2 * Copyright (c) 2011-2015 The DragonFly Project. All rights reserved.
4 * This code is derived from software contributed to The DragonFly Project
5 * by Matthew Dillon <dillon@dragonflybsd.org>
6 * by Venkatesh Srinivas <vsrinivas@dragonflybsd.org>
8 * Redistribution and use in source and binary forms, with or without
9 * modification, are permitted provided that the following conditions
12 * 1. Redistributions of source code must retain the above copyright
13 * notice, this list of conditions and the following disclaimer.
14 * 2. Redistributions in binary form must reproduce the above copyright
15 * notice, this list of conditions and the following disclaimer in
16 * the documentation and/or other materials provided with the
18 * 3. Neither the name of The DragonFly Project nor the names of its
19 * contributors may be used to endorse or promote products derived
20 * from this software without specific, prior written permission.
22 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
23 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
24 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
25 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
26 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
27 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
28 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
29 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
30 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
31 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
32 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
37 * HAMMER2 IN-MEMORY CACHE OF MEDIA STRUCTURES
39 * This header file contains structures used internally by the HAMMER2
40 * implementation. See hammer2_disk.h for on-disk structures.
42 * There is an in-memory representation of all on-media data structure.
43 * Almost everything is represented by a hammer2_chain structure in-memory.
44 * Other higher-level structures typically map to chains.
46 * A great deal of data is accessed simply via its buffer cache buffer,
47 * which is mapped for the duration of the chain's lock. Hammer2 must
48 * implement its own buffer cache layer on top of the system layer to
49 * allow for different threads to lock different sub-block-sized buffers.
51 * When modifications are made to a chain a new filesystem block must be
52 * allocated. Multiple modifications do not typically allocate new blocks
53 * until the current block has been flushed. Flushes do not block the
54 * front-end unless the front-end operation crosses the current inode being
57 * The in-memory representation may remain cached (for example in order to
58 * placemark clustering locks) even after the related data has been
62 #ifndef _VFS_HAMMER2_HAMMER2_H_
63 #define _VFS_HAMMER2_HAMMER2_H_
65 #include <sys/param.h>
66 #include <sys/types.h>
67 #include <sys/kernel.h>
69 #include <sys/systm.h>
71 #include <sys/malloc.h>
72 #include <sys/mount.h>
73 #include <sys/vnode.h>
75 #include <sys/mountctl.h>
78 #include <sys/thread.h>
79 #include <sys/globaldata.h>
80 #include <sys/lockf.h>
82 #include <sys/queue.h>
83 #include <sys/limits.h>
85 #include <sys/mutex.h>
86 #include <sys/kern_syscall.h>
88 #include <sys/signal2.h>
90 #include <sys/mutex2.h>
91 #include <sys/thread2.h>
93 #include "hammer2_disk.h"
94 #include "hammer2_mount.h"
95 #include "hammer2_ioctl.h"
100 struct hammer2_cluster;
101 struct hammer2_inode;
105 struct hammer2_state;
109 * Mutex and lock shims. Hammer2 requires support for asynchronous and
110 * abortable locks, and both exclusive and shared spinlocks. Normal
111 * synchronous non-abortable locks can be substituted for spinlocks.
113 typedef mtx_t hammer2_mtx_t;
114 typedef mtx_link_t hammer2_mtx_link_t;
115 typedef mtx_state_t hammer2_mtx_state_t;
117 typedef struct spinlock hammer2_spin_t;
119 #define hammer2_mtx_ex mtx_lock_ex_quick
120 #define hammer2_mtx_sh mtx_lock_sh_quick
121 #define hammer2_mtx_unlock mtx_unlock
122 #define hammer2_mtx_owned mtx_owned
123 #define hammer2_mtx_init mtx_init
124 #define hammer2_mtx_temp_release mtx_lock_temp_release
125 #define hammer2_mtx_temp_restore mtx_lock_temp_restore
126 #define hammer2_mtx_refs mtx_lockrefs
128 #define hammer2_spin_init spin_init
129 #define hammer2_spin_sh spin_lock_shared
130 #define hammer2_spin_ex spin_lock
131 #define hammer2_spin_unsh spin_unlock_shared
132 #define hammer2_spin_unex spin_unlock
135 * General lock support
139 hammer2_mtx_upgrade(hammer2_mtx_t *mtx)
143 if (mtx_islocked_ex(mtx)) {
147 mtx_lock_ex_quick(mtx);
154 * Downgrade an inode lock from exclusive to shared only if the inode
155 * lock was previously shared. If the inode lock was previously exclusive,
160 hammer2_mtx_downgrade(hammer2_mtx_t *mtx, int wasexclusive)
162 if (wasexclusive == 0)
167 * The xid tracks internal transactional updates.
169 * XXX fix-me, really needs to be 64-bits
171 typedef uint32_t hammer2_xid_t;
173 #define HAMMER2_XID_MIN 0x00000000U
174 #define HAMMER2_XID_MAX 0x7FFFFFFFU
177 * The chain structure tracks a portion of the media topology from the
178 * root (volume) down. Chains represent volumes, inodes, indirect blocks,
179 * data blocks, and freemap nodes and leafs.
181 * The chain structure utilizes a simple singly-homed topology and the
182 * chain's in-memory topology will move around as the chains do, due mainly
183 * to renames and indirect block creation.
185 * Block Table Updates
187 * Block table updates for insertions and updates are delayed until the
188 * flush. This allows us to avoid having to modify the parent chain
189 * all the way to the root.
191 * Block table deletions are performed immediately (modifying the parent
192 * in the process) because the flush code uses the chain structure to
193 * track delayed updates and the chain will be (likely) gone or moved to
194 * another location in the topology after a deletion.
196 * A prior iteration of the code tried to keep the relationship intact
197 * on deletes by doing a delete-duplicate operation on the chain, but
198 * it added way too much complexity to the codebase.
200 * Flush Synchronization
202 * The flush code must flush modified chains bottom-up. Because chain
203 * structures can shift around and are NOT topologically stable,
204 * modified chains are independently indexed for the flush. As the flush
205 * runs it modifies (or further modifies) and updates the parents,
206 * propagating the flush all the way to the volume root.
208 * Modifying front-end operations can occur during a flush but will block
209 * in two cases: (1) when the front-end tries to operate on the inode
210 * currently in the midst of being flushed and (2) if the front-end
211 * crosses an inode currently being flushed (such as during a rename).
212 * So, for example, if you rename directory "x" to "a/b/c/d/e/f/g/x" and
213 * the flusher is currently working on "a/b/c", the rename will block
214 * temporarily in order to ensure that "x" exists in one place or the
217 * Meta-data statistics are updated by the flusher. The front-end will
218 * make estimates but meta-data must be fully synchronized only during a
219 * flush in order to ensure that it remains correct across a crash.
221 * Multiple flush synchronizations can theoretically be in-flight at the
222 * same time but the implementation is not coded to handle the case and
223 * currently serializes them.
227 * Snapshots currently require the subdirectory tree being snapshotted
228 * to be flushed. The snapshot then creates a new super-root inode which
229 * copies the flushed blockdata of the directory or file that was
234 * - Note that the radix tree runs in powers of 2 only so sub-trees
235 * cannot straddle edges.
