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NetBSD/sys/kern/vfs_wapbl.c

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/* $NetBSD: vfs_wapbl.c,v 1.2 2008/07/31 05:38:05 simonb Exp $ */
/*-
* Copyright (c) 2003,2008 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Wasabi Systems, Inc.
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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.
*/
/*
* This implements file system independent write ahead filesystem logging.
*/
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: vfs_wapbl.c,v 1.2 2008/07/31 05:38:05 simonb Exp $");
#include <sys/param.h>
#ifdef _KERNEL
#include <sys/param.h>
#include <sys/namei.h>
#include <sys/proc.h>
#include <sys/uio.h>
#include <sys/vnode.h>
#include <sys/file.h>
#include <sys/malloc.h>
#include <sys/resourcevar.h>
#include <sys/conf.h>
#include <sys/mount.h>
#include <sys/kernel.h>
#include <sys/kauth.h>
#include <sys/mutex.h>
#include <sys/atomic.h>
#include <sys/wapbl.h>
#if WAPBL_UVM_ALLOC
#include <uvm/uvm.h>
#endif
#include <miscfs/specfs/specdev.h>
MALLOC_JUSTDEFINE(M_WAPBL, "wapbl", "write-ahead physical block logging");
#define wapbl_malloc(s) malloc((s), M_WAPBL, M_WAITOK)
#define wapbl_free(a) free((a), M_WAPBL)
#define wapbl_calloc(n, s) malloc((n)*(s), M_WAPBL, M_WAITOK | M_ZERO)
#else /* !_KERNEL */
#include <assert.h>
#include <errno.h>
#include <stdio.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <sys/time.h>
#include <sys/wapbl.h>
#define KDASSERT(x) assert(x)
#define KASSERT(x) assert(x)
#define wapbl_malloc(s) malloc(s)
#define wapbl_free(a) free(a)
#define wapbl_calloc(n, s) calloc((n), (s))
#endif /* !_KERNEL */
/*
* INTERNAL DATA STRUCTURES
*/
/*
* This structure holds per-mount log information.
*
* Legend: a = atomic access only
* r = read-only after init
* l = rwlock held
* m = mutex held
* u = unlocked access ok
* b = bufcache_lock held
*/
struct wapbl {
struct vnode *wl_logvp; /* r: log here */
struct vnode *wl_devvp; /* r: log on this device */
struct mount *wl_mount; /* r: mountpoint wl is associated with */
daddr_t wl_logpbn; /* r: Physical block number of start of log */
int wl_log_dev_bshift; /* r: logarithm of device block size of log
device */
int wl_fs_dev_bshift; /* r: logarithm of device block size of
filesystem device */
unsigned wl_lock_count; /* a: Count of transactions in progress */
size_t wl_circ_size; /* r: Number of bytes in buffer of log */
size_t wl_circ_off; /* r: Number of bytes reserved at start */
size_t wl_bufcount_max; /* r: Number of buffers reserved for log */
size_t wl_bufbytes_max; /* r: Number of buf bytes reserved for log */
off_t wl_head; /* l: Byte offset of log head */
off_t wl_tail; /* l: Byte offset of log tail */
/*
* head == tail == 0 means log is empty
* head == tail != 0 means log is full
* see assertions in wapbl_advance() for other boundary conditions.
* only truncate moves the tail, except when flush sets it to
* wl_header_size only flush moves the head, except when truncate
* sets it to 0.
*/
struct wapbl_wc_header *wl_wc_header; /* l */
void *wl_wc_scratch; /* l: scratch space (XXX: por que?!?) */
kmutex_t wl_mtx; /* u: short-term lock */
krwlock_t wl_rwlock; /* u: File system transaction lock */
/*
* Must be held while accessing
* wl_count or wl_bufs or head or tail
*/
/*
* Callback called from within the flush routine to flush any extra
* bits. Note that flush may be skipped without calling this if
* there are no outstanding buffers in the transaction.
*/
wapbl_flush_fn_t wl_flush; /* r */
wapbl_flush_fn_t wl_flush_abort;/* r */
size_t wl_bufbytes; /* m: Byte count of pages in wl_bufs */
size_t wl_bufcount; /* m: Count of buffers in wl_bufs */
size_t wl_bcount; /* m: Total bcount of wl_bufs */
LIST_HEAD(, buf) wl_bufs; /* m: Buffers in current transaction */
kcondvar_t wl_reclaimable_cv; /* m (obviously) */
size_t wl_reclaimable_bytes; /* m: Amount of space available for
reclamation by truncate */
int wl_error_count; /* m: # of wl_entries with errors */
size_t wl_reserved_bytes; /* never truncate log smaller than this */
#ifdef WAPBL_DEBUG_BUFBYTES
size_t wl_unsynced_bufbytes; /* Byte count of unsynced buffers */
#endif
daddr_t *wl_deallocblks;/* l: address of block */
int *wl_dealloclens; /* l: size of block (fragments, kom ih<69>g) */
int wl_dealloccnt; /* l: total count */
int wl_dealloclim; /* l: max count */
/* hashtable of inode numbers for allocated but unlinked inodes */
/* synch ??? */
LIST_HEAD(wapbl_ino_head, wapbl_ino) *wl_inohash;
u_long wl_inohashmask;
int wl_inohashcnt;
SIMPLEQ_HEAD(, wapbl_entry) wl_entries; /* On disk transaction
accounting */
};
#ifdef WAPBL_DEBUG_PRINT
int wapbl_debug_print = WAPBL_DEBUG_PRINT;
#endif
/****************************************************************/
#ifdef _KERNEL
#ifdef WAPBL_DEBUG
struct wapbl *wapbl_debug_wl;
#endif
static int wapbl_write_commit(struct wapbl *wl, off_t head, off_t tail);
static int wapbl_write_blocks(struct wapbl *wl, off_t *offp);
static int wapbl_write_revocations(struct wapbl *wl, off_t *offp);
static int wapbl_write_inodes(struct wapbl *wl, off_t *offp);
#endif /* _KERNEL */
static int wapbl_replay_prescan(struct wapbl_replay *wr);
static int wapbl_replay_get_inodes(struct wapbl_replay *wr);
static __inline size_t wapbl_space_free(size_t avail, off_t head,
off_t tail);
static __inline size_t wapbl_space_used(size_t avail, off_t head,
off_t tail);
#ifdef _KERNEL
#define WAPBL_INODETRK_SIZE 83
static int wapbl_ino_pool_refcount;
static struct pool wapbl_ino_pool;
struct wapbl_ino {
LIST_ENTRY(wapbl_ino) wi_hash;
ino_t wi_ino;
mode_t wi_mode;
};
static void wapbl_inodetrk_init(struct wapbl *wl, u_int size);
static void wapbl_inodetrk_free(struct wapbl *wl);
static struct wapbl_ino *wapbl_inodetrk_get(struct wapbl *wl, ino_t ino);
static size_t wapbl_transaction_len(struct wapbl *wl);
static __inline size_t wapbl_transaction_inodes_len(struct wapbl *wl);
/*
* This is useful for debugging. If set, the log will
* only be truncated when necessary.
*/
int wapbl_lazy_truncate = 0;
struct wapbl_ops wapbl_ops = {
.wo_wapbl_discard = wapbl_discard,
.wo_wapbl_replay_isopen = wapbl_replay_isopen1,
.wo_wapbl_replay_read = wapbl_replay_read,
.wo_wapbl_add_buf = wapbl_add_buf,
.wo_wapbl_remove_buf = wapbl_remove_buf,
.wo_wapbl_resize_buf = wapbl_resize_buf,
.wo_wapbl_begin = wapbl_begin,
.wo_wapbl_end = wapbl_end,
.wo_wapbl_junlock_assert= wapbl_junlock_assert,
/* XXX: the following is only used to say "this is a wapbl buf" */
.wo_wapbl_biodone = wapbl_biodone,
};
void
wapbl_init()
{
malloc_type_attach(M_WAPBL);
}
int
wapbl_start(struct wapbl ** wlp, struct mount *mp, struct vnode *vp,
daddr_t off, size_t count, size_t blksize, struct wapbl_replay *wr,
wapbl_flush_fn_t flushfn, wapbl_flush_fn_t flushabortfn)
{
struct wapbl *wl;
struct vnode *devvp;
daddr_t logpbn;
int error;
int log_dev_bshift = DEV_BSHIFT;
int fs_dev_bshift = DEV_BSHIFT;
int run;
WAPBL_PRINTF(WAPBL_PRINT_OPEN, ("wapbl_start: vp=%p off=%" PRId64
" count=%zu blksize=%zu\n", vp, off, count, blksize));
if (log_dev_bshift > fs_dev_bshift) {
WAPBL_PRINTF(WAPBL_PRINT_OPEN,
("wapbl: log device's block size cannot be larger "
"than filesystem's\n"));
/*
* Not currently implemented, although it could be if
* needed someday.
*/
return ENOSYS;
}
if (off < 0)
return EINVAL;
if (blksize < DEV_BSIZE)
return EINVAL;
if (blksize % DEV_BSIZE)
return EINVAL;
/* XXXTODO: verify that the full load is writable */
/*
* XXX check for minimum log size
* minimum is governed by minimum amount of space
* to complete a transaction. (probably truncate)
*/
/* XXX for now pick something minimal */
if ((count * blksize) < MAXPHYS) {
return ENOSPC;
}
if ((error = VOP_BMAP(vp, off, &devvp, &logpbn, &run)) != 0) {
return error;
}
wl = wapbl_calloc(1, sizeof(*wl));
rw_init(&wl->wl_rwlock);
mutex_init(&wl->wl_mtx, MUTEX_DEFAULT, IPL_NONE);
cv_init(&wl->wl_reclaimable_cv, "wapblrec");
LIST_INIT(&wl->wl_bufs);
SIMPLEQ_INIT(&wl->wl_entries);
wl->wl_logvp = vp;
wl->wl_devvp = devvp;
wl->wl_mount = mp;
wl->wl_logpbn = logpbn;
wl->wl_log_dev_bshift = log_dev_bshift;
wl->wl_fs_dev_bshift = fs_dev_bshift;
wl->wl_flush = flushfn;
wl->wl_flush_abort = flushabortfn;
/* Reserve two log device blocks for the commit headers */
wl->wl_circ_off = 2<<wl->wl_log_dev_bshift;
wl->wl_circ_size = ((count * blksize) - wl->wl_circ_off);
/* truncate the log usage to a multiple of log_dev_bshift */
wl->wl_circ_size >>= wl->wl_log_dev_bshift;
wl->wl_circ_size <<= wl->wl_log_dev_bshift;
/*
* wl_bufbytes_max limits the size of the in memory transaction space.
* - Since buffers are allocated and accounted for in units of
* PAGE_SIZE it is required to be a multiple of PAGE_SIZE
* (i.e. 1<<PAGE_SHIFT)
* - Since the log device has to be written in units of
* 1<<wl_log_dev_bshift it is required to be a mulitple of
* 1<<wl_log_dev_bshift.
* - Since filesystem will provide data in units of 1<<wl_fs_dev_bshift,
* it is convenient to be a multiple of 1<<wl_fs_dev_bshift.
