int hammer2_remount(hammer2_dev_t *hmp, struct mount *mp, char *path __unused, struct ucred *cred) { hammer2_volume_t *vol; struct vnode *devvp; int i, error, result = 0; if (!(hmp->ronly && (mp->mnt_kern_flag & MNTK_WANTRDWR))) return 0; for (i = 0; i < hmp->nvolumes; ++i) { vol = &hmp->volumes[i]; devvp = vol->dev->devvp; KKASSERT(devvp); vn_lock(devvp, LK_EXCLUSIVE | LK_RETRY); VOP_OPEN(devvp, FREAD | FWRITE, FSCRED, NULL); vn_unlock(devvp); error = 0; if (vol->id == HAMMER2_ROOT_VOLUME) { error = hammer2_recovery(hmp); if (error == 0) error |= hammer2_fixup_pfses(hmp); } vn_lock(devvp, LK_EXCLUSIVE | LK_RETRY); if (error == 0) { VOP_CLOSE(devvp, FREAD, NULL); } else { VOP_CLOSE(devvp, FREAD | FWRITE, NULL); } vn_unlock(devvp); result |= error; } if (result == 0) { kprintf("hammer2: enable read/write\n"); hmp->ronly = 0; } return result; } #endif int hammer2_vfs_unmount(struct mount *mp, int mntflags) { hammer2_pfs_t *pmp; int flags; int error = 0; pmp = MPTOPMP(mp); if (pmp == NULL) return(0); lockmgr(&hammer2_mntlk, LK_EXCLUSIVE); /* * If mount initialization proceeded far enough we must flush * its vnodes and sync the underlying mount points. Three syncs * are required to fully flush the filesystem (freemap updates lag * by one flush, and one extra for safety). */ if (mntflags & MNT_FORCE) flags = FORCECLOSE; else flags = 0; if (pmp->iroot) { error = vflush(mp, 0, flags); if (error) goto failed; hammer2_vfs_sync(mp, MNT_WAIT); hammer2_vfs_sync(mp, MNT_WAIT); hammer2_vfs_sync(mp, MNT_WAIT); } /* * Cleanup the frontend support XOPS threads */ hammer2_xop_helper_cleanup(pmp); if (pmp->mp) hammer2_unmount_helper(mp, pmp, NULL); error = 0; failed: lockmgr(&hammer2_mntlk, LK_RELEASE); return (error); } /* * Mount helper, hook the system mount into our PFS. * The mount lock is held. * * We must bump the mount_count on related devices for any * mounted PFSs. */ static void hammer2_mount_helper(struct mount *mp, hammer2_pfs_t *pmp) { hammer2_cluster_t *cluster; hammer2_chain_t *rchain; int i; mp->mnt_data = (qaddr_t)pmp; pmp->mp = mp; /* * After pmp->mp is set we have to adjust hmp->mount_count. */ cluster = &pmp->iroot->cluster; for (i = 0; i < cluster->nchains; ++i) { rchain = cluster->array[i].chain; if (rchain == NULL) continue; ++rchain->hmp->mount_count; } /* * Create missing Xop threads */ hammer2_xop_helper_create(pmp); } /* * Unmount helper, unhook the system mount from our PFS. * The mount lock is held. * * If hmp is supplied a mount responsible for being the first to open * the block device failed and the block device and all PFSs using the * block device must be cleaned up. * * If pmp is supplied multiple devices might be backing the PFS and each * must be disconnected. This might not be the last PFS using some of the * underlying devices. Also, we have to adjust our hmp->mount_count * accounting for the devices backing the pmp which is now undergoing an * unmount. */ static void hammer2_unmount_helper(struct mount *mp, hammer2_pfs_t *pmp, hammer2_dev_t *hmp) { hammer2_cluster_t *cluster; hammer2_chain_t *rchain; int dumpcnt; int i; /* * If no device supplied this is a high-level unmount and we have to * to disconnect the mount, adjust mount_count, and locate devices * that might now have no mounts. */ if (pmp) { KKASSERT(hmp == NULL); KKASSERT(MPTOPMP(mp) == pmp); pmp->mp = NULL; mp->mnt_data = NULL; /* * After pmp->mp is cleared we have to account for * mount_count. */ cluster = &pmp->iroot->cluster; for (i = 0; i < cluster->nchains; ++i) { rchain = cluster->array[i].chain; if (rchain == NULL) continue; --rchain->hmp->mount_count; /* scrapping hmp now may invalidate the pmp */ } again: TAILQ_FOREACH(hmp, &hammer2_mntlist, mntentry) { if (hmp->mount_count == 0) { hammer2_unmount_helper(NULL, NULL, hmp); goto again; } } return; } /* * Try to terminate the block device. We can't terminate it if * there are still PFSs referencing it. */ if (hmp->mount_count) return; /* * Decomission the network before we start messing with the * device and PFS. */ hammer2_iocom_uninit(hmp); hammer2_bulkfree_uninit(hmp); hammer2_pfsfree_scan(hmp, 0); /* * Cycle the volume data lock as a safety (probably not needed any * more). To ensure everything is out we need to flush at least * three times. (1) The running of the sideq can dirty the * filesystem, (2) A normal flush can dirty the freemap, and * (3) ensure that the freemap is fully synchronized. * * The next mount's recovery scan can clean everything up but we want * to leave the filesystem in a 100% clean state on a normal unmount. */ #if 0 hammer2_voldata_lock(hmp); hammer2_voldata_unlock(hmp); #endif /* * Flush whatever is left. Unmounted but modified PFS's might still * have some dirty