237 RB_HEAD(hammer2_chain_tree, hammer2_chain);
238 TAILQ_HEAD(h2_flush_list, hammer2_chain);
239 TAILQ_HEAD(h2_core_list, hammer2_chain);
240 TAILQ_HEAD(h2_iocb_list, hammer2_iocb);
242 #define CHAIN_CORE_DELETE_BMAP_ENTRIES \
243 (HAMMER2_PBUFSIZE / sizeof(hammer2_blockref_t) / sizeof(uint32_t))
245 struct hammer2_chain_core {
248 struct hammer2_chain_tree rbtree; /* sub-chains */
249 int live_zero; /* blockref array opt */
251 u_int live_count; /* live (not deleted) chains in tree */
252 u_int chain_count; /* live + deleted chains under core */
253 int generation; /* generation number (inserts only) */
256 typedef struct hammer2_chain_core hammer2_chain_core_t;
258 #define HAMMER2_CORE_UNUSED0001 0x0001
259 #define HAMMER2_CORE_COUNTEDBREFS 0x0002
261 RB_HEAD(hammer2_io_tree, hammer2_io);
264 * IOCB - IO callback (into chain, cluster, or manual request)
266 struct hammer2_iocb {
267 TAILQ_ENTRY(hammer2_iocb) entry;
268 void (*callback)(struct hammer2_iocb *iocb);
269 struct hammer2_io *dio;
270 struct hammer2_cluster *cluster;
271 struct hammer2_chain *chain;
279 typedef struct hammer2_iocb hammer2_iocb_t;
281 #define HAMMER2_IOCB_INTERLOCK 0x00000001
282 #define HAMMER2_IOCB_ONQ 0x00000002
283 #define HAMMER2_IOCB_DONE 0x00000004
284 #define HAMMER2_IOCB_INPROG 0x00000008
285 #define HAMMER2_IOCB_UNUSED10 0x00000010
286 #define HAMMER2_IOCB_QUICK 0x00010000
287 #define HAMMER2_IOCB_ZERO 0x00020000
288 #define HAMMER2_IOCB_READ 0x00040000
289 #define HAMMER2_IOCB_WAKEUP 0x00080000
292 * DIO - Management structure wrapping system buffer cache.
294 * Used for multiple purposes including concurrent management
295 * if small requests by chains into larger DIOs.
298 RB_ENTRY(hammer2_io) rbnode; /* indexed by device offset */
299 struct h2_iocb_list iocbq;
300 struct spinlock spin;
301 struct hammer2_dev *hmp;
306 int act; /* activity */
309 typedef struct hammer2_io hammer2_io_t;
311 #define HAMMER2_DIO_INPROG 0x80000000 /* bio in progress */
312 #define HAMMER2_DIO_GOOD 0x40000000 /* dio->bp is stable */
313 #define HAMMER2_DIO_WAITING 0x20000000 /* (old) */
314 #define HAMMER2_DIO_DIRTY 0x10000000 /* flush on last drop */
316 #define HAMMER2_DIO_MASK 0x0FFFFFFF
319 * Primary chain structure keeps track of the topology in-memory.
321 struct hammer2_chain {
322 hammer2_chain_core_t core;
323 RB_ENTRY(hammer2_chain) rbnode; /* live chain(s) */
324 hammer2_blockref_t bref;
325 struct hammer2_chain *parent;
326 struct hammer2_state *state; /* if active cache msg */
327 struct hammer2_dev *hmp;
328 struct hammer2_pfs *pmp; /* A PFS or super-root (spmp) */
330 hammer2_xid_t flush_xid; /* flush sequencing */
331 hammer2_key_t data_count; /* delta's to apply */
332 hammer2_key_t inode_count; /* delta's to apply */
333 hammer2_key_t data_count_up; /* delta's to apply */
334 hammer2_key_t inode_count_up; /* delta's to apply */
335 hammer2_io_t *dio; /* physical data buffer */
336 u_int bytes; /* physical data size */
340 int error; /* on-lock data error state */
342 hammer2_media_data_t *data; /* data pointer shortcut */
343 TAILQ_ENTRY(hammer2_chain) flush_node; /* flush list */
346 typedef struct hammer2_chain hammer2_chain_t;
348 int hammer2_chain_cmp(hammer2_chain_t *chain1, hammer2_chain_t *chain2);
349 RB_PROTOTYPE(hammer2_chain_tree, hammer2_chain, rbnode, hammer2_chain_cmp);
352 * Special notes on flags:
354 * INITIAL - This flag allows a chain to be created and for storage to
355 * be allocated without having to immediately instantiate the
356 * related buffer. The data is assumed to be all-zeros. It
357 * is primarily used for indirect blocks.
359 * MODIFIED - The chain's media data has been modified.
361 * UPDATE - Chain might not be modified but parent blocktable needs update
363 * FICTITIOUS - Faked chain as a placeholder for an error condition. This
364 * chain is unsuitable for I/O.
366 * BMAPPED - Indicates that the chain is present in the parent blockmap.
368 * BMAPUPD - Indicates that the chain is present but needs to be updated
369 * in the parent blockmap.
371 #define HAMMER2_CHAIN_MODIFIED 0x00000001 /* dirty chain data */
372 #define HAMMER2_CHAIN_ALLOCATED 0x00000002 /* kmalloc'd chain */
373 #define HAMMER2_CHAIN_DESTROY 0x00000004
374 #define HAMMER2_CHAIN_UNLINKED 0x00000008 /* unlinked file */
375 #define HAMMER2_CHAIN_DELETED 0x00000010 /* deleted chain */
376 #define HAMMER2_CHAIN_INITIAL 0x00000020 /* initial create */
377 #define HAMMER2_CHAIN_UPDATE 0x00000040 /* need parent update */
378 #define HAMMER2_CHAIN_DEFERRED 0x00000080 /* flush depth defer */
379 #define HAMMER2_CHAIN_IOFLUSH 0x00000100 /* bawrite on put */
380 #define HAMMER2_CHAIN_ONFLUSH 0x00000200 /* on a flush list */
381 #define HAMMER2_CHAIN_FICTITIOUS 0x00000400 /* unsuitable for I/O */
382 #define HAMMER2_CHAIN_VOLUMESYNC 0x00000800 /* needs volume sync */
383 #define HAMMER2_CHAIN_UNUSED00001000 0x00001000
384 #define HAMMER2_CHAIN_UNUSED00002000 0x00002000
385 #define HAMMER2_CHAIN_ONRBTREE 0x00004000 /* on parent RB tree */
386 #define HAMMER2_CHAIN_UNUSED00008000 0x00008000
387 #define HAMMER2_CHAIN_EMBEDDED 0x00010000 /* embedded data */
388 #define HAMMER2_CHAIN_RELEASE 0x00020000 /* don't keep around */
389 #define HAMMER2_CHAIN_BMAPPED 0x00040000 /* present in blkmap */
390 #define HAMMER2_CHAIN_BMAPUPD 0x00080000 /* +needs updating */
391 #define HAMMER2_CHAIN_UNUSED00100000 0x00100000
392 #define HAMMER2_CHAIN_UNUSED00200000 0x00200000
393 #define HAMMER2_CHAIN_PFSBOUNDARY 0x00400000 /* super->pfs inode */
395 #define HAMMER2_CHAIN_FLUSH_MASK (HAMMER2_CHAIN_MODIFIED | \
396 HAMMER2_CHAIN_UPDATE | \
397 HAMMER2_CHAIN_ONFLUSH)
400 * Hammer2 error codes, used by chain->error and cluster->error. The error
401 * code is typically set on-lock unless no I/O was requested, and set on
402 * I/O otherwise. If set for a cluster it generally means that the cluster
403 * code could not find a valid copy to present.
405 * IO - An I/O error occurred
406 * CHECK - I/O succeeded but did not match the check code
407 * INCOMPLETE - A cluster is not complete enough to use, or
408 * a chain cannot be loaded because its parent has an error.
410 * NOTE: API allows callers to check zero/non-zero to determine if an error
413 * NOTE: Chain's data field is usually NULL on an IO error but not necessarily
414 * NULL on other errors. Check chain->error, not chain->data.
