/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define MNTROOTINO 2 static mntnode_t *mntgetnode(vnode_t *); vnodeops_t *mntvnodeops; /* * Design of kernel mnttab accounting. * * To support whitespace in mount names, we implement an ioctl * (MNTIOC_GETMNTENT) which allows a programmatic interface to the data in * /etc/mnttab. The libc functions getmntent() and getextmntent() are built * atop this interface. * * To minimize the amount of memory used in the kernel, we keep all the * necessary information in the user's address space. Large server * configurations can have /etc/mnttab files in excess of 64k. * * To support both vanilla read() calls as well as ioctl() calls, we have two * different snapshots of the kernel data structures, mnt_read and mnt_ioctl. * These snapshots include the base location in user memory, the number of * mounts in the snapshot, and any metadata associated with it. The metadata is * used only to support the ioctl() interface, and is a series of extmnttab * structures. When the user issues an ioctl(), we simply copyout a pointer to * that structure, and the rest is handled in userland. */ /* * NOTE: The following variable enables the generation of the "dev=xxx" * in the option string for a mounted file system. Really this should * be gotten rid of altogether, but for the sake of backwards compatibility * we had to leave it in. It is defined as a 32-bit device number. This * means that when 64-bit device numbers are in use, if either the major or * minor part of the device number will not fit in a 16 bit quantity, the * "dev=" will be set to NODEV (0x7fffffff). See PSARC 1999/566 and * 1999/131 for details. The cmpldev() function used to generate the 32-bit * device number handles this check and assigns the proper value. */ int mntfs_enabledev = 1; /* enable old "dev=xxx" option */ static int mntfs_devsize(struct vfs *vfsp) { dev32_t odev; (void) cmpldev(&odev, vfsp->vfs_dev); return (snprintf(NULL, 0, "dev=%x", odev)); } static int mntfs_devprint(struct vfs *vfsp, char *buf) { dev32_t odev; (void) cmpldev(&odev, vfsp->vfs_dev); return (snprintf(buf, MAX_MNTOPT_STR, "dev=%x", odev)); } static int mntfs_optsize(struct vfs *vfsp) { int i, size = 0; mntopt_t *mop; for (i = 0; i < vfsp->vfs_mntopts.mo_count; i++) { mop = &vfsp->vfs_mntopts.mo_list[i]; if (mop->mo_flags & MO_NODISPLAY) continue; if (mop->mo_flags & MO_SET) { if (size) size++; /* space for comma */ size += strlen(mop->mo_name); /* * count option value if there is one */ if (mop->mo_arg != NULL) { size += strlen(mop->mo_arg) + 1; } } } if (vfsp->vfs_zone != NULL && vfsp->vfs_zone != global_zone) { /* * Add space for "zone=" if required. */ if (size) size++; /* space for comma */ size += sizeof ("zone=") - 1; size += strlen(vfsp->vfs_zone->zone_name); } if (mntfs_enabledev) { if (size != 0) size++; /* space for comma */ size += mntfs_devsize(vfsp); } if (size == 0) size = strlen("-"); return (size); } static int mntfs_optprint(struct vfs *vfsp, char *buf) { int i, optinbuf = 0; mntopt_t *mop; char *origbuf = buf; for (i = 0; i < vfsp->vfs_mntopts.mo_count; i++) { mop = &vfsp->vfs_mntopts.mo_list[i]; if (mop->mo_flags & MO_NODISPLAY) continue; if (mop->mo_flags & MO_SET) { if (optinbuf) *buf++ = ','; else optinbuf = 1; buf += snprintf(buf, MAX_MNTOPT_STR, "%s", mop->mo_name); /* * print option value if there is one */ if (mop->mo_arg != NULL) { buf += snprintf(buf, MAX_MNTOPT_STR, "=%s", mop->mo_arg); } } } if (vfsp->vfs_zone != NULL && vfsp->vfs_zone != global_zone) { if (optinbuf) *buf++ = ','; else optinbuf = 1; buf += snprintf(buf, MAX_MNTOPT_STR, "zone=%s", vfsp->vfs_zone->zone_name); } if (mntfs_enabledev) { if (optinbuf++) *buf++ = ','; buf += mntfs_devprint(vfsp, buf); } if (!optinbuf) { buf += snprintf(buf, MAX_MNTOPT_STR, "-"); } return (buf - origbuf); } static size_t mntfs_vfs_len(vfs_t *vfsp, zone_t *zone) { size_t size = 0; const char *resource, *mntpt; mntpt = refstr_value(vfsp->vfs_mntpt); if (mntpt != NULL && mntpt[0] != '\0') { size += strlen(ZONE_PATH_TRANSLATE(mntpt, zone)) + 1; } else { size += strlen("-") + 1; } resource = refstr_value(vfsp->vfs_resource); if (resource != NULL && resource[0] != '\0') { if (resource[0] != '/') { size += strlen(resource) + 1; } else if (!ZONE_PATH_VISIBLE(resource, zone)) { /* * Same as the zone's view of the mount point. */ size += strlen(ZONE_PATH_TRANSLATE(mntpt, zone)) + 1; } else { size += strlen(ZONE_PATH_TRANSLATE(resource, zone)) + 1; } } else { size += strlen("-") + 1; } size += strlen(vfssw[vfsp->vfs_fstype].vsw_name) + 1; size += mntfs_optsize(vfsp); size += snprintf(NULL, 0, "\t%ld\n", vfsp->vfs_mtime); return (size); } static void mntfs_zonerootvfs(zone_t *zone, vfs_t *rootvfsp) { /* * Basically copy over the real vfs_t on which the root vnode is * located, changing its mountpoint and resource to match those of * the zone's rootpath. */ *rootvfsp = *zone->zone_rootvp->v_vfsp; rootvfsp->vfs_mntpt = refstr_alloc(zone->zone_rootpath); rootvfsp->vfs_resource = rootvfsp->vfs_mntpt; } static size_t mntfs_zone_len(uint_t *nent_ptr, zone_t *zone, int showhidden) { struct vfs *zonelist; struct vfs *vfsp; size_t size = 0; uint_t cnt = 0; ASSERT(zone->zone_rootpath != NULL); /* * If the zone has a root entry, it will be the first in the list. If * it doesn't, we conjure one up. */ vfsp = zonelist = zone->zone_vfslist; if (zonelist == NULL || strcmp(refstr_value(vfsp->vfs_mntpt), zone->zone_rootpath) != 0) { vfs_t tvfs; /* * The root of the zone is not a mount point. The vfs we want * to report is that of the zone's root vnode. */ ASSERT(zone != global_zone); mntfs_zonerootvfs(zone, &tvfs); size += mntfs_vfs_len(&tvfs, zone); refstr_rele(tvfs.vfs_mntpt); cnt++; } if (zonelist == NULL) goto out; do { /* * Skip mounts that should not show up in mnttab */ if (!showhidden && (vfsp->vfs_flag & VFS_NOMNTTAB)) { vfsp = vfsp->vfs_zone_next; continue; } cnt++; size += mntfs_vfs_len(vfsp, zone); vfsp = vfsp->vfs_zone_next; } while (vfsp != zonelist); out: *nent_ptr = cnt; return (size); } static size_t mntfs_global_len(uint_t *nent_ptr, int showhidden) { struct vfs *vfsp; size_t size = 0; uint_t cnt = 0; vfsp = rootvfs; do { /* * Skip mounts that should not