ufs/ffs/ffs_wapbl.c

1.14  mlelstv /*	$NetBSD: ffs_wapbl.c,v 1.14 2010/02/23 20:41:41 mlelstv Exp $	*/
 1.2   simonb
 1.2   simonb /*-
 1.2   simonb  * Copyright (c) 2003,2006,2008 The NetBSD Foundation, Inc.
 1.2   simonb  * All rights reserved.
 1.2   simonb  *
 1.2   simonb  * This code is derived from software contributed to The NetBSD Foundation
 1.2   simonb  * by Wasabi Systems, Inc.
 1.2   simonb  *
 1.2   simonb  * Redistribution and use in source and binary forms, with or without
 1.2   simonb  * modification, are permitted provided that the following conditions
 1.2   simonb  * are met:
 1.2   simonb  * 1. Redistributions of source code must retain the above copyright
 1.2   simonb  *    notice, this list of conditions and the following disclaimer.
 1.2   simonb  * 2. Redistributions in binary form must reproduce the above copyright
 1.2   simonb  *    notice, this list of conditions and the following disclaimer in the
 1.2   simonb  *    documentation and/or other materials provided with the distribution.
 1.2   simonb  *
 1.2   simonb  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.2   simonb  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.2   simonb  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.2   simonb  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.2   simonb  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.2   simonb  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.2   simonb  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.2   simonb  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.2   simonb  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.2   simonb  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.2   simonb  * POSSIBILITY OF SUCH DAMAGE.
 1.2   simonb  */
 1.2   simonb
 1.2   simonb #include <sys/cdefs.h>
1.14  mlelstv __KERNEL_RCSID(0, "$NetBSD: ffs_wapbl.c,v 1.14 2010/02/23 20:41:41 mlelstv Exp $");
 1.7    joerg
 1.7    joerg #define WAPBL_INTERNAL
 1.2   simonb
 1.2   simonb #if defined(_KERNEL_OPT)
 1.2   simonb #include "opt_ffs.h"
 1.2   simonb #endif
 1.2   simonb
 1.2   simonb #include <sys/param.h>
 1.2   simonb #include <sys/systm.h>
 1.2   simonb #include <sys/kernel.h>
 1.2   simonb #include <sys/vnode.h>
 1.2   simonb #include <sys/mount.h>
 1.2   simonb #include <sys/file.h>
 1.2   simonb #include <sys/disk.h>
 1.2   simonb #include <sys/ioctl.h>
 1.2   simonb #include <sys/errno.h>
 1.2   simonb #include <sys/kauth.h>
 1.2   simonb #include <sys/wapbl.h>
 1.2   simonb
 1.2   simonb #include <ufs/ufs/inode.h>
 1.2   simonb #include <ufs/ufs/quota.h>
 1.2   simonb #include <ufs/ufs/ufsmount.h>
 1.2   simonb #include <ufs/ufs/ufs_bswap.h>
 1.2   simonb #include <ufs/ufs/ufs_extern.h>
 1.2   simonb #include <ufs/ufs/ufs_wapbl.h>
 1.2   simonb
 1.2   simonb #include <ufs/ffs/fs.h>
 1.2   simonb #include <ufs/ffs/ffs_extern.h>
 1.2   simonb
 1.2   simonb #undef	WAPBL_DEBUG
 1.2   simonb #ifdef WAPBL_DEBUG
 1.2   simonb int ffs_wapbl_debug = 1;
 1.2   simonb #define DPRINTF(fmt, args...)						\
 1.2   simonb do {									\
 1.2   simonb 	if (ffs_wapbl_debug)						\
 1.2   simonb 		printf("%s:%d "fmt, __func__ , __LINE__, ##args);	\
 1.2   simonb } while (/* CONSTCOND */0)
 1.2   simonb #else
 1.2   simonb #define	DPRINTF(fmt, args...)						\
 1.2   simonb do {									\
 1.2   simonb 	/* nothing */							\
 1.2   simonb } while (/* CONSTCOND */0)
 1.2   simonb #endif
 1.2   simonb
 1.4   simonb static int ffs_superblock_layout(struct fs *);
 1.2   simonb static int wapbl_log_position(struct mount *, struct fs *, struct vnode *,
 1.2   simonb     daddr_t *, size_t *, size_t *, uint64_t *);
 1.2   simonb static int wapbl_create_infs_log(struct mount *, struct fs *, struct vnode *,
1.14  mlelstv     daddr_t *, size_t *, uint64_t *);
 1.2   simonb static void wapbl_find_log_start(struct mount *, struct vnode *, off_t,
 1.2   simonb     daddr_t *, daddr_t *, size_t *);
 1.2   simonb static int wapbl_remove_log(struct mount *);
1.14  mlelstv static int wapbl_allocate_log_file(struct mount *, struct vnode *,
1.14  mlelstv     daddr_t *, size_t *, uint64_t *);
 1.2   simonb
 1.2   simonb /*
 1.4   simonb  * Return the super block layout format - UFS1 or UFS2.
 1.4   simonb  * WAPBL only works with UFS2 layout (which is still available
 1.4   simonb  * with FFSv1).
 1.4   simonb  *
 1.4   simonb  * XXX Should this be in ufs/ffs/fs.h?  Same style of check is
 1.4   simonb  * also used in ffs_alloc.c in a few places.