* Therefore it must be multiple of the least common multiple of those
* three quantities. Fortunately, all of those quantities are
* guaranteed to be a power of two, and the least common multiple of
* a set of numbers which are all powers of two is simply the maximum
* of those numbers. Finally, the maximum logarithm of a power of two
* is the same as the log of the maximum power of two. So we can do
* the following operations to size wl_bufbytes_max:
*/
/* XXX fix actual number of pages reserved per filesystem. */
wl->wl_bufbytes_max = MIN(wl->wl_circ_size, buf_memcalc() / 2);
/* Round wl_bufbytes_max to the largest power of two constraint */
wl->wl_bufbytes_max >>= PAGE_SHIFT;
wl->wl_bufbytes_max <<= PAGE_SHIFT;
wl->wl_bufbytes_max >>= wl->wl_log_dev_bshift;
wl->wl_bufbytes_max <<= wl->wl_log_dev_bshift;
wl->wl_bufbytes_max >>= wl->wl_fs_dev_bshift;
wl->wl_bufbytes_max <<= wl->wl_fs_dev_bshift;
/* XXX maybe use filesystem fragment size instead of 1024 */
/* XXX fix actual number of buffers reserved per filesystem. */
wl->wl_bufcount_max = (nbuf / 2) * 1024;
/* XXX tie this into resource estimation */
wl->wl_dealloclim = 2 * btodb(wl->wl_bufbytes_max);
#if WAPBL_UVM_ALLOC
wl->wl_deallocblks = (void *) uvm_km_zalloc(kernel_map,
round_page(sizeof(*wl->wl_deallocblks) * wl->wl_dealloclim));
KASSERT(wl->wl_deallocblks != NULL);
wl->wl_dealloclens = (void *) uvm_km_zalloc(kernel_map,
round_page(sizeof(*wl->wl_dealloclens) * wl->wl_dealloclim));
KASSERT(wl->wl_dealloclens != NULL);
#else
wl->wl_deallocblks = wapbl_malloc(sizeof(*wl->wl_deallocblks) *
wl->wl_dealloclim);
wl->wl_dealloclens = wapbl_malloc(sizeof(*wl->wl_dealloclens) *
wl->wl_dealloclim);
#endif
wapbl_inodetrk_init(wl, WAPBL_INODETRK_SIZE);
/* Initialize the commit header */
{
struct wapbl_wc_header *wc;
size_t len = 1<<wl->wl_log_dev_bshift;
wc = wapbl_calloc(1, len);
wc->wc_type = WAPBL_WC_HEADER;
wc->wc_len = len;
wc->wc_circ_off = wl->wl_circ_off;
wc->wc_circ_size = wl->wl_circ_size;
/* XXX wc->wc_fsid */
wc->wc_log_dev_bshift = wl->wl_log_dev_bshift;
wc->wc_fs_dev_bshift = wl->wl_fs_dev_bshift;
wl->wl_wc_header = wc;
wl->wl_wc_scratch = wapbl_malloc(len);
}
/*
* if there was an existing set of unlinked but
* allocated inodes, preserve it in the new
* log.
*/
if (wr && wr->wr_inodescnt) {
int i;
WAPBL_PRINTF(WAPBL_PRINT_REPLAY,
("wapbl_start: reusing log with %d inodes\n",
wr->wr_inodescnt));
/*
* Its only valid to reuse the replay log if its
* the same as the new log we just opened.
*/
KDASSERT(!wapbl_replay_isopen(wr));
KASSERT(devvp->v_rdev == wr->wr_devvp->v_rdev);
KASSERT(logpbn == wr->wr_logpbn);
KASSERT(wl->wl_circ_size == wr->wr_wc_header.wc_circ_size);
KASSERT(wl->wl_circ_off == wr->wr_wc_header.wc_circ_off);
KASSERT(wl->wl_log_dev_bshift ==
wr->wr_wc_header.wc_log_dev_bshift);
KASSERT(wl->wl_fs_dev_bshift ==
wr->wr_wc_header.wc_fs_dev_bshift);
wl->wl_wc_header->wc_generation =
wr->wr_wc_header.wc_generation + 1;
for (i = 0; i < wr->wr_inodescnt; i++)
wapbl_register_inode(wl, wr->wr_inodes[i].wr_inumber,
wr->wr_inodes[i].wr_imode);
/* Make sure new transaction won't overwrite old inodes list */
KDASSERT(wapbl_transaction_len(wl) <=
wapbl_space_free(wl->wl_circ_size, wr->wr_inodeshead,
wr->wr_inodestail));
wl->wl_head = wl->wl_tail = wr->wr_inodeshead;
wl->wl_reclaimable_bytes = wl->wl_reserved_bytes =
wapbl_transaction_len(wl);
error = wapbl_write_inodes(wl, &wl->wl_head);
if (error)
goto errout;
KASSERT(wl->wl_head != wl->wl_tail);
KASSERT(wl->wl_head != 0);
}
error = wapbl_write_commit(wl, wl->wl_head, wl->wl_tail);
if (error) {
goto errout;
}
*wlp = wl;
#if defined(WAPBL_DEBUG)
wapbl_debug_wl = wl;
#endif
return 0;
errout:
wapbl_discard(wl);
wapbl_free(wl->wl_wc_scratch);
wapbl_free(wl->wl_wc_header);
#if WAPBL_UVM_ALLOC
uvm_km_free_wakeup(kernel_map, (vaddr_t) wl->wl_deallocblks,
round_page(sizeof(*wl->wl_deallocblks *
wl->wl_dealloclim)));
uvm_km_free_wakeup(kernel_map, (vaddr_t) wl->wl_dealloclens,
round_page(sizeof(*wl->wl_dealloclens *
wl->wl_dealloclim)));
#else
wapbl_free(wl->wl_deallocblks);
wapbl_free(wl->wl_dealloclens);
#endif
wapbl_inodetrk_free(wl);
wapbl_free(wl);
return error;
}
/*
* Like wapbl_flush, only discards the transaction
* completely
*/
void
wapbl_discard(struct wapbl *wl)
{
struct wapbl_entry *we;
struct buf *bp;
int i;
/*
* XXX we may consider using upgrade here
* if we want to call flush from inside a transaction
*/
rw_enter(&wl->wl_rwlock, RW_WRITER);
wl->wl_flush(wl->wl_mount, wl->wl_deallocblks, wl->wl_dealloclens,
wl->wl_dealloccnt);
#ifdef WAPBL_DEBUG_PRINT
{
struct wapbl_entry *we;
pid_t pid = -1;
lwpid_t lid = -1;
if (curproc)
pid = curproc->p_pid;
if (curlwp)
lid = curlwp->l_lid;
#ifdef WAPBL_DEBUG_BUFBYTES
WAPBL_PRINTF(WAPBL_PRINT_DISCARD,
("wapbl_discard: thread %d.%d discarding "
"transaction\n"
"\tbufcount=%zu bufbytes=%zu bcount=%zu "
"deallocs=%d inodes=%d\n"
"\terrcnt = %u, reclaimable=%zu reserved=%zu "
"unsynced=%zu\n",
pid, lid, wl->wl_bufcount, wl->wl_bufbytes,
wl->wl_bcount, wl->wl_dealloccnt,
wl->wl_inohashcnt, wl->wl_error_count,
wl->wl_reclaimable_bytes, wl->wl_reserved_bytes,
wl->wl_unsynced_bufbytes));
SIMPLEQ_FOREACH(we, &wl->wl_entries, we_entries) {
WAPBL_PRINTF(WAPBL_PRINT_DISCARD,
("\tentry: bufcount = %zu, reclaimable = %zu, "
"error = %d, unsynced = %zu\n",
we->we_bufcount, we->we_reclaimable_bytes,
we->we_error, we->we_unsynced_bufbytes));
}
#else /* !WAPBL_DEBUG_BUFBYTES */
WAPBL_PRINTF(WAPBL_PRINT_DISCARD,
("wapbl_discard: thread %d.%d discarding transaction\n"
"\tbufcount=%zu bufbytes=%zu bcount=%zu "
"deallocs=%d inodes=%d\n"
"\terrcnt = %u, reclaimable=%zu reserved=%zu\n",
pid, lid, wl->wl_bufcount, wl->wl_bufbytes,
wl->wl_bcount, wl->wl_dealloccnt,
wl->wl_inohashcnt, wl->wl_error_count,
wl->wl_reclaimable_bytes, wl->wl_reserved_bytes));
SIMPLEQ_FOREACH(we, &wl->wl_entries, we_entries) {
WAPBL_PRINTF(WAPBL_PRINT_DISCARD,
("\tentry: bufcount = %zu, reclaimable = %zu, "
"error = %d\n",
we->we_bufcount, we->we_reclaimable_bytes,
we->we_error));
}
#endif /* !WAPBL_DEBUG_BUFBYTES */
}
#endif /* WAPBL_DEBUG_PRINT */
for (i = 0; i <= wl->wl_inohashmask; i++) {
struct wapbl_ino_head *wih;
struct wapbl_ino *wi;
wih = &wl->wl_inohash[i];
while ((wi = LIST_FIRST(wih)) != NULL) {
LIST_REMOVE(wi, wi_hash);
pool_put(&wapbl_ino_pool, wi);
KASSERT(wl->wl_inohashcnt > 0);
wl->wl_inohashcnt--;
}
}
/*
* clean buffer list
*/
mutex_enter(&bufcache_lock);
mutex_enter(&wl->wl_mtx);
while ((bp = LIST_FIRST(&wl->wl_bufs)) != NULL) {
if (bbusy(bp, 0, 0, &wl->wl_mtx) == 0) {
/*
* The buffer will be unlocked and
* removed from the transaction in brelse
*/
mutex_exit(&wl->wl_mtx);
brelsel(bp, 0);
mutex_enter(&wl->wl_mtx);
}
}
mutex_exit(&wl->wl_mtx);
mutex_exit(&bufcache_lock);
/*
* Remove references to this wl from wl_entries, free any which
* no longer have buffers, others will be freed in wapbl_biodone
* when they no longer have any buffers.