show up in mnttab */ if (!showhidden && (vfsp->vfs_flag & VFS_NOMNTTAB)) { vfsp = vfsp->vfs_next; continue; } cnt++; size += mntfs_vfs_len(vfsp, global_zone); vfsp = vfsp->vfs_next; } while (vfsp != rootvfs); *nent_ptr = cnt; return (size); } static void mntfs_vfs_generate(vfs_t *vfsp, zone_t *zone, struct extmnttab *tab, char **basep, int forread) { const char *resource, *mntpt; char *cp = *basep; mntpt = refstr_value(vfsp->vfs_mntpt); resource = refstr_value(vfsp->vfs_resource); if (tab) tab->mnt_special = cp; if (resource != NULL && resource[0] != '\0') { if (resource[0] != '/') { cp += snprintf(cp, MAXPATHLEN, "%s", resource); } else if (!ZONE_PATH_VISIBLE(resource, zone)) { /* * Use the mount point as the resource. */ cp += snprintf(cp, MAXPATHLEN, "%s", ZONE_PATH_TRANSLATE(mntpt, zone)); } else { cp += snprintf(cp, MAXPATHLEN, "%s", ZONE_PATH_TRANSLATE(resource, zone)); } } else { cp += snprintf(cp, MAXPATHLEN, "-"); } *cp++ = forread ? '\t' : '\0'; if (tab) tab->mnt_mountp = cp; if (mntpt != NULL && mntpt[0] != '\0') { /* * We know the mount point is visible from within the zone, * otherwise it wouldn't be on the zone's vfs list. */ cp += snprintf(cp, MAXPATHLEN, "%s", ZONE_PATH_TRANSLATE(mntpt, zone)); } else { cp += snprintf(cp, MAXPATHLEN, "-"); } *cp++ = forread ? '\t' : '\0'; if (tab) tab->mnt_fstype = cp; cp += snprintf(cp, MAXPATHLEN, "%s", vfssw[vfsp->vfs_fstype].vsw_name); *cp++ = forread ? '\t' : '\0'; if (tab) tab->mnt_mntopts = cp; cp += mntfs_optprint(vfsp, cp); *cp++ = forread ? '\t' : '\0'; if (tab) tab->mnt_time = cp; cp += snprintf(cp, MAX_MNTOPT_STR, "%ld", vfsp->vfs_mtime); *cp++ = forread ? '\n' : '\0'; if (tab) { tab->mnt_major = getmajor(vfsp->vfs_dev); tab->mnt_minor = getminor(vfsp->vfs_dev); } *basep = cp; } static void mntfs_zone_generate(zone_t *zone, int showhidden, struct extmnttab *tab, char *basep, int forread) { vfs_t *zonelist; vfs_t *vfsp; char *cp = basep; /* * If the zone has a root entry, it will be the first in the list. If * it doesn't, we conjure one up. */ vfsp = zonelist = zone->zone_vfslist; if (zonelist == NULL || strcmp(refstr_value(vfsp->vfs_mntpt), zone->zone_rootpath) != 0) { vfs_t tvfs; /* * The root of the zone is not a mount point. The vfs we want * to report is that of the zone's root vnode. */ ASSERT(zone != global_zone); mntfs_zonerootvfs(zone, &tvfs); mntfs_vfs_generate(&tvfs, zone, tab, &cp, forread); refstr_rele(tvfs.vfs_mntpt); if (tab) tab++; } if (zonelist == NULL) return; do { /* * Skip mounts that should not show up in mnttab */ if (!showhidden && (vfsp->vfs_flag & VFS_NOMNTTAB)) { vfsp = vfsp->vfs_zone_next; continue; } mntfs_vfs_generate(vfsp, zone, tab, &cp, forread); if (tab) tab++; vfsp = vfsp->vfs_zone_next; } while (vfsp != zonelist); } static void mntfs_global_generate(int showhidden, struct extmnttab *tab, char *basep, int forread) { vfs_t *vfsp; char *cp = basep; vfsp = rootvfs; do { /* * Skip mounts that should not show up in mnttab */ if (!showhidden && vfsp->vfs_flag & VFS_NOMNTTAB) { vfsp = vfsp->vfs_next; continue; } mntfs_vfs_generate(vfsp, global_zone, tab, &cp, forread); if (tab) tab++; vfsp = vfsp->vfs_next; } while (vfsp != rootvfs); } static char * mntfs_mapin(char *base, size_t size) { size_t rlen = roundup(size, PAGESIZE); struct as *as = curproc->p_as; char *addr; as_rangelock(as); map_addr(&addr, rlen, 0, 1, 0); if (addr == NULL || as_map(as, addr, rlen, segvn_create, zfod_argsp)) { as_rangeunlock(as); return (NULL); } as_rangeunlock(as); if (copyout(base, addr, size)) { (void) as_unmap(as, addr, rlen); return (NULL); } return (addr); } static void mntfs_freesnap(mntsnap_t *snap) { if (snap->mnts_text != NULL) (void) as_unmap(curproc->p_as, snap->mnts_text, roundup(snap->mnts_textsize, PAGESIZE)); snap->mnts_textsize = snap->mnts_count = 0; if (snap->mnts_metadata != NULL) (void) as_unmap(curproc->p_as, snap->mnts_metadata, roundup(snap->mnts_metasize, PAGESIZE)); snap->mnts_metasize = 0; } #ifdef _SYSCALL32_IMPL typedef struct extmnttab32 { uint32_t mnt_special; uint32_t mnt_mountp; uint32_t mnt_fstype; uint32_t mnt_mntopts; uint32_t mnt_time; uint_t mnt_major; uint_t mnt_minor; } extmnttab32_t; #endif /* * Snapshot the latest version of the kernel mounted resource information * * There are two types of snapshots: one destined for reading, and one destined * for ioctl(). The difference is that the ioctl() interface is delimited by * NULLs, while the read() interface is delimited by tabs and newlines. */ /* ARGSUSED */ static int mntfs_snapshot(mntnode_t *mnp, int forread, int datamodel) { size_t size; timespec_t lastmodt; mntdata_t *mntdata = MTOD(mnp); zone_t *zone = mntdata->mnt_zone; boolean_t global_view = (MTOD(mnp)->mnt_zone == global_zone); boolean_t showhidden = ((mnp->mnt_flags & MNT_SHOWHIDDEN) != 0); struct extmnttab *metadata_baseaddr; char *text_baseaddr; int i; mntsnap_t *snap; if (forread) snap = &mnp->mnt_read; else snap = &mnp->mnt_ioctl; vfs_list_read_lock(); /* * Check if the mnttab info has changed since the last snapshot */ vfs_mnttab_modtime(&lastmodt); if (snap->mnts_count && lastmodt.tv_sec == snap->mnts_time.tv_sec && lastmodt.tv_nsec == snap->mnts_time.tv_nsec) { vfs_list_unlock(); return (0); } if (snap->mnts_count != 0) mntfs_freesnap(snap); if (global_view) size = mntfs_global_len(&snap->mnts_count, showhidden); else size = mntfs_zone_len(&snap->mnts_count, zone, showhidden); ASSERT(size != 0); if (!forread) metadata_baseaddr = kmem_alloc( snap->mnts_count * sizeof (struct extmnttab), KM_SLEEP); else metadata_baseaddr = NULL; text_baseaddr = kmem_alloc(size, KM_SLEEP); if (global_view) mntfs_global_generate(showhidden, metadata_baseaddr, text_baseaddr, forread); else mntfs_zone_generate(zone, showhidden, metadata_baseaddr, text_baseaddr, forread); vfs_mnttab_modtime(&snap->mnts_time); vfs_list_unlock(); snap->mnts_text = mntfs_mapin(text_baseaddr, size); snap->mnts_textsize = size; kmem_free(text_baseaddr, size); /* * The pointers in the metadata refer to addreesses in the range * [base_addr, base_addr + size]. Now that we have mapped the text into * the user's address space, we have to convert these addresses into the * new (user) range. We also handle the conversion