chains on them. */ hammer2_chain_lock(&hmp->vchain, HAMMER2_RESOLVE_ALWAYS); hammer2_chain_lock(&hmp->fchain, HAMMER2_RESOLVE_ALWAYS); if (hmp->fchain.flags & HAMMER2_CHAIN_FLUSH_MASK) { hammer2_voldata_modify(hmp); hammer2_flush(&hmp->fchain, HAMMER2_FLUSH_TOP | HAMMER2_FLUSH_ALL); } hammer2_chain_unlock(&hmp->fchain); if (hmp->vchain.flags & HAMMER2_CHAIN_FLUSH_MASK) { hammer2_flush(&hmp->vchain, HAMMER2_FLUSH_TOP | HAMMER2_FLUSH_ALL); } hammer2_chain_unlock(&hmp->vchain); if ((hmp->vchain.flags | hmp->fchain.flags) & HAMMER2_CHAIN_FLUSH_MASK) { kprintf("hammer2_unmount: chains left over after final sync\n"); kprintf(" vchain %08x\n", hmp->vchain.flags); kprintf(" fchain %08x\n", hmp->fchain.flags); if (hammer2_debug & 0x0010) Debugger("entered debugger"); } hammer2_pfsfree_scan(hmp, 1); KKASSERT(hmp->spmp == NULL); /* * Finish up with the device vnode */ if (!TAILQ_EMPTY(&hmp->devvpl)) { hammer2_close_devvp(&hmp->devvpl, hmp->ronly); hammer2_cleanup_devvp(&hmp->devvpl); } KKASSERT(TAILQ_EMPTY(&hmp->devvpl)); /* * Clear vchain/fchain flags that might prevent final cleanup * of these chains. */ if (hmp->vchain.flags & HAMMER2_CHAIN_MODIFIED) { atomic_add_long(&hammer2_count_modified_chains, -1); atomic_clear_int(&hmp->vchain.flags, HAMMER2_CHAIN_MODIFIED); hammer2_pfs_memory_wakeup(hmp->vchain.pmp, -1); } if (hmp->vchain.flags & HAMMER2_CHAIN_UPDATE) { atomic_clear_int(&hmp->vchain.flags, HAMMER2_CHAIN_UPDATE); } if (hmp->fchain.flags & HAMMER2_CHAIN_MODIFIED) { atomic_add_long(&hammer2_count_modified_chains, -1); atomic_clear_int(&hmp->fchain.flags, HAMMER2_CHAIN_MODIFIED); hammer2_pfs_memory_wakeup(hmp->fchain.pmp, -1); } if (hmp->fchain.flags & HAMMER2_CHAIN_UPDATE) { atomic_clear_int(&hmp->fchain.flags, HAMMER2_CHAIN_UPDATE); } /* * Final drop of embedded freemap root chain to * clean up fchain.core (fchain structure is not * flagged ALLOCATED so it is cleaned out and then * left to rot). */ hammer2_chain_drop(&hmp->fchain); /* * Final drop of embedded volume root chain to clean * up vchain.core (vchain structure is not flagged * ALLOCATED so it is cleaned out and then left to * rot). */ dumpcnt = 50; hammer2_dump_chain(&hmp->vchain, 0, 0, &dumpcnt, 'v', (u_int)-1); dumpcnt = 50; hammer2_dump_chain(&hmp->fchain, 0, 0, &dumpcnt, 'f', (u_int)-1); hammer2_chain_drop(&hmp->vchain); hammer2_io_cleanup(hmp, &hmp->iotree); if (hmp->iofree_count) { kprintf("io_cleanup: %d I/O's left hanging\n", hmp->iofree_count); } TAILQ_REMOVE(&hammer2_mntlist, hmp, mntentry); kmalloc_destroy_obj(&hmp->mchain); kmalloc_destroy_obj(&hmp->mio); kmalloc_destroy(&hmp->mmsg); kfree(hmp, M_HAMMER2); } int hammer2_vfs_vget(struct mount *mp, struct vnode *dvp, ino_t ino, struct vnode **vpp) { hammer2_xop_lookup_t *xop; hammer2_pfs_t *pmp; hammer2_inode_t *ip; hammer2_tid_t inum; int error; inum = (hammer2_tid_t)ino & HAMMER2_DIRHASH_USERMSK; error = 0; pmp = MPTOPMP(mp); /* * Easy if we already have it cached */ ip = hammer2_inode_lookup(pmp, inum); if (ip) { hammer2_inode_lock(ip, HAMMER2_RESOLVE_SHARED); *vpp = hammer2_igetv(ip, &error); hammer2_inode_unlock(ip); hammer2_inode_drop(ip); /* from lookup */ return error; } /* * Otherwise we have to find the inode */ xop = hammer2_xop_alloc(pmp->iroot, 0); xop->lhc = inum; hammer2_xop_start(&xop->head, &hammer2_lookup_desc); error = hammer2_xop_collect(&xop->head, 0); if (error == 0) ip = hammer2_inode_get(pmp, &xop->head, -1, -1); hammer2_xop_retire(&xop->head, HAMMER2_XOPMASK_VOP); if (ip) { *vpp = hammer2_igetv(ip, &error); hammer2_inode_unlock(ip); } else { *vpp = NULL; error = ENOENT; } return (error); } int hammer2_vfs_root(struct mount *mp, struct vnode **vpp) { hammer2_pfs_t *pmp; struct vnode *vp; int error; pmp = MPTOPMP(mp); if (pmp->iroot == NULL) { kprintf("hammer2 (%s): no root inode\n", mp->mnt_stat.f_mntfromname); *vpp = NULL; return EINVAL; } error = 0; hammer2_inode_lock(pmp->iroot, HAMMER2_RESOLVE_SHARED); while (pmp->inode_tid == 0) { hammer2_xop_ipcluster_t *xop; const hammer2_inode_meta_t *meta; xop = hammer2_xop_alloc(pmp->iroot, HAMMER2_XOP_MODIFYING); hammer2_xop_start(&xop->head, &hammer2_ipcluster_desc); error = hammer2_xop_collect(&xop->head, 0); if (error == 0) { meta = &hammer2_xop_gdata(&xop->head)->ipdata.meta; pmp->iroot->meta = *meta; pmp->inode_tid = meta->pfs_inum + 1; hammer2_xop_pdata(&xop->head); /* meta invalid */ if (pmp->inode_tid < HAMMER2_INODE_START) pmp->inode_tid = HAMMER2_INODE_START; pmp->modify_tid = xop->head.cluster.focus->bref.modify_tid + 1; #if 0 kprintf("PFS: Starting inode %jd\n", (intmax_t)pmp->inode_tid); kprintf("PMP focus good set nextino=%ld mod=%016jx\n", pmp->inode_tid, pmp->modify_tid); #endif //wakeup(&pmp->iroot); XXX