*/
while ((we = SIMPLEQ_FIRST(&wl->wl_entries)) != NULL) {
SIMPLEQ_REMOVE_HEAD(&wl->wl_entries, we_entries);
/* XXX should we be accumulating wl_error_count
* and increasing reclaimable bytes ? */
we->we_wapbl = NULL;
if (we->we_bufcount == 0) {
#ifdef WAPBL_DEBUG_BUFBYTES
KASSERT(we->we_unsynced_bufbytes == 0);
#endif
wapbl_free(we);
}
}
/* Discard list of deallocs */
wl->wl_dealloccnt = 0;
/* XXX should we clear wl_reserved_bytes? */
KASSERT(wl->wl_bufbytes == 0);
KASSERT(wl->wl_bcount == 0);
KASSERT(wl->wl_bufcount == 0);
KASSERT(LIST_EMPTY(&wl->wl_bufs));
KASSERT(SIMPLEQ_EMPTY(&wl->wl_entries));
KASSERT(wl->wl_inohashcnt == 0);
rw_exit(&wl->wl_rwlock);
}
int
wapbl_stop(struct wapbl *wl, int force)
{
struct vnode *vp;
int error;
WAPBL_PRINTF(WAPBL_PRINT_OPEN, ("wapbl_stop called\n"));
error = wapbl_flush(wl, 1);
if (error) {
if (force)
wapbl_discard(wl);
else
return error;
}
/* Unlinked inodes persist after a flush */
if (wl->wl_inohashcnt) {
if (force) {
wapbl_discard(wl);
} else {
return EBUSY;
}
}
KASSERT(wl->wl_bufbytes == 0);
KASSERT(wl->wl_bcount == 0);
KASSERT(wl->wl_bufcount == 0);
KASSERT(LIST_EMPTY(&wl->wl_bufs));
KASSERT(wl->wl_dealloccnt == 0);
KASSERT(SIMPLEQ_EMPTY(&wl->wl_entries));
KASSERT(wl->wl_inohashcnt == 0);
vp = wl->wl_logvp;
wapbl_free(wl->wl_wc_scratch);
wapbl_free(wl->wl_wc_header);
#if WAPBL_UVM_ALLOC
uvm_km_free_wakeup(kernel_map, (vaddr_t) wl->wl_deallocblks,
round_page(sizeof(*wl->wl_deallocblks *
wl->wl_dealloclim)));
uvm_km_free_wakeup(kernel_map, (vaddr_t) wl->wl_dealloclens,
round_page(sizeof(*wl->wl_dealloclens *
wl->wl_dealloclim)));
#else
wapbl_free(wl->wl_deallocblks);
wapbl_free(wl->wl_dealloclens);
#endif
wapbl_inodetrk_free(wl);
cv_destroy(&wl->wl_reclaimable_cv);
mutex_destroy(&wl->wl_mtx);
rw_destroy(&wl->wl_rwlock);
wapbl_free(wl);
return 0;
}
static int
wapbl_doio(void *data, size_t len, struct vnode *devvp, daddr_t pbn, int flags)
{
struct pstats *pstats = curlwp->l_proc->p_stats;
struct buf *bp;
int error;
KASSERT((flags & ~(B_WRITE | B_READ)) == 0);
KASSERT(devvp->v_type == VBLK);
if ((flags & (B_WRITE | B_READ)) == B_WRITE) {
mutex_enter(&devvp->v_interlock);
devvp->v_numoutput++;
mutex_exit(&devvp->v_interlock);
pstats->p_ru.ru_oublock++;
} else {
pstats->p_ru.ru_inblock++;
}
bp = getiobuf(devvp, true);
bp->b_flags = flags;
bp->b_cflags = BC_BUSY; /* silly & dubious */
bp->b_dev = devvp->v_rdev;
bp->b_data = data;
bp->b_bufsize = bp->b_resid = bp->b_bcount = len;
bp->b_blkno = pbn;
WAPBL_PRINTF(WAPBL_PRINT_IO,
("wapbl_doio: %s %d bytes at block %"PRId64" on dev 0x%x\n",
BUF_ISWRITE(bp) ? "write" : "read", bp->b_bcount,
bp->b_blkno, bp->b_dev));
VOP_STRATEGY(devvp, bp);
error = biowait(bp);
putiobuf(bp);
if (error) {
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("wapbl_doio: %s %zu bytes at block %" PRId64
" on dev 0x%x failed with error %d\n",
(((flags & (B_WRITE | B_READ)) == B_WRITE) ?
"write" : "read"),
len, pbn, devvp->v_rdev, error));
}
return error;
}
int
wapbl_write(void *data, size_t len, struct vnode *devvp, daddr_t pbn)
{
return wapbl_doio(data, len, devvp, pbn, B_WRITE);
}
int
wapbl_read(void *data, size_t len, struct vnode *devvp, daddr_t pbn)
{
return wapbl_doio(data, len, devvp, pbn, B_READ);
}
/*
* Off is byte offset returns new offset for next write
* handles log wraparound
*/
static int
wapbl_circ_write(struct wapbl *wl, void *data, size_t len, off_t *offp)
{
size_t slen;
off_t off = *offp;
int error;
KDASSERT(((len >> wl->wl_log_dev_bshift) <<
wl->wl_log_dev_bshift) == len);
if (off < wl->wl_circ_off)
off = wl->wl_circ_off;
slen = wl->wl_circ_off + wl->wl_circ_size - off;
if (slen < len) {
error = wapbl_write(data, slen, wl->wl_devvp,
wl->wl_logpbn + (off >> wl->wl_log_dev_bshift));
if (error)
return error;
data = (uint8_t *)data + slen;
len -= slen;
off = wl->wl_circ_off;
}
error = wapbl_write(data, len, wl->wl_devvp,
wl->wl_logpbn + (off >> wl->wl_log_dev_bshift));
if (error)
return error;
off += len;
if (off >= wl->wl_circ_off + wl->wl_circ_size)
off = wl->wl_circ_off;
*offp = off;
return 0;
}
/****************************************************************/
int
wapbl_begin(struct wapbl *wl, const char *file, int line)
{
int doflush;
unsigned lockcount;
krw_t op;
KDASSERT(wl);
/*
* XXX: The original code calls for the use of a RW_READER lock
* here, but it turns out there are performance issues with high
* metadata-rate workloads (e.g. multiple simultaneous tar
* extractions). For now, we force the lock to be RW_WRITER,
* since that currently has the best performance characteristics
* (even for a single tar-file extraction).
*
*/
#define WAPBL_DEBUG_SERIALIZE 1
#ifdef WAPBL_DEBUG_SERIALIZE
op = RW_WRITER;
#else
op = RW_READER;
#endif
/*
* XXX this needs to be made much more sophisticated.
* perhaps each wapbl_begin could reserve a specified
* number of buffers and bytes.
*/
mutex_enter(&wl->wl_mtx);
lockcount = wl->wl_lock_count;
doflush = ((wl->wl_bufbytes + (lockcount * MAXPHYS)) >
wl->wl_bufbytes_max / 2) ||
((wl->wl_bufcount + (lockcount * 10)) >
wl->wl_bufcount_max / 2) ||
(wapbl_transaction_len(wl) > wl->wl_circ_size / 2);
mutex_exit(&wl->wl_mtx);
if (doflush) {
WAPBL_PRINTF(WAPBL_PRINT_FLUSH,
("force flush lockcnt=%d bufbytes=%zu "
"(max=%zu) bufcount=%zu (max=%zu)\n",
lockcount, wl->wl_bufbytes,
wl->wl_bufbytes_max, wl->wl_bufcount,
wl->wl_bufcount_max));
}
if (doflush) {
int error = wapbl_flush(wl, 0);
if (error)
return error;
}
rw_enter(&wl->wl_rwlock, op);
mutex_enter(&wl->wl_mtx);
wl->wl_lock_count++;
mutex_exit(&wl->wl_mtx);
#if defined(WAPBL_DEBUG_PRINT) && defined(WAPBL_DEBUG_SERIALIZE)
WAPBL_PRINTF(WAPBL_PRINT_TRANSACTION,
("wapbl_begin thread %d.%d with bufcount=%zu "
"bufbytes=%zu bcount=%zu at %s:%d\n",
curproc->p_pid, curlwp->l_lid, wl->wl_bufcount,
wl->wl_bufbytes, wl->wl_bcount, file, line));
#endif
return 0;
}
void
wapbl_end(struct wapbl *wl)
{
#if defined(WAPBL_DEBUG_PRINT) && defined(WAPBL_DEBUG_SERIALIZE)
WAPBL_PRINTF(WAPBL_PRINT_TRANSACTION,
("wapbl_end thread %d.%d with bufcount=%zu "
"bufbytes=%zu bcount=%zu\n",
curproc->p_pid, curlwp->l_lid, wl->wl_bufcount,
wl->wl_bufbytes, wl->wl_bcount));
#endif
mutex_enter(&wl->wl_mtx);
KASSERT(wl->wl_lock_count > 0);
wl->wl_lock_count--;
mutex_exit(&wl->wl_mtx);
rw_exit(&wl->wl_rwlock);
}
void
wapbl_add_buf(struct wapbl *wl, struct buf * bp)
{
KASSERT(bp->b_cflags & BC_BUSY);
KASSERT(bp->b_vp);
wapbl_jlock_assert(wl);
#if 0
/*
* XXX this might be an issue for swapfiles.
* see uvm_swap.c:1702
*
* XXX2 why require it then? leap of semantics?
*/
KASSERT((bp->b_cflags & BC_NOCACHE) == 0);
#endif
mutex_enter(&wl->wl_mtx);
if (bp->b_flags & B_LOCKED) {
LIST_REMOVE(bp, b_wapbllist);
WAPBL_PRINTF(WAPBL_PRINT_BUFFER2,
("wapbl_add_buf thread %d.%d re-adding buf %p "
"with %d bytes %d bcount\n",
curproc->p_pid, curlwp->l_lid, bp, bp->b_bufsize,
bp->b_bcount));
} else {
/* unlocked by dirty buffers shouldn't exist */
KASSERT(!(bp->b_oflags & BO_DELWRI));
wl->wl_bufbytes += bp->b_bufsize;
wl->wl_bcount += bp->b_bcount;
wl->wl_bufcount++;
WAPBL_PRINTF(WAPBL_PRINT_BUFFER,
("wapbl_add_buf thread %d.%d adding buf %p "
"with %d bytes %d bcount\n",
curproc->p_pid, curlwp->l_lid, bp, bp->b_bufsize,
bp->b_bcount));
}
LIST_INSERT_HEAD(&wl->wl_bufs, bp, b_wapbllist);
mutex_exit(&wl->wl_mtx);
bp->b_flags |= B_LOCKED;
}
static void
wapbl_remove_buf_locked(struct wapbl * wl, struct buf *bp)
{
KASSERT(mutex_owned(&wl->wl_mtx));
KASSERT(bp->b_cflags & BC_BUSY);
wapbl_jlock_assert(wl);
#if 0
/*
* XXX this might be an issue for swapfiles.
* see uvm_swap.c:1725
*
* XXXdeux: see above
*/
KASSERT((bp->b_flags & BC_NOCACHE) == 0);
#endif
KASSERT(bp->b_flags & B_LOCKED);
WAPBL_PRINTF(WAPBL_PRINT_BUFFER,
("wapbl_remove_buf thread %d.%d removing buf %p with "
"%d bytes %d bcount\n",
curproc->p_pid, curlwp->l_lid, bp, bp->b_bufsize, bp->b_bcount));
KASSERT(wl->wl_bufbytes >= bp->b_bufsize);
wl->wl_bufbytes -= bp->b_bufsize;
KASSERT(wl->wl_bcount >= bp->b_bcount);
wl->wl_bcount -= bp->b_bcount;
KASSERT(wl->wl_bufcount > 0);
wl->wl_bufcount--;
KASSERT((wl->wl_bufcount == 0) == (wl->wl_bufbytes == 0));
KASSERT((wl->wl_bufcount == 0) == (wl->wl_bcount == 0));
LIST_REMOVE(bp, b_wapbllist);
bp->b_flags &= ~B_LOCKED;
}
/* called from brelsel() in vfs_bio among other places */
void
wapbl_remove_buf(struct wapbl * wl, struct buf *bp)
{
mutex_enter(&wl->wl_mtx);
wapbl_remove_buf_locked(wl, bp);
mutex_exit(&wl->wl_mtx);
}
void
wapbl_resize_buf(struct wapbl *wl, struct buf *bp, long oldsz, long oldcnt)
{
KASSERT(bp->b_cflags & BC_BUSY);
/*
* XXX: why does this depend on B_LOCKED? otherwise the buf
* is not for a transaction? if so, why is this called in the
* first place?