for 32-bit and * 32-bit applications here. */ if (!forread) { struct extmnttab *tab; #ifdef _SYSCALL32_IMPL struct extmnttab32 *tab32; if (datamodel == DATAMODEL_ILP32) { tab = (struct extmnttab *)metadata_baseaddr; tab32 = (struct extmnttab32 *)metadata_baseaddr; for (i = 0; i < snap->mnts_count; i++) { tab32[i].mnt_special = (uintptr_t)snap->mnts_text + (tab[i].mnt_special - text_baseaddr); tab32[i].mnt_mountp = (uintptr_t)snap->mnts_text + (tab[i].mnt_mountp - text_baseaddr); tab32[i].mnt_fstype = (uintptr_t)snap->mnts_text + (tab[i].mnt_fstype - text_baseaddr); tab32[i].mnt_mntopts = (uintptr_t)snap->mnts_text + (tab[i].mnt_mntopts - text_baseaddr); tab32[i].mnt_time = (uintptr_t)snap->mnts_text + (tab[i].mnt_time - text_baseaddr); tab32[i].mnt_major = tab[i].mnt_major; tab32[i].mnt_minor = tab[i].mnt_minor; } snap->mnts_metasize = snap->mnts_count * sizeof (struct extmnttab32); snap->mnts_metadata = mntfs_mapin( (char *)metadata_baseaddr, snap->mnts_metasize); } else { #endif tab = (struct extmnttab *)metadata_baseaddr; for (i = 0; i < snap->mnts_count; i++) { tab[i].mnt_special = snap->mnts_text + (tab[i].mnt_special - text_baseaddr); tab[i].mnt_mountp = snap->mnts_text + (tab[i].mnt_mountp - text_baseaddr); tab[i].mnt_fstype = snap->mnts_text + (tab[i].mnt_fstype - text_baseaddr); tab[i].mnt_mntopts = snap->mnts_text + (tab[i].mnt_mntopts - text_baseaddr); tab[i].mnt_time = snap->mnts_text + (tab[i].mnt_time - text_baseaddr); } snap->mnts_metasize = snap->mnts_count * sizeof (struct extmnttab); snap->mnts_metadata = mntfs_mapin( (char *)metadata_baseaddr, snap->mnts_metasize); #ifdef _SYSCALL32_IMPL } #endif kmem_free(metadata_baseaddr, snap->mnts_count * sizeof (struct extmnttab)); } mntdata->mnt_size = size; if (snap->mnts_text == NULL || (!forread && snap->mnts_metadata == NULL)) { mntfs_freesnap(snap); return (ENOMEM); } return (0); } /* * Public function to convert vfs_mntopts into a string. * A buffer of sufficient size is allocated, which is returned via bufp, * and whose length is returned via lenp. */ void mntfs_getmntopts(struct vfs *vfsp, char **bufp, size_t *lenp) { size_t len; char *buf; vfs_list_read_lock(); len = mntfs_optsize(vfsp) + 1; buf = kmem_alloc(len, KM_NOSLEEP); if (buf == NULL) { *bufp = NULL; vfs_list_unlock(); return; } buf[len - 1] = '\0'; (void) mntfs_optprint(vfsp, buf); ASSERT(buf[len - 1] == '\0'); vfs_list_unlock(); *bufp = buf; *lenp = len; } /* ARGSUSED */ static int mntopen(vnode_t **vpp, int flag, cred_t *cr) { vnode_t *vp = *vpp; mntnode_t *nmnp; /* * Not allowed to open for writing, return error. */ if (flag & FWRITE) return (EPERM); /* * Create a new mnt/vnode for each open, this will give us a handle to * hang the snapshot on. */ nmnp = mntgetnode(vp); *vpp = MTOV(nmnp); atomic_add_32(&MTOD(nmnp)->mnt_nopen, 1); VN_RELE(vp); return (0); } /* ARGSUSED */ static int mntclose(vnode_t *vp, int flag, int count, offset_t offset, cred_t *cr) { mntnode_t *mnp = VTOM(vp); /* Clean up any locks or shares held by the current process */ cleanlocks(vp, ttoproc(curthread)->p_pid, 0); cleanshares(vp, ttoproc(curthread)->p_pid); if (count > 1) return (0); if (vp->v_count == 1) { mntfs_freesnap(&mnp->mnt_read); mntfs_freesnap(&mnp->mnt_ioctl); atomic_add_32(&MTOD(mnp)->mnt_nopen, -1); } return (0); } /* ARGSUSED */ static int mntread(vnode_t *vp, uio_t *uio, int ioflag, cred_t *cred, caller_context_t *ct) { int error = 0; off_t off = uio->uio_offset; size_t len = uio->uio_resid; mntnode_t *mnp = VTOM(vp); char *buf; mntsnap_t *snap = &mnp->mnt_read; int datamodel; if (off == (off_t)0 || snap->mnts_count == 0) { /* * It is assumed that any kernel callers wishing * to read mnttab will be using extmnttab entries * and not extmnttab32 entries, whether or not * the kernel is LP64 or ILP32. Thus, force the * datamodel that mntfs_snapshot uses to be * DATAMODEL_LP64. */ if (uio->uio_segflg == UIO_SYSSPACE) datamodel = DATAMODEL_LP64; else datamodel = get_udatamodel(); if ((error = mntfs_snapshot(mnp, 1, datamodel)) != 0) return (error); } if ((size_t)(off + len) > snap->mnts_textsize) len = snap->mnts_textsize - off; if (off < 0 || len > snap->mnts_textsize) return (EFAULT); if (len == 0) return (0); /* * The mnttab image is stored in the user's address space, * so we have to copy it into the kernel from userland, * then copy it back out to the specified address. */ buf = kmem_alloc(len, KM_SLEEP); if (copyin(snap->mnts_text + off, buf, len)) error = EFAULT; else { error = uiomove(buf, len, UIO_READ, uio); } kmem_free(buf, len); return (error); } static int mntgetattr(vnode_t *vp, vattr_t *vap, int flags, cred_t *cr) { mntnode_t *mnp = VTOM(vp); int error; vnode_t *rvp; extern timespec_t vfs_mnttab_ctime; mntdata_t *mntdata = MTOD(VTOM(vp)); mntsnap_t *snap = mnp->mnt_read.mnts_count ? &mnp->mnt_read : &mnp->mnt_ioctl; /* * Return all the attributes. Should be refined * so that it returns only those asked for. * Most of this is complete fakery anyway. */ rvp = mnp->mnt_mountvp; /* * Attributes are same as underlying file with modifications */ if (error = VOP_GETATTR(rvp, vap, flags, cr)) return (error); /* * We always look like a regular file */ vap->va_type = VREG; /* * mode should basically be read only */ vap->va_mode &= 07444; vap->va_fsid = vp->v_vfsp->vfs_dev; vap->va_blksize = DEV_BSIZE; vap->va_rdev = 0; vap->va_seq = 0; /* * Set nlink to the number of open vnodes for mnttab info * plus one for existing. */ vap->va_nlink = mntdata->mnt_nopen + 1; /* * If we haven't taken a snapshot yet, set the * size to the size of the latest snapshot. */ vap->va_size = snap->mnts_textsize ? snap->mnts_textsize : mntdata->mnt_size; /* * Fetch mtime from the vfs mnttab timestamp */ vap->va_ctime = vfs_mnttab_ctime; vfs_list_read_lock(); vfs_mnttab_modtime(&vap->va_mtime); vap->va_atime = vap->va_mtime; vfs_list_unlock(); /* * Nodeid is always ROOTINO; */ vap->va_nodeid = (ino64_t)MNTROOTINO; vap->va_nblocks = btod(vap->va_size); return (0); } static int mntaccess(vnode_t *vp, int mode, int flags, cred_t *cr) { mntnode_t *mnp = VTOM(vp); if (mode & (VWRITE|VEXEC)) return (EROFS); /* * Do access check on the underlying directory vnode. */ return (VOP_ACCESS(mnp->mnt_mountvp, mode, flags, cr)); } /* * New /mntfs vnode required; allocate it and fill in most of the fields. */ static mntnode_t * mntgetnode(vnode_t *dp) { mntnode_t *mnp; vnode_t *vp; mnp = kmem_zalloc(sizeof (mntnode_t), KM_SLEEP); mnp->mnt_vnode = vn_alloc(KM_SLEEP); mnp->mnt_mountvp = VTOM(dp)->mnt_mountvp; vp = MTOV(mnp); vp->v_flag = VNOCACHE|VNOMAP|VNOSWAP|VNOMOUNT; vn_setops(vp, mntvnodeops); vp->v_vfsp = dp->v_vfsp; vp->v_type = VREG; vp->v_data = (caddr_t)mnp; return (mnp); } /* * Free the storage obtained from mntgetnode(). */ static void mntfreenode(mntnode_t *mnp) { vnode_t *vp = MTOV(mnp); vn_invalid(vp); vn_free(vp); kmem_free(mnp, sizeof (*mnp)); } /* ARGSUSED */ static int mntfsync(vnode_t *vp, int syncflag, cred_t *cr) { return (0); } /* ARGSUSED */ static void mntinactive(vnode_t *vp, cred_t *cr) { mntnode_t *mnp = VTOM(vp); mntfreenode(mnp); } /* ARGSUSED */ static int mntseek(vnode_t *vp, offset_t ooff, offset_t *noffp) { if (*noffp == 0) VTOM(vp)->mnt_offset = 0; return (0); } /* * Return the answer requested to poll(). * POLLRDBAND will return when the mtime of the mnttab * information is newer than the latest one read for this open. */ /* ARGSUSED */ static int mntpoll(vnode_t *vp, short ev, int any, short *revp, pollhead_t **phpp) { mntnode_t *mnp = VTOM(vp); mntsnap_t *snap = &mnp->mnt_read; if (mnp->mnt_ioctl.mnts_time.tv_sec > snap->mnts_time.tv_sec || (mnp->mnt_ioctl.mnts_time.tv_sec == snap->mnts_time.tv_sec && mnp->mnt_ioctl.mnts_time.tv_nsec > snap->mnts_time.tv_nsec)) snap = &mnp->mnt_ioctl; *revp = 0; *phpp = (pollhead_t *)NULL; if (ev & POLLIN) *revp |= POLLIN; if (ev & POLLRDNORM) *revp |= POLLRDNORM; if (ev & POLLRDBAND) { vfs_mnttab_poll(&snap->mnts_time, phpp); if (*phpp == (pollhead_t *)NULL) *revp |= POLLRDBAND; } if (*revp || *phpp != NULL || any) { return (0); } /* * If someone is polling an unsupported poll events (e.g. * POLLOUT, POLLPRI, etc.), just return POLLERR revents. * That way we will ensure that we don't return a 0 * revents with a NULL pollhead pointer. */ *revp = POLLERR; return (0); } /* ARGSUSED */ static int mntioctl(struct vnode *vp, int cmd, intptr_t arg, int flag, cred_t *cr, int *rvalp) { uint_t *up = (uint_t *)arg; mntnode_t *mnp = VTOM(vp); mntsnap_t *snap = &mnp->mnt_ioctl; int error; error = 0; switch (cmd) { case MNTIOC_NMNTS: { /* get no. of mounted resources */ if (snap->mnts_count == 0) { if ((error = mntfs_snapshot(mnp, 0, flag & DATAMODEL_MASK)) != 0) return (error); } if (suword32(up, snap->mnts_count) != 0) error = EFAULT; break; } case MNTIOC_GETDEVLIST: { /* get mounted device major/minor nos */ uint_t *devlist; int i; size_t len; if (snap->mnts_count == 0) { if ((error = mntfs_snapshot(mnp, 0, flag & DATAMODEL_MASK)) != 0) return (error); } len = 2 * snap->mnts_count * sizeof (uint_t); devlist = kmem_alloc(len, KM_SLEEP); for (i = 0; i < snap->mnts_count; i++) { #ifdef _SYSCALL32_IMPL if ((flag & DATAMODEL_MASK) == DATAMODEL_ILP32) { struct extmnttab32 tab; if ((error = xcopyin(snap->mnts_text + i * sizeof (struct extmnttab32), &tab, sizeof (tab))) != 