hammer2_xop_retire(&xop->head, HAMMER2_XOPMASK_VOP); /* * Prime the mount info. */ hammer2_vfs_statfs(mp, &mp->mnt_stat, NULL); break; } /* * Loop, try again */ hammer2_xop_retire(&xop->head, HAMMER2_XOPMASK_VOP); hammer2_inode_unlock(pmp->iroot); error = tsleep(&pmp->iroot, PCATCH, "h2root", hz); hammer2_inode_lock(pmp->iroot, HAMMER2_RESOLVE_SHARED); if (error == EINTR) break; } if (error) { hammer2_inode_unlock(pmp->iroot); *vpp = NULL; } else { vp = hammer2_igetv(pmp->iroot, &error); hammer2_inode_unlock(pmp->iroot); *vpp = vp; } return (error); } /* * Filesystem status * * XXX incorporate ipdata->meta.inode_quota and data_quota */ static int hammer2_vfs_statfs(struct mount *mp, struct statfs *sbp, struct ucred *cred) { hammer2_pfs_t *pmp; hammer2_dev_t *hmp; hammer2_blockref_t bref; struct statfs tmp; int i; /* * NOTE: iroot might not have validated the cluster yet. */ pmp = MPTOPMP(mp); bzero(&tmp, sizeof(tmp)); for (i = 0; i < pmp->iroot->cluster.nchains; ++i) { hmp = pmp->pfs_hmps[i]; if (hmp == NULL) continue; if (pmp->iroot->cluster.array[i].chain) bref = pmp->iroot->cluster.array[i].chain->bref; else bzero(&bref, sizeof(bref)); tmp.f_files = bref.embed.stats.inode_count; tmp.f_ffree = 0; tmp.f_blocks = hmp->voldata.allocator_size / mp->mnt_vstat.f_bsize; tmp.f_bfree = hmp->voldata.allocator_free / mp->mnt_vstat.f_bsize; tmp.f_bavail = tmp.f_bfree; if (cred && cred->cr_uid != 0) { uint64_t adj; /* 5% */ adj = hmp->free_reserved / mp->mnt_vstat.f_bsize; tmp.f_blocks -= adj; tmp.f_bfree -= adj; tmp.f_bavail -= adj; } mp->mnt_stat.f_blocks = tmp.f_blocks; mp->mnt_stat.f_bfree = tmp.f_bfree; mp->mnt_stat.f_bavail = tmp.f_bavail; mp->mnt_stat.f_files = tmp.f_files; mp->mnt_stat.f_ffree = tmp.f_ffree; *sbp = mp->mnt_stat; } return (0); } static int hammer2_vfs_statvfs(struct mount *mp, struct statvfs *sbp, struct ucred *cred) { hammer2_pfs_t *pmp; hammer2_dev_t *hmp; hammer2_blockref_t bref; struct statvfs tmp; int i; /* * NOTE: iroot might not have validated the cluster yet. */ pmp = MPTOPMP(mp); bzero(&tmp, sizeof(tmp)); for (i = 0; i < pmp->iroot->cluster.nchains; ++i) { hmp = pmp->pfs_hmps[i]; if (hmp == NULL) continue; if (pmp->iroot->cluster.array[i].chain) bref = pmp->iroot->cluster.array[i].chain->bref; else bzero(&bref, sizeof(bref)); tmp.f_files = bref.embed.stats.inode_count; tmp.f_ffree = 0; tmp.f_blocks = hmp->voldata.allocator_size / mp->mnt_vstat.f_bsize; tmp.f_bfree = hmp->voldata.allocator_free / mp->mnt_vstat.f_bsize; tmp.f_bavail = tmp.f_bfree; if (cred && cred->cr_uid != 0) { uint64_t adj; /* 5% */ adj = hmp->free_reserved / mp->mnt_vstat.f_bsize; tmp.f_blocks -= adj; tmp.f_bfree -= adj; tmp.f_bavail -= adj; } mp->mnt_vstat.f_blocks = tmp.f_blocks; mp->mnt_vstat.f_bfree = tmp.f_bfree; mp->mnt_vstat.f_bavail = tmp.f_bavail; mp->mnt_vstat.f_files = tmp.f_files; mp->mnt_vstat.f_ffree = tmp.f_ffree; *sbp = mp->mnt_vstat; } return (0); } /* * Mount-time recovery (RW mounts) * * Updates to the free block table are allowed to lag flushes by one * transaction. In case of a crash, then on a fresh mount we must do an * incremental scan of the last committed transaction id and make sure that * all related blocks have been marked allocated. */ struct hammer2_recovery_elm { TAILQ_ENTRY(hammer2_recovery_elm) entry; hammer2_chain_t *chain; hammer2_tid_t sync_tid; }; TAILQ_HEAD(hammer2_recovery_list, hammer2_recovery_elm); struct hammer2_recovery_info { struct hammer2_recovery_list list; hammer2_tid_t mtid; int depth; }; static int hammer2_recovery_scan(hammer2_dev_t *hmp, hammer2_chain_t *parent, struct hammer2_recovery_info *info, hammer2_tid_t sync_tid); #define HAMMER2_RECOVERY_MAXDEPTH 10 static int hammer2_recovery(hammer2_dev_t *hmp) { struct hammer2_recovery_info info; struct hammer2_recovery_elm *elm; hammer2_chain_t *parent; hammer2_tid_t sync_tid; hammer2_tid_t mirror_tid; int error; hammer2_trans_init(hmp->spmp, 0); sync_tid = hmp->voldata.freemap_tid; mirror_tid = hmp->voldata.mirror_tid; kprintf("hammer2_mount: \"%s\": ", hmp->devrepname); if (sync_tid >= mirror_tid) { kprintf("no recovery needed\n"); } else { kprintf("freemap recovery %016jx-%016jx\n", sync_tid + 1, mirror_tid); } TAILQ_INIT(&info.list); info.depth = 0; parent = hammer2_chain_lookup_init(&hmp->vchain, 0); error = hammer2_recovery_scan(hmp, parent, &info, sync_tid); hammer2_chain_lookup_done(parent); while ((elm = TAILQ_FIRST(&info.list)) != NULL) { TAILQ_REMOVE(&info.list, elm, entry); parent = elm->chain; sync_tid = elm->sync_tid; kfree(elm, M_HAMMER2); hammer2_chain_lock(parent, HAMMER2_RESOLVE_ALWAYS); error |= hammer2_recovery_scan(hmp, parent, &info, hmp->voldata.freemap_tid); hammer2_chain_unlock(parent); hammer2_chain_drop(parent); /* drop elm->chain ref */ } hammer2_trans_done(hmp->spmp, 0); return error; } static int hammer2_recovery_scan(hammer2_dev_t *hmp, hammer2_chain_t *parent, struct hammer2_recovery_info *info, hammer2_tid_t sync_tid) { const hammer2_inode_data_t *ripdata; hammer2_chain_t *chain; hammer2_blockref_t bref; int tmp_error; int rup_error; int error; int first; /* * Adjust freemap to ensure that the block(s) are marked allocated. */ if (parent->bref.type != HAMMER2_BREF_TYPE_VOLUME) { hammer2_freemap_adjust(hmp, &parent->bref, HAMMER2_FREEMAP_DORECOVER); } /* * Check type for recursive scan */ switch(parent->bref.type) { case HAMMER2_BREF_TYPE_VOLUME: /* data already instantiated */ break; case HAMMER2_BREF_TYPE_INODE: /* * Must instantiate data for DIRECTDATA test and also * for recursion. */ hammer2_chain_lock(parent, HAMMER2_RESOLVE_ALWAYS); ripdata = &parent->data->ipdata; if (ripdata->meta.op_flags & HAMMER2_OPFLAG_DIRECTDATA) { /* not applicable to recovery scan */ hammer2_chain_unlock(parent); return 0; } hammer2_chain_unlock(parent); break; case HAMMER2_BREF_TYPE_INDIRECT: /* * Must instantiate data for recursion */ hammer2_chain_lock(parent, HAMMER2_RESOLVE_ALWAYS); hammer2_chain_unlock(parent); break; case HAMMER2_BREF_TYPE_DIRENT: case HAMMER2_BREF_TYPE_DATA: case HAMMER2_BREF_TYPE_FREEMAP: case HAMMER2_BREF_TYPE_FREEMAP_NODE: case HAMMER2_BREF_TYPE_FREEMAP_LEAF: /* not applicable to recovery scan */ return 0; break; default: return HAMMER2_ERROR_BADBREF; } /* * Defer operation if depth limit reached. */ if (info->depth >= HAMMER2_RECOVERY_MAXDEPTH) { struct hammer2_recovery_elm *elm; elm = kmalloc(sizeof(*elm), M_HAMMER2, M_ZERO | M_WAITOK); elm->chain = parent; elm->sync_tid = sync_tid; hammer2_chain_ref(parent); TAILQ_INSERT_TAIL(&info->list, elm, entry); /* unlocked by caller */ return(0); } /* * Recursive scan of the last flushed transaction only. We are * doing this without pmp assignments so don't leave the chains * hanging around after we are done with them. * * error Cumulative error this level only * rup_error Cumulative error for recursion * tmp_error Specific non-cumulative recursion error */ chain = NULL; first = 1; rup_error = 0; error = 0; for (;;) { error |= hammer2_chain_scan(parent, &chain, &bref, &first, HAMMER2_LOOKUP_NODATA); /* * Problem during scan or EOF */ if (error) break; /* * If this is a leaf */ if (chain == NULL) { if (bref.mirror_tid > sync_tid) { hammer2_freemap_adjust(hmp, &bref, HAMMER2_FREEMAP_DORECOVER); } continue; } /* * This may or may not be a recursive node. */ atomic_set_int(&chain->flags, HAMMER2_CHAIN_RELEASE); if (bref.mirror_tid > sync_tid) { ++info->depth; tmp_error = hammer2_recovery_scan(hmp, chain, info, sync_tid); --info->depth; } else { tmp_error = 0; } /* * Flush the recovery at the PFS boundary to stage it for * the final flush of the super-root topology. */ if (tmp_error == 0 && (bref.flags & HAMMER2_BREF_FLAG_PFSROOT) && (chain->flags & HAMMER2_CHAIN_ONFLUSH)) { hammer2_flush(chain, HAMMER2_FLUSH_TOP | HAMMER2_FLUSH_ALL); } rup_error |= tmp_error; } return ((error | rup_error) & ~HAMMER2_ERROR_EOF); } /* * This fixes up an error introduced in earlier H2 implementations where * moving a PFS inode into an indirect block wound up causing the * HAMMER2_BREF_FLAG_PFSROOT flag in the bref to get cleared. */ static int hammer2_fixup_pfses(hammer2_dev_t *hmp) { const hammer2_inode_data_t *ripdata; hammer2_chain_t *parent; hammer2_chain_t *chain; hammer2_key_t key_next; hammer2_pfs_t *spmp; int error; error = 0; /* * Lookup mount point under the media-localized super-root. * * cluster->pmp will incorrectly point to spmp and must be fixed * up later on. */ spmp = hmp->spmp; hammer2_inode_lock(spmp->iroot, 0); parent = hammer2_inode_chain(spmp->iroot, 0, HAMMER2_RESOLVE_ALWAYS); chain = hammer2_chain_lookup(&parent, &key_next, HAMMER2_KEY_MIN, HAMMER2_KEY_MAX, &error, 0); while (chain) { if (chain->bref.type != HAMMER2_BREF_TYPE_INODE) continue; if (chain->error) { kprintf("I/O error scanning PFS labels\n"); error |= chain->error; } else if ((chain->bref.flags & HAMMER2_BREF_FLAG_PFSROOT) == 0) { int error2; ripdata = &chain->data->ipdata; hammer2_trans_init(hmp->spmp, 0); error2 = hammer2_chain_modify(chain, chain->bref.modify_tid, 0, 0); if (error2 == 0) { kprintf("hammer2: Correct mis-flagged PFS %s\n", ripdata->filename); chain->bref.flags |= HAMMER2_BREF_FLAG_PFSROOT; } else { error |= error2; } hammer2_flush(chain, HAMMER2_FLUSH_TOP | HAMMER2_FLUSH_ALL); hammer2_trans_done(hmp->spmp, 0); } chain = hammer2_chain_next(&parent, chain, &key_next, key_next, HAMMER2_KEY_MAX, &error, 0); } if (parent) { hammer2_chain_unlock(parent); hammer2_chain_drop(parent); } hammer2_inode_unlock(spmp->iroot); return