*/
if (bp->b_flags & B_LOCKED) {
mutex_enter(&wl->wl_mtx);
wl->wl_bufbytes += bp->b_bufsize - oldsz;
wl->wl_bcount += bp->b_bcount - oldcnt;
mutex_exit(&wl->wl_mtx);
}
}
#endif /* _KERNEL */
/****************************************************************/
/* Some utility inlines */
/* This is used to advance the pointer at old to new value at old+delta */
static __inline off_t
wapbl_advance(size_t size, size_t off, off_t old, size_t delta)
{
off_t new;
/* Define acceptable ranges for inputs. */
KASSERT(delta <= size);
KASSERT((old == 0) || (old >= off));
KASSERT(old < (size + off));
if ((old == 0) && (delta != 0))
new = off + delta;
else if ((old + delta) < (size + off))
new = old + delta;
else
new = (old + delta) - size;
/* Note some interesting axioms */
KASSERT((delta != 0) || (new == old));
KASSERT((delta == 0) || (new != 0));
KASSERT((delta != (size)) || (new == old));
/* Define acceptable ranges for output. */
KASSERT((new == 0) || (new >= off));
KASSERT(new < (size + off));
return new;
}
static __inline size_t
wapbl_space_used(size_t avail, off_t head, off_t tail)
{
if (tail == 0) {
KASSERT(head == 0);
return 0;
}
return ((head + (avail - 1) - tail) % avail) + 1;
}
static __inline size_t
wapbl_space_free(size_t avail, off_t head, off_t tail)
{
return avail - wapbl_space_used(avail, head, tail);
}
static __inline void
wapbl_advance_head(size_t size, size_t off, size_t delta, off_t *headp,
off_t *tailp)
{
off_t head = *headp;
off_t tail = *tailp;
KASSERT(delta <= wapbl_space_free(size, head, tail));
head = wapbl_advance(size, off, head, delta);
if ((tail == 0) && (head != 0))
tail = off;
*headp = head;
*tailp = tail;
}
static __inline void
wapbl_advance_tail(size_t size, size_t off, size_t delta, off_t *headp,
off_t *tailp)
{
off_t head = *headp;
off_t tail = *tailp;
KASSERT(delta <= wapbl_space_used(size, head, tail));
tail = wapbl_advance(size, off, tail, delta);
if (head == tail) {
head = tail = 0;
}
*headp = head;
*tailp = tail;
}
#ifdef _KERNEL
/****************************************************************/
/*
* Remove transactions whose buffers are completely flushed to disk.
* Will block until at least minfree space is available.
* only intended to be called from inside wapbl_flush and therefore
* does not protect against commit races with itself or with flush.
*/
static int
wapbl_truncate(struct wapbl *wl, size_t minfree, int waitonly)
{
size_t delta;
size_t avail;
off_t head;
off_t tail;
int error = 0;
KASSERT(minfree <= (wl->wl_circ_size - wl->wl_reserved_bytes));
KASSERT(rw_write_held(&wl->wl_rwlock));
mutex_enter(&wl->wl_mtx);
/*
* First check to see if we have to do a commit
* at all.
*/
avail = wapbl_space_free(wl->wl_circ_size, wl->wl_head, wl->wl_tail);
if (minfree < avail) {
mutex_exit(&wl->wl_mtx);
return 0;
}
minfree -= avail;
while ((wl->wl_error_count == 0) &&
(wl->wl_reclaimable_bytes < minfree)) {
WAPBL_PRINTF(WAPBL_PRINT_TRUNCATE,
("wapbl_truncate: sleeping on %p wl=%p bytes=%zd "
"minfree=%zd\n",
&wl->wl_reclaimable_bytes, wl, wl->wl_reclaimable_bytes,
minfree));
cv_wait(&wl->wl_reclaimable_cv, &wl->wl_mtx);
}
if (wl->wl_reclaimable_bytes < minfree) {
KASSERT(wl->wl_error_count);
/* XXX maybe get actual error from buffer instead someday? */
error = EIO;
}
head = wl->wl_head;
tail = wl->wl_tail;
delta = wl->wl_reclaimable_bytes;
/* If all of of the entries are flushed, then be sure to keep
* the reserved bytes reserved. Watch out for discarded transactions,
* which could leave more bytes reserved than are reclaimable.
*/
if (SIMPLEQ_EMPTY(&wl->wl_entries) &&
(delta >= wl->wl_reserved_bytes)) {
delta -= wl->wl_reserved_bytes;
}
wapbl_advance_tail(wl->wl_circ_size, wl->wl_circ_off, delta, &head,
&tail);
KDASSERT(wl->wl_reserved_bytes <=
wapbl_space_used(wl->wl_circ_size, head, tail));
mutex_exit(&wl->wl_mtx);
if (error)
return error;
if (waitonly)
return 0;
/*
* This is where head, tail and delta are unprotected
* from races against itself or flush. This is ok since
* we only call this routine from inside flush itself.
*
* XXX: how can it race against itself when accessed only
* from behind the write-locked rwlock?
*/
error = wapbl_write_commit(wl, head, tail);
if (error)
return error;
wl->wl_head = head;
wl->wl_tail = tail;
mutex_enter(&wl->wl_mtx);
KASSERT(wl->wl_reclaimable_bytes >= delta);
wl->wl_reclaimable_bytes -= delta;
mutex_exit(&wl->wl_mtx);
WAPBL_PRINTF(WAPBL_PRINT_TRUNCATE,
("wapbl_truncate thread %d.%d truncating %zu bytes\n",
curproc->p_pid, curlwp->l_lid, delta));
return 0;
}
/****************************************************************/
void
wapbl_biodone(struct buf *bp)
{
struct wapbl_entry *we = bp->b_private;
struct wapbl *wl = we->we_wapbl;
/*
* Handle possible flushing of buffers after log has been
* decomissioned.
*/
if (!wl) {
KASSERT(we->we_bufcount > 0);
we->we_bufcount--;
#ifdef WAPBL_DEBUG_BUFBYTES
KASSERT(we->we_unsynced_bufbytes >= bp->b_bufsize);
we->we_unsynced_bufbytes -= bp->b_bufsize;
#endif
if (we->we_bufcount == 0) {
#ifdef WAPBL_DEBUG_BUFBYTES
KASSERT(we->we_unsynced_bufbytes == 0);
#endif
wapbl_free(we);
}
brelse(bp, 0);
return;
}
#ifdef ohbother
KDASSERT(bp->b_flags & B_DONE);
KDASSERT(!(bp->b_flags & B_DELWRI));
KDASSERT(bp->b_flags & B_ASYNC);
KDASSERT(bp->b_flags & B_BUSY);
KDASSERT(!(bp->b_flags & B_LOCKED));
KDASSERT(!(bp->b_flags & B_READ));
KDASSERT(!(bp->b_flags & B_INVAL));
KDASSERT(!(bp->b_flags & B_NOCACHE));
#endif
if (bp->b_error) {
#ifdef notyet /* Can't currently handle possible dirty buffer reuse */
XXXpooka: interfaces not fully updated
Note: this was not enabled in the original patch
against netbsd4 either. I don't know if comment
above is true or not.
/*
* If an error occurs, report the error and leave the
* buffer as a delayed write on the LRU queue.
* restarting the write would likely result in
* an error spinloop, so let it be done harmlessly
* by the syncer.
*/
bp->b_flags &= ~(B_DONE);
simple_unlock(&bp->b_interlock);
if (we->we_error == 0) {
mutex_enter(&wl->wl_mtx);
wl->wl_error_count++;
mutex_exit(&wl->wl_mtx);
cv_broadcast(&wl->wl_reclaimable_cv);
}
we->we_error = bp->b_error;
bp->b_error = 0;
brelse(bp);
return;
#else
/* For now, just mark the log permanently errored out */
mutex_enter(&wl->wl_mtx);
if (wl->wl_error_count == 0) {
wl->wl_error_count++;
cv_broadcast(&wl->wl_reclaimable_cv);
}
mutex_exit(&wl->wl_mtx);
#endif
}
mutex_enter(&wl->wl_mtx);
KASSERT(we->we_bufcount > 0);
we->we_bufcount--;
#ifdef WAPBL_DEBUG_BUFBYTES
KASSERT(we->we_unsynced_bufbytes >= bp->b_bufsize);
we->we_unsynced_bufbytes -= bp->b_bufsize;
KASSERT(wl->wl_unsynced_bufbytes >= bp->b_bufsize);
wl->wl_unsynced_bufbytes -= bp->b_bufsize;
#endif
/*
* If the current transaction can be reclaimed, start
* at the beginning and reclaim any consecutive reclaimable
* transactions. If we successfully reclaim anything,
* then wakeup anyone waiting for the reclaim.
*/
if (we->we_bufcount == 0) {
size_t delta = 0;
int errcnt = 0;
#ifdef WAPBL_DEBUG_BUFBYTES
KDASSERT(we->we_unsynced_bufbytes == 0);
#endif
/*
* clear any posted error, since the buffer it came from
* has successfully flushed by now
*/
while ((we = SIMPLEQ_FIRST(&wl->wl_entries)) &&
(we->we_bufcount == 0)) {
delta += we->we_reclaimable_bytes;
if (we->we_error)
errcnt++;
SIMPLEQ_REMOVE_HEAD(&wl->wl_entries, we_entries);
wapbl_free(we);
}
if (delta) {
wl->wl_reclaimable_bytes += delta;
KASSERT(wl->wl_error_count >= errcnt);
wl->wl_error_count -= errcnt;
cv_broadcast(&wl->wl_reclaimable_cv);
}
}
mutex_exit(&wl->wl_mtx);
brelse(bp, 0);
}
/*
* Write transactions to disk + start I/O for contents
*/
int
wapbl_flush(struct wapbl *wl, int waitfor)
{
struct buf *bp;
struct wapbl_entry *we;
off_t off;
off_t head;
off_t tail;
size_t delta = 0;
size_t flushsize;
size_t reserved;
int error = 0;
/*
* Do a quick check to see if a full flush can be skipped
* This assumes that the flush callback does not need to be called
* unless there are other outstanding bufs.
*/
if (!waitfor) {
size_t nbufs;
mutex_enter(&wl->wl_mtx); /* XXX need mutex here to
protect the KASSERTS */
nbufs = wl->wl_bufcount;
KASSERT((wl->wl_bufcount == 0) == (wl->wl_bufbytes == 0));
KASSERT((wl->wl_bufcount == 0) == (wl->wl_bcount == 0));
mutex_exit(&wl->wl_mtx);
if (nbufs == 0)
return 0;
}
/*
* XXX we may consider using LK_UPGRADE here
* if we want to call flush from inside a transaction
*/
rw_enter(&wl->wl_rwlock, RW_WRITER);
wl->wl_flush(wl->wl_mount, wl->wl_deallocblks, wl->wl_dealloclens,
wl->wl_dealloccnt);
/*
* Now that we are fully locked and flushed,
* do another check for nothing to do.
*/
if (wl->wl_bufcount == 0) {
goto out;
}
#if 0
WAPBL_PRINTF(WAPBL_PRINT_FLUSH,
("wapbl_flush thread %d.%d flushing entries with "
"bufcount=%zu bufbytes=%zu\n",
curproc->p_pid, curlwp->l_lid, wl->wl_bufcount,
wl->wl_bufbytes));
#endif
/* Calculate amount of space needed to flush */
flushsize = wapbl_transaction_len(wl);
if (flushsize > (wl->wl_circ_size - wl->wl_reserved_bytes)) {
/*
* XXX this could be handled more gracefully, perhaps place
* only a partial transaction in the log and allow the
* remaining to flush without the protection of the journal.