0) break; devlist[i*2] = tab.mnt_major; devlist[i*2+1] = tab.mnt_minor; } else { #endif struct extmnttab tab; if ((error = xcopyin(snap->mnts_text + i * sizeof (struct extmnttab), &tab, sizeof (tab))) != 0) break; devlist[i*2] = tab.mnt_major; devlist[i*2+1] = tab.mnt_minor; #ifdef _SYSCALL32_IMPL } #endif } if (error == 0) error = xcopyout(devlist, up, len); kmem_free(devlist, len); break; } case MNTIOC_SETTAG: /* set tag on mounted file system */ case MNTIOC_CLRTAG: /* clear tag on mounted file system */ { struct mnttagdesc *dp = (struct mnttagdesc *)arg; STRUCT_DECL(mnttagdesc, tagdesc); char *cptr; uint32_t major, minor; char tagbuf[MAX_MNTOPT_TAG]; char *pbuf; size_t len; uint_t start = 0; mntdata_t *mntdata = MTOD(mnp); zone_t *zone = mntdata->mnt_zone; STRUCT_INIT(tagdesc, flag & DATAMODEL_MASK); if (copyin(dp, STRUCT_BUF(tagdesc), STRUCT_SIZE(tagdesc))) { error = EFAULT; break; } pbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); if (zone != global_zone) { (void) strcpy(pbuf, zone->zone_rootpath); /* truncate "/" and nul */ start = zone->zone_rootpathlen - 2; ASSERT(pbuf[start] == '/'); } cptr = STRUCT_FGETP(tagdesc, mtd_mntpt); error = copyinstr(cptr, pbuf + start, MAXPATHLEN - start, &len); if (error) { kmem_free(pbuf, MAXPATHLEN); break; } if (start != 0 && pbuf[start] != '/') { kmem_free(pbuf, MAXPATHLEN); error = EINVAL; break; } cptr = STRUCT_FGETP(tagdesc, mtd_tag); if ((error = copyinstr(cptr, tagbuf, MAX_MNTOPT_TAG, &len))) { kmem_free(pbuf, MAXPATHLEN); break; } major = STRUCT_FGET(tagdesc, mtd_major); minor = STRUCT_FGET(tagdesc, mtd_minor); if (cmd == MNTIOC_SETTAG) error = vfs_settag(major, minor, pbuf, tagbuf, cr); else error = vfs_clrtag(major, minor, pbuf, tagbuf, cr); kmem_free(pbuf, MAXPATHLEN); break; } case MNTIOC_SHOWHIDDEN: { mutex_enter(&vp->v_lock); mnp->mnt_flags |= MNT_SHOWHIDDEN; mutex_exit(&vp->v_lock); break; } case MNTIOC_GETMNTENT: { size_t idx; uintptr_t addr; idx = mnp->mnt_offset; if (snap->mnts_count == 0 || idx == 0) { if ((error = mntfs_snapshot(mnp, 0, flag & DATAMODEL_MASK)) != 0) return (error); } /* * If the next index is beyond the end of the current mnttab, * return EOF */ if (idx >= snap->mnts_count) { *rvalp = 1; return (0); } #ifdef _SYSCALL32_IMPL if ((flag & DATAMODEL_MASK) == DATAMODEL_ILP32) { addr = (uintptr_t)(snap->mnts_metadata + idx * sizeof (struct extmnttab32)); error = suword32((void *)arg, addr); } else { #endif addr = (uintptr_t)(snap->mnts_metadata + idx * sizeof (struct extmnttab)); error = sulword((void *)arg, addr); #ifdef _SYSCALL32_IMPL } #endif if (error != 0) return (error); mnp->mnt_offset++; break; } default: error = EINVAL; break; } return (error); } /* * /mntfs vnode operations vector */ const fs_operation_def_t mnt_vnodeops_template[] = { VOPNAME_OPEN, mntopen, VOPNAME_CLOSE, mntclose, VOPNAME_READ, mntread, VOPNAME_IOCTL, mntioctl, VOPNAME_GETATTR, mntgetattr, VOPNAME_ACCESS, mntaccess, VOPNAME_FSYNC, mntfsync, VOPNAME_INACTIVE, (fs_generic_func_p) mntinactive, VOPNAME_SEEK, mntseek, VOPNAME_POLL, (fs_generic_func_p) mntpoll, VOPNAME_DISPOSE, fs_error, VOPNAME_SHRLOCK, fs_error, NULL, NULL };