416 #define HAMMER2_ERROR_NONE 0
417 #define HAMMER2_ERROR_IO 1 /* device I/O error */
418 #define HAMMER2_ERROR_CHECK 2 /* check code mismatch */
419 #define HAMMER2_ERROR_INCOMPLETE 3 /* incomplete cluster */
420 #define HAMMER2_ERROR_DEPTH 4 /* temporary depth limit */
423 * Flags passed to hammer2_chain_lookup() and hammer2_chain_next()
425 * NOTE: MATCHIND allows an indirect block / freemap node to be returned
426 * when the passed key range matches the radix. Remember that key_end
427 * is inclusive (e.g. {0x000,0xFFF}, not {0x000,0x1000}).
429 * NOTE: NODIRECT prevents a lookup of offset 0 in an inode from returning
430 * the inode itself if the inode is in DIRECTDATA mode (i.e. file is
433 #define HAMMER2_LOOKUP_NOLOCK 0x00000001 /* ref only */
434 #define HAMMER2_LOOKUP_NODATA 0x00000002 /* data left NULL */
435 #define HAMMER2_LOOKUP_NODIRECT 0x00000004 /* no offset=0 DD */
436 #define HAMMER2_LOOKUP_SHARED 0x00000100
437 #define HAMMER2_LOOKUP_MATCHIND 0x00000200 /* return all chains */
438 #define HAMMER2_LOOKUP_ALLNODES 0x00000400 /* allow NULL focus */
439 #define HAMMER2_LOOKUP_ALWAYS 0x00000800 /* resolve data */
442 * Flags passed to hammer2_chain_modify() and hammer2_chain_resize()
444 * NOTE: OPTDATA allows us to avoid instantiating buffers for INDIRECT
445 * blocks in the INITIAL-create state.
447 #define HAMMER2_MODIFY_OPTDATA 0x00000002 /* data can be NULL */
448 #define HAMMER2_MODIFY_NO_MODIFY_TID 0x00000004
449 #define HAMMER2_MODIFY_UNUSED0008 0x00000008
450 #define HAMMER2_MODIFY_NOREALLOC 0x00000010
453 * Flags passed to hammer2_chain_lock()
455 * NOTE: RDONLY is set to optimize cluster operations when *no* modifications
456 * will be made to either the cluster being locked or any underlying
457 * cluster. It allows the cluster to lock and access data for a subset
458 * of available nodes instead of all available nodes.
460 #define HAMMER2_RESOLVE_NEVER 1
461 #define HAMMER2_RESOLVE_MAYBE 2
462 #define HAMMER2_RESOLVE_ALWAYS 3
463 #define HAMMER2_RESOLVE_MASK 0x0F
465 #define HAMMER2_RESOLVE_SHARED 0x10 /* request shared lock */
466 #define HAMMER2_RESOLVE_UNUSED20 0x20
467 #define HAMMER2_RESOLVE_RDONLY 0x40 /* higher level op flag */
470 * Flags passed to hammer2_chain_delete()
472 #define HAMMER2_DELETE_PERMANENT 0x0001
473 #define HAMMER2_DELETE_NOSTATS 0x0002
475 #define HAMMER2_INSERT_NOSTATS 0x0002
476 #define HAMMER2_INSERT_PFSROOT 0x0004
479 * Flags passed to hammer2_chain_delete_duplicate()
481 #define HAMMER2_DELDUP_RECORE 0x0001
484 * Cluster different types of storage together for allocations
486 #define HAMMER2_FREECACHE_INODE 0
487 #define HAMMER2_FREECACHE_INDIR 1
488 #define HAMMER2_FREECACHE_DATA 2
489 #define HAMMER2_FREECACHE_UNUSED3 3
490 #define HAMMER2_FREECACHE_TYPES 4
493 * hammer2_freemap_alloc() block preference
495 #define HAMMER2_OFF_NOPREF ((hammer2_off_t)-1)
498 * BMAP read-ahead maximum parameters
500 #define HAMMER2_BMAP_COUNT 16 /* max bmap read-ahead */
501 #define HAMMER2_BMAP_BYTES (HAMMER2_PBUFSIZE * HAMMER2_BMAP_COUNT)
504 * hammer2_freemap_adjust()
506 #define HAMMER2_FREEMAP_DORECOVER 1
507 #define HAMMER2_FREEMAP_DOMAYFREE 2
508 #define HAMMER2_FREEMAP_DOREALFREE 3
511 * HAMMER2 cluster - A set of chains representing the same entity.
513 * hammer2_cluster typically represents a temporary set of representitive
514 * chains. The one exception is that a hammer2_cluster is embedded in
515 * hammer2_inode. This embedded cluster is ONLY used to track the
516 * representitive chains and cannot be directly locked.
518 * A cluster is usually temporary (and thus per-thread) for locking purposes,
519 * allowing us to embed the asynchronous storage required for cluster
520 * operations in the cluster itself and adjust the state and status without
521 * having to worry too much about SMP issues.
523 * The exception is the cluster embedded in the hammer2_inode structure.
524 * This is used to cache the cluster state on an inode-by-inode basis.
525 * Individual hammer2_chain structures not incorporated into clusters might
526 * also stick around to cache miscellanious elements.
528 * Because the cluster is a 'working copy' and is usually subject to cluster
529 * quorum rules, it is quite possible for us to end up with an insufficient
530 * number of live chains to execute an operation. If an insufficient number
531 * of chains remain in a working copy, the operation may have to be
532 * downgraded, retried, stall until the requisit number of chains are
533 * available, or possibly even error out depending on the mount type.
535 * A cluster's focus is set when it is locked. The focus can only be set
536 * to a chain still part of the synchronized set.
538 #define HAMMER2_MAXCLUSTER 8
540 struct hammer2_cluster_item {
542 hammer2_mtx_link_t async_link;
544 hammer2_chain_t *chain;
546 struct hammer2_cluster *cluster; /* link back to cluster */
552 typedef struct hammer2_cluster_item hammer2_cluster_item_t;
555 * INVALID - Invalid for focus, i.e. not part of synchronized set.
556 * Once set, this bit is sticky across operations.
558 * FEMOD - Indicates that front-end modifying operations can
559 * mess with this entry and MODSYNC will copy also
562 #define HAMMER2_CITEM_INVALID 0x00000001
563 #define HAMMER2_CITEM_FEMOD 0x00000002
565 struct hammer2_cluster {
566 int refs; /* track for deallocation */
568 struct hammer2_pfs *pmp;
571 int error; /* error code valid on lock */
574 hammer2_chain_t *focus; /* current focus (or mod) */
575 hammer2_cluster_item_t array[HAMMER2_MAXCLUSTER];
578 typedef struct hammer2_cluster hammer2_cluster_t;
581 * WRHARD - Hard mounts can write fully synchronized
582 * RDHARD - Hard mounts can read fully synchronized
583 * UNHARD - Unsynchronized masters present
584 * NOHARD - No masters visible
585 * WRSOFT - Soft mounts can write to at least the SOFT_MASTER
586 * RDSOFT - Soft mounts can read from at least a SOFT_SLAVE
587 * UNSOFT - Unsynchronized slaves present
588 * NOSOFT - No slaves visible
589 * RDSLAVE - slaves are accessible (possibly unsynchronized or remote).
590 * MSYNCED - All masters are fully synchronized
591 * SSYNCED - All known local slaves are fully synchronized to masters
593 * All available masters are always incorporated. All PFSs belonging to a
594 * cluster (master, slave, copy, whatever) always try to synchronize the
595 * total number of known masters in the PFSs root inode.