*/
panic("wapbl_flush: current transaction too big to flush\n");
}
error = wapbl_truncate(wl, flushsize, 0);
if (error)
goto out2;
off = wl->wl_head;
KASSERT((off == 0) || ((off >= wl->wl_circ_off) &&
(off < wl->wl_circ_off + wl->wl_circ_size)));
error = wapbl_write_blocks(wl, &off);
if (error)
goto out2;
error = wapbl_write_revocations(wl, &off);
if (error)
goto out2;
error = wapbl_write_inodes(wl, &off);
if (error)
goto out2;
reserved = 0;
if (wl->wl_inohashcnt)
reserved = wapbl_transaction_inodes_len(wl);
head = wl->wl_head;
tail = wl->wl_tail;
wapbl_advance_head(wl->wl_circ_size, wl->wl_circ_off, flushsize,
&head, &tail);
#ifdef WAPBL_DEBUG
if (head != off) {
panic("lost head! head=%"PRIdMAX" tail=%" PRIdMAX
" off=%"PRIdMAX" flush=%zu\n",
(intmax_t)head, (intmax_t)tail, (intmax_t)off,
flushsize);
}
#else
KASSERT(head == off);
#endif
/* Opportunistically move the tail forward if we can */
if (!wapbl_lazy_truncate) {
mutex_enter(&wl->wl_mtx);
delta = wl->wl_reclaimable_bytes;
mutex_exit(&wl->wl_mtx);
wapbl_advance_tail(wl->wl_circ_size, wl->wl_circ_off, delta,
&head, &tail);
}
error = wapbl_write_commit(wl, head, tail);
if (error)
goto out2;
/* poolme? or kmemme? */
we = wapbl_calloc(1, sizeof(*we));
#ifdef WAPBL_DEBUG_BUFBYTES
WAPBL_PRINTF(WAPBL_PRINT_FLUSH,
("wapbl_flush: thread %d.%d head+=%zu tail+=%zu used=%zu"
" unsynced=%zu"
"\n\tbufcount=%zu bufbytes=%zu bcount=%zu deallocs=%d "
"inodes=%d\n",
curproc->p_pid, curlwp->l_lid, flushsize, delta,
wapbl_space_used(wl->wl_circ_size, head, tail),
wl->wl_unsynced_bufbytes, wl->wl_bufcount,
wl->wl_bufbytes, wl->wl_bcount, wl->wl_dealloccnt,
wl->wl_inohashcnt));
#else
WAPBL_PRINTF(WAPBL_PRINT_FLUSH,
("wapbl_flush: thread %d.%d head+=%zu tail+=%zu used=%zu"
"\n\tbufcount=%zu bufbytes=%zu bcount=%zu deallocs=%d "
"inodes=%d\n",
curproc->p_pid, curlwp->l_lid, flushsize, delta,
wapbl_space_used(wl->wl_circ_size, head, tail),
wl->wl_bufcount, wl->wl_bufbytes, wl->wl_bcount,
wl->wl_dealloccnt, wl->wl_inohashcnt));
#endif
mutex_enter(&bufcache_lock);
mutex_enter(&wl->wl_mtx);
wl->wl_reserved_bytes = reserved;
wl->wl_head = head;
wl->wl_tail = tail;
KASSERT(wl->wl_reclaimable_bytes >= delta);
wl->wl_reclaimable_bytes -= delta;
wl->wl_dealloccnt = 0;
#ifdef WAPBL_DEBUG_BUFBYTES
wl->wl_unsynced_bufbytes += wl->wl_bufbytes;
#endif
we->we_wapbl = wl;
we->we_bufcount = wl->wl_bufcount;
#ifdef WAPBL_DEBUG_BUFBYTES
we->we_unsynced_bufbytes = wl->wl_bufbytes;
#endif
we->we_reclaimable_bytes = flushsize;
we->we_error = 0;
SIMPLEQ_INSERT_TAIL(&wl->wl_entries, we, we_entries);
/*
* this flushes bufs in reverse order than they were queued
* it shouldn't matter, but if we care we could use TAILQ instead.
* XXX Note they will get put on the lru queue when they flush
* so we might actually want to change this to preserve order.
*/
while ((bp = LIST_FIRST(&wl->wl_bufs)) != NULL) {
if (bbusy(bp, 0, 0, &wl->wl_mtx)) {
continue;
}
bp->b_iodone = wapbl_biodone;
bp->b_private = we;
bremfree(bp);
wapbl_remove_buf_locked(wl, bp);
mutex_exit(&wl->wl_mtx);
mutex_exit(&bufcache_lock);
bawrite(bp);
mutex_enter(&bufcache_lock);
mutex_enter(&wl->wl_mtx);
}
mutex_exit(&wl->wl_mtx);
mutex_exit(&bufcache_lock);
#if 0
WAPBL_PRINTF(WAPBL_PRINT_FLUSH,
("wapbl_flush thread %d.%d done flushing entries...\n",
curproc->p_pid, curlwp->l_lid));
#endif
out:
/*
* If the waitfor flag is set, don't return until everything is
* fully flushed and the on disk log is empty.
*/
if (waitfor) {
error = wapbl_truncate(wl, wl->wl_circ_size -
wl->wl_reserved_bytes, wapbl_lazy_truncate);
}
out2:
if (error) {
wl->wl_flush_abort(wl->wl_mount, wl->wl_deallocblks,
wl->wl_dealloclens, wl->wl_dealloccnt);
}
#ifdef WAPBL_DEBUG_PRINT
if (error) {
pid_t pid = -1;
lwpid_t lid = -1;
if (curproc)
pid = curproc->p_pid;
if (curlwp)
lid = curlwp->l_lid;
mutex_enter(&wl->wl_mtx);
#ifdef WAPBL_DEBUG_BUFBYTES
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("wapbl_flush: thread %d.%d aborted flush: "
"error = %d\n"
"\tbufcount=%zu bufbytes=%zu bcount=%zu "
"deallocs=%d inodes=%d\n"
"\terrcnt = %d, reclaimable=%zu reserved=%zu "
"unsynced=%zu\n",
pid, lid, error, wl->wl_bufcount,
wl->wl_bufbytes, wl->wl_bcount,
wl->wl_dealloccnt, wl->wl_inohashcnt,
wl->wl_error_count, wl->wl_reclaimable_bytes,
wl->wl_reserved_bytes, wl->wl_unsynced_bufbytes));
SIMPLEQ_FOREACH(we, &wl->wl_entries, we_entries) {
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("\tentry: bufcount = %zu, reclaimable = %zu, "
"error = %d, unsynced = %zu\n",
we->we_bufcount, we->we_reclaimable_bytes,
we->we_error, we->we_unsynced_bufbytes));
}
#else
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("wapbl_flush: thread %d.%d aborted flush: "
"error = %d\n"
"\tbufcount=%zu bufbytes=%zu bcount=%zu "
"deallocs=%d inodes=%d\n"
"\terrcnt = %d, reclaimable=%zu reserved=%zu\n",
pid, lid, error, wl->wl_bufcount,
wl->wl_bufbytes, wl->wl_bcount,
wl->wl_dealloccnt, wl->wl_inohashcnt,
wl->wl_error_count, wl->wl_reclaimable_bytes,
wl->wl_reserved_bytes));
SIMPLEQ_FOREACH(we, &wl->wl_entries, we_entries) {
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("\tentry: bufcount = %zu, reclaimable = %zu, "
"error = %d\n", we->we_bufcount,
we->we_reclaimable_bytes, we->we_error));
}
#endif
mutex_exit(&wl->wl_mtx);
}
#endif
rw_exit(&wl->wl_rwlock);
return error;
}
/****************************************************************/
void
wapbl_jlock_assert(struct wapbl *wl)
{
#ifdef WAPBL_DEBUG_SERIALIZE
KASSERT(rw_write_held(&wl->wl_rwlock));
#else
KASSERT(rw_read_held(&wl->wl_rwlock) || rw_write_held(&wl->wl_rwlock));
#endif
}
void
wapbl_junlock_assert(struct wapbl *wl)
{
#ifdef WAPBL_DEBUG_SERIALIZE
KASSERT(!rw_write_held(&wl->wl_rwlock));
#endif
}
/****************************************************************/
/* locks missing */
void
wapbl_print(struct wapbl *wl,
int full,
void (*pr)(const char *, ...))
