static void netmap_dev_pager_dtor(void *handle) { struct netmap_vm_handle_t *vmh = handle; struct cdev *dev = vmh->dev; struct netmap_priv_d *priv = vmh->priv; (void)dev; D("handle %p", handle); netmap_dtor(priv); kfree(vmh, M_DEVBUF); #if 0 dev_rel(dev); #endif }
static int udf_unmount(struct mount *mp, int mntflags) { struct udf_mnt *udfmp; int error, flags = 0; udfmp = VFSTOUDFFS(mp); if (mntflags & MNT_FORCE) flags |= FORCECLOSE; if ((error = vflush(mp, 0, flags, curthread))) return (error); if (udfmp->im_flags & UDFMNT_KICONV && udf_iconv) { if (udfmp->im_d2l) udf_iconv->close(udfmp->im_d2l); #if 0 if (udfmp->im_l2d) udf_iconv->close(udfmp->im_l2d); #endif } DROP_GIANT(); g_topology_lock(); g_vfs_close(udfmp->im_cp); g_topology_unlock(); PICKUP_GIANT(); vrele(udfmp->im_devvp); dev_rel(udfmp->im_dev); if (udfmp->s_table != NULL) free(udfmp->s_table, M_UDFMOUNT); free(udfmp, M_UDFMOUNT); mp->mnt_data = NULL; MNT_ILOCK(mp); mp->mnt_flag &= ~MNT_LOCAL; MNT_IUNLOCK(mp); return (0); }
/* See: old_dev_pager_dtor() in device_pager.c as an example. * Called when the VM object is dead (i.e. when the client calls munmap()). We * need to free the CFB VM object. If this was the last mapping (i.e. FD) using * that pool, we can free the pool and any CFBs in it. */ static void cheri_compositor_cfb_pg_dtor(void *handle) { struct cfb_vm_object *cfb_vm_obj; struct cdev *dev; struct cheri_compositor_softc *sc; cfb_vm_obj = handle; dev = cfb_vm_obj->dev; sc = dev->si_drv1; CHERI_COMPOSITOR_DEBUG(sc, "handle: %p", handle); /* Unref and potentially free the CFB pool and its CFBs. */ CHERI_COMPOSITOR_LOCK(sc); unref_cfb_pool(sc, cfb_vm_obj->pool); CHERI_COMPOSITOR_UNLOCK(sc); free(cfb_vm_obj, M_CHERI_COMPOSITOR); /* Release the mapping's device reference. */ dev_rel(dev); }
static int udf_mountfs(struct vnode *devvp, struct mount *mp) { struct buf *bp = NULL; struct cdev *dev; struct anchor_vdp avdp; struct udf_mnt *udfmp = NULL; struct part_desc *pd; struct logvol_desc *lvd; struct fileset_desc *fsd; struct file_entry *root_fentry; uint32_t sector, size, mvds_start, mvds_end; uint32_t logical_secsize; uint32_t fsd_offset = 0; uint16_t part_num = 0, fsd_part = 0; int error = EINVAL; int logvol_found = 0, part_found = 0, fsd_found = 0; int bsize; struct g_consumer *cp; struct bufobj *bo; dev = devvp->v_rdev; dev_ref(dev); DROP_GIANT(); g_topology_lock(); error = g_vfs_open(devvp, &cp, "udf", 0); g_topology_unlock(); PICKUP_GIANT(); VOP_UNLOCK(devvp, 0); if (error) goto bail; bo = &devvp->v_bufobj; if (devvp->v_rdev->si_iosize_max != 0) mp->mnt_iosize_max = devvp->v_rdev->si_iosize_max; if (mp->mnt_iosize_max > MAXPHYS) mp->mnt_iosize_max = MAXPHYS; /* XXX: should be M_WAITOK */ udfmp = malloc(sizeof(struct udf_mnt), M_UDFMOUNT, M_NOWAIT | M_ZERO); if (udfmp == NULL) { printf("Cannot allocate UDF mount struct\n"); error = ENOMEM; goto bail; } mp->mnt_data = udfmp; mp->mnt_stat.f_fsid.val[0] = dev2udev(devvp->v_rdev); mp->mnt_stat.f_fsid.val[1] = mp->mnt_vfc->vfc_typenum; MNT_ILOCK(mp); mp->mnt_flag |= MNT_LOCAL; mp->mnt_kern_flag |= MNTK_LOOKUP_SHARED | MNTK_EXTENDED_SHARED; MNT_IUNLOCK(mp); udfmp->im_mountp = mp; udfmp->im_dev = dev; udfmp->im_devvp = devvp; udfmp->im_d2l = NULL; udfmp->im_cp = cp; udfmp->im_bo = bo; #if 0 udfmp->im_l2d = NULL; #endif /* * The UDF specification defines a logical sectorsize of 2048 * for DVD media. */ logical_secsize = 2048; if (((logical_secsize % cp->provider->sectorsize) != 0) || (logical_secsize < cp->provider->sectorsize)) { error = EINVAL; goto bail; } bsize = cp->provider->sectorsize; /* * Get the Anchor Volume Descriptor Pointer from sector 256. * XXX Should also check sector n - 256, n, and 512. */ sector = 256; if ((error = bread(devvp, sector * btodb(logical_secsize), bsize, NOCRED, &bp)) != 0) goto bail; if ((error = udf_checktag((struct desc_tag *)bp->b_data, TAGID_ANCHOR))) goto bail; bcopy(bp->b_data, &avdp, sizeof(struct anchor_vdp)); brelse(bp); bp = NULL; /* * Extract the Partition Descriptor and Logical Volume Descriptor * from the Volume Descriptor Sequence. * XXX Should we care about the partition type right now? * XXX What about multiple partitions? */ mvds_start = le32toh(avdp.main_vds_ex.loc); mvds_end = mvds_start + (le32toh(avdp.main_vds_ex.len) - 1) / bsize; for (sector = mvds_start; sector < mvds_end; sector++) { if ((error = bread(devvp, sector * btodb(logical_secsize), bsize, NOCRED, &bp)) != 0) { printf("Can't read sector %d of VDS\n", sector); goto bail; } lvd = (struct logvol_desc *)bp->b_data; if (!udf_checktag(&lvd->tag, TAGID_LOGVOL)) { udfmp->bsize = le32toh(lvd->lb_size); udfmp->bmask = udfmp->bsize - 1; udfmp->bshift = ffs(udfmp->bsize) - 1; fsd_part = le16toh(lvd->_lvd_use.fsd_loc.loc.part_num); fsd_offset = le32toh(lvd->_lvd_use.fsd_loc.loc.lb_num); if (udf_find_partmaps(udfmp, lvd)) break; logvol_found = 1; } pd = (struct part_desc *)bp->b_data; if (!udf_checktag(&pd->tag, TAGID_PARTITION)) { part_found = 1; part_num = le16toh(pd->part_num); udfmp->part_len = le32toh(pd->part_len); udfmp->part_start = le32toh(pd->start_loc); } brelse(bp); bp = NULL; if ((part_found) && (logvol_found)) break; } if (!part_found || !logvol_found) { error = EINVAL; goto bail; } if (fsd_part != part_num) { printf("FSD does not lie within the partition!\n"); error = EINVAL; goto bail; } /* * Grab the Fileset Descriptor * Thanks to Chuck McCrobie <*****@*****.**> for pointing * me in the right direction here. */ sector = udfmp->part_start + fsd_offset; if ((error = RDSECTOR(devvp, sector, udfmp->bsize, &bp)) != 0) { printf("Cannot read sector %d of FSD\n", sector); goto bail; } fsd = (struct fileset_desc *)bp->b_data; if (!udf_checktag(&fsd->tag, TAGID_FSD)) { fsd_found = 1; bcopy(&fsd->rootdir_icb, &udfmp->root_icb, sizeof(struct long_ad)); } brelse(bp); bp = NULL; if (!fsd_found) { printf("Couldn't find the fsd\n"); error = EINVAL; goto bail; } /* * Find the file entry for the root directory. */ sector = le32toh(udfmp->root_icb.loc.lb_num) + udfmp->part_start; size = le32toh(udfmp->root_icb.len); if ((error = udf_readdevblks(udfmp, sector, size, &bp)) != 0) { printf("Cannot read sector %d\n", sector); goto bail; } root_fentry = (struct file_entry *)bp->b_data; if ((error = udf_checktag(&root_fentry->tag, TAGID_FENTRY))) { printf("Invalid root file entry!\n"); goto bail; } brelse(bp); bp = NULL; return 0; bail: if (udfmp != NULL) free(udfmp, M_UDFMOUNT); if (bp != NULL) brelse(bp); if (cp != NULL) { DROP_GIANT(); g_topology_lock(); g_vfs_close(cp); g_topology_unlock(); PICKUP_GIANT(); } dev_rel(dev); return error; };
/* * Unmount the filesystem described by mp. */ static int msdosfs_unmount(struct mount *mp, int mntflags) { struct msdosfsmount *pmp; int error, flags; error = flags = 0; pmp = VFSTOMSDOSFS(mp); if ((pmp->pm_flags & MSDOSFSMNT_RONLY) == 0) error = msdosfs_sync(mp, MNT_WAIT); if ((mntflags & MNT_FORCE) != 0) flags |= FORCECLOSE; else if (error != 0) return (error); error = vflush(mp, 0, flags, curthread); if (error != 0 && error != ENXIO) return (error); if ((pmp->pm_flags & MSDOSFSMNT_RONLY) == 0) { error = markvoldirty(pmp, 0); if (error && error != ENXIO) { (void)markvoldirty(pmp, 1); return (error); } } if (pmp->pm_flags & MSDOSFSMNT_KICONV && msdosfs_iconv) { if (pmp->pm_w2u) msdosfs_iconv->close(pmp->pm_w2u); if (pmp->pm_u2w) msdosfs_iconv->close(pmp->pm_u2w); if (pmp->pm_d2u) msdosfs_iconv->close(pmp->pm_d2u); if (pmp->pm_u2d) msdosfs_iconv->close(pmp->pm_u2d); } #ifdef MSDOSFS_DEBUG { struct vnode *vp = pmp->pm_devvp; struct bufobj *bo; bo = &vp->v_bufobj; BO_LOCK(bo); VI_LOCK(vp); vn_printf(vp, "msdosfs_umount(): just before calling VOP_CLOSE()\n"); printf("freef %p, freeb %p, mount %p\n", TAILQ_NEXT(vp, v_actfreelist), vp->v_actfreelist.tqe_prev, vp->v_mount); printf("cleanblkhd %p, dirtyblkhd %p, numoutput %ld, type %d\n", TAILQ_FIRST(&vp->v_bufobj.bo_clean.bv_hd), TAILQ_FIRST(&vp->v_bufobj.bo_dirty.bv_hd), vp->v_bufobj.bo_numoutput, vp->v_type); VI_UNLOCK(vp); BO_UNLOCK(bo); } #endif DROP_GIANT(); if (pmp->pm_devvp->v_type == VCHR && pmp->pm_devvp->v_rdev != NULL) pmp->pm_devvp->v_rdev->si_mountpt = NULL; g_topology_lock(); g_vfs_close(pmp->pm_cp); g_topology_unlock(); PICKUP_GIANT(); vrele(pmp->pm_devvp); dev_rel(pmp->pm_dev); free(pmp->pm_inusemap, M_MSDOSFSFAT); if (pmp->pm_flags & MSDOSFS_LARGEFS) msdosfs_fileno_free(mp); lockdestroy(&pmp->pm_fatlock); free(pmp, M_MSDOSFSMNT); mp->mnt_data = NULL; MNT_ILOCK(mp); mp->mnt_flag &= ~MNT_LOCAL; MNT_IUNLOCK(mp); return (error); }