error; } /* * Sync a mount point; this is called periodically on a per-mount basis from * the filesystem syncer, and whenever a user issues a sync. */ int hammer2_vfs_sync(struct mount *mp, int waitfor) { int error; error = hammer2_vfs_sync_pmp(MPTOPMP(mp), waitfor); return error; } /* * Because frontend operations lock vnodes before we get a chance to * lock the related inode, we can't just acquire a vnode lock without * risking a deadlock. The frontend may be holding a vnode lock while * also blocked on our SYNCQ flag while trying to get the inode lock. * * To deal with this situation we can check the vnode lock situation * after locking the inode and perform a work-around. */ int hammer2_vfs_sync_pmp(hammer2_pfs_t *pmp, int waitfor) { hammer2_inode_t *ip; hammer2_depend_t *depend; hammer2_depend_t *depend_next; struct vnode *vp; uint32_t pass2; int error; int wakecount; int dorestart; /* * Move all inodes on sideq to syncq. This will clear sideq. * This should represent all flushable inodes. These inodes * will already have refs due to being on syncq or sideq. We * must do this all at once with the spinlock held to ensure that * all inode dependencies are part of the same flush. * * We should be able to do this asynchronously from frontend * operations because we will be locking the inodes later on * to actually flush them, and that will partition any frontend * op using the same inode. Either it has already locked the * inode and we will block, or it has not yet locked the inode * and it will block until we are finished flushing that inode. * * When restarting, only move the inodes flagged as PASS2 from * SIDEQ to SYNCQ. PASS2 propagation by inode_lock4() and * inode_depend() are atomic with the spin-lock. */ hammer2_trans_init(pmp, HAMMER2_TRANS_ISFLUSH); #ifdef HAMMER2_DEBUG_SYNC kprintf("FILESYSTEM SYNC BOUNDARY\n"); #endif dorestart = 0; /* * Move inodes from depq to syncq, releasing the related * depend structures. */ restart: #ifdef HAMMER2_DEBUG_SYNC kprintf("FILESYSTEM SYNC RESTART (%d)\n", dorestart); #endif hammer2_trans_setflags(pmp, 0/*HAMMER2_TRANS_COPYQ*/); hammer2_trans_clearflags(pmp, HAMMER2_TRANS_RESCAN); /* * Move inodes from depq to syncq. When restarting, only depq's * marked pass2 are moved. */ hammer2_spin_ex(&pmp->list_spin); depend_next = TAILQ_FIRST(&pmp->depq); wakecount = 0; while ((depend = depend_next) != NULL) { depend_next = TAILQ_NEXT(depend, entry); if (dorestart && depend->pass2 == 0) continue; TAILQ_FOREACH(ip, &depend->sideq, entry) { KKASSERT(ip->flags & HAMMER2_INODE_SIDEQ); atomic_set_int(&ip->flags, HAMMER2_INODE_SYNCQ); atomic_clear_int(&ip->flags, HAMMER2_INODE_SIDEQ); ip->depend = NULL; } /* * NOTE: pmp->sideq_count includes both sideq and syncq */ TAILQ_CONCAT(&pmp->syncq, &depend->sideq, entry); depend->count = 0; depend->pass2 = 0; TAILQ_REMOVE(&pmp->depq, depend, entry); } hammer2_spin_unex(&pmp->list_spin); hammer2_trans_clearflags(pmp, /*HAMMER2_TRANS_COPYQ |*/ HAMMER2_TRANS_WAITING); dorestart = 0; /* * sideq_count may have dropped enough to allow us to unstall * the frontend. */ hammer2_pfs_memory_wakeup(pmp, 0); /* * Now run through all inodes on syncq. * * Flush transactions only interlock with other flush transactions. * Any conflicting frontend operations will block on the inode, but * may hold a vnode lock while doing so. */ hammer2_spin_ex(&pmp->list_spin); while ((ip = TAILQ_FIRST(&pmp->syncq)) != NULL) { /* * Remove the inode from the SYNCQ, transfer the syncq ref * to us. We must clear SYNCQ to allow any potential * front-end deadlock to proceed. We must set PASS2 so * the dependency code knows what to do. */ pass2 = ip->flags; cpu_ccfence(); if (atomic_cmpset_int(&ip->flags, pass2, (pass2 & ~(HAMMER2_INODE_SYNCQ | HAMMER2_INODE_SYNCQ_WAKEUP)) | HAMMER2_INODE_SYNCQ_PASS2) == 0) { continue; } TAILQ_REMOVE(&pmp->syncq, ip, entry); --pmp->sideq_count; hammer2_spin_unex(&pmp->list_spin); /* * Tickle anyone waiting on ip->flags or the hysteresis * on the dirty inode count. */ if (pass2 & HAMMER2_INODE_SYNCQ_WAKEUP) wakeup(&ip->flags); if (++wakecount >= hammer2_limit_dirty_inodes / 20 + 1) { wakecount = 0; hammer2_pfs_memory_wakeup(pmp, 0); } /* * Relock the inode, and we inherit a ref from the above. * We will check for a race after we acquire the vnode. */ hammer2_mtx_ex(&ip->lock); /* * We need the vp in order to vfsync() dirty buffers, so if * one isn't attached we can skip it. * * Ordering the inode lock and then the vnode lock has the * potential to deadlock. If we had left SYNCQ set that could * also deadlock us against the frontend even if we don't hold * any locks, but the latter is not a problem now since we * cleared it. igetv will temporarily release the inode lock * in a safe manner to work-around the deadlock. * * Unfortunately it is still possible to deadlock when the * frontend obtains multiple inode locks, because all the * related vnodes are already locked (nor can the vnode locks * be released and reacquired without messing up RECLAIM and * INACTIVE sequencing). * * The solution for now is to move the vp back onto SIDEQ * and set dorestart, which will restart the flush after we * exhaust the current SYNCQ. Note that additional * dependencies may build up, so we definitely need to move * the whole SIDEQ back to SYNCQ when we restart. */ vp = ip->vp; if (vp) { if (vget(vp, LK_EXCLUSIVE|LK_NOWAIT)) { /* * Failed to get the vnode, requeue the inode * (PASS2 is already set so it will be found * again on the restart). * * Then unlock, possibly sleep, and retry * later. We sleep if PASS2 was *previously* * set, before we set it again above. */ vp = NULL; dorestart = 1; #ifdef HAMMER2_DEBUG_SYNC kprintf("inum %ld (sync delayed by vnode)\n", (long)ip->meta.inum); #endif hammer2_inode_delayed_sideq(ip); hammer2_mtx_unlock(&ip->lock); hammer2_inode_drop(ip); if (pass2 & HAMMER2_INODE_SYNCQ_PASS2) { tsleep(&dorestart, 0, "h2syndel", 2); } hammer2_spin_ex(&pmp->list_spin); continue; } } else { vp = NULL; } /* * If the inode wound up on a SIDEQ again it will already be * prepped for another PASS2. In this situation if we flush * it now we will just wind up flushing it again in the same * syncer run, so we might as well not flush it now. */ if (ip->flags & HAMMER2_INODE_SIDEQ) { hammer2_mtx_unlock(&ip->lock); hammer2_inode_drop(ip); if (vp) vput(vp); dorestart = 1; hammer2_spin_ex(&pmp->list_spin); continue; } /* * Ok we have the inode exclusively locked and if vp is * not NULL that will also be exclusively locked. Do the * meat of the flush. * * vp token needed for v_rbdirty_tree check / vclrisdirty * sequencing. Though we hold the vnode exclusively so * we shouldn't need to hold the token also in this case. */ if (vp) { vfsync(vp, MNT_WAIT, 1, NULL, NULL); bio_track_wait(NULL, 0, 0); /* XXX */ } /* * If the inode has not yet been inserted into the tree * we must do so. Then sync and flush it. The flush should * update the parent. */ if (ip->flags & HAMMER2_INODE_DELETING) { #ifdef HAMMER2_DEBUG_SYNC kprintf("inum %ld destroy\n", (long)ip->meta.inum); #endif hammer2_inode_chain_des(ip); atomic_add_long(&hammer2_iod_inode_deletes, 1); } else if (ip->flags & HAMMER2_INODE_CREATING) { #ifdef HAMMER2_DEBUG_SYNC kprintf("inum %ld insert\n", (long)ip->meta.inum); #endif hammer2_inode_chain_ins(ip); atomic_add_long(&hammer2_iod_inode_creates, 1); } #ifdef HAMMER2_DEBUG_SYNC kprintf("inum %ld chain-sync\n", (long)ip->meta.inum); #endif /* * Because I kinda messed up the design and index the inodes * under the root inode, along side the directory entries, * we can't flush the inode index under the iroot until the * end. If we do it now we might miss effects created by * other inodes on the SYNCQ. * * Do a normal (non-FSSYNC) flush instead, which allows the * vnode code to work the same. We don't want to force iroot * back onto the SIDEQ, and we also don't want the flush code * to update pfs_iroot_blocksets until the final flush later. * * XXX at the moment this will likely result in a double-flush * of the iroot chain. */ hammer2_inode_chain_sync(ip); if (ip == pmp->iroot) { hammer2_inode_chain_flush(ip, HAMMER2_XOP_INODE_STOP); } else { hammer2_inode_chain_flush(ip, HAMMER2_XOP_INODE_STOP | HAMMER2_XOP_FSSYNC); } if (vp) { lwkt_gettoken(NULL); if ((ip->flags & (HAMMER2_INODE_MODIFIED | HAMMER2_INODE_RESIZED | HAMMER2_INODE_DIRTYDATA)) == 0) { //RB_EMPTY(&vp->v_rbdirty_tree) && //!bio_track_active(&vp->v_track_write)) { vclrisdirty(vp); } else { hammer2_inode_delayed_sideq(ip); } lwkt_reltoken(NULL); vput(vp); vp = NULL; /* safety */ } atomic_clear_int(&ip->flags, HAMMER2_INODE_SYNCQ_PASS2); hammer2_inode_unlock(ip); /* unlock+drop */ /* ip pointer invalid */ /* * If the inode got dirted after we dropped our locks, * it will have already been moved back to the SIDEQ. */ hammer2_spin_ex(&pmp->list_spin); } hammer2_spin_unex(&pmp->list_spin); hammer2_pfs_memory_wakeup(pmp, 0); if (dorestart || (pmp->trans.flags & HAMMER2_TRANS_RESCAN)) { #ifdef HAMMER2_DEBUG_SYNC kprintf("FILESYSTEM SYNC STAGE 1 RESTART\n"); /*tsleep(&dorestart, 0, "h2STG1-R", hz*20);*/ #endif dorestart = 1; goto restart; } #ifdef HAMMER2_DEBUG_SYNC kprintf("FILESYSTEM SYNC STAGE 2 BEGIN\n"); /*tsleep(&dorestart, 0, "h2STG2", hz*20);*/ #endif /* * We have to flush the PFS root last, even if it does not appear to * be dirty, because all the inodes in the PFS are indexed under it. * The normal flushing of iroot above would only occur if directory * entries under the root were changed. * * Specifying VOLHDR will cause an additionl flush of hmp->spmp * for the media making up the cluster. */ if ((ip = pmp->iroot) != NULL) { hammer2_inode_ref(ip); hammer2_mtx_ex(&ip->lock); hammer2_inode_chain_sync(ip); hammer2_inode_chain_flush(ip, HAMMER2_XOP_INODE_STOP | HAMMER2_XOP_FSSYNC | HAMMER2_XOP_VOLHDR); hammer2_inode_unlock(ip); /* unlock+drop */ } #ifdef HAMMER2_DEBUG_SYNC kprintf("FILESYSTEM SYNC STAGE 2 DONE\n"); #endif /* * device bioq sync */ hammer2_bioq_sync(pmp); error = 0; /* XXX */ hammer2_trans_done(pmp, HAMMER2_TRANS_ISFLUSH); return (error); } #if 0 static int hammer2_vfs_vptofh(struct vnode *vp, struct fid *fhp) { hammer2_inode_t *ip; KKASSERT(MAXFIDSZ >= 16); ip = VTOI(vp); fhp->fid_len = offsetof(struct fid, fid_data[16]); fhp->fid_ext = 0; ((hammer2_tid_t *)fhp->fid_data)[0] = ip->meta.inum; ((hammer2_tid_t *)fhp->fid_data)[1] = 0; return 0; } static int hammer2_vfs_fhtovp(struct mount *mp, struct vnode *rootvp, struct fid *fhp, struct vnode **vpp) { hammer2_tid_t inum; int error; inum = ((hammer2_tid_t *)fhp->fid_data)[0] & HAMMER2_DIRHASH_USERMSK; if (vpp) { if (inum == 1) error = hammer2_vfs_root(mp, vpp); else error = hammer2_vfs_vget(mp, NULL, inum, vpp); } else { error = 0; } return error; } static int hammer2_vfs_checkexp(struct mount *mp, struct sockaddr *nam, int *exflagsp, struct ucred **credanonp) { hammer2_pfs_t *pmp; struct netcred *np; int error; pmp = MPTOPMP(mp); np = vfs_export_lookup(mp, &pmp->export, nam); if (np) { *exflagsp = np->netc_exflags; *credanonp = &np->netc_anon; error = 0; } else { error = EACCES; } return error; } #endif /* * This handles hysteresis on regular file flushes. Because the BIOs are * routed to a thread it is possible for an excessive number to build up * and cause long front-end stalls long before the runningbuffspace limit * is hit, so we implement hammer2_flush_pipe to control the * hysteresis. * * This is a particular problem when compression is used. */ void hammer2_lwinprog_ref(hammer2_pfs_t *pmp) { atomic_add_int(&pmp->count_lwinprog, 1); } void hammer2_lwinprog_drop(hammer2_pfs_t *pmp) { #if 0 int lwinprog; lwinprog = atomic_fetchadd_int(&pmp->count_lwinprog, -1); if ((lwinprog & HAMMER2_LWINPROG_WAITING) && (lwinprog & HAMMER2_LWINPROG_MASK) <= hammer2_flush_pipe * 2 / 3) { atomic_clear_int(&pmp->count_lwinprog, HAMMER2_LWINPROG_WAITING); wakeup(&pmp->count_lwinprog); } if ((lwinprog & HAMMER2_LWINPROG_WAITING0) && (lwinprog & HAMMER2_LWINPROG_MASK) <= 0) { atomic_clear_int(&pmp->count_lwinprog, HAMMER2_LWINPROG_WAITING0); wakeup(&pmp->count_lwinprog); } #endif } void hammer2_lwinprog_wait(hammer2_pfs_t *pmp, int flush_pipe) { #if 0 int lwinprog; int lwflag = (flush_pipe) ? HAMMER2_LWINPROG_WAITING : HAMMER2_LWINPROG_WAITING0; for (;;) { lwinprog = pmp->count_lwinprog; cpu_ccfence(); if ((lwinprog & HAMMER2_LWINPROG_MASK) <= flush_pipe) break; tsleep_interlock(&pmp->count_lwinprog, 0); atomic_set_int(&pmp->count_lwinprog, lwflag); lwinprog = pmp->count_lwinprog; if ((lwinprog & HAMMER2_LWINPROG_MASK) <= flush_pipe) break; tsleep(&pmp->count_lwinprog, PINTERLOCKED, "h2wpipe", hz); } #endif } #if 0 /* * It is possible for an excessive number of dirty chains or dirty inodes * to build up. When this occurs we start an asynchronous filesystem sync. * If the level continues to build up, we stall, waiting for it to drop, * with some hysteresis. * * This relies on the kernel calling hammer2_vfs_modifying() prior to * obtaining any vnode locks before making a modifying VOP call. */ static int hammer2_vfs_modifying(struct mount *mp) { if (mp->mnt_flag & MNT_RDONLY) return EROFS; hammer2_pfs_memory_wait(MPTOPMP(mp)); return 0; } #endif /* * Initiate an asynchronous filesystem sync and, with hysteresis, * stall if the internal data structure count becomes too bloated. */ void hammer2_pfs_memory_wait(hammer2_pfs_t *pmp) { uint32_t waiting; int pcatch; int error; if (pmp == NULL || pmp->mp == NULL) return; for (;;) { waiting = pmp->inmem_dirty_chains & HAMMER2_DIRTYCHAIN_MASK; cpu_ccfence(); /* * Start the syncer running at 1/2 the limit */ if (waiting > hammer2_limit_dirty_chains / 2 || pmp->sideq_count > hammer2_limit_dirty_inodes / 2) { trigger_syncer(pmp->mp); } /* * Stall at the limit waiting for the counts to drop. * This code will typically be woken up once the count * drops below 3/4 the limit, or in one second. */ if (waiting < hammer2_limit_dirty_chains && pmp->sideq_count < hammer2_limit_dirty_inodes) { break; } pcatch = curthread->td_proc ? PCATCH : 0; tsleep_interlock(&pmp->inmem_dirty_chains, pcatch); atomic_set_int(&pmp->inmem_dirty_chains, HAMMER2_DIRTYCHAIN_WAITING); if (waiting < hammer2_limit_dirty_chains && pmp->sideq_count < hammer2_limit_dirty_inodes) { break; } trigger_syncer(pmp->mp); error = tsleep(&pmp->inmem_dirty_chains, PINTERLOCKED | pcatch, "h2memw", hz); if (error == ERESTART) break; } } /* * Wake up any stalled frontend ops waiting, with hysteresis, using * 2/3 of the limit. */ void hammer2_pfs_memory_wakeup(hammer2_pfs_t *pmp, int count) { uint32_t waiting; if (pmp) { waiting = atomic_fetchadd_int(&pmp->inmem_dirty_chains, count); /* don't need --waiting to test flag */ if ((waiting & HAMMER2_DIRTYCHAIN_WAITING) && (pmp->inmem_dirty_chains & HAMMER2_DIRTYCHAIN_MASK) <= hammer2_limit_dirty_chains * 2 / 3 && pmp->sideq_count <= hammer2_limit_dirty_inodes * 2 / 3) { atomic_clear_int(&pmp->inmem_dirty_chains, HAMMER2_DIRTYCHAIN_WAITING); wakeup(&pmp->inmem_dirty_chains); } } } void hammer2_pfs_memory_inc(hammer2_pfs_t *pmp) { if (pmp) { atomic_add_int(&pmp->inmem_dirty_chains, 1); } } /* * Volume header data locks */ void hammer2_voldata_lock(hammer2_dev_t *hmp) { lockmgr(&hmp->vollk, LK_EXCLUSIVE); } void hammer2_voldata_unlock(hammer2_dev_t *hmp) { lockmgr(&hmp->vollk, LK_RELEASE); } /* * Caller indicates that the volume header is being modified. Flag * the related chain and adjust its transaction id. * * The transaction id is set to voldata.mirror_tid + 1, similar to * what hammer2_chain_modify() does. Be very careful here, volume * data can be updated independently of the rest of the filesystem. */ void hammer2_voldata_modify(hammer2_dev_t *hmp) { if ((hmp->vchain.flags & HAMMER2_CHAIN_MODIFIED) == 0) { atomic_add_long(&hammer2_count_modified_chains, 1); atomic_set_int(&hmp->vchain.flags, HAMMER2_CHAIN_MODIFIED); hammer2_pfs_memory_inc(hmp->vchain.pmp); hmp->vchain.bref.mirror_tid = hmp->voldata.mirror_tid + 1; } } /* * Returns 0 if the filesystem has tons of free space * Returns 1 if the filesystem has less than 10% remaining * Returns 2 if the filesystem has less than 2%/5% (user/root) remaining. */ int hammer2_vfs_enospace(hammer2_inode_t *ip, off_t bytes, struct ucred *cred) { hammer2_pfs_t *pmp; hammer2_dev_t *hmp; hammer2_off_t free_reserved; hammer2_off_t free_nominal; int i; pmp = ip->pmp; if (/*XXX*/ 1 || pmp->free_ticks == 0 || pmp->free_ticks != ticks) { free_reserved = HAMMER2_SEGSIZE; free_nominal = 0x7FFFFFFFFFFFFFFFLLU; for (i = 0; i < pmp->iroot->cluster.nchains; ++i) { hmp = pmp->pfs_hmps[i]; if (hmp == NULL) continue; if (pmp->pfs_types[i] != HAMMER2_PFSTYPE_MASTER && pmp->pfs_types[i] != HAMMER2_PFSTYPE_SOFT_MASTER) continue; if (free_nominal > hmp->voldata.allocator_free) free_nominal = hmp->voldata.allocator_free; if (free_reserved < hmp->free_reserved) free_reserved = hmp->free_reserved; } /* * SMP races ok */ pmp->free_reserved = free_reserved; pmp->free_nominal = free_nominal; pmp->free_ticks = ticks; } else { free_reserved = pmp->free_reserved; free_nominal = pmp->free_nominal; } if (cred && cred->cr_uid != 0) { if ((int64_t)(free_nominal - bytes) < (int64_t)free_reserved) { return 2; } } else { if ((int64_t)(free_nominal - bytes) < (int64_t)free_reserved / 2) { return 2; } } if ((int64_t)(free_nominal - bytes) < (int64_t)free_reserved * 2) return 1; return 0; } /* * Debugging */ void hammer2_dump_chain(hammer2_chain_t *chain, int tab, int bi, int *countp, char pfx, u_int flags) { hammer2_chain_t *scan; hammer2_chain_t *parent; if (hammer2_debug & 0x80000000) *countp = INT_MAX; --*countp; if (*countp == 0) { kprintf("%*.*s...\n", tab, tab, ""); return; } if (*countp < 0) return; kprintf("%*.*s%c-chain %p %s.%-3d %016jx %016jx/%-2d mir=%016jx\n", tab, tab, "", pfx, chain, hammer2_bref_type_str(chain->bref.type), bi, chain->bref.data_off, chain->bref.key, chain->bref.keybits, chain->bref.mirror_tid); kprintf("%*.*s [%08x] (%s) refs=%d", tab, tab, "", chain->flags, ((chain->bref.type == HAMMER2_BREF_TYPE_INODE && chain->data) ? (char *)chain->data->ipdata.filename : "?"), chain->refs); parent = chain->parent; if (parent) kprintf("\n%*.*s p=%p [pflags %08x prefs %d]", tab, tab, "", parent, parent->flags, parent->refs); if (RB_EMPTY(&chain->core.rbtree)) { kprintf("\n"); } else { int bi = 0; kprintf(" {\n"); RB_FOREACH(scan, hammer2_chain_tree, &chain->core.rbtree) { if ((scan->flags & flags) || flags == (u_int)-1) { hammer2_dump_chain(scan, tab + 4, bi, countp, 'a', flags); } bi++; } if (chain->bref.type == HAMMER2_BREF_TYPE_INODE && chain->data) kprintf("%*.*s}(%s)\n", tab, tab, "", chain->data->ipdata.filename); else kprintf("%*.*s}\n", tab, tab, ""); } } void hammer2_dump_chains(hammer2_dev_t *hmp, char vpfx, char fpfx) { int dumpcnt; dumpcnt = 50; hammer2_dump_chain(&hmp->vchain, 0, 0, &dumpcnt, vpfx, (u_int)-1); dumpcnt = 50; hammer2_dump_chain(&hmp->fchain, 0, 0, &dumpcnt, fpfx, (u_int)-1); }