597 * A cluster might have access to many slaves, copies, or caches, but we
598 * have a limited number of cluster slots. Any such elements which are
599 * directly mounted from block device(s) will always be incorporated. Note
600 * that SSYNCED only applies to such elements which are directly mounted,
601 * not to any remote slaves, copies, or caches that could be available. These
602 * bits are used to monitor and drive our synchronization threads.
604 * When asking the question 'is any data accessible at all', then a simple
605 * test against (RDHARD|RDSOFT|RDSLAVE) gives you the answer. If any of
606 * these bits are set the object can be read with certain caveats:
607 * RDHARD - no caveats. RDSOFT - authoritative but might not be synchronized.
608 * and RDSLAVE - not authoritative, has some data but it could be old or
611 * When both soft and hard mounts are available, data will be read and written
612 * via the soft mount only. But all might be in the cluster because
613 * background synchronization threads still need to do their work.
615 #define HAMMER2_CLUSTER_INODE 0x00000001 /* embedded in inode struct */
616 #define HAMMER2_CLUSTER_UNUSED2 0x00000002
617 #define HAMMER2_CLUSTER_LOCKED 0x00000004 /* cluster lks not recursive */
618 #define HAMMER2_CLUSTER_WRHARD 0x00000100 /* hard-mount can write */
619 #define HAMMER2_CLUSTER_RDHARD 0x00000200 /* hard-mount can read */
620 #define HAMMER2_CLUSTER_UNHARD 0x00000400 /* unsynchronized masters */
621 #define HAMMER2_CLUSTER_NOHARD 0x00000800 /* no masters visible */
622 #define HAMMER2_CLUSTER_WRSOFT 0x00001000 /* soft-mount can write */
623 #define HAMMER2_CLUSTER_RDSOFT 0x00002000 /* soft-mount can read */
624 #define HAMMER2_CLUSTER_UNSOFT 0x00004000 /* unsynchronized slaves */
625 #define HAMMER2_CLUSTER_NOSOFT 0x00008000 /* no slaves visible */
626 #define HAMMER2_CLUSTER_MSYNCED 0x00010000 /* all masters synchronized */
627 #define HAMMER2_CLUSTER_SSYNCED 0x00020000 /* known slaves synchronized */
629 #define HAMMER2_CLUSTER_ANYDATA ( HAMMER2_CLUSTER_RDHARD | \
630 HAMMER2_CLUSTER_RDSOFT | \
631 HAMMER2_CLUSTER_RDSLAVE)
633 #define HAMMER2_CLUSTER_RDOK ( HAMMER2_CLUSTER_RDHARD | \
634 HAMMER2_CLUSTER_RDSOFT)
636 #define HAMMER2_CLUSTER_WROK ( HAMMER2_CLUSTER_WRHARD | \
637 HAMMER2_CLUSTER_WRSOFT)
639 #define HAMMER2_CLUSTER_ZFLAGS ( HAMMER2_CLUSTER_WRHARD | \
640 HAMMER2_CLUSTER_RDHARD | \
641 HAMMER2_CLUSTER_WRSOFT | \
642 HAMMER2_CLUSTER_RDSOFT | \
643 HAMMER2_CLUSTER_MSYNCED | \
644 HAMMER2_CLUSTER_SSYNCED)
647 * Helper functions (cluster must be locked for flags to be valid).
651 hammer2_cluster_rdok(hammer2_cluster_t *cluster)
653 return (cluster->flags & HAMMER2_CLUSTER_RDOK);
658 hammer2_cluster_wrok(hammer2_cluster_t *cluster)
660 return (cluster->flags & HAMMER2_CLUSTER_WROK);
663 RB_HEAD(hammer2_inode_tree, hammer2_inode);
668 * NOTE: The inode-embedded cluster is never used directly for I/O (since
669 * it may be shared). Instead it will be replicated-in and synchronized
670 * back out if changed.
672 struct hammer2_inode {
673 RB_ENTRY(hammer2_inode) rbnode; /* inumber lookup (HL) */
674 hammer2_mtx_t lock; /* inode lock */
675 struct hammer2_pfs *pmp; /* PFS mount */
676 struct hammer2_inode *pip; /* parent inode */
678 hammer2_cluster_t cluster;
679 struct lockf advlock;
682 u_int refs; /* +vpref, +flushref */
683 uint8_t comp_heuristic;
688 typedef struct hammer2_inode hammer2_inode_t;
690 #define HAMMER2_INODE_MODIFIED 0x0001
691 #define HAMMER2_INODE_SROOT 0x0002 /* kmalloc special case */
692 #define HAMMER2_INODE_RENAME_INPROG 0x0004
693 #define HAMMER2_INODE_ONRBTREE 0x0008
694 #define HAMMER2_INODE_RESIZED 0x0010
695 #define HAMMER2_INODE_MTIME 0x0020
697 int hammer2_inode_cmp(hammer2_inode_t *ip1, hammer2_inode_t *ip2);
698 RB_PROTOTYPE2(hammer2_inode_tree, hammer2_inode, rbnode, hammer2_inode_cmp,
702 * inode-unlink side-structure
704 struct hammer2_inode_unlink {
705 TAILQ_ENTRY(hammer2_inode_unlink) entry;
708 TAILQ_HEAD(h2_unlk_list, hammer2_inode_unlink);
710 typedef struct hammer2_inode_unlink hammer2_inode_unlink_t;
713 * A hammer2 transaction and flush sequencing structure.
715 * This global structure is tied into hammer2_dev and is used
716 * to sequence modifying operations and flushes. These operations
717 * run on whole cluster PFSs, not individual nodes (at this level),
718 * so we do not record mirror_tid here.
720 struct hammer2_trans {
721 TAILQ_ENTRY(hammer2_trans) entry;
722 struct hammer2_pfs *pmp;
723 hammer2_xid_t sync_xid; /* transaction sequencer */
724 hammer2_tid_t inode_tid; /* inode number assignment */
725 hammer2_tid_t modify_tid; /* modify transaction id */
726 thread_t td; /* pointer */
729 uint8_t inodes_created;
733 typedef struct hammer2_trans hammer2_trans_t;
735 #define HAMMER2_TRANS_ISFLUSH 0x0001 /* formal flush */
736 #define HAMMER2_TRANS_CONCURRENT 0x0002 /* concurrent w/flush */
737 #define HAMMER2_TRANS_BUFCACHE 0x0004 /* from bioq strategy write */
738 #define HAMMER2_TRANS_NEWINODE 0x0008 /* caller allocating inode */
739 #define HAMMER2_TRANS_KEEPMODIFY 0x0010 /* do not change bref.modify */
740 #define HAMMER2_TRANS_PREFLUSH 0x0020 /* preflush state */
742 #define HAMMER2_FREEMAP_HEUR_NRADIX 4 /* pwr 2 PBUFRADIX-MINIORADIX */
743 #define HAMMER2_FREEMAP_HEUR_TYPES 8
744 #define HAMMER2_FREEMAP_HEUR (HAMMER2_FREEMAP_HEUR_NRADIX * \
745 HAMMER2_FREEMAP_HEUR_TYPES)
748 * Transaction Rendezvous
750 TAILQ_HEAD(hammer2_trans_queue, hammer2_trans);
752 struct hammer2_trans_manage {
753 hammer2_xid_t flush_xid; /* last flush transaction */
754 hammer2_xid_t alloc_xid;
755 struct lock translk; /* lockmgr lock */
756 struct hammer2_trans_queue transq; /* modifying transactions */
757 int flushcnt; /* track flush trans */
760 typedef struct hammer2_trans_manage hammer2_trans_manage_t;
763 * Cluster node synchronization thread element.