 1.4   simonb  */
 1.4   simonb static int
 1.4   simonb ffs_superblock_layout(struct fs *fs)
 1.4   simonb {
 1.4   simonb 	if ((fs->fs_magic == FS_UFS1_MAGIC) &&
 1.4   simonb 	    ((fs->fs_old_flags & FS_FLAGS_UPDATED) == 0))
 1.4   simonb 		return 1;
 1.4   simonb 	else
 1.4   simonb 		return 2;
 1.4   simonb }
 1.4   simonb
 1.4   simonb /*
 1.2   simonb  * This function is invoked after a log is replayed to
 1.2   simonb  * disk to perform logical cleanup actions as described by
 1.2   simonb  * the log
 1.2   simonb  */
 1.2   simonb void
 1.2   simonb ffs_wapbl_replay_finish(struct mount *mp)
 1.2   simonb {
 1.2   simonb 	struct wapbl_replay *wr = mp->mnt_wapbl_replay;
 1.2   simonb 	int i;
 1.2   simonb 	int error;
 1.2   simonb
 1.2   simonb 	if (!wr)
 1.2   simonb 		return;
 1.2   simonb
 1.2   simonb 	KDASSERT((mp->mnt_flag & MNT_RDONLY) == 0);
 1.2   simonb
 1.2   simonb 	for (i = 0; i < wr->wr_inodescnt; i++) {
 1.2   simonb 		struct vnode *vp;
 1.2   simonb 		struct inode *ip;
 1.2   simonb 		error = VFS_VGET(mp, wr->wr_inodes[i].wr_inumber, &vp);
 1.2   simonb 		if (error) {
 1.2   simonb 			printf("ffs_wapbl_replay_finish: "
 1.2   simonb 			    "unable to cleanup inode %" PRIu32 "\n",
 1.2   simonb 			    wr->wr_inodes[i].wr_inumber);
 1.2   simonb 			continue;
 1.2   simonb 		}
 1.2   simonb 		ip = VTOI(vp);
 1.2   simonb 		KDASSERT(wr->wr_inodes[i].wr_inumber == ip->i_number);
 1.6    joerg #ifdef WAPBL_DEBUG
 1.2   simonb 		printf("ffs_wapbl_replay_finish: "
 1.2   simonb 		    "cleaning inode %" PRIu64 " size=%" PRIu64 " mode=%o nlink=%d\n",
 1.2   simonb 		    ip->i_number, ip->i_size, ip->i_mode, ip->i_nlink);
 1.6    joerg #endif
 1.2   simonb 		KASSERT(ip->i_nlink == 0);
 1.2   simonb
 1.2   simonb 		/*
 1.2   simonb 		 * The journal may have left partially allocated inodes in mode
 1.2   simonb 		 * zero.  This may occur if a crash occurs betweeen the node
 1.2   simonb 		 * allocation in ffs_nodeallocg and when the node is properly
 1.2   simonb 		 * initialized in ufs_makeinode.  If so, just dallocate them.
 1.2   simonb 		 */
 1.2   simonb 		if (ip->i_mode == 0) {
 1.2   simonb 			UFS_WAPBL_BEGIN(mp);
 1.2   simonb 			ffs_vfree(vp, ip->i_number, wr->wr_inodes[i].wr_imode);
 1.2   simonb 			UFS_WAPBL_END(mp);
 1.2   simonb 		}
 1.2   simonb 		vput(vp);
 1.2   simonb 	}
 1.8    joerg 	wapbl_replay_stop(wr);
 1.2   simonb 	wapbl_replay_free(wr);
 1.8    joerg 	mp->mnt_wapbl_replay = NULL;
 1.2   simonb }
 1.2   simonb
 1.2   simonb /* Callback for wapbl */
 1.2   simonb void
 1.2   simonb ffs_wapbl_sync_metadata(struct mount *mp, daddr_t *deallocblks,
 1.2   simonb     int *dealloclens, int dealloccnt)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	int i, error;
 1.2   simonb
 1.2   simonb #ifdef WAPBL_DEBUG_INODES
 1.2   simonb 	ufs_wapbl_verify_inodes(mp, "ffs_wapbl_sync_metadata");
 1.2   simonb #endif
 1.2   simonb
 1.2   simonb 	for (i = 0; i< dealloccnt; i++) {
 1.2   simonb 		/*
 1.2   simonb 		 * blkfree errors are unreported, might silently fail
 1.2   simonb 		 * if it cannot read the cylinder group block
 1.2   simonb 		 */
 1.2   simonb 		ffs_blkfree(fs, ump->um_devvp,
 1.2   simonb 		    dbtofsb(fs, deallocblks[i]), dealloclens[i], -1);
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	fs->fs_fmod = 0;
 1.2   simonb 	fs->fs_time = time_second;
 1.2   simonb 	error = ffs_cgupdate(ump, 0);
 1.2   simonb 	KASSERT(error == 0);
 1.2   simonb }
 1.2   simonb
 1.2   simonb void
 1.2   simonb ffs_wapbl_abort_sync_metadata(struct mount *mp, daddr_t *deallocblks,
 1.2   simonb     int *dealloclens, int dealloccnt)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	int i;
 1.2   simonb
 1.2   simonb 	for (i = 0; i < dealloccnt; i++) {
 1.2   simonb 		/*
 1.2   simonb 		 * Since the above blkfree may have failed, this blkalloc might
 1.2   simonb 		 * fail as well, so don't check its error.  Note that if the
 1.2   simonb 		 * blkfree succeeded above, then this shouldn't fail because
 1.2   simonb 		 * the buffer will be locked in the current transaction.