static int mountmsdosfs(struct vnode *devvp, struct mount *mp) { struct msdosfsmount *pmp; struct buf *bp; struct cdev *dev; union bootsector *bsp; struct byte_bpb33 *b33; struct byte_bpb50 *b50; struct byte_bpb710 *b710; u_int8_t SecPerClust; u_long clusters; int ronly, error; struct g_consumer *cp; struct bufobj *bo; bp = NULL; /* This and pmp both used in error_exit. */ pmp = NULL; ronly = (mp->mnt_flag & MNT_RDONLY) != 0; dev = devvp->v_rdev; dev_ref(dev); DROP_GIANT(); g_topology_lock(); error = g_vfs_open(devvp, &cp, "msdosfs", ronly ? 0 : 1); g_topology_unlock(); PICKUP_GIANT(); VOP_UNLOCK(devvp, 0); if (error) goto error_exit; bo = &devvp->v_bufobj; /* * Read the boot sector of the filesystem, and then check the * boot signature. If not a dos boot sector then error out. * * NOTE: 8192 is a magic size that works for ffs. */ error = bread(devvp, 0, 8192, NOCRED, &bp); if (error) goto error_exit; bp->b_flags |= B_AGE; bsp = (union bootsector *)bp->b_data; b33 = (struct byte_bpb33 *)bsp->bs33.bsBPB; b50 = (struct byte_bpb50 *)bsp->bs50.bsBPB; b710 = (struct byte_bpb710 *)bsp->bs710.bsBPB; #ifndef MSDOSFS_NOCHECKSIG if (bsp->bs50.bsBootSectSig0 != BOOTSIG0 || bsp->bs50.bsBootSectSig1 != BOOTSIG1) { error = EINVAL; goto error_exit; } #endif pmp = malloc(sizeof *pmp, M_MSDOSFSMNT, M_WAITOK | M_ZERO); pmp->pm_mountp = mp; pmp->pm_cp = cp; pmp->pm_bo = bo; lockinit(&pmp->pm_fatlock, 0, msdosfs_lock_msg, 0, 0); /* * Initialize ownerships and permissions, since nothing else will * initialize them iff we are mounting root. */ pmp->pm_uid = UID_ROOT; pmp->pm_gid = GID_WHEEL; pmp->pm_mask = pmp->pm_dirmask = S_IXUSR | S_IXGRP | S_IXOTH | S_IRUSR | S_IRGRP | S_IROTH | S_IWUSR; /* * Experimental support for large MS-DOS filesystems. * WARNING: This uses at least 32 bytes of kernel memory (which is not * reclaimed until the FS is unmounted) for each file on disk to map * between the 32-bit inode numbers used by VFS and the 64-bit * pseudo-inode numbers used internally by msdosfs. This is only * safe to use in certain controlled situations (e.g. read-only FS * with less than 1 million files). * Since the mappings do not persist across unmounts (or reboots), these * filesystems are not suitable for exporting through NFS, or any other * application that requires fixed inode numbers. */ vfs_flagopt(mp->mnt_optnew, "large", &pmp->pm_flags, MSDOSFS_LARGEFS); /* * Compute several useful quantities from the bpb in the * bootsector. Copy in the dos 5 variant of the bpb then fix up * the fields that are different between dos 5 and dos 3.3. */ SecPerClust = b50->bpbSecPerClust; pmp->pm_BytesPerSec = getushort(b50->bpbBytesPerSec); if (pmp->pm_BytesPerSec < DEV_BSIZE) { error = EINVAL; goto error_exit; } pmp->pm_ResSectors = getushort(b50->bpbResSectors); pmp->pm_FATs = b50->bpbFATs; pmp->pm_RootDirEnts = getushort(b50->bpbRootDirEnts); pmp->pm_Sectors = getushort(b50->bpbSectors); pmp->pm_FATsecs = getushort(b50->bpbFATsecs); pmp->pm_SecPerTrack = getushort(b50->bpbSecPerTrack); pmp->pm_Heads = getushort(b50->bpbHeads); pmp->pm_Media = b50->bpbMedia; /* calculate the ratio of sector size to DEV_BSIZE */ pmp->pm_BlkPerSec = pmp->pm_BytesPerSec / DEV_BSIZE; /* * We don't check pm_Heads nor pm_SecPerTrack, because * these may not be set for EFI file systems. We don't * use these anyway, so we're unaffected if they are * invalid. */ if (!pmp->pm_BytesPerSec || !SecPerClust) { error = EINVAL; goto error_exit; } if (pmp->pm_Sectors == 0) { pmp->pm_HiddenSects = getulong(b50->bpbHiddenSecs); pmp->pm_HugeSectors = getulong(b50->bpbHugeSectors); } else { pmp->pm_HiddenSects = getushort(b33->bpbHiddenSecs); pmp->pm_HugeSectors = pmp->pm_Sectors; } if (!