765 * Multiple syncthr's can hang off of a hammer2_pfs structure, typically one
766 * for each block device that is part of the PFS. Synchronization threads
767 * for PFSs accessed over the network are handled by their respective hosts.
769 * Synchronization threads are responsible for keeping a local node
770 * synchronized to the greater cluster.
772 * A syncthr can also hang off each hammer2_dev's super-root PFS (spmp).
773 * This thread is responsible for automatic bulkfree and dedup scans.
775 struct hammer2_syncthr {
776 struct hammer2_pfs *pmp;
781 int clindex; /* sync_thrs[] array index */
782 hammer2_trans_t trans;
786 typedef struct hammer2_syncthr hammer2_syncthr_t;
788 #define HAMMER2_SYNCTHR_UNMOUNTING 0x0001 /* unmount request */
789 #define HAMMER2_SYNCTHR_DEV 0x0002 /* related to dev, not pfs */
790 #define HAMMER2_SYNCTHR_SPANNED 0x0004 /* LNK_SPAN active */
791 #define HAMMER2_SYNCTHR_REMASTER 0x0008 /* remaster request */
792 #define HAMMER2_SYNCTHR_STOP 0x0010 /* exit request */
793 #define HAMMER2_SYNCTHR_FREEZE 0x0020 /* force idle */
794 #define HAMMER2_SYNCTHR_FROZEN 0x0040 /* restart */
798 * Global (per partition) management structure, represents a hard block
799 * device. Typically referenced by hammer2_chain structures when applicable.
800 * Typically not used for network-managed elements.
802 * Note that a single hammer2_dev can be indirectly tied to multiple system
803 * mount points. There is no direct relationship. System mounts are
804 * per-cluster-id, not per-block-device, and a single hard mount might contain
805 * many PFSs and those PFSs might combine together in various ways to form
806 * the set of available clusters.
809 struct vnode *devvp; /* device vnode */
810 int ronly; /* read-only mount */
811 int mount_count; /* number of actively mounted PFSs */
812 TAILQ_ENTRY(hammer2_dev) mntentry; /* hammer2_mntlist */
814 struct malloc_type *mchain;
817 kdmsg_iocom_t iocom; /* volume-level dmsg interface */
818 struct spinlock io_spin; /* iotree access */
819 struct hammer2_io_tree iotree;
821 hammer2_chain_t vchain; /* anchor chain (topology) */
822 hammer2_chain_t fchain; /* anchor chain (freemap) */
823 struct spinlock list_spin;
824 struct h2_flush_list flushq; /* flush seeds */
825 struct hammer2_pfs *spmp; /* super-root pmp for transactions */
826 struct lock vollk; /* lockmgr lock */
827 hammer2_off_t heur_freemap[HAMMER2_FREEMAP_HEUR];
828 int volhdrno; /* last volhdrno written */
829 char devrepname[64]; /* for kprintf */
830 hammer2_volume_data_t voldata;
831 hammer2_volume_data_t volsync; /* synchronized voldata */
834 typedef struct hammer2_dev hammer2_dev_t;
837 * Helper functions (cluster must be locked for flags to be valid).
841 hammer2_chain_rdok(hammer2_chain_t *chain)
843 return (chain->error == 0);
848 hammer2_chain_wrok(hammer2_chain_t *chain)
850 return (chain->error == 0 && chain->hmp->ronly == 0);
854 * Per-cluster management structure. This structure will be tied to a
855 * system mount point if the system is mounting the PFS, but is also used
856 * to manage clusters encountered during the super-root scan or received
857 * via LNK_SPANs that might not be mounted.
859 * This structure is also used to represent the super-root that hangs off
860 * of a hard mount point. The super-root is not really a cluster element.
861 * In this case the spmp_hmp field will be non-NULL. It's just easier to do
862 * this than to special case super-root manipulation in the hammer2_chain*
863 * code as being only hammer2_dev-related.
865 * pfs_mode and pfs_nmasters are rollup fields which critically describes
866 * how elements of the cluster act on the cluster. pfs_mode is only applicable
867 * when a PFS is mounted by the system. pfs_nmasters is our best guess as to
868 * how many masters have been configured for a cluster and is always
869 * applicable. pfs_types[] is an array with 1:1 correspondance to the
870 * iroot cluster and describes the PFS types of the nodes making up the
873 * WARNING! Portions of this structure have deferred initialization. In
874 * particular, if not mounted there will be no ihidden or wthread.
875 * umounted network PFSs will also be missing iroot and numerous
876 * other fields will not be initialized prior to mount.
878 * Synchronization threads are chain-specific and only applicable
879 * to local hard PFS entries. A hammer2_pfs structure may contain
880 * more than one when multiple hard PFSs are present on the local
881 * machine which require synchronization monitoring. Most PFSs
882 * (such as snapshots) are 1xMASTER PFSs which do not need a
883 * synchronization thread.
885 * WARNING! The chains making up pfs->iroot's cluster are accounted for in
886 * hammer2_dev->mount_count when the pfs is associated with a mount
891 TAILQ_ENTRY(hammer2_pfs) mntentry; /* hammer2_pfslist */
893 hammer2_dev_t *spmp_hmp; /* only if super-root pmp */
894 hammer2_inode_t *iroot; /* PFS root inode */
895 hammer2_inode_t *ihidden; /* PFS hidden directory */
896 uint8_t pfs_types[HAMMER2_MAXCLUSTER];
897 char *pfs_names[HAMMER2_MAXCLUSTER];
898 hammer2_trans_manage_t tmanage; /* transaction management */
899 struct lock lock; /* PFS lock for certain ops */
900 hammer2_off_t inode_count; /* copy of inode_count */
901 struct netexport export; /* nfs export */
902 int ronly; /* read-only mount */
903 struct malloc_type *minode;
904 struct malloc_type *mmsg;
905 struct spinlock inum_spin; /* inumber lookup */
906 struct hammer2_inode_tree inum_tree; /* (not applicable to spmp) */
907 hammer2_tid_t modify_tid; /* modify transaction id */
908 hammer2_tid_t inode_tid; /* inode allocator */
909 uint8_t pfs_nmasters; /* total masters */
910 uint8_t pfs_mode; /* operating mode PFSMODE */
915 uint32_t inmem_dirty_chains;
916 int count_lwinprog; /* logical write in prog */
917 struct spinlock list_spin;
918 struct h2_unlk_list unlinkq; /* last-close unlink */
919 hammer2_syncthr_t sync_thrs[HAMMER2_MAXCLUSTER];
920 thread_t wthread_td; /* write thread td */
921 struct bio_queue_head wthread_bioq; /* logical buffer bioq */
922 hammer2_mtx_t wthread_mtx; /* interlock */
923 int wthread_destroy;/* termination sequencing */
924 uint32_t flags; /* cached cluster flags */
927 typedef struct hammer2_pfs hammer2_pfs_t;
929 #define HAMMER2_DIRTYCHAIN_WAITING 0x80000000
930 #define HAMMER2_DIRTYCHAIN_MASK 0x7FFFFFFF
932 #define HAMMER2_LWINPROG_WAITING 0x80000000
933 #define HAMMER2_LWINPROG_MASK 0x7FFFFFFF
938 #define HAMMER2_BULK_ABORT 0x00000001
945 MALLOC_DECLARE(M_HAMMER2);
947 #define VTOI(vp) ((hammer2_inode_t *)(vp)->v_data)
948 #define ITOV(ip) ((ip)->vp)
951 * Currently locked chains retain the locked buffer cache buffer for
952 * indirect blocks, and indirect blocks can be one of two sizes. The
953 * device buffer has to match the case to avoid deadlocking recursive
954 * chains that might otherwise try to access different offsets within
955 * the same device buffer.