{
struct buf *bp;
struct wapbl_entry *we;
(*pr)("wapbl %p", wl);
(*pr)("\nlogvp = %p, devvp = %p, logpbn = %"PRId64"\n",
wl->wl_logvp, wl->wl_devvp, wl->wl_logpbn);
(*pr)("circ = %zu, header = %zu, head = %"PRIdMAX" tail = %"PRIdMAX"\n",
wl->wl_circ_size, wl->wl_circ_off,
(intmax_t)wl->wl_head, (intmax_t)wl->wl_tail);
(*pr)("fs_dev_bshift = %d, log_dev_bshift = %d\n",
wl->wl_log_dev_bshift, wl->wl_fs_dev_bshift);
#ifdef WAPBL_DEBUG_BUFBYTES
(*pr)("bufcount = %zu, bufbytes = %zu bcount = %zu reclaimable = %zu "
"reserved = %zu errcnt = %d unsynced = %zu\n",
wl->wl_bufcount, wl->wl_bufbytes, wl->wl_bcount,
wl->wl_reclaimable_bytes, wl->wl_reserved_bytes,
wl->wl_error_count, wl->wl_unsynced_bufbytes);
#else
(*pr)("bufcount = %zu, bufbytes = %zu bcount = %zu reclaimable = %zu "
"reserved = %zu errcnt = %d\n", wl->wl_bufcount, wl->wl_bufbytes,
wl->wl_bcount, wl->wl_reclaimable_bytes, wl->wl_reserved_bytes,
wl->wl_error_count);
#endif
(*pr)("\tdealloccnt = %d, dealloclim = %d\n",
wl->wl_dealloccnt, wl->wl_dealloclim);
(*pr)("\tinohashcnt = %d, inohashmask = 0x%08x\n",
wl->wl_inohashcnt, wl->wl_inohashmask);
(*pr)("entries:\n");
SIMPLEQ_FOREACH(we, &wl->wl_entries, we_entries) {
#ifdef WAPBL_DEBUG_BUFBYTES
(*pr)("\tbufcount = %zu, reclaimable = %zu, error = %d, "
"unsynced = %zu\n",
we->we_bufcount, we->we_reclaimable_bytes,
we->we_error, we->we_unsynced_bufbytes);
#else
(*pr)("\tbufcount = %zu, reclaimable = %zu, error = %d\n",
we->we_bufcount, we->we_reclaimable_bytes, we->we_error);
#endif
}
if (full) {
int cnt = 0;
(*pr)("bufs =");
LIST_FOREACH(bp, &wl->wl_bufs, b_wapbllist) {
if (!LIST_NEXT(bp, b_wapbllist)) {
(*pr)(" %p", bp);
} else if ((++cnt % 6) == 0) {
(*pr)(" %p,\n\t", bp);
} else {
(*pr)(" %p,", bp);
}
}
(*pr)("\n");
(*pr)("dealloced blks = ");
{
int i;
cnt = 0;
for (i = 0; i < wl->wl_dealloccnt; i++) {
(*pr)(" %"PRId64":%d,",
wl->wl_deallocblks[i],
wl->wl_dealloclens[i]);
if ((++cnt % 4) == 0) {
(*pr)("\n\t");
}
}
}
(*pr)("\n");
(*pr)("registered inodes = ");
{
int i;
cnt = 0;
for (i = 0; i <= wl->wl_inohashmask; i++) {
struct wapbl_ino_head *wih;
struct wapbl_ino *wi;
wih = &wl->wl_inohash[i];
LIST_FOREACH(wi, wih, wi_hash) {
if (wi->wi_ino == 0)
continue;
(*pr)(" %"PRId32"/0%06"PRIo32",",
wi->wi_ino, wi->wi_mode);
if ((++cnt % 4) == 0) {
(*pr)("\n\t");
}
}
}
(*pr)("\n");
}
}
}
#if defined(WAPBL_DEBUG) || defined(DDB)
void
wapbl_dump(struct wapbl *wl)
{
#if defined(WAPBL_DEBUG)
if (!wl)
wl = wapbl_debug_wl;
#endif
if (!wl)
return;
wapbl_print(wl, 1, printf);
}
#endif
/****************************************************************/
void
wapbl_register_deallocation(struct wapbl *wl, daddr_t blk, int len)
{
wapbl_jlock_assert(wl);
/* XXX should eventually instead tie this into resource estimation */
/* XXX this KASSERT needs locking/mutex analysis */
KASSERT(wl->wl_dealloccnt < wl->wl_dealloclim);
wl->wl_deallocblks[wl->wl_dealloccnt] = blk;
wl->wl_dealloclens[wl->wl_dealloccnt] = len;
wl->wl_dealloccnt++;
WAPBL_PRINTF(WAPBL_PRINT_ALLOC,
("wapbl_register_deallocation: blk=%"PRId64" len=%d\n", blk, len));
}
/****************************************************************/
static void
wapbl_inodetrk_init(struct wapbl *wl, u_int size)
{
wl->wl_inohash = hashinit(size, HASH_LIST, true, &wl->wl_inohashmask);
if (atomic_inc_uint_nv(&wapbl_ino_pool_refcount) == 1) {
pool_init(&wapbl_ino_pool, sizeof(struct wapbl_ino), 0, 0, 0,
"wapblinopl", &pool_allocator_nointr, IPL_NONE);
}
}
static void
wapbl_inodetrk_free(struct wapbl *wl)
{
/* XXX this KASSERT needs locking/mutex analysis */
KASSERT(wl->wl_inohashcnt == 0);
hashdone(wl->wl_inohash, HASH_LIST, wl->wl_inohashmask);
if (atomic_dec_uint_nv(&wapbl_ino_pool_refcount) == 0) {
pool_destroy(&wapbl_ino_pool);
}
}
static struct wapbl_ino *
wapbl_inodetrk_get(struct wapbl *wl, ino_t ino)
{
struct wapbl_ino_head *wih;
struct wapbl_ino *wi;
KASSERT(mutex_owned(&wl->wl_mtx));
wih = &wl->wl_inohash[ino & wl->wl_inohashmask];
LIST_FOREACH(wi, wih, wi_hash) {
if (ino == wi->wi_ino)
return wi;
}
return 0;
}
void
wapbl_register_inode(struct wapbl *wl, ino_t ino, mode_t mode)
{
struct wapbl_ino_head *wih;
struct wapbl_ino *wi;
wi = pool_get(&wapbl_ino_pool, PR_WAITOK);
mutex_enter(&wl->wl_mtx);
if (wapbl_inodetrk_get(wl, ino) == NULL) {
wi->wi_ino = ino;
wi->wi_mode = mode;
wih = &wl->wl_inohash[ino & wl->wl_inohashmask];
LIST_INSERT_HEAD(wih, wi, wi_hash);
wl->wl_inohashcnt++;
WAPBL_PRINTF(WAPBL_PRINT_INODE,
("wapbl_register_inode: ino=%"PRId64"\n", ino));
mutex_exit(&wl->wl_mtx);
} else {
mutex_exit(&wl->wl_mtx);
pool_put(&wapbl_ino_pool, wi);
}
}
void
wapbl_unregister_inode(struct wapbl *wl, ino_t ino, mode_t mode)
{
struct wapbl_ino *wi;
mutex_enter(&wl->wl_mtx);
wi = wapbl_inodetrk_get(wl, ino);
if (wi) {
WAPBL_PRINTF(WAPBL_PRINT_INODE,
("wapbl_unregister_inode: ino=%"PRId64"\n", ino));
KASSERT(wl->wl_inohashcnt > 0);
wl->wl_inohashcnt--;
LIST_REMOVE(wi, wi_hash);
mutex_exit(&wl->wl_mtx);
pool_put(&wapbl_ino_pool, wi);
} else {
mutex_exit(&wl->wl_mtx);
}
}
/****************************************************************/
static __inline size_t
wapbl_transaction_inodes_len(struct wapbl *wl)
{
int blocklen = 1<<wl->wl_log_dev_bshift;
int iph;
/* Calculate number of inodes described in a inodelist header */
iph = (blocklen - offsetof(struct wapbl_wc_inodelist, wc_inodes)) /
sizeof(((struct wapbl_wc_inodelist *)0)->wc_inodes[0]);
KASSERT(iph > 0);
return MAX(1, howmany(wl->wl_inohashcnt, iph))*blocklen;
}
/* Calculate amount of space a transaction will take on disk */
static size_t
wapbl_transaction_len(struct wapbl *wl)
{
int blocklen = 1<<wl->wl_log_dev_bshift;
size_t len;
int bph;
/* Calculate number of blocks described in a blocklist header */
bph = (blocklen - offsetof(struct wapbl_wc_blocklist, wc_blocks)) /
sizeof(((struct wapbl_wc_blocklist *)0)->wc_blocks[0]);
KASSERT(bph > 0);
len = wl->wl_bcount;
len += howmany(wl->wl_bufcount, bph)*blocklen;
len += howmany(wl->wl_dealloccnt, bph)*blocklen;
len += wapbl_transaction_inodes_len(wl);
return len;
}
/*
* Perform commit operation
*
* Note that generation number incrementation needs to
* be protected against racing with other invocations
* of wapbl_commit. This is ok since this routine
* is only invoked from wapbl_flush
*/
static int
wapbl_write_commit(struct wapbl *wl, off_t head, off_t tail)
{
struct wapbl_wc_header *wc = wl->wl_wc_header;
struct timespec ts;
int error;
int force = 1;
/* XXX Calc checksum here, instead we do this for now */
error = VOP_IOCTL(wl->wl_devvp, DIOCCACHESYNC, &force, FWRITE, FSCRED);
if (error) {
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("wapbl_write_commit: DIOCCACHESYNC on dev 0x%x "
"returned %d\n", wl->wl_devvp->v_rdev, error));
}
wc->wc_head = head;
wc->wc_tail = tail;
wc->wc_checksum = 0;
wc->wc_version = 1;
getnanotime(&ts);
wc->wc_time = ts.tv_sec;;
wc->wc_timensec = ts.tv_nsec;
WAPBL_PRINTF(WAPBL_PRINT_WRITE,
("wapbl_write_commit: head = %"PRIdMAX "tail = %"PRIdMAX"\n",
(intmax_t)head, (intmax_t)tail));
/*
* XXX if generation will rollover, then first zero
* over second commit header before trying to write both headers.
*/
error = wapbl_write(wc, wc->wc_len, wl->wl_devvp,
wl->wl_logpbn + wc->wc_generation % 2);
if (error)
return error;
error = VOP_IOCTL(wl->wl_devvp, DIOCCACHESYNC, &force, FWRITE, FSCRED);
if (error) {
WAPBL_PRINTF(WAPBL_PRINT_ERROR,
("wapbl_write_commit: DIOCCACHESYNC on dev 0x%x "
"returned %d\n", wl->wl_devvp->v_rdev, error));
}
/*
* If the generation number was zero, write it out a second time.
* This handles initialization and generation number rollover
*/
if (wc->wc_generation++ == 0) {
error = wapbl_write_commit(wl, head, tail);
/*
* This panic should be able to be removed if we do the
* zero'ing mentioned above, and we are certain to roll
* back generation number on failure.
*/
if (error)
panic("wapbl_write_commit: error writing duplicate "
"log header: %d\n", error);
}
return 0;
}
/* Returns new offset value */
static int
wapbl_write_blocks(struct wapbl *wl, off_t *offp)
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wl->wl_wc_scratch;
int blocklen = 1<<wl->wl_log_dev_bshift;
int bph;
struct buf *bp;
off_t off = *offp;
int error;
KASSERT(rw_write_held(&wl->wl_rwlock));
bph = (blocklen - offsetof(struct wapbl_wc_blocklist, wc_blocks)) /
sizeof(((struct wapbl_wc_blocklist *)0)->wc_blocks[0]);
bp = LIST_FIRST(&wl->wl_bufs);
while (bp) {
int cnt;
struct buf *obp = bp;
KASSERT(bp->b_flags & B_LOCKED);
wc->wc_type = WAPBL_WC_BLOCKS;
wc->wc_len = blocklen;
wc->wc_blkcount = 0;
while (bp && (wc->wc_blkcount < bph)) {
/*
* Make sure all the physical block numbers are up to
* date. If this is not always true on a given
* filesystem, then VOP_BMAP must be called. We
* could call VOP_BMAP here, or else in the filesystem
* specific flush callback, although neither of those
* solutions allow us to take the vnode lock. If a
* filesystem requires that we must take the vnode lock
* to call VOP_BMAP, then we can probably do it in
* bwrite when the vnode lock should already be held
* by the invoking code.