(pmp->pm_flags & MSDOSFS_LARGEFS)) { if (pmp->pm_HugeSectors > 0xffffffff / (pmp->pm_BytesPerSec / sizeof(struct direntry)) + 1) { /* * We cannot deal currently with this size of disk * due to fileid limitations (see msdosfs_getattr and * msdosfs_readdir) */ error = EINVAL; vfs_mount_error(mp, "Disk too big, try '-o large' mount option"); goto error_exit; } } if (pmp->pm_RootDirEnts == 0) { if (pmp->pm_FATsecs || getushort(b710->bpbFSVers)) { error = EINVAL; #ifdef MSDOSFS_DEBUG printf("mountmsdosfs(): bad FAT32 filesystem\n"); #endif goto error_exit; } pmp->pm_fatmask = FAT32_MASK; pmp->pm_fatmult = 4; pmp->pm_fatdiv = 1; pmp->pm_FATsecs = getulong(b710->bpbBigFATsecs); if (getushort(b710->bpbExtFlags) & FATMIRROR) pmp->pm_curfat = getushort(b710->bpbExtFlags) & FATNUM; else pmp->pm_flags |= MSDOSFS_FATMIRROR; } else pmp->pm_flags |= MSDOSFS_FATMIRROR; /* * Check a few values (could do some more): * - logical sector size: power of 2, >= block size * - sectors per cluster: power of 2, >= 1 * - number of sectors: >= 1, <= size of partition * - number of FAT sectors: >= 1 */ if ( (SecPerClust == 0) || (SecPerClust & (SecPerClust - 1)) || (pmp->pm_BytesPerSec < DEV_BSIZE) || (pmp->pm_BytesPerSec & (pmp->pm_BytesPerSec - 1)) || (pmp->pm_HugeSectors == 0) || (pmp->pm_FATsecs == 0) || (SecPerClust * pmp->pm_BlkPerSec > MAXBSIZE / DEV_BSIZE) ) { error = EINVAL; goto error_exit; } pmp->pm_HugeSectors *= pmp->pm_BlkPerSec; pmp->pm_HiddenSects *= pmp->pm_BlkPerSec; /* XXX not used? */ pmp->pm_FATsecs *= pmp->pm_BlkPerSec; SecPerClust *= pmp->pm_BlkPerSec; pmp->pm_fatblk = pmp->pm_ResSectors * pmp->pm_BlkPerSec; if (FAT32(pmp)) { pmp->pm_rootdirblk = getulong(b710->bpbRootClust); pmp->pm_firstcluster = pmp->pm_fatblk + (pmp->pm_FATs * pmp->pm_FATsecs); pmp->pm_fsinfo = getushort(b710->bpbFSInfo) * pmp->pm_BlkPerSec; } else { pmp->pm_rootdirblk = pmp->pm_fatblk + (pmp->pm_FATs * pmp->pm_FATsecs); pmp->pm_rootdirsize = howmany(pmp->pm_RootDirEnts * sizeof(struct direntry), DEV_BSIZE); /* in blocks */ pmp->pm_firstcluster = pmp->pm_rootdirblk + pmp->pm_rootdirsize; } pmp->pm_maxcluster = (pmp->pm_HugeSectors - pmp->pm_firstcluster) / SecPerClust + 1; pmp->pm_fatsize = pmp->pm_FATsecs * DEV_BSIZE; /* XXX not used? */ if (pmp->pm_fatmask == 0) { if (pmp->pm_maxcluster <= ((CLUST_RSRVD - CLUST_FIRST) & FAT12_MASK)) { /* * This will usually be a floppy disk. This size makes * sure that one fat entry will not be split across * multiple blocks. */ pmp->pm_fatmask = FAT12_MASK; pmp->pm_fatmult = 3; pmp->pm_fatdiv = 2; } else { pmp->pm_fatmask = FAT16_MASK; pmp->pm_fatmult = 2; pmp->pm_fatdiv = 1; } } clusters = (pmp->pm_fatsize / pmp->pm_fatmult) * pmp->pm_fatdiv; if (pmp->pm_maxcluster >= clusters) { #ifdef MSDOSFS_DEBUG printf("Warning: number of clusters (%ld) exceeds FAT " "capacity (%ld)\n", pmp->pm_maxcluster + 1, clusters); #endif pmp->pm_maxcluster = clusters - 1; } if (FAT12(pmp)) pmp->pm_fatblocksize = 3 * 512; else pmp->pm_fatblocksize = PAGE_SIZE; pmp->pm_fatblocksize = roundup(pmp->pm_fatblocksize, pmp->pm_BytesPerSec); pmp->pm_fatblocksec = pmp->pm_fatblocksize / DEV_BSIZE; pmp->pm_bnshift = ffs(DEV_BSIZE) - 1; /* * Compute mask and shift value for isolating cluster relative byte * offsets and cluster numbers from a file offset. */ pmp->pm_bpcluster = SecPerClust * DEV_BSIZE; pmp->pm_crbomask = pmp->pm_bpcluster - 1; pmp->pm_cnshift = ffs(pmp->pm_bpcluster) - 1; /* * Check for valid cluster size * must be a power of 2 */ if (pmp->pm_bpcluster ^ (1 << pmp->pm_cnshift)) { error = EINVAL; goto error_exit; } /* * Release the bootsector buffer. */ brelse(bp); bp = NULL; /* * Check