959 hammer2_devblkradix(int radix)
962 if (radix <= HAMMER2_LBUFRADIX) {
963 return (HAMMER2_LBUFRADIX);
965 return (HAMMER2_PBUFRADIX);
968 return (HAMMER2_PBUFRADIX);
972 * XXX almost time to remove this. DIO uses PBUFSIZE exclusively now.
976 hammer2_devblksize(size_t bytes)
979 if (bytes <= HAMMER2_LBUFSIZE) {
980 return(HAMMER2_LBUFSIZE);
982 KKASSERT(bytes <= HAMMER2_PBUFSIZE &&
983 (bytes ^ (bytes - 1)) == ((bytes << 1) - 1));
984 return (HAMMER2_PBUFSIZE);
987 return (HAMMER2_PBUFSIZE);
993 MPTOPMP(struct mount *mp)
995 return ((hammer2_pfs_t *)mp->mnt_data);
998 #define LOCKSTART int __nlocks = curthread->td_locks
999 #define LOCKENTER (++curthread->td_locks)
1000 #define LOCKEXIT (--curthread->td_locks)
1001 #define LOCKSTOP KKASSERT(curthread->td_locks == __nlocks)
1003 extern struct vop_ops hammer2_vnode_vops;
1004 extern struct vop_ops hammer2_spec_vops;
1005 extern struct vop_ops hammer2_fifo_vops;
1007 extern int hammer2_debug;
1008 extern int hammer2_cluster_enable;
1009 extern int hammer2_hardlink_enable;
1010 extern int hammer2_flush_pipe;
1011 extern int hammer2_synchronous_flush;
1012 extern int hammer2_dio_count;
1013 extern long hammer2_limit_dirty_chains;
1014 extern long hammer2_iod_file_read;
1015 extern long hammer2_iod_meta_read;
1016 extern long hammer2_iod_indr_read;
1017 extern long hammer2_iod_fmap_read;
1018 extern long hammer2_iod_volu_read;
1019 extern long hammer2_iod_file_write;
1020 extern long hammer2_iod_meta_write;
1021 extern long hammer2_iod_indr_write;
1022 extern long hammer2_iod_fmap_write;
1023 extern long hammer2_iod_volu_write;
1024 extern long hammer2_ioa_file_read;
1025 extern long hammer2_ioa_meta_read;
1026 extern long hammer2_ioa_indr_read;
1027 extern long hammer2_ioa_fmap_read;
1028 extern long hammer2_ioa_volu_read;
1029 extern long hammer2_ioa_file_write;
1030 extern long hammer2_ioa_meta_write;
1031 extern long hammer2_ioa_indr_write;
1032 extern long hammer2_ioa_fmap_write;
1033 extern long hammer2_ioa_volu_write;
1035 extern struct objcache *cache_buffer_read;
1036 extern struct objcache *cache_buffer_write;
1039 extern int write_thread_wakeup;
1044 #define hammer2_icrc32(buf, size) iscsi_crc32((buf), (size))
1045 #define hammer2_icrc32c(buf, size, crc) iscsi_crc32_ext((buf), (size), (crc))
1047 int hammer2_signal_check(time_t *timep);
1048 const char *hammer2_error_str(int error);
1050 hammer2_cluster_t *hammer2_inode_lock(hammer2_inode_t *ip, int how);
1051 void hammer2_inode_unlock(hammer2_inode_t *ip, hammer2_cluster_t *cluster);
1052 hammer2_mtx_state_t hammer2_inode_lock_temp_release(hammer2_inode_t *ip);
1053 void hammer2_inode_lock_temp_restore(hammer2_inode_t *ip,
1054 hammer2_mtx_state_t ostate);
1055 int hammer2_inode_lock_upgrade(hammer2_inode_t *ip);
1056 void hammer2_inode_lock_downgrade(hammer2_inode_t *ip, int);
1058 void hammer2_dev_exlock(hammer2_dev_t *hmp);
1059 void hammer2_dev_shlock(hammer2_dev_t *hmp);
1060 void hammer2_dev_unlock(hammer2_dev_t *hmp);
1062 int hammer2_get_dtype(const hammer2_inode_data_t *ipdata);
1063 int hammer2_get_vtype(const hammer2_inode_data_t *ipdata);
1064 u_int8_t hammer2_get_obj_type(enum vtype vtype);
1065 void hammer2_time_to_timespec(u_int64_t xtime, struct timespec *ts);
1066 u_int64_t hammer2_timespec_to_time(const struct timespec *ts);
1067 u_int32_t hammer2_to_unix_xid(const uuid_t *uuid);
1068 void hammer2_guid_to_uuid(uuid_t *uuid, u_int32_t guid);
1069 hammer2_xid_t hammer2_trans_newxid(hammer2_pfs_t *pmp);
1070 void hammer2_trans_manage_init(hammer2_trans_manage_t *tman);
1072 hammer2_key_t hammer2_dirhash(const unsigned char *name, size_t len);
1073 int hammer2_getradix(size_t bytes);
1075 int hammer2_calc_logical(hammer2_inode_t *ip, hammer2_off_t uoff,
1076 hammer2_key_t *lbasep, hammer2_key_t *leofp);
1077 int hammer2_calc_physical(hammer2_inode_t *ip,
1078 const hammer2_inode_data_t *ipdata,
1079 hammer2_key_t lbase);
1080 void hammer2_update_time(uint64_t *timep);
1081 void hammer2_adjreadcounter(hammer2_blockref_t *bref, size_t bytes);
1086 struct vnode *hammer2_igetv(hammer2_inode_t *ip, hammer2_cluster_t *cparent,
1088 hammer2_inode_t *hammer2_inode_lookup(hammer2_pfs_t *pmp,
1089 hammer2_tid_t inum);
1090 hammer2_inode_t *hammer2_inode_get(hammer2_pfs_t *pmp,
1091 hammer2_inode_t *dip, hammer2_cluster_t *cluster);
1092 void hammer2_inode_free(hammer2_inode_t *ip);
1093 void hammer2_inode_ref(hammer2_inode_t *ip);
1094 void hammer2_inode_drop(hammer2_inode_t *ip);
1095 void hammer2_inode_repoint(hammer2_inode_t *ip, hammer2_inode_t *pip,
1096 hammer2_cluster_t *cluster);
1097 void hammer2_inode_repoint_one(hammer2_inode_t *ip, hammer2_cluster_t *cluster,
1100 void hammer2_run_unlinkq(hammer2_trans_t *trans, hammer2_pfs_t *pmp);
1102 hammer2_inode_t *hammer2_inode_create(hammer2_trans_t *trans,
1103 hammer2_inode_t *dip,
1104 struct vattr *vap, struct ucred *cred,
1105 const uint8_t *name, size_t name_len,
1106 hammer2_cluster_t **clusterp,
1107 int flags, int *errorp);
1108 int hammer2_inode_connect(hammer2_trans_t *trans,
1109 hammer2_cluster_t **clusterp, int hlink,
1110 hammer2_inode_t *dip, hammer2_cluster_t *dcluster,
1111 const uint8_t *name, size_t name_len,
1113 hammer2_inode_t *hammer2_inode_common_parent(hammer2_inode_t *fdip,
1114 hammer2_inode_t *tdip);
1115 void hammer2_inode_fsync(hammer2_trans_t *trans, hammer2_inode_t *ip,
1116 hammer2_cluster_t *cparent);
1117 int hammer2_unlink_file(hammer2_trans_t *trans, hammer2_inode_t *dip,
1118 const uint8_t *name, size_t name_len, int isdir,
1119 int *hlinkp, struct nchandle *nch, int nlinks);