 1.2   simonb 		 */
 1.9    joerg 		ffs_blkalloc_ump(ump, dbtofsb(fs, deallocblks[i]),
 1.2   simonb 		    dealloclens[i]);
 1.2   simonb 	}
 1.2   simonb }
 1.2   simonb
 1.2   simonb static int
 1.2   simonb wapbl_remove_log(struct mount *mp)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	struct vnode *vp;
 1.2   simonb 	struct inode *ip;
 1.2   simonb 	ino_t log_ino;
 1.2   simonb 	int error;
 1.2   simonb
 1.4   simonb 	/* If super block layout is too old to support WAPBL, return */
 1.4   simonb 	if (ffs_superblock_layout(fs) < 2)
 1.4   simonb 		return 0;
 1.4   simonb
 1.2   simonb 	/* If all the log locators are 0, just clean up */
 1.2   simonb 	if (fs->fs_journallocs[0] == 0 &&
 1.2   simonb 	    fs->fs_journallocs[1] == 0 &&
 1.2   simonb 	    fs->fs_journallocs[2] == 0 &&
 1.2   simonb 	    fs->fs_journallocs[3] == 0) {
 1.2   simonb 		DPRINTF("empty locators, just clear\n");
 1.2   simonb 		goto done;
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	switch (fs->fs_journal_location) {
 1.2   simonb 	case UFS_WAPBL_JOURNALLOC_NONE:
 1.2   simonb 		/* nothing! */
 1.2   simonb 		DPRINTF("no log\n");
 1.2   simonb 		break;
 1.2   simonb
 1.2   simonb 	case UFS_WAPBL_JOURNALLOC_IN_FILESYSTEM:
 1.2   simonb 		log_ino = fs->fs_journallocs[UFS_WAPBL_INFS_INO];
 1.2   simonb 		DPRINTF("in-fs log, ino = %" PRId64 "\n",log_ino);
 1.2   simonb
 1.2   simonb 		/* if no existing log inode, just clear all fields and bail */
 1.2   simonb 		if (log_ino == 0)
 1.2   simonb 			goto done;
 1.2   simonb 		error = VFS_VGET(mp, log_ino, &vp);
 1.2   simonb 		if (error != 0) {
 1.2   simonb 			printf("ffs_wapbl: vget failed %d\n",
 1.2   simonb 			    error);
 1.2   simonb 			/* clear out log info on error */
 1.2   simonb 			goto done;
 1.2   simonb 		}
 1.2   simonb 		ip = VTOI(vp);
 1.2   simonb 		KASSERT(log_ino == ip->i_number);
 1.2   simonb 		if ((ip->i_flags & SF_LOG) == 0) {
 1.2   simonb 			printf("ffs_wapbl: try to clear non-log inode "
 1.2   simonb 			    "%" PRId64 "\n", log_ino);
 1.2   simonb 			vput(vp);
 1.2   simonb 			/* clear out log info on error */
 1.2   simonb 			goto done;
 1.2   simonb 		}
 1.2   simonb
 1.2   simonb 		/*
 1.2   simonb 		 * remove the log inode by setting its link count back
 1.2   simonb 		 * to zero and bail.
 1.2   simonb 		 */
 1.2   simonb 		ip->i_nlink = 0;
 1.2   simonb 		DIP_ASSIGN(ip, nlink, 0);
 1.2   simonb 		vput(vp);
 1.2   simonb
 1.2   simonb 	case UFS_WAPBL_JOURNALLOC_END_PARTITION:
 1.2   simonb 		DPRINTF("end-of-partition log\n");
 1.2   simonb 		/* no extra work required */
 1.2   simonb 		break;
 1.2   simonb
 1.2   simonb 	default:
 1.2   simonb 		printf("ffs_wapbl: unknown journal type %d\n",
 1.2   simonb 		    fs->fs_journal_location);
1.13   bouyer 		break;
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb
 1.2   simonb done:
 1.2   simonb 	/* Clear out all previous knowledge of journal */
 1.2   simonb 	fs->fs_journal_version = 0;
 1.2   simonb 	fs->fs_journal_location = 0;
 1.2   simonb 	fs->fs_journal_flags = 0;
 1.2   simonb 	fs->fs_journallocs[0] = 0;
 1.2   simonb 	fs->fs_journallocs[1] = 0;
 1.2   simonb 	fs->fs_journallocs[2] = 0;
 1.2   simonb 	fs->fs_journallocs[3] = 0;
 1.2   simonb 	(void) ffs_sbupdate(ump, MNT_WAIT);
 1.2   simonb
 1.2   simonb 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb int
 1.2   simonb ffs_wapbl_start(struct mount *mp)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	struct vnode *devvp = ump->um_devvp;
 1.2   simonb 	daddr_t off;
 1.2   simonb 	size_t count;
 1.2   simonb 	size_t blksize;
 1.2   simonb 	uint64_t extradata;
 1.2   simonb 	int error;
 1.2   simonb
1.11     yamt 	if (mp->mnt_wapbl == NULL) {
 1.2   simonb 		if (fs->fs_journal_flags & UFS_WAPBL_FLAGS_CLEAR_LOG) {
 1.2   simonb 			/* Clear out any existing journal file */
 1.2   simonb 			error = wapbl_remove_log(mp);
 1.2   simonb 			if (error != 0)
 1.2   simonb 				return error;
 1.2   simonb 		}
 1.2   simonb
 1.2   simonb 		if (mp->mnt_flag & MNT_LOG) {
 1.2   simonb 			KDASSERT(fs->fs_ronly == 0);
 1.2   simonb
 1.4   simonb 			/* WAPBL needs UFS2 format super block */
 1.4   simonb 			if (ffs_superblock_layout(fs) < 2) {
 1.4   simonb 				printf("%s fs superblock in old format, "
 1.4   simonb 				   "not journaling\n",
 1.4   simonb 				   VFSTOUFS(mp)->um_fs->fs_fsmnt);
 1.4   simonb 				mp->mnt_flag &= ~MNT_LOG;
 1.4   simonb 				return EINVAL;
 1.4   simonb 			}
 1.4   simonb
 1.2   simonb 			error = wapbl_log_position(mp, fs, devvp, &off,
 1.2   simonb 			    &count, &blksize, &extradata);
 1.2   simonb 			if (error)
 1.2   simonb 				return error;
 1.2   simonb
 1.2   simonb 			error = wapbl_start(&mp->mnt_wapbl, mp, devvp, off,
 1.2   simonb 			    count, blksize, mp->mnt_wapbl_replay,
 1.2   simonb 			    ffs_wapbl_sync_metadata,
 1.2   simonb 			    ffs_wapbl_abort_sync_metadata);
 1.2   simonb 			if (error)
 1.2   simonb 				return error;
 1.2   simonb
 1.2   simonb 			mp->mnt_wapbl_op = &wapbl_ops;
 1.2   simonb
 1.2   simonb #ifdef WAPBL_DEBUG
 1.2   simonb 			printf("%s: enabling logging\n", fs->fs_fsmnt);
 1.2   simonb #endif
 1.2   simonb
 1.2   simonb 			if ((fs->fs_flags & FS_DOWAPBL) == 0) {
 1.2   simonb 				UFS_WAPBL_BEGIN(mp);
 1.2   simonb 				fs->fs_flags |= FS_DOWAPBL;
 1.2   simonb 				error = ffs_sbupdate(ump, MNT_WAIT);
 1.2   simonb 				if (error) {
 1.2   simonb 					UFS_WAPBL_END(mp);
 1.2   simonb 					ffs_wapbl_stop(mp, MNT_FORCE);
 1.2   simonb 					return error;
 1.2   simonb 				}
 1.2   simonb 				UFS_WAPBL_END(mp);
 1.2   simonb 				error = wapbl_flush(mp->mnt_wapbl, 1);
 1.2   simonb 				if (error) {
 1.2   simonb 					ffs_wapbl_stop(mp, MNT_FORCE);
 1.2   simonb 					return error;
 1.2   simonb 				}
 1.2   simonb 			}
 1.2   simonb 		} else if (fs->fs_flags & FS_DOWAPBL) {
 1.2   simonb 			fs->fs_fmod = 1;
 1.2   simonb 			fs->fs_flags &= ~FS_DOWAPBL;
 1.2   simonb 		}
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	/*
 1.2   simonb 	 * It is recommended that you finish replay with logging enabled.