the fsinfo sector if we have one. Silently fix up our * in-core copy of fp->fsinxtfree if it is unknown (0xffffffff) * or too large. Ignore fp->fsinfree for now, since we need to * read the entire FAT anyway to fill the inuse map. */ if (pmp->pm_fsinfo) { struct fsinfo *fp; if ((error = bread(devvp, pmp->pm_fsinfo, pmp->pm_BytesPerSec, NOCRED, &bp)) != 0) goto error_exit; fp = (struct fsinfo *)bp->b_data; if (!bcmp(fp->fsisig1, "RRaA", 4) && !bcmp(fp->fsisig2, "rrAa", 4) && !bcmp(fp->fsisig3, "\0\0\125\252", 4)) { pmp->pm_nxtfree = getulong(fp->fsinxtfree); if (pmp->pm_nxtfree > pmp->pm_maxcluster) pmp->pm_nxtfree = CLUST_FIRST; } else pmp->pm_fsinfo = 0; brelse(bp); bp = NULL; } /* * Finish initializing pmp->pm_nxtfree (just in case the first few * sectors aren't properly reserved in the FAT). This completes * the fixup for fp->fsinxtfree, and fixes up the zero-initialized * value if there is no fsinfo. We will use pmp->pm_nxtfree * internally even if there is no fsinfo. */ if (pmp->pm_nxtfree < CLUST_FIRST) pmp->pm_nxtfree = CLUST_FIRST; /* * Allocate memory for the bitmap of allocated clusters, and then * fill it in. */ pmp->pm_inusemap = malloc(howmany(pmp->pm_maxcluster + 1, N_INUSEBITS) * sizeof(*pmp->pm_inusemap), M_MSDOSFSFAT, M_WAITOK); /* * fillinusemap() needs pm_devvp. */ pmp->pm_devvp = devvp; pmp->pm_dev = dev; /* * Have the inuse map filled in. */ MSDOSFS_LOCK_MP(pmp); error = fillinusemap(pmp); MSDOSFS_UNLOCK_MP(pmp); if (error != 0) goto error_exit; /* * If they want fat updates to be synchronous then let them suffer * the performance degradation in exchange for the on disk copy of * the fat being correct just about all the time. I suppose this * would be a good thing to turn on if the kernel is still flakey. */ if (mp->mnt_flag & MNT_SYNCHRONOUS) pmp->pm_flags |= MSDOSFSMNT_WAITONFAT; /* * Finish up. */ if (ronly) pmp->pm_flags |= MSDOSFSMNT_RONLY; else { if ((error = markvoldirty(pmp, 1)) != 0) { (void)markvoldirty(pmp, 0); goto error_exit; } pmp->pm_fmod = 1; } mp->mnt_data = pmp; mp->mnt_stat.f_fsid.val[0] = dev2udev(dev); mp->mnt_stat.f_fsid.val[1] = mp->mnt_vfc->vfc_typenum; MNT_ILOCK(mp); mp->mnt_flag |= MNT_LOCAL; mp->mnt_kern_flag |= MNTK_USES_BCACHE; MNT_IUNLOCK(mp); if (pmp->pm_flags & MSDOSFS_LARGEFS) msdosfs_fileno_init(mp); return 0; error_exit: if (bp) brelse(bp); if (cp != NULL) { DROP_GIANT(); g_topology_lock(); g_vfs_close(cp); g_topology_unlock(); PICKUP_GIANT(); } if (pmp) { lockdestroy(&pmp->pm_fatlock); if (pmp->pm_inusemap) free(pmp->pm_inusemap, M_MSDOSFSFAT); free(pmp, M_MSDOSFSMNT); mp->mnt_data = NULL; } dev_rel(dev); return (error); }
/* * Common code for mount and mountroot */ static int reiserfs_mountfs(struct vnode *devvp, struct mount *mp, struct thread *td) { int error, old_format = 0; struct reiserfs_mount *rmp; struct reiserfs_sb_info *sbi; struct reiserfs_super_block *rs; struct cdev *dev; struct g_consumer *cp; struct bufobj *bo; //ronly = (mp->mnt_flag & MNT_RDONLY) != 0; dev = devvp->v_rdev; dev_ref(dev); DROP_GIANT(); g_topology_lock(); error = g_vfs_open(devvp, &cp, "reiserfs", /* read-only */ 0); g_topology_unlock(); PICKUP_GIANT(); VOP_UNLOCK(devvp, 0); if (error) { dev_rel(dev); return (error); } bo = &devvp->v_bufobj; bo->bo_private = cp; bo->bo_ops = g_vfs_bufops; if (devvp->v_rdev->si_iosize_max != 0) mp->mnt_iosize_max = devvp->v_rdev->si_iosize_max; if (mp->mnt_iosize_max > MAXPHYS) mp->mnt_iosize_max = MAXPHYS; rmp = NULL; sbi = NULL; /* rmp contains any information about this specific mount */ rmp = malloc(sizeof *rmp, M_REISERFSMNT, M_WAITOK | M_ZERO); if (!rmp) { error = (ENOMEM); goto out; } sbi = malloc(sizeof *sbi, M_REISERFSMNT, M_WAITOK | M_ZERO); if (!sbi) { error = (ENOMEM); goto out; } rmp->rm_reiserfs = sbi; rmp->rm_mountp = mp; rmp->rm_devvp = devvp; rmp->rm_dev = dev; rmp->rm_bo = &devvp->v_bufobj; rmp->rm_cp = cp; /* Set default values for options: non-aggressive tails */ REISERFS_SB(sbi)->s_mount_opt = (1 << REISERFS_SMALLTAIL); REISERFS_SB(sbi)->s_rd_only = 1; REISERFS_SB(sbi)->s_devvp = devvp; /* Read the super block */ if ((error = read_super_block(rmp, REISERFS_OLD_DISK_OFFSET)) == 0) { /* The read process succeeded, it's an old format */ old_format = 1; } else if ((error = read_super_block(rmp, REISERFS_DISK_OFFSET)) != 0) { reiserfs_log(LOG_ERR, "can not find a ReiserFS filesystem\n"); goto out; } rs = SB_DISK_SUPER_BLOCK(sbi); /* * Let's do basic sanity check to verify that underlying device is * not smaller than the filesystem. If the check fails then abort and * scream, because bad stuff will happen otherwise. */ #if 0 if (s->s_bdev && s->s_bdev->bd_inode && i_size_read(s->s_bdev->bd_inode) < sb_block_count(rs) * sb_blocksize(rs)) { reiserfs_log(LOG_ERR, "reiserfs: filesystem cannot be mounted because it is " "bigger than the device.\n"); reiserfs_log(LOG_ERR, "reiserfs: you may need to run fsck " "rr may be you forgot to reboot after fdisk when it " "told you to.\n"); goto out; } #endif /* * XXX This is from the original Linux code, but why affecting 2 values * to the same variable? */ sbi->s_mount_state = SB_REISERFS_STATE(sbi); sbi->s_mount_state = REISERFS_VALID_FS; if ((error = (old_format ? read_old_bitmaps(rmp) : read_bitmaps(rmp)))) { reiserfs_log(LOG_ERR, "unable to read bitmap\n"); goto out; } /* Make data=ordered the default */ if (!reiserfs_data_log(sbi) && !reiserfs_data_ordered(sbi) && !reiserfs_data_writeback(sbi)) { REISERFS_SB(sbi)->s_mount_opt |= (1 << REISERFS_DATA_ORDERED); } if (reiserfs_data_log(sbi)) { reiserfs_log(LOG_INFO, "using journaled data mode\n"); } else if (reiserfs_data_ordered(sbi)) { reiserfs_log(LOG_INFO, "using ordered data mode\n"); } else { reiserfs_log(LOG_INFO, "using writeback data mode\n"); } /* TODO Not yet supported */ #if 0 if(journal_init(sbi, jdev_name, old_format, commit_max_age)) { reiserfs_log(LOG_ERR, "unable to initialize journal space\n"); goto out; } else { jinit_done = 1 ; /* once this is set, journal_release must be called if we error out of the mount */ } if (reread_meta_blocks(sbi)) { reiserfs_log(LOG_ERR, "unable to reread meta blocks after journal init\n"); goto out; } #endif /* Define and initialize hash function */ sbi->s_hash_function = hash_function(rmp); if (sbi->s_hash_function == NULL) { reiserfs_log(LOG_ERR, "couldn't determined hash function\n"); error = (EINVAL); goto out; } if (is_reiserfs_3_5(rs) || (is_reiserfs_jr(rs) && SB_VERSION(sbi) == REISERFS_VERSION_1)) bit_set(&(sbi->s_properties), REISERFS_3_5); else bit_set(&(sbi->s_properties), REISERFS_3_6); mp->mnt_data = rmp; mp->mnt_stat.f_fsid.val[0] = dev2udev(dev); mp->mnt_stat.f_fsid.val[1] = mp->mnt_vfc->vfc_typenum; MNT_ILOCK(mp); mp->mnt_flag |= MNT_LOCAL; mp->mnt_kern_flag |= MNTK_MPSAFE; MNT_IUNLOCK(mp); #if defined(si_mountpoint) devvp->v_rdev->si_mountpoint = mp; #endif return (0); out: reiserfs_log(LOG_INFO, "*** error during mount ***\n"); if (sbi) { if (SB_AP_BITMAP(sbi)) { int i; for (i = 0; i < SB_BMAP_NR(sbi); i++) { if (!SB_AP_BITMAP(sbi)[i].bp_data) break; free(SB_AP_BITMAP(sbi)[i].bp_data, M_REISERFSMNT); } free(SB_AP_BITMAP(sbi), M_REISERFSMNT); } if (sbi->s_rs) { free(sbi->s_rs, M_REISERFSMNT); sbi->s_rs = NULL; } } if (cp != NULL) { DROP_GIANT(); g_topology_lock(); g_vfs_close(cp); g_topology_unlock(); PICKUP_GIANT(); } if (sbi) free(sbi, M_REISERFSMNT); if (rmp) free(rmp, M_REISERFSMNT); dev_rel(dev); return (error); }