1120 int hammer2_hardlink_consolidate(hammer2_trans_t *trans,
1121 hammer2_inode_t *ip, hammer2_cluster_t **clusterp,
1122 hammer2_inode_t *cdip, hammer2_cluster_t *cdcluster,
1124 int hammer2_hardlink_deconsolidate(hammer2_trans_t *trans, hammer2_inode_t *dip,
1125 hammer2_chain_t **chainp, hammer2_chain_t **ochainp);
1126 int hammer2_hardlink_find(hammer2_inode_t *dip, hammer2_cluster_t **cparentp,
1127 hammer2_cluster_t **clusterp);
1128 int hammer2_parent_find(hammer2_cluster_t **cparentp,
1129 hammer2_cluster_t *cluster);
1130 void hammer2_inode_install_hidden(hammer2_pfs_t *pmp);
1135 void hammer2_voldata_lock(hammer2_dev_t *hmp);
1136 void hammer2_voldata_unlock(hammer2_dev_t *hmp);
1137 void hammer2_voldata_modify(hammer2_dev_t *hmp);
1138 hammer2_chain_t *hammer2_chain_alloc(hammer2_dev_t *hmp,
1140 hammer2_trans_t *trans,
1141 hammer2_blockref_t *bref);
1142 void hammer2_chain_core_init(hammer2_chain_t *chain);
1143 void hammer2_chain_ref(hammer2_chain_t *chain);
1144 void hammer2_chain_drop(hammer2_chain_t *chain);
1145 void hammer2_chain_lock(hammer2_chain_t *chain, int how);
1146 const hammer2_media_data_t *hammer2_chain_rdata(hammer2_chain_t *chain);
1147 hammer2_media_data_t *hammer2_chain_wdata(hammer2_chain_t *chain);
1152 int hammer2_cluster_isunlinked(hammer2_cluster_t *cluster);
1153 void hammer2_cluster_load_async(hammer2_cluster_t *cluster,
1154 void (*callback)(hammer2_iocb_t *iocb),
1156 void hammer2_chain_moved(hammer2_chain_t *chain);
1157 void hammer2_chain_modify(hammer2_trans_t *trans,
1158 hammer2_chain_t *chain, int flags);
1159 void hammer2_chain_resize(hammer2_trans_t *trans, hammer2_inode_t *ip,
1160 hammer2_chain_t *parent,
1161 hammer2_chain_t *chain,
1162 int nradix, int flags);
1163 void hammer2_chain_unlock(hammer2_chain_t *chain);
1164 void hammer2_chain_wait(hammer2_chain_t *chain);
1165 hammer2_chain_t *hammer2_chain_get(hammer2_chain_t *parent, int generation,
1166 hammer2_blockref_t *bref);
1167 hammer2_chain_t *hammer2_chain_lookup_init(hammer2_chain_t *parent, int flags);
1168 void hammer2_chain_lookup_done(hammer2_chain_t *parent);
1169 hammer2_chain_t *hammer2_chain_lookup(hammer2_chain_t **parentp,
1170 hammer2_key_t *key_nextp,
1171 hammer2_key_t key_beg, hammer2_key_t key_end,
1172 int *cache_indexp, int flags);
1173 hammer2_chain_t *hammer2_chain_next(hammer2_chain_t **parentp,
1174 hammer2_chain_t *chain,
1175 hammer2_key_t *key_nextp,
1176 hammer2_key_t key_beg, hammer2_key_t key_end,
1177 int *cache_indexp, int flags);
1178 hammer2_chain_t *hammer2_chain_scan(hammer2_chain_t *parent,
1179 hammer2_chain_t *chain,
1180 int *cache_indexp, int flags);
1182 int hammer2_chain_create(hammer2_trans_t *trans, hammer2_chain_t **parentp,
1183 hammer2_chain_t **chainp,
1185 hammer2_key_t key, int keybits,
1186 int type, size_t bytes, int flags);
1187 void hammer2_chain_rename(hammer2_trans_t *trans, hammer2_blockref_t *bref,
1188 hammer2_chain_t **parentp,
1189 hammer2_chain_t *chain, int flags);
1190 int hammer2_chain_snapshot(hammer2_trans_t *trans, hammer2_chain_t **chainp,
1191 hammer2_ioc_pfs_t *pfs);
1192 void hammer2_chain_delete(hammer2_trans_t *trans, hammer2_chain_t *parent,
1193 hammer2_chain_t *chain, int flags);
1194 void hammer2_chain_delete_duplicate(hammer2_trans_t *trans,
1195 hammer2_chain_t **chainp, int flags);
1196 void hammer2_flush(hammer2_trans_t *trans, hammer2_chain_t *chain, int istop);
1197 void hammer2_chain_commit(hammer2_trans_t *trans, hammer2_chain_t *chain);
1198 void hammer2_chain_setflush(hammer2_trans_t *trans, hammer2_chain_t *chain);
1199 void hammer2_chain_countbrefs(hammer2_chain_t *chain,
1200 hammer2_blockref_t *base, int count);
1202 void hammer2_chain_setcheck(hammer2_chain_t *chain, void *bdata);
1203 int hammer2_chain_testcheck(hammer2_chain_t *chain, void *bdata);
1206 void hammer2_pfs_memory_wait(hammer2_pfs_t *pmp);
1207 void hammer2_pfs_memory_inc(hammer2_pfs_t *pmp);
1208 void hammer2_pfs_memory_wakeup(hammer2_pfs_t *pmp);
1210 void hammer2_base_delete(hammer2_trans_t *trans, hammer2_chain_t *chain,
1211 hammer2_blockref_t *base, int count,
1212 int *cache_indexp, hammer2_chain_t *child);
1213 void hammer2_base_insert(hammer2_trans_t *trans, hammer2_chain_t *chain,
1214 hammer2_blockref_t *base, int count,
1215 int *cache_indexp, hammer2_chain_t *child);
1220 void hammer2_trans_init(hammer2_trans_t *trans, hammer2_pfs_t *pmp,
1222 void hammer2_trans_done(hammer2_trans_t *trans);
1223 void hammer2_trans_assert_strategy(hammer2_pfs_t *pmp);
1228 int hammer2_ioctl(hammer2_inode_t *ip, u_long com, void *data,
1229 int fflag, struct ucred *cred);
1234 void hammer2_io_putblk(hammer2_io_t **diop);
1235 void hammer2_io_cleanup(hammer2_dev_t *hmp, struct hammer2_io_tree *tree);
1236 char *hammer2_io_data(hammer2_io_t *dio, off_t lbase);
1237 void hammer2_io_getblk(hammer2_dev_t *hmp, off_t lbase, int lsize,
1238 hammer2_iocb_t *iocb);
1239 void hammer2_io_complete(hammer2_iocb_t *iocb);
1240 void hammer2_io_callback(struct bio *bio);
1241 void hammer2_iocb_wait(hammer2_iocb_t *iocb);
1242 int hammer2_io_new(hammer2_dev_t *hmp, off_t lbase, int lsize,
1243 hammer2_io_t **diop);
1244 int hammer2_io_newnz(hammer2_dev_t *hmp, off_t lbase, int lsize,
1245 hammer2_io_t **diop);
1246 int hammer2_io_newq(hammer2_dev_t *hmp, off_t lbase, int lsize,
1247 hammer2_io_t **diop);
1248 int hammer2_io_bread(hammer2_dev_t *hmp, off_t lbase, int lsize,
1249 hammer2_io_t **diop);
1250 void hammer2_io_bawrite(hammer2_io_t **diop);
1251 void hammer2_io_bdwrite(hammer2_io_t **diop);