 1.2   simonb 	 * However, even if logging is not enabled, the remaining log
 1.2   simonb 	 * replay should be safely recoverable with an fsck, so perform
 1.2   simonb 	 * it anyway.
 1.2   simonb 	 */
 1.2   simonb 	if ((fs->fs_ronly == 0) && mp->mnt_wapbl_replay) {
 1.2   simonb 		int saveflag = mp->mnt_flag & MNT_RDONLY;
 1.2   simonb 		/*
 1.2   simonb 		 * Make sure MNT_RDONLY is not set so that the inode
 1.2   simonb 		 * cleanup in ufs_inactive will actually do its work.
 1.2   simonb 		 */
 1.2   simonb 		mp->mnt_flag &= ~MNT_RDONLY;
 1.2   simonb 		ffs_wapbl_replay_finish(mp);
 1.2   simonb 		mp->mnt_flag |= saveflag;
 1.2   simonb 		KASSERT(fs->fs_ronly == 0);
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb int
 1.2   simonb ffs_wapbl_stop(struct mount *mp, int force)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	int error;
 1.2   simonb
 1.2   simonb 	if (mp->mnt_wapbl) {
 1.2   simonb 		KDASSERT(fs->fs_ronly == 0);
 1.2   simonb
 1.2   simonb 		/*
 1.2   simonb 		 * Make sure turning off FS_DOWAPBL is only removed
 1.2   simonb 		 * as the only change in the final flush since otherwise
 1.2   simonb 		 * a transaction may reorder writes.
 1.2   simonb 		 */
 1.2   simonb 		error = wapbl_flush(mp->mnt_wapbl, 1);
 1.2   simonb 		if (error && !force)
 1.2   simonb 			return error;
 1.2   simonb 		if (error && force)
 1.2   simonb 			goto forceout;
 1.2   simonb 		error = UFS_WAPBL_BEGIN(mp);
 1.2   simonb 		if (error && !force)
 1.2   simonb 			return error;
 1.2   simonb 		if (error && force)
 1.2   simonb 			goto forceout;
 1.2   simonb 		KASSERT(fs->fs_flags & FS_DOWAPBL);
 1.2   simonb
 1.2   simonb 		fs->fs_flags &= ~FS_DOWAPBL;
 1.2   simonb 		error = ffs_sbupdate(ump, MNT_WAIT);
 1.2   simonb 		KASSERT(error == 0);	/* XXX a bit drastic! */
 1.2   simonb 		UFS_WAPBL_END(mp);
 1.2   simonb 	forceout:
 1.2   simonb 		error = wapbl_stop(mp->mnt_wapbl, force);
 1.2   simonb 		if (error) {
 1.2   simonb 			KASSERT(!force);
 1.2   simonb 			fs->fs_flags |= FS_DOWAPBL;
 1.2   simonb 			return error;
 1.2   simonb 		}
 1.2   simonb 		fs->fs_flags &= ~FS_DOWAPBL; /* Repeat in case of forced error */
1.11     yamt 		mp->mnt_wapbl = NULL;
 1.2   simonb
 1.2   simonb #ifdef WAPBL_DEBUG
 1.2   simonb 		printf("%s: disabled logging\n", fs->fs_fsmnt);
 1.2   simonb #endif
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb int
 1.2   simonb ffs_wapbl_replay_start(struct mount *mp, struct fs *fs, struct vnode *devvp)
 1.2   simonb {
 1.2   simonb 	int error;
 1.2   simonb 	daddr_t off;
 1.2   simonb 	size_t count;
 1.2   simonb 	size_t blksize;
 1.2   simonb 	uint64_t extradata;
 1.2   simonb
 1.4   simonb 	/*
 1.4   simonb 	 * WAPBL needs UFS2 format super block, if we got here with a
 1.4   simonb 	 * UFS1 format super block something is amiss...
 1.4   simonb 	 */
 1.4   simonb 	if (ffs_superblock_layout(fs) < 2)
 1.4   simonb 		return EINVAL;
 1.4   simonb
 1.2   simonb 	error = wapbl_log_position(mp, fs, devvp, &off, &count, &blksize,
 1.2   simonb 	    &extradata);
 1.2   simonb
 1.2   simonb 	if (error)
 1.2   simonb 		return error;
 1.2   simonb
 1.2   simonb 	error = wapbl_replay_start(&mp->mnt_wapbl_replay, devvp, off,
 1.2   simonb 		count, blksize);
 1.2   simonb 	if (error)
 1.2   simonb 		return error;
 1.2   simonb
 1.2   simonb 	mp->mnt_wapbl_op = &wapbl_ops;
 1.2   simonb
 1.2   simonb 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb /*
 1.2   simonb  * If the superblock doesn't already have a recorded journal location
 1.2   simonb  * then we allocate the journal in one of two positions:
 1.2   simonb  *
 1.2   simonb  *  - At the end of the partition after the filesystem if there's
 1.2   simonb  *    enough space.  "Enough space" is defined as >= 1MB of journal
 1.2   simonb  *    per 1GB of filesystem or 64MB, whichever is smaller.