/* * Unmount system call */ static int reiserfs_unmount(struct mount *mp, int mntflags) { int error, flags = 0; struct reiserfs_mount *rmp; struct reiserfs_sb_info *sbi; reiserfs_log(LOG_DEBUG, "get private data\n"); rmp = VFSTOREISERFS(mp); sbi = rmp->rm_reiserfs; /* Flangs handling */ reiserfs_log(LOG_DEBUG, "handle mntflags\n"); if (mntflags & MNT_FORCE) flags |= FORCECLOSE; /* Flush files -> vflush */ reiserfs_log(LOG_DEBUG, "flush vnodes\n"); if ((error = vflush(mp, 0, flags, curthread))) return (error); /* XXX Super block update */ if (sbi) { if (SB_AP_BITMAP(sbi)) { int i; reiserfs_log(LOG_DEBUG, "release bitmap buffers (total: %d)\n", SB_BMAP_NR(sbi)); for (i = 0; i < SB_BMAP_NR(sbi); i++) { if (SB_AP_BITMAP(sbi)[i].bp_data) { free(SB_AP_BITMAP(sbi)[i].bp_data, M_REISERFSMNT); SB_AP_BITMAP(sbi)[i].bp_data = NULL; } } reiserfs_log(LOG_DEBUG, "free bitmaps structure\n"); free(SB_AP_BITMAP(sbi), M_REISERFSMNT); SB_AP_BITMAP(sbi) = NULL; } if (sbi->s_rs) { reiserfs_log(LOG_DEBUG, "free super block data\n"); free(sbi->s_rs, M_REISERFSMNT); sbi->s_rs = NULL; } } reiserfs_log(LOG_DEBUG, "close device\n"); #if defined(si_mountpoint) rmp->rm_devvp->v_rdev->si_mountpoint = NULL; #endif DROP_GIANT(); g_topology_lock(); g_vfs_close(rmp->rm_cp); g_topology_unlock(); PICKUP_GIANT(); vrele(rmp->rm_devvp); dev_rel(rmp->rm_dev); if (sbi) { reiserfs_log(LOG_DEBUG, "free sbi\n"); free(sbi, M_REISERFSMNT); sbi = rmp->rm_reiserfs = NULL; } if (rmp) { reiserfs_log(LOG_DEBUG, "free rmp\n"); free(rmp, M_REISERFSMNT); rmp = NULL; } mp->mnt_data = 0; MNT_ILOCK(mp); mp->mnt_flag &= ~MNT_LOCAL; MNT_IUNLOCK(mp); reiserfs_log(LOG_DEBUG, "done\n"); return (error); }
static int fuse_vfsop_unmount(struct mount *mp, int mntflags) { int err = 0; int flags = 0; struct cdev *fdev; struct fuse_data *data; struct fuse_dispatcher fdi; struct thread *td = curthread; fuse_trace_printf_vfsop(); if (mntflags & MNT_FORCE) { flags |= FORCECLOSE; } data = fuse_get_mpdata(mp); if (!data) { panic("no private data for mount point?"); } /* There is 1 extra root vnode reference (mp->mnt_data). */ FUSE_LOCK(); if (data->vroot != NULL) { struct vnode *vroot = data->vroot; data->vroot = NULL; FUSE_UNLOCK(); vrele(vroot); } else FUSE_UNLOCK(); err = vflush(mp, 0, flags, td); if (err) { debug_printf("vflush failed"); return err; } if (fdata_get_dead(data)) { goto alreadydead; } fdisp_init(&fdi, 0); fdisp_make(&fdi, FUSE_DESTROY, mp, 0, td, NULL); err = fdisp_wait_answ(&fdi); fdisp_destroy(&fdi); fdata_set_dead(data); alreadydead: FUSE_LOCK(); data->mp = NULL; fdev = data->fdev; fdata_trydestroy(data); FUSE_UNLOCK(); MNT_ILOCK(mp); mp->mnt_data = NULL; mp->mnt_flag &= ~MNT_LOCAL; MNT_IUNLOCK(mp); dev_rel(fdev); return 0; }
static int fuse_vfsop_mount(struct mount *mp) { int err; uint64_t mntopts, __mntopts; int max_read_set; uint32_t max_read; int daemon_timeout; int fd; size_t len; struct cdev *fdev; struct fuse_data *data; struct thread *td; struct file *fp, *fptmp; char *fspec, *subtype; struct vfsoptlist *opts; subtype = NULL; max_read_set = 0; max_read = ~0; err = 0; mntopts = 0; __mntopts = 0; td = curthread; fuse_trace_printf_vfsop(); if (mp->mnt_flag & MNT_UPDATE) return EOPNOTSUPP; mp->mnt_flag |= MNT_SYNCHRONOUS; mp->mnt_data = NULL; /* Get the new options passed to mount */ opts = mp->mnt_optnew; if (!opts) return EINVAL; /* `fspath' contains the mount point (eg. /mnt/fuse/sshfs); REQUIRED */ if (!vfs_getopts(opts, "fspath", &err)) return err; /* `from' contains the device name (eg. /dev/fuse0); REQUIRED */ fspec = vfs_getopts(opts, "from", &err); if (!fspec) return err; /* `fd' contains the filedescriptor for this session; REQUIRED */ if (vfs_scanopt(opts, "fd", "%d", &fd) != 1) return EINVAL; err = fuse_getdevice(fspec, td, &fdev); if (err != 0) return err; /* * With the help of underscored options the mount program * can inform us from the flags it sets by default */ FUSE_FLAGOPT(allow_other, FSESS_DAEMON_CAN_SPY); FUSE_FLAGOPT(push_symlinks_in, FSESS_PUSH_SYMLINKS_IN); FUSE_FLAGOPT(default_permissions, FSESS_DEFAULT_PERMISSIONS); FUSE_FLAGOPT(no_attrcache, FSESS_NO_ATTRCACHE); FUSE_FLAGOPT(no_readahed, FSESS_NO_READAHEAD); FUSE_FLAGOPT(no_datacache, FSESS_NO_DATACACHE); FUSE_FLAGOPT(no_namecache, FSESS_NO_NAMECACHE); FUSE_FLAGOPT(no_mmap, FSESS_NO_MMAP); FUSE_FLAGOPT(brokenio, FSESS_BROKENIO); if (vfs_scanopt(opts, "max_read=", "%u", &max_read) == 1) max_read_set = 1; if (vfs_scanopt(opts, "timeout=", "%u", &daemon_timeout) == 