1252 int hammer2_io_bwrite(hammer2_io_t **diop);
1253 int hammer2_io_isdirty(hammer2_io_t *dio);
1254 void hammer2_io_setdirty(hammer2_io_t *dio);
1255 void hammer2_io_setinval(hammer2_io_t *dio, u_int bytes);
1256 void hammer2_io_brelse(hammer2_io_t **diop);
1257 void hammer2_io_bqrelse(hammer2_io_t **diop);
1262 int hammer2_msg_dbg_rcvmsg(kdmsg_msg_t *msg);
1263 int hammer2_msg_adhoc_input(kdmsg_msg_t *msg);
1268 void hammer2_clusterctl_wakeup(kdmsg_iocom_t *iocom);
1269 void hammer2_volconf_update(hammer2_dev_t *hmp, int index);
1270 void hammer2_dump_chain(hammer2_chain_t *chain, int tab, int *countp, char pfx);
1271 void hammer2_bioq_sync(hammer2_pfs_t *pmp);
1272 int hammer2_vfs_sync(struct mount *mp, int waitflags);
1273 hammer2_pfs_t *hammer2_pfsalloc(hammer2_cluster_t *cluster,
1274 const hammer2_inode_data_t *ripdata,
1275 hammer2_tid_t modify_tid);
1277 void hammer2_lwinprog_ref(hammer2_pfs_t *pmp);
1278 void hammer2_lwinprog_drop(hammer2_pfs_t *pmp);
1279 void hammer2_lwinprog_wait(hammer2_pfs_t *pmp);
1284 int hammer2_freemap_alloc(hammer2_trans_t *trans, hammer2_chain_t *chain,
1286 void hammer2_freemap_adjust(hammer2_trans_t *trans, hammer2_dev_t *hmp,
1287 hammer2_blockref_t *bref, int how);
1292 int hammer2_cluster_need_resize(hammer2_cluster_t *cluster, int bytes);
1293 uint8_t hammer2_cluster_type(hammer2_cluster_t *cluster);
1294 const hammer2_media_data_t *hammer2_cluster_rdata(hammer2_cluster_t *cluster);
1295 hammer2_media_data_t *hammer2_cluster_wdata(hammer2_cluster_t *cluster);
1296 hammer2_cluster_t *hammer2_cluster_from_chain(hammer2_chain_t *chain);
1297 int hammer2_cluster_modified(hammer2_cluster_t *cluster);
1298 int hammer2_cluster_duplicated(hammer2_cluster_t *cluster);
1299 void hammer2_cluster_set_chainflags(hammer2_cluster_t *cluster, uint32_t flags);
1300 void hammer2_cluster_clr_chainflags(hammer2_cluster_t *cluster, uint32_t flags);
1301 void hammer2_cluster_bref(hammer2_cluster_t *cluster, hammer2_blockref_t *bref);
1302 void hammer2_cluster_setflush(hammer2_trans_t *trans,
1303 hammer2_cluster_t *cluster);
1304 void hammer2_cluster_setmethod_check(hammer2_trans_t *trans,
1305 hammer2_cluster_t *cluster, int check_algo);
1306 hammer2_cluster_t *hammer2_cluster_alloc(hammer2_pfs_t *pmp,
1307 hammer2_trans_t *trans,
1308 hammer2_blockref_t *bref);
1309 void hammer2_cluster_ref(hammer2_cluster_t *cluster);
1310 void hammer2_cluster_drop(hammer2_cluster_t *cluster);
1311 void hammer2_cluster_wait(hammer2_cluster_t *cluster);
1312 void hammer2_cluster_lock(hammer2_cluster_t *cluster, int how);
1313 void hammer2_cluster_resolve(hammer2_cluster_t *cluster);
1314 hammer2_cluster_t *hammer2_cluster_copy(hammer2_cluster_t *ocluster);
1315 void hammer2_cluster_unlock(hammer2_cluster_t *cluster);
1316 void hammer2_cluster_resize(hammer2_trans_t *trans, hammer2_inode_t *ip,
1317 hammer2_cluster_t *cparent, hammer2_cluster_t *cluster,
1318 int nradix, int flags);
1319 hammer2_inode_data_t *hammer2_cluster_modify_ip(hammer2_trans_t *trans,
1320 hammer2_inode_t *ip, hammer2_cluster_t *cluster,
1322 void hammer2_cluster_modify(hammer2_trans_t *trans, hammer2_cluster_t *cluster,
1324 void hammer2_cluster_modsync(hammer2_cluster_t *cluster);
1325 hammer2_cluster_t *hammer2_cluster_lookup_init(hammer2_cluster_t *cparent,
1327 void hammer2_cluster_lookup_done(hammer2_cluster_t *cparent);
1328 hammer2_cluster_t *hammer2_cluster_lookup(hammer2_cluster_t *cparent,
1329 hammer2_key_t *key_nextp,
1330 hammer2_key_t key_beg, hammer2_key_t key_end,
1332 hammer2_cluster_t *hammer2_cluster_next(hammer2_cluster_t *cparent,
1333 hammer2_cluster_t *cluster,
1334 hammer2_key_t *key_nextp,
1335 hammer2_key_t key_beg, hammer2_key_t key_end,
1337 void hammer2_cluster_next_single_chain(hammer2_cluster_t *cparent,
1338 hammer2_cluster_t *cluster,
1339 hammer2_key_t *key_nextp,
1340 hammer2_key_t key_beg,
1341 hammer2_key_t key_end,
1343 hammer2_cluster_t *hammer2_cluster_scan(hammer2_cluster_t *cparent,
1344 hammer2_cluster_t *cluster, int flags);
1345 int hammer2_cluster_create(hammer2_trans_t *trans, hammer2_cluster_t *cparent,
1346 hammer2_cluster_t **clusterp,
1347 hammer2_key_t key, int keybits,
1348 int type, size_t bytes, int flags);
1349 void hammer2_cluster_rename(hammer2_trans_t *trans, hammer2_blockref_t *bref,
1350 hammer2_cluster_t *cparent, hammer2_cluster_t *cluster,
1352 void hammer2_cluster_delete(hammer2_trans_t *trans, hammer2_cluster_t *pcluster,
1353 hammer2_cluster_t *cluster, int flags);
1354 int hammer2_cluster_snapshot(hammer2_trans_t *trans,
1355 hammer2_cluster_t *ocluster, hammer2_ioc_pfs_t *pfs);
1356 hammer2_cluster_t *hammer2_cluster_parent(hammer2_cluster_t *cluster);
1358 int hammer2_bulk_scan(hammer2_trans_t *trans, hammer2_chain_t *parent,
1359 int (*func)(hammer2_chain_t *chain, void *info),
1361 int hammer2_bulkfree_pass(hammer2_dev_t *hmp,
1362 struct hammer2_ioc_bulkfree *bfi);
1367 void hammer2_iocom_init(hammer2_dev_t *hmp);
1368 void hammer2_iocom_uninit(hammer2_dev_t *hmp);
1369 void hammer2_cluster_reconnect(hammer2_dev_t *hmp, struct file *fp);
1374 void hammer2_syncthr_create(hammer2_syncthr_t *thr, hammer2_pfs_t *pmp,
1375 int clindex, void (*func)(void *arg));
1376 void hammer2_syncthr_delete(hammer2_syncthr_t *thr);
1377 void hammer2_syncthr_remaster(hammer2_syncthr_t *thr);
1378 void hammer2_syncthr_freeze(hammer2_syncthr_t *thr);
1379 void hammer2_syncthr_unfreeze(hammer2_syncthr_t *thr);
1380 void hammer2_syncthr_primary(void *arg);
1382 #endif /* !_KERNEL */
1383 #endif /* !_VFS_HAMMER2_HAMMER2_H_ */