 1.2   simonb  *
 1.2   simonb  *  - Inside the filesystem.  We try to allocate a contiguous journal
 1.2   simonb  *    based on the total filesystem size - the target is 1MB of journal
 1.2   simonb  *    per 1GB of filesystem, up to a maximum journal size of 64MB.  As
 1.2   simonb  *    a worst case allowing for fragmentation, we'll allocate a journal
 1.2   simonb  *    1/4 of the desired size but never smaller than 1MB.
 1.2   simonb  *
 1.2   simonb  *    XXX In the future if we allow for non-contiguous journal files we
 1.2   simonb  *    can tighten the above restrictions.
 1.2   simonb  *
 1.2   simonb  * XXX
 1.2   simonb  * These seems like a lot of duplication both here and in some of
 1.2   simonb  * the userland tools (fsck_ffs, dumpfs, tunefs) with similar
 1.2   simonb  * "switch (fs_journal_location)" constructs.  Can we centralise
 1.2   simonb  * this sort of code somehow/somewhere?
 1.2   simonb  */
 1.2   simonb static int
 1.2   simonb wapbl_log_position(struct mount *mp, struct fs *fs, struct vnode *devvp,
 1.2   simonb     daddr_t *startp, size_t *countp, size_t *blksizep, uint64_t *extradatap)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	daddr_t logstart, logend, desired_logsize;
1.14  mlelstv 	uint64_t numsecs;
1.14  mlelstv 	unsigned secsize;
1.14  mlelstv 	int error, location;
 1.2   simonb
 1.2   simonb 	if (fs->fs_journal_version == UFS_WAPBL_VERSION) {
 1.2   simonb 		switch (fs->fs_journal_location) {
 1.2   simonb 		case UFS_WAPBL_JOURNALLOC_END_PARTITION:
 1.2   simonb 			DPRINTF("found existing end-of-partition log\n");
 1.2   simonb 			*startp = fs->fs_journallocs[UFS_WAPBL_EPART_ADDR];
 1.2   simonb 			*countp = fs->fs_journallocs[UFS_WAPBL_EPART_COUNT];
 1.2   simonb 			*blksizep = fs->fs_journallocs[UFS_WAPBL_EPART_BLKSZ];
 1.5    pooka 			DPRINTF(" start = %" PRId64 ", size = %zu, "
 1.5    pooka 			    "blksize = %zu\n", *startp, *countp, *blksizep);
 1.2   simonb 			return 0;
 1.2   simonb
 1.2   simonb 		case UFS_WAPBL_JOURNALLOC_IN_FILESYSTEM:
 1.2   simonb 			DPRINTF("found existing in-filesystem log\n");
 1.2   simonb 			*startp = fs->fs_journallocs[UFS_WAPBL_INFS_ADDR];
 1.2   simonb 			*countp = fs->fs_journallocs[UFS_WAPBL_INFS_COUNT];
 1.2   simonb 			*blksizep = fs->fs_journallocs[UFS_WAPBL_INFS_BLKSZ];
 1.5    pooka 			DPRINTF(" start = %" PRId64 ", size = %zu, "
 1.5    pooka 			    "blksize = %zu\n", *startp, *countp, *blksizep);
 1.2   simonb 			return 0;
 1.2   simonb
 1.2   simonb 		default:
 1.2   simonb 			printf("ffs_wapbl: unknown journal type %d\n",
 1.2   simonb 			    fs->fs_journal_location);
 1.2   simonb 			return EINVAL;
 1.2   simonb 		}
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	desired_logsize =
 1.2   simonb 	    lfragtosize(fs, fs->fs_size) / UFS_WAPBL_JOURNAL_SCALE;
 1.2   simonb 	DPRINTF("desired log size = %" PRId64 " kB\n", desired_logsize / 1024);
 1.2   simonb 	desired_logsize = max(desired_logsize, UFS_WAPBL_MIN_JOURNAL_SIZE);
 1.2   simonb 	desired_logsize = min(desired_logsize, UFS_WAPBL_MAX_JOURNAL_SIZE);
 1.2   simonb 	DPRINTF("adjusted desired log size = %" PRId64 " kB\n",
 1.2   simonb 	    desired_logsize / 1024);
 1.2   simonb
 1.2   simonb 	/* Is there space after after filesystem on partition for log? */
 1.2   simonb 	logstart = fsbtodb(fs, fs->fs_size);
1.14  mlelstv 	error = getdisksize(devvp, &numsecs, &secsize);
1.14  mlelstv 	if (error)
1.14  mlelstv 		return error;
1.14  mlelstv 	KDASSERT(secsize != 0);
1.14  mlelstv 	logend = btodb(numsecs * secsize);
 1.2   simonb
1.14  mlelstv 	if (dbtob(logend - logstart) >= desired_logsize) {