1) { if (daemon_timeout < FUSE_MIN_DAEMON_TIMEOUT) daemon_timeout = FUSE_MIN_DAEMON_TIMEOUT; else if (daemon_timeout > FUSE_MAX_DAEMON_TIMEOUT) daemon_timeout = FUSE_MAX_DAEMON_TIMEOUT; } else { daemon_timeout = FUSE_DEFAULT_DAEMON_TIMEOUT; } subtype = vfs_getopts(opts, "subtype=", &err); FS_DEBUG2G("mntopts 0x%jx\n", (uintmax_t)mntopts); err = fget(td, fd, CAP_READ, &fp); if (err != 0) { FS_DEBUG("invalid or not opened device: data=%p\n", data); goto out; } fptmp = td->td_fpop; td->td_fpop = fp; err = devfs_get_cdevpriv((void **)&data); td->td_fpop = fptmp; fdrop(fp, td); FUSE_LOCK(); if (err != 0 || data == NULL || data->mp != NULL) { FS_DEBUG("invalid or not opened device: data=%p data.mp=%p\n", data, data != NULL ? data->mp : NULL); err = ENXIO; FUSE_UNLOCK(); goto out; } if (fdata_get_dead(data)) { FS_DEBUG("device is dead during mount: data=%p\n", data); err = ENOTCONN; FUSE_UNLOCK(); goto out; } /* Sanity + permission checks */ if (!data->daemoncred) panic("fuse daemon found, but identity unknown"); if (mntopts & FSESS_DAEMON_CAN_SPY) err = priv_check(td, PRIV_VFS_FUSE_ALLOWOTHER); if (err == 0 && td->td_ucred->cr_uid != data->daemoncred->cr_uid) /* are we allowed to do the first mount? */ err = priv_check(td, PRIV_VFS_FUSE_MOUNT_NONUSER); if (err) { FUSE_UNLOCK(); goto out; } /* We need this here as this slot is used by getnewvnode() */ mp->mnt_stat.f_iosize = PAGE_SIZE; mp->mnt_data = data; data->ref++; data->mp = mp; data->dataflags |= mntopts; data->max_read = max_read; data->daemon_timeout = daemon_timeout; #ifdef XXXIP if (!priv_check(td, PRIV_VFS_FUSE_SYNC_UNMOUNT)) data->dataflags |= FSESS_CAN_SYNC_UNMOUNT; #endif FUSE_UNLOCK(); vfs_getnewfsid(mp); mp->mnt_flag |= MNT_LOCAL; mp->mnt_kern_flag |= MNTK_MPSAFE; if (subtype) { strlcat(mp->mnt_stat.f_fstypename, ".", MFSNAMELEN); strlcat(mp->mnt_stat.f_fstypename, subtype, MFSNAMELEN); } copystr(fspec, mp->mnt_stat.f_mntfromname, MNAMELEN - 1, &len); bzero(mp->mnt_stat.f_mntfromname + len, MNAMELEN - len); FS_DEBUG2G("mp %p: %s\n", mp, mp->mnt_stat.f_mntfromname); /* Now handshaking with daemon */ fuse_internal_send_init(data, td); out: if (err) { FUSE_LOCK(); if (data->mp == mp) { /* * Destroy device only if we acquired reference to * it */ FS_DEBUG("mount failed, destroy device: data=%p mp=%p" " err=%d\n", data, mp, err); data->mp = NULL; fdata_trydestroy(data); } FUSE_UNLOCK(); dev_rel(fdev); } return err; }
static int fuse_getdevice(const char *fspec, struct thread *td, struct cdev **fdevp) { struct nameidata nd, *ndp = &nd; struct vnode *devvp; struct cdev *fdev; int err; /* * Not an update, or updating the name: look up the name * and verify that it refers to a sensible disk device. */ NDINIT(ndp, LOOKUP, FOLLOW, UIO_SYSSPACE, fspec, td); if ((err = namei(ndp)) != 0) return err; NDFREE(ndp, NDF_ONLY_PNBUF); devvp = ndp->ni_vp; if (devvp->v_type != VCHR) { vrele(devvp); return ENXIO; } fdev = devvp->v_rdev; dev_ref(fdev); if (fuse_enforce_dev_perms) { /* * Check if mounter can open the fuse device. * * This has significance only if we are doing a secondary mount * which doesn't involve actually opening fuse devices, but we * still want to enforce the permissions of the device (in * order to keep control over the circle of fuse users). * * (In case of primary mounts, we are either the superuser so * we can do anything anyway, or we can mount only if the * device is already opened by us, ie. we are permitted to open * the device.) */ #if 0 #ifdef MAC err = mac_check_vnode_open(td->td_ucred, devvp, VREAD | VWRITE); if (!err) #endif #endif /* 0 */ err = VOP_ACCESS(devvp, VREAD | VWRITE, td->td_ucred, td); if (err) { vrele(devvp); dev_rel(fdev); return err; } } /* * according to coda code, no extra lock is needed -- * although in sys/vnode.h this field is marked "v" */ vrele(devvp); if (!fdev->si_devsw || strcmp("fuse", fdev->si_devsw->d_name)) { dev_rel(fdev); return ENXIO; } *fdevp = fdev; return 0; }