*/
KASSERT((bp->b_vp->v_type == VBLK) ||
(bp->b_blkno != bp->b_lblkno));
KASSERT(bp->b_blkno > 0);
wc->wc_blocks[wc->wc_blkcount].wc_daddr = bp->b_blkno;
wc->wc_blocks[wc->wc_blkcount].wc_dlen = bp->b_bcount;
wc->wc_len += bp->b_bcount;
wc->wc_blkcount++;
bp = LIST_NEXT(bp, b_wapbllist);
}
WAPBL_PRINTF(WAPBL_PRINT_WRITE,
("wapbl_write_blocks: len = %u off = %"PRIdMAX"\n",
wc->wc_len, (intmax_t)off));
error = wapbl_circ_write(wl, wc, blocklen, &off);
if (error)
return error;
bp = obp;
cnt = 0;
while (bp && (cnt++ < bph)) {
error = wapbl_circ_write(wl, bp->b_data,
bp->b_bcount, &off);
if (error)
return error;
bp = LIST_NEXT(bp, b_wapbllist);
}
}
*offp = off;
return 0;
}
static int
wapbl_write_revocations(struct wapbl *wl, off_t *offp)
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wl->wl_wc_scratch;
int i;
int blocklen = 1<<wl->wl_log_dev_bshift;
int bph;
off_t off = *offp;
int error;
if (wl->wl_dealloccnt == 0)
return 0;
bph = (blocklen - offsetof(struct wapbl_wc_blocklist, wc_blocks)) /
sizeof(((struct wapbl_wc_blocklist *)0)->wc_blocks[0]);
i = 0;
while (i < wl->wl_dealloccnt) {
wc->wc_type = WAPBL_WC_REVOCATIONS;
wc->wc_len = blocklen;
wc->wc_blkcount = 0;
while ((i < wl->wl_dealloccnt) && (wc->wc_blkcount < bph)) {
wc->wc_blocks[wc->wc_blkcount].wc_daddr =
wl->wl_deallocblks[i];
wc->wc_blocks[wc->wc_blkcount].wc_dlen =
wl->wl_dealloclens[i];
wc->wc_blkcount++;
i++;
}
WAPBL_PRINTF(WAPBL_PRINT_WRITE,
("wapbl_write_revocations: len = %u off = %"PRIdMAX"\n",
wc->wc_len, (intmax_t)off));
error = wapbl_circ_write(wl, wc, blocklen, &off);
if (error)
return error;
}
*offp = off;
return 0;
}
static int
wapbl_write_inodes(struct wapbl *wl, off_t *offp)
{
struct wapbl_wc_inodelist *wc =
(struct wapbl_wc_inodelist *)wl->wl_wc_scratch;
int i;
int blocklen = 1<<wl->wl_log_dev_bshift;
off_t off = *offp;
int error;
struct wapbl_ino_head *wih;
struct wapbl_ino *wi;
int iph;
iph = (blocklen - offsetof(struct wapbl_wc_inodelist, wc_inodes)) /
sizeof(((struct wapbl_wc_inodelist *)0)->wc_inodes[0]);
i = 0;
wih = &wl->wl_inohash[0];
wi = 0;
do {
wc->wc_type = WAPBL_WC_INODES;
wc->wc_len = blocklen;
wc->wc_inocnt = 0;
wc->wc_clear = (i == 0);
while ((i < wl->wl_inohashcnt) && (wc->wc_inocnt < iph)) {
while (!wi) {
KASSERT((wih - &wl->wl_inohash[0])
<= wl->wl_inohashmask);
wi = LIST_FIRST(wih++);
}
wc->wc_inodes[wc->wc_inocnt].wc_inumber = wi->wi_ino;
wc->wc_inodes[wc->wc_inocnt].wc_imode = wi->wi_mode;
wc->wc_inocnt++;
i++;
wi = LIST_NEXT(wi, wi_hash);
}
WAPBL_PRINTF(WAPBL_PRINT_WRITE,
("wapbl_write_inodes: len = %u off = %"PRIdMAX"\n",
wc->wc_len, (intmax_t)off));
error = wapbl_circ_write(wl, wc, blocklen, &off);
if (error)
return error;
} while (i < wl->wl_inohashcnt);
*offp = off;
return 0;
}
#endif /* _KERNEL */
/****************************************************************/
#ifdef _KERNEL
static struct pool wapbl_blk_pool;
static int wapbl_blk_pool_refcount;
#endif
struct wapbl_blk {
LIST_ENTRY(wapbl_blk) wb_hash;
daddr_t wb_blk;
off_t wb_off; /* Offset of this block in the log */
};
#define WAPBL_BLKPOOL_MIN 83
static void
wapbl_blkhash_init(struct wapbl_replay *wr, u_int size)
{
if (size < WAPBL_BLKPOOL_MIN)
size = WAPBL_BLKPOOL_MIN;
KASSERT(wr->wr_blkhash == 0);
#ifdef _KERNEL
wr->wr_blkhash = hashinit(size, HASH_LIST, true, &wr->wr_blkhashmask);
if (atomic_inc_uint_nv(&wapbl_blk_pool_refcount) == 1) {
pool_init(&wapbl_blk_pool, sizeof(struct wapbl_blk), 0, 0, 0,
"wapblblkpl", &pool_allocator_nointr, IPL_NONE);
}
#else /* ! _KERNEL */
/* Manually implement hashinit */
{
int i;
unsigned long hashsize;
for (hashsize = 1; hashsize < size; hashsize <<= 1)
continue;
wr->wr_blkhash = wapbl_malloc(hashsize * sizeof(*wr->wr_blkhash));
for (i = 0; i < wr->wr_blkhashmask; i++)
LIST_INIT(&wr->wr_blkhash[i]);
wr->wr_blkhashmask = hashsize - 1;
}
#endif /* ! _KERNEL */
}
static void
wapbl_blkhash_free(struct wapbl_replay *wr)
{
KASSERT(wr->wr_blkhashcnt == 0);
#ifdef _KERNEL
hashdone(wr->wr_blkhash, HASH_LIST, wr->wr_blkhashmask);
if (atomic_dec_uint_nv(&wapbl_blk_pool_refcount) == 0) {
pool_destroy(&wapbl_blk_pool);
}
#else /* ! _KERNEL */
wapbl_free(wr->wr_blkhash);
#endif /* ! _KERNEL */
}
static struct wapbl_blk *
wapbl_blkhash_get(struct wapbl_replay *wr, daddr_t blk)
{
struct wapbl_blk_head *wbh;
struct wapbl_blk *wb;
wbh = &wr->wr_blkhash[blk & wr->wr_blkhashmask];
LIST_FOREACH(wb, wbh, wb_hash) {
if (blk == wb->wb_blk)
return wb;
}
return 0;
}
static void
wapbl_blkhash_ins(struct wapbl_replay *wr, daddr_t blk, off_t off)
{
struct wapbl_blk_head *wbh;
struct wapbl_blk *wb;
wb = wapbl_blkhash_get(wr, blk);
if (wb) {
KASSERT(wb->wb_blk == blk);
wb->wb_off = off;
} else {
#ifdef _KERNEL
wb = pool_get(&wapbl_blk_pool, PR_WAITOK);
#else /* ! _KERNEL */
wb = wapbl_malloc(sizeof(*wb));
#endif /* ! _KERNEL */
wb->wb_blk = blk;
wb->wb_off = off;
wbh = &wr->wr_blkhash[blk & wr->wr_blkhashmask];
LIST_INSERT_HEAD(wbh, wb, wb_hash);
wr->wr_blkhashcnt++;
}
}
static void
wapbl_blkhash_rem(struct wapbl_replay *wr, daddr_t blk)
{
struct wapbl_blk *wb = wapbl_blkhash_get(wr, blk);
if (wb) {
KASSERT(wr->wr_blkhashcnt > 0);
wr->wr_blkhashcnt--;
LIST_REMOVE(wb, wb_hash);
#ifdef _KERNEL
pool_put(&wapbl_blk_pool, wb);
#else /* ! _KERNEL */
wapbl_free(wb);
#endif /* ! _KERNEL */
}
}
static void
wapbl_blkhash_clear(struct wapbl_replay *wr)
{
int i;
for (i = 0; i <= wr->wr_blkhashmask; i++) {
struct wapbl_blk *wb;
while ((wb = LIST_FIRST(&wr->wr_blkhash[i]))) {
KASSERT(wr->wr_blkhashcnt > 0);
wr->wr_blkhashcnt--;
LIST_REMOVE(wb, wb_hash);
#ifdef _KERNEL
pool_put(&wapbl_blk_pool, wb);
#else /* ! _KERNEL */
wapbl_free(wb);
#endif /* ! _KERNEL */
}
}
KASSERT(wr->wr_blkhashcnt == 0);
}
/****************************************************************/
static int
wapbl_circ_read(struct wapbl_replay *wr, void *data, size_t len, off_t *offp)
{
size_t slen;
struct wapbl_wc_header *wc = &wr->wr_wc_header;
off_t off = *offp;
int error;
KASSERT(((len >> wc->wc_log_dev_bshift) <<
wc->wc_log_dev_bshift) == len);
if (off < wc->wc_circ_off)
off = wc->wc_circ_off;
slen = wc->wc_circ_off + wc->wc_circ_size - off;
if (slen < len) {
error = wapbl_read(data, slen, wr->wr_devvp,
wr->wr_logpbn + (off >> wc->wc_log_dev_bshift));
if (error)
return error;
data = (uint8_t *)data + slen;
len -= slen;
off = wc->wc_circ_off;
}
error = wapbl_read(data, len, wr->wr_devvp,
wr->wr_logpbn + (off >> wc->wc_log_dev_bshift));
if (error)
return error;
off += len;
if (off >= wc->wc_circ_off + wc->wc_circ_size)
off = wc->wc_circ_off;
*offp = off;
return 0;
}
static void
wapbl_circ_advance(struct wapbl_replay *wr, size_t len, off_t *offp)
{
size_t slen;
struct wapbl_wc_header *wc = &wr->wr_wc_header;
off_t off = *offp;
KASSERT(((len >> wc->wc_log_dev_bshift) <<
wc->wc_log_dev_bshift) == len);
if (off < wc->wc_circ_off)
off = wc->wc_circ_off;
slen = wc->wc_circ_off + wc->wc_circ_size - off;
if (slen < len) {
len -= slen;
off = wc->wc_circ_off;
}
off += len;
if (off >= wc->wc_circ_off + wc->wc_circ_size)
off = wc->wc_circ_off;
*offp = off;
}
/****************************************************************/
int
wapbl_replay_start(struct wapbl_replay **wrp, struct vnode *vp,
daddr_t off, size_t count, size_t blksize)
{
struct wapbl_replay *wr;
int error;
struct vnode *devvp;
daddr_t logpbn;
uint8_t *scratch;
struct wapbl_wc_header *wch;
struct wapbl_wc_header *wch2;
/* Use this until we read the actual log header */
int log_dev_bshift = DEV_BSHIFT;
size_t used;
WAPBL_PRINTF(WAPBL_PRINT_REPLAY,
("wapbl_replay_start: vp=%p off=%"PRId64 " count=%zu blksize=%zu\n",
vp, off, count, blksize));
if (off < 0)
return EINVAL;
if (blksize < DEV_BSIZE)
return EINVAL;
if (blksize % DEV_BSIZE)
return EINVAL;
#ifdef _KERNEL
#if 0
/* XXX vp->v_size isn't reliably set for VBLK devices,
* especially root. However, we might still want to verify
* that the full load is readable */
if ((off + count) * blksize > vp->v_size)
return EINVAL;
#endif
if ((error = VOP_BMAP(vp, off, &devvp, &logpbn, 0)) != 0) {
return error;
}
#else /* ! _KERNEL */
devvp = vp;
logpbn = off;
#endif /* ! _KERNEL */
scratch = wapbl_malloc(MAXBSIZE);
error = wapbl_read(scratch, 2<<log_dev_bshift, devvp, logpbn);
if (error)
goto errout;
wch = (struct wapbl_wc_header *)scratch;
wch2 =
(struct wapbl_wc_header *)(scratch + (1<<log_dev_bshift));
/* XXX verify checksums and magic numbers */
if (wch->wc_type != WAPBL_WC_HEADER) {
printf("Unrecognized wapbl magic: 0x%08x\n", wch->wc_type);
error = EFTYPE;
goto errout;
}
if (wch2->wc_generation > wch->wc_generation)
wch = wch2;
wr = wapbl_calloc(1, sizeof(*wr));
wr->wr_logvp = vp;
wr->wr_devvp = devvp;
wr->wr_logpbn = logpbn;
wr->wr_scratch = scratch;