1.14  mlelstv 		DPRINTF("enough space, use end-of-partition log\n");
 1.2   simonb
1.14  mlelstv 		location = UFS_WAPBL_JOURNALLOC_END_PARTITION;
1.14  mlelstv 		*blksizep = secsize;
 1.2   simonb
 1.2   simonb 		*startp = logstart;
 1.2   simonb 		*countp = (logend - logstart);
 1.2   simonb 		*extradatap = 0;
 1.2   simonb
 1.2   simonb 		fs->fs_journallocs[UFS_WAPBL_EPART_ADDR] = *startp;
 1.2   simonb 		fs->fs_journallocs[UFS_WAPBL_EPART_COUNT] = *countp;
 1.2   simonb 		fs->fs_journallocs[UFS_WAPBL_EPART_BLKSZ] = *blksizep;
 1.2   simonb 		fs->fs_journallocs[UFS_WAPBL_EPART_UNUSED] = *extradatap;
1.14  mlelstv 	} else {
1.14  mlelstv 		DPRINTF("end-of-partition has only %" PRId64 " free\n",
1.14  mlelstv 		    logend - logstart);
1.14  mlelstv
1.14  mlelstv 		location = UFS_WAPBL_JOURNALLOC_IN_FILESYSTEM;
1.14  mlelstv 		*blksizep = secsize;
 1.2   simonb
1.14  mlelstv 		error = wapbl_create_infs_log(mp, fs, devvp,
1.14  mlelstv 		                  startp, countp, extradatap);
1.14  mlelstv 		ffs_sync(mp, MNT_WAIT, FSCRED);
1.14  mlelstv
1.14  mlelstv 		fs->fs_journallocs[UFS_WAPBL_INFS_ADDR] = *startp;
1.14  mlelstv 		fs->fs_journallocs[UFS_WAPBL_INFS_COUNT] = *countp;
1.14  mlelstv 		fs->fs_journallocs[UFS_WAPBL_INFS_BLKSZ] = *blksizep;
1.14  mlelstv 		fs->fs_journallocs[UFS_WAPBL_INFS_INO] = *extradatap;
 1.2   simonb 	}
 1.2   simonb
1.14  mlelstv 	if (error == 0) {
1.14  mlelstv 		/* update superblock with log location */
1.14  mlelstv 		fs->fs_journal_version = UFS_WAPBL_VERSION;
1.14  mlelstv 		fs->fs_journal_location = location;
1.14  mlelstv 		fs->fs_journal_flags = 0;
 1.2   simonb
1.14  mlelstv 		error = ffs_sbupdate(ump, MNT_WAIT);
1.14  mlelstv 	}
 1.2   simonb
 1.2   simonb 	return error;
 1.2   simonb }
 1.2   simonb
 1.2   simonb /*
 1.2   simonb  * Try to create a journal log inside the filesystem.
 1.2   simonb  */
 1.2   simonb static int
 1.2   simonb wapbl_create_infs_log(struct mount *mp, struct fs *fs, struct vnode *devvp,
1.14  mlelstv     daddr_t *startp, size_t *countp, uint64_t *extradatap)
 1.2   simonb {
 1.2   simonb 	struct vnode *vp, *rvp;
 1.2   simonb 	struct inode *ip;
 1.2   simonb 	int error;
 1.2   simonb
 1.2   simonb 	if ((error = VFS_ROOT(mp, &rvp)) != 0)
 1.2   simonb 		return error;
 1.2   simonb
 1.2   simonb 	if ((error = UFS_VALLOC(rvp, 0 | S_IFREG, NOCRED, &vp)) != 0) {
 1.2   simonb 		vput(rvp);
 1.2   simonb 		return error;
 1.2   simonb 	}
 1.2   simonb 	vput(rvp);
 1.2   simonb
 1.2   simonb 	vp->v_type = VREG;
 1.2   simonb 	ip = VTOI(vp);
 1.2   simonb 	ip->i_flag |= IN_ACCESS | IN_CHANGE | IN_UPDATE;
 1.2   simonb 	ip->i_mode = 0 | IFREG;
 1.2   simonb 	DIP_ASSIGN(ip, mode, ip->i_mode);
 1.2   simonb 	ip->i_flags = SF_LOG;
 1.2   simonb 	DIP_ASSIGN(ip, flags, ip->i_flags);
 1.2   simonb 	ip->i_nlink = 1;
 1.2   simonb 	DIP_ASSIGN(ip, nlink, 1);
 1.2   simonb 	ffs_update(vp, NULL, NULL, UPDATE_WAIT);
 1.2   simonb
1.14  mlelstv 	if ((error = wapbl_allocate_log_file(mp, vp,
1.14  mlelstv 	                 startp, countp, extradatap)) != 0) {
 1.2   simonb 		/*
 1.2   simonb 		 * If we couldn't allocate the space for the log file,
 1.2   simonb 		 * remove the inode by setting its link count back to
 1.2   simonb 		 * zero and bail.
 1.2   simonb 		 */
 1.2   simonb 		ip->i_nlink = 0;
 1.2   simonb 		DIP_ASSIGN(ip, nlink, 0);
 1.2   simonb 		vput(vp);
 1.2   simonb
 1.2   simonb 		return error;
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	/*
 1.2   simonb 	 * Now that we have the place-holder inode for the journal,
 1.2   simonb 	 * we don't need the vnode ever again.
 1.2   simonb 	 */
 1.2   simonb 	vput(vp);
 1.2   simonb
 1.2   simonb 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb int
1.14  mlelstv wapbl_allocate_log_file(struct mount *mp, struct vnode *vp,
1.14  mlelstv     daddr_t *startp, size_t *countp, uint64_t *extradatap)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	daddr_t addr, indir_addr;
 1.2   simonb 	off_t logsize;
 1.2   simonb 	size_t size;
 1.2   simonb 	int error;
 1.2   simonb
 1.2   simonb 	logsize = 0;
 1.2   simonb 	/* check if there's a suggested log size */
 1.2   simonb 	if (fs->fs_journal_flags & UFS_WAPBL_FLAGS_CREATE_LOG &&
 1.2   simonb 	    fs->fs_journal_location == UFS_WAPBL_JOURNALLOC_IN_FILESYSTEM)
 1.2   simonb 		logsize = fs->fs_journallocs[UFS_WAPBL_INFS_COUNT];
 1.2   simonb
 1.2   simonb 	if (vp->v_size > 0) {
 1.2   simonb 		printf("%s: file size (%" PRId64 ") non zero\n", __func__,
 1.2   simonb 		    vp->v_size);
 1.2   simonb 		return EEXIST;
 1.2   simonb 	}
 1.2   simonb 	wapbl_find_log_start(mp, vp, logsize, &addr, &indir_addr, &size);
 1.2   simonb 	if (addr == 0) {
 1.2   simonb 		printf("%s: log not allocated, largest extent is "
 1.2   simonb 		    "%" PRId64 "MB\n", __func__,
 1.2   simonb 		    lblktosize(fs, size) / (1024 * 1024));
 1.2   simonb 		return ENOSPC;
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	logsize = lblktosize(fs, size);	/* final log size */
 1.2   simonb
 1.2   simonb 	VTOI(vp)->i_ffs_first_data_blk = addr;
 1.2   simonb 	VTOI(vp)->i_ffs_first_indir_blk = indir_addr;
 1.2   simonb
 1.2   simonb 	error = GOP_ALLOC(vp, 0, logsize, B_CONTIG, FSCRED);
 1.2   simonb 	if (error) {
 1.2   simonb 		printf("%s: GOP_ALLOC error %d\n", __func__, error);
 1.2   simonb 		return error;
 1.2   simonb 	}
 1.2   simonb
1.14  mlelstv 	*startp     = fsbtodb(fs, addr);
1.14  mlelstv 	*countp     = btodb(logsize);
1.14  mlelstv 	*extradatap = VTOI(vp)->i_number;
 1.2   simonb
1.14  mlelstv 	return 0;
 1.2   simonb }
 1.2   simonb
 1.2   simonb /*
 1.2   simonb  * Find a suitable location for the journal in the filesystem.
 1.2   simonb  *
 1.2   simonb  * Our strategy here is to look for a contiguous block of free space
 1.2   simonb  * at least "logfile" MB in size (plus room for any indirect blocks).
 1.2   simonb  * We start at the middle of the filesystem and check each cylinder
 1.2   simonb  * group working outwards.  If "logfile" MB is not available as a
 1.2   simonb  * single contigous chunk, then return the address and size of the
 1.2   simonb  * largest chunk found.
 1.2   simonb  *
 1.2   simonb  * XXX
 1.2   simonb  * At what stage does the search fail?  Is if the largest space we could
 1.2   simonb  * find is less than a quarter the requested space reasonable?  If the
 1.2   simonb  * search fails entirely, return a block address if "0" it indicate this.
 1.2   simonb  */
 1.2   simonb static void
 1.2   simonb wapbl_find_log_start(struct mount *mp, struct vnode *vp, off_t logsize,
 1.2   simonb     daddr_t *addr, daddr_t *indir_addr, size_t *size)
 1.2   simonb {
 1.2   simonb 	struct ufsmount *ump = VFSTOUFS(mp);
 1.2   simonb 	struct fs *fs = ump->um_fs;
 1.2   simonb 	struct vnode *devvp = ump->um_devvp;
 1.2   simonb 	struct cg *cgp;
 1.2   simonb 	struct buf *bp;
 1.2   simonb 	uint8_t *blksfree;
 1.2   simonb 	daddr_t blkno, best_addr, start_addr;
 1.2   simonb 	daddr_t desired_blks, min_desired_blks;
 1.2   simonb 	daddr_t freeblks, best_blks;
 1.2   simonb 	int bpcg, cg, error, fixedsize, indir_blks, n, s;
 1.2   simonb #ifdef FFS_EI
 1.2   simonb 	const int needswap = UFS_FSNEEDSWAP(fs);
 1.2   simonb #endif
 1.2   simonb
 1.2   simonb 	if (logsize == 0) {
 1.2   simonb 		fixedsize = 0;	/* We can adjust the size if tight */
 1.2   simonb 		logsize = lfragtosize(fs, fs->fs_dsize) /
 1.2   simonb 		    UFS_WAPBL_JOURNAL_SCALE;
 1.2   simonb 		DPRINTF("suggested log size = %" PRId64 "\n", logsize);
 1.2   simonb 		logsize = max(logsize, UFS_WAPBL_MIN_JOURNAL_SIZE);
 1.2   simonb 		logsize = min(logsize, UFS_WAPBL_MAX_JOURNAL_SIZE);
 1.2   simonb 		DPRINTF("adjusted log size = %" PRId64 "\n", logsize);
 1.2   simonb 	} else {
 1.2   simonb 		fixedsize = 1;
 1.2   simonb 		DPRINTF("fixed log size = %" PRId64 "\n", logsize);
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	desired_blks = logsize / fs->fs_bsize;
 1.2   simonb 	DPRINTF("desired blocks = %" PRId64 "\n", desired_blks);
 1.2   simonb
 1.2   simonb 	/* add in number of indirect blocks needed */
 1.2   simonb 	indir_blks = 0;
 1.2   simonb 	if (desired_blks >= NDADDR) {
 1.2   simonb 		struct indir indirs[NIADDR + 2];
 1.2   simonb 		int num;
 1.2   simonb
 1.2   simonb 		error = ufs_getlbns(vp, desired_blks, indirs, &num);
 1.2   simonb 		if (error) {
 1.2   simonb 			printf("%s: ufs_getlbns failed, error %d!\n",
 1.2   simonb 			    __func__, error);
 1.2   simonb 			goto bad;
 1.2   simonb 		}
 1.2   simonb
 1.2   simonb 		switch (num) {
 1.2   simonb 		case 2:
 1.2   simonb 			indir_blks = 1;		/* 1st level indirect */
 1.2   simonb 			break;
 1.2   simonb 		case 3:
 1.2   simonb 			indir_blks = 1 +	/* 1st level indirect */
 1.2   simonb 			    1 +			/* 2nd level indirect */
 1.2   simonb 			    indirs[1].in_off + 1; /* extra 1st level indirect */
 1.2   simonb 			break;
 1.2   simonb 		default:
 1.2   simonb 			printf("%s: unexpected numlevels %d from ufs_getlbns\n",
 1.2   simonb 			    __func__, num);
 1.2   simonb 			*size = 0;
 1.2   simonb 			goto bad;
 1.2   simonb 		}
 1.2   simonb 		desired_blks += indir_blks;
 1.2   simonb 	}
 1.2   simonb 	DPRINTF("desired blocks = %" PRId64 " (including indirect)\n",
 1.2   simonb 	    desired_blks);
 1.2   simonb
 1.2   simonb 	/*
 1.2   simonb 	 * If a specific size wasn't requested, allow for a smaller log
 1.2   simonb 	 * if we're really tight for space...