memcpy(&wr->wr_wc_header, wch, sizeof(wr->wr_wc_header));
used = wapbl_space_used(wch->wc_circ_size, wch->wc_head, wch->wc_tail);
WAPBL_PRINTF(WAPBL_PRINT_REPLAY,
("wapbl_replay: head=%"PRId64" tail=%"PRId64" off=%"PRId64
" len=%"PRId64" used=%zu\n",
wch->wc_head, wch->wc_tail, wch->wc_circ_off,
wch->wc_circ_size, used));
wapbl_blkhash_init(wr, (used >> wch->wc_fs_dev_bshift));
error = wapbl_replay_prescan(wr);
if (error) {
wapbl_replay_stop(wr);
wapbl_replay_free(wr);
return error;
}
error = wapbl_replay_get_inodes(wr);
if (error) {
wapbl_replay_stop(wr);
wapbl_replay_free(wr);
return error;
}
*wrp = wr;
return 0;
errout:
wapbl_free(scratch);
return error;
}
void
wapbl_replay_stop(struct wapbl_replay *wr)
{
WAPBL_PRINTF(WAPBL_PRINT_REPLAY, ("wapbl_replay_stop called\n"));
KDASSERT(wapbl_replay_isopen(wr));
wapbl_free(wr->wr_scratch);
wr->wr_scratch = 0;
wr->wr_logvp = 0;
wapbl_blkhash_clear(wr);
wapbl_blkhash_free(wr);
}
void
wapbl_replay_free(struct wapbl_replay *wr)
{
KDASSERT(!wapbl_replay_isopen(wr));
if (wr->wr_inodes)
wapbl_free(wr->wr_inodes);
wapbl_free(wr);
}
int
wapbl_replay_isopen1(struct wapbl_replay *wr)
{
return wapbl_replay_isopen(wr);
}
static int
wapbl_replay_prescan(struct wapbl_replay *wr)
{
off_t off;
struct wapbl_wc_header *wch = &wr->wr_wc_header;
int error;
int logblklen = 1<<wch->wc_log_dev_bshift;
int fsblklen = 1<<wch->wc_fs_dev_bshift;
wapbl_blkhash_clear(wr);
off = wch->wc_tail;
while (off != wch->wc_head) {
struct wapbl_wc_null *wcn;
off_t saveoff = off;
error = wapbl_circ_read(wr, wr->wr_scratch, logblklen, &off);
if (error)
goto errout;
wcn = (struct wapbl_wc_null *)wr->wr_scratch;
switch (wcn->wc_type) {
case WAPBL_WC_BLOCKS:
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wr->wr_scratch;
int i;
for (i = 0; i < wc->wc_blkcount; i++) {
int j, n;
/*
* Enter each physical block into the
* hashtable independently
*/
n = wc->wc_blocks[i].wc_dlen >>
wch->wc_fs_dev_bshift;
for (j = 0; j < n; j++) {
wapbl_blkhash_ins(wr,
wc->wc_blocks[i].wc_daddr + j,
off);
wapbl_circ_advance(wr,
fsblklen, &off);
}
}
}
break;
case WAPBL_WC_REVOCATIONS:
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wr->wr_scratch;
int i;
for (i = 0; i < wc->wc_blkcount; i++) {
int j, n;
/*
* Remove any blocks found from the
* hashtable
*/
n = wc->wc_blocks[i].wc_dlen >>
wch->wc_fs_dev_bshift;
for (j = 0; j < n; j++) {
wapbl_blkhash_rem(wr,
wc->wc_blocks[i].wc_daddr + j);
}
}
}
break;
case WAPBL_WC_INODES:
{
struct wapbl_wc_inodelist *wc =
(struct wapbl_wc_inodelist *)wr->wr_scratch;
/*
* Keep track of where we found this so we
* can use it later
*/
if (wc->wc_clear) {
wr->wr_inodestail = saveoff;
wr->wr_inodescnt = 0;
}
if (wr->wr_inodestail)
wr->wr_inodeshead = off;
wr->wr_inodescnt += wc->wc_inocnt;
}
break;
default:
printf("Unrecognized wapbl type: 0x%08x\n",
wcn->wc_type);
error = EFTYPE;
goto errout;
}
wapbl_circ_advance(wr, wcn->wc_len, &saveoff);
if (off != saveoff) {
printf("wapbl_replay: corrupted records\n");
error = EFTYPE;
goto errout;
}
}
return 0;
errout:
wapbl_blkhash_clear(wr);
return error;
}
static int
wapbl_replay_get_inodes(struct wapbl_replay *wr)
{
off_t off;
struct wapbl_wc_header *wch = &wr->wr_wc_header;
int logblklen = 1<<wch->wc_log_dev_bshift;
int cnt= 0;
KDASSERT(wapbl_replay_isopen(wr));
if (wr->wr_inodescnt == 0)
return 0;
KASSERT(!wr->wr_inodes);
wr->wr_inodes = wapbl_malloc(wr->wr_inodescnt*sizeof(wr->wr_inodes[0]));
off = wr->wr_inodestail;
while (off != wr->wr_inodeshead) {
struct wapbl_wc_null *wcn;
int error;
off_t saveoff = off;
error = wapbl_circ_read(wr, wr->wr_scratch, logblklen, &off);
if (error) {
wapbl_free(wr->wr_inodes);
wr->wr_inodes = 0;
return error;
}
wcn = (struct wapbl_wc_null *)wr->wr_scratch;
switch (wcn->wc_type) {
case WAPBL_WC_BLOCKS:
case WAPBL_WC_REVOCATIONS:
break;
case WAPBL_WC_INODES:
{
struct wapbl_wc_inodelist *wc =
(struct wapbl_wc_inodelist *)wr->wr_scratch;
/*
* Keep track of where we found this so we
* can use it later
*/
if (wc->wc_clear) {
cnt = 0;
}
/* This memcpy assumes that wr_inodes is
* laid out the same as wc_inodes. */
memcpy(&wr->wr_inodes[cnt], wc->wc_inodes,
wc->wc_inocnt*sizeof(wc->wc_inodes[0]));
cnt += wc->wc_inocnt;
}
break;
default:
KASSERT(0);
}
off = saveoff;
wapbl_circ_advance(wr, wcn->wc_len, &off);
}
KASSERT(cnt == wr->wr_inodescnt);
return 0;
}
#ifdef DEBUG
int
wapbl_replay_verify(struct wapbl_replay *wr, struct vnode *fsdevvp)
{
off_t off;
struct wapbl_wc_header *wch = &wr->wr_wc_header;
int mismatchcnt = 0;
int logblklen = 1<<wch->wc_log_dev_bshift;
int fsblklen = 1<<wch->wc_fs_dev_bshift;
void *scratch1 = wapbl_malloc(MAXBSIZE);
void *scratch2 = wapbl_malloc(MAXBSIZE);
int error = 0;
KDASSERT(wapbl_replay_isopen(wr));
off = wch->wc_tail;
while (off != wch->wc_head) {
struct wapbl_wc_null *wcn;
#ifdef DEBUG
off_t saveoff = off;
#endif
error = wapbl_circ_read(wr, wr->wr_scratch, logblklen, &off);
if (error)
goto out;
wcn = (struct wapbl_wc_null *)wr->wr_scratch;
switch (wcn->wc_type) {
case WAPBL_WC_BLOCKS:
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wr->wr_scratch;
int i;
for (i = 0; i < wc->wc_blkcount; i++) {
int foundcnt = 0;
int dirtycnt = 0;
int j, n;
/*
* Check each physical block into the
* hashtable independently
*/
n = wc->wc_blocks[i].wc_dlen >>
wch->wc_fs_dev_bshift;
for (j = 0; j < n; j++) {
struct wapbl_blk *wb =
wapbl_blkhash_get(wr,
wc->wc_blocks[i].wc_daddr + j);
if (wb && (wb->wb_off == off)) {
foundcnt++;
error =
wapbl_circ_read(wr,
scratch1, fsblklen,
&off);
if (error)
goto out;
error =
wapbl_read(scratch2,
fsblklen, fsdevvp,
wb->wb_blk);
if (error)
goto out;
if (memcmp(scratch1,
scratch2,
fsblklen)) {
printf(
"wapbl_verify: mismatch block %"PRId64" at off %"PRIdMAX"\n",
wb->wb_blk, (intmax_t)off);
dirtycnt++;
mismatchcnt++;
}
} else {
wapbl_circ_advance(wr,
fsblklen, &off);
}
}
#if 0
/*
* If all of the blocks in an entry
* are clean, then remove all of its
* blocks from the hashtable since they
* never will need replay.
*/
if ((foundcnt != 0) &&
(dirtycnt == 0)) {
off = saveoff;
wapbl_circ_advance(wr,
logblklen, &off);
for (j = 0; j < n; j++) {
struct wapbl_blk *wb =
wapbl_blkhash_get(wr,
wc->wc_blocks[i].wc_daddr + j);
if (wb &&
(wb->wb_off == off)) {
wapbl_blkhash_rem(wr, wb->wb_blk);
}
wapbl_circ_advance(wr,
fsblklen, &off);
}
}
#endif
}
}
break;
case WAPBL_WC_REVOCATIONS:
case WAPBL_WC_INODES:
break;
default:
KASSERT(0);
}
#ifdef DEBUG
wapbl_circ_advance(wr, wcn->wc_len, &saveoff);
KASSERT(off == saveoff);
#endif
}
out:
wapbl_free(scratch1);
wapbl_free(scratch2);
if (!error && mismatchcnt)
error = EFTYPE;
return error;
}
#endif
int
wapbl_replay_write(struct wapbl_replay *wr, struct vnode *fsdevvp)
{
off_t off;
struct wapbl_wc_header *wch = &wr->wr_wc_header;
int logblklen = 1<<wch->wc_log_dev_bshift;
int fsblklen = 1<<wch->wc_fs_dev_bshift;
void *scratch1 = wapbl_malloc(MAXBSIZE);
int error = 0;
KDASSERT(wapbl_replay_isopen(wr));
/*
* This parses the journal for replay, although it could
* just as easily walk the hashtable instead.
*/
off = wch->wc_tail;
while (off != wch->wc_head) {
struct wapbl_wc_null *wcn;
#ifdef DEBUG
off_t saveoff = off;
#endif
error = wapbl_circ_read(wr, wr->wr_scratch, logblklen, &off);
if (error)
goto out;
wcn = (struct wapbl_wc_null *)wr->wr_scratch;
switch (wcn->wc_type) {
case WAPBL_WC_BLOCKS:
{
struct wapbl_wc_blocklist *wc =
(struct wapbl_wc_blocklist *)wr->wr_scratch;
int i;
for (i = 0; i < wc->wc_blkcount; i++) {
int j, n;
/*
* Check each physical block against
* the hashtable independently
*/
n = wc->wc_blocks[i].wc_dlen >>
wch->wc_fs_dev_bshift;
for (j = 0; j < n; j++) {
struct wapbl_blk *wb =
wapbl_blkhash_get(wr,
wc->wc_blocks[i].wc_daddr + j);
if (wb && (wb->wb_off == off)) {
error = wapbl_circ_read(
wr, scratch1,
fsblklen, &off);
if (error)
goto out;
error =
wapbl_write(scratch1,
fsblklen, fsdevvp,
wb->wb_blk);
if (error)
goto out;
} else {
wapbl_circ_advance(wr,
fsblklen, &off);
}
}
}
}
break;
case WAPBL_WC_REVOCATIONS:
case WAPBL_WC_INODES:
break;
default:
KASSERT(0);
}
#ifdef DEBUG
wapbl_circ_advance(wr, wcn->wc_len, &saveoff);
KASSERT(off == saveoff);
#endif
}
out:
wapbl_free(scratch1);
return error;
}
int
wapbl_replay_read(struct wapbl_replay *wr, void *data, daddr_t blk, long len)
{
struct wapbl_wc_header *wch = &wr->wr_wc_header;
int fsblklen = 1<<wch->wc_fs_dev_bshift;
KDASSERT(wapbl_replay_isopen(wr));
KASSERT((len % fsblklen) == 0);
while (len != 0) {
struct wapbl_blk *wb = wapbl_blkhash_get(wr, blk);
if (wb) {
off_t off = wb->wb_off;
int error;
error = wapbl_circ_read(wr, data, fsblklen, &off);
if (error)
return error;
}
data = (uint8_t *)data + fsblklen;
len -= fsblklen;
blk++;
}
return 0;
}
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