 1.2   simonb 	 */
 1.2   simonb 	min_desired_blks = desired_blks;
 1.2   simonb 	if (!fixedsize)
 1.2   simonb 		min_desired_blks = desired_blks / 4;
 1.2   simonb
 1.2   simonb 	/* Look at number of blocks per CG.  If it's too small, bail early. */
 1.2   simonb 	bpcg = fragstoblks(fs, fs->fs_fpg);
 1.2   simonb 	if (min_desired_blks > bpcg) {
 1.2   simonb 		printf("ffs_wapbl: cylinder group size of %" PRId64 " MB "
 1.2   simonb 		    " is not big enough for journal\n",
 1.2   simonb 		    lblktosize(fs, bpcg) / (1024 * 1024));
 1.2   simonb 		goto bad;
 1.2   simonb 	}
 1.2   simonb
 1.2   simonb 	/*
 1.2   simonb 	 * Start with the middle cylinder group, and search outwards in
 1.2   simonb 	 * both directions until we either find the requested log size
 1.2   simonb 	 * or reach the start/end of the file system.  If we reach the
 1.2   simonb 	 * start/end without finding enough space for the full requested
 1.2   simonb 	 * log size, use the largest extent found if it is large enough
 1.2   simonb 	 * to satisfy the our minimum size.
 1.2   simonb 	 *
 1.2   simonb 	 * XXX
 1.2   simonb 	 * Can we just use the cluster contigsum stuff (esp on UFS2)
 1.2   simonb 	 * here to simplify this search code?
 1.2   simonb 	 */
 1.2   simonb 	best_addr = 0;
 1.2   simonb 	best_blks = 0;
 1.2   simonb 	for (cg = fs->fs_ncg / 2, s = 0, n = 1;
 1.2   simonb 	    best_blks < desired_blks && cg >= 0 && cg < fs->fs_ncg;
 1.2   simonb 	    s++, n = -n, cg += n * s) {
 1.2   simonb 		DPRINTF("check cg %d of %d\n", cg, fs->fs_ncg);
 1.2   simonb 		error = bread(devvp, fsbtodb(fs, cgtod(fs, cg)),
 1.2   simonb 		    fs->fs_cgsize, FSCRED, 0, &bp);
 1.2   simonb 		cgp = (struct cg *)bp->b_data;
 1.2   simonb 		if (error || !cg_chkmagic(cgp, UFS_FSNEEDSWAP(fs))) {
 1.2   simonb 			brelse(bp, 0);
 1.2   simonb 			continue;
 1.2   simonb 		}
 1.2   simonb
 1.2   simonb 		blksfree = cg_blksfree(cgp, needswap);
 1.2   simonb
 1.2   simonb 		for (blkno = 0; blkno < bpcg;) {
 1.2   simonb 			/* look for next free block */
 1.2   simonb 			/* XXX use scanc() and fragtbl[] here? */
 1.2   simonb 			for (; blkno < bpcg - min_desired_blks; blkno++)
 1.2   simonb 				if (ffs_isblock(fs, blksfree, blkno))
 1.2   simonb 					break;
 1.2   simonb
 1.2   simonb 			/* past end of search space in this CG? */
 1.2   simonb 			if (blkno >= bpcg - min_desired_blks)
 1.2   simonb 				break;
 1.2   simonb
 1.2   simonb 			/* count how many free blocks in this extent */
 1.2   simonb 			start_addr = blkno;
 1.2   simonb 			for (freeblks = 0; blkno < bpcg; blkno++, freeblks++)
 1.2   simonb 				if (!ffs_isblock(fs, blksfree, blkno))
 1.2   simonb 					break;
 1.2   simonb
 1.2   simonb 			if (freeblks > best_blks) {
 1.2   simonb 				best_blks = freeblks;
 1.2   simonb 				best_addr = blkstofrags(fs, start_addr) +
 1.2   simonb 				    cgbase(fs, cg);
 1.2   simonb
 1.2   simonb 				if (freeblks >= desired_blks) {
 1.2   simonb 					DPRINTF("found len %" PRId64
 1.2   simonb 					    " at offset %" PRId64 " in gc\n",
 1.2   simonb 					    freeblks, start_addr);
 1.2   simonb 					break;
 1.2   simonb 				}
 1.2   simonb 			}
 1.2   simonb 		}
 1.2   simonb 		brelse(bp, 0);
 1.2   simonb 	}
 1.2   simonb 	DPRINTF("best found len = %" PRId64 ", wanted %" PRId64
 1.2   simonb 	    " at addr %" PRId64 "\n", best_blks, desired_blks, best_addr);
 1.2   simonb
 1.2   simonb 	if (best_blks < min_desired_blks) {
 1.2   simonb 		*addr = 0;
 1.2   simonb 		*indir_addr = 0;
 1.2   simonb 	} else {
 1.2   simonb 		/* put indirect blocks at start, and data blocks after */
 1.2   simonb 		*addr = best_addr + blkstofrags(fs, indir_blks);
 1.2   simonb 		*indir_addr = best_addr;
 1.2   simonb 	}
 1.2   simonb 	*size = min(desired_blks, best_blks) - indir_blks;
 1.2   simonb 	return;
 1.2   simonb
 1.2   simonb bad:
 1.2   simonb 	*addr = 0;
 1.2   simonb 	*indir_addr = 0;
 1.2   simonb 	*size = 0;
 1.2   simonb 	return;
 1.2   simonb }