/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (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 (c) 2006, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * Copyright 2012 Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2012, 2014 by Delphix. All rights reserved. */ #include #include #include #include #include #include #include "libshare_impl.h" #include #include #include extern sa_share_t _sa_add_share(sa_group_t, char *, int, int *, uint64_t); extern sa_group_t _sa_create_zfs_group(sa_group_t, char *); extern char *sa_fstype(char *); extern void set_node_attr(void *, char *, char *); extern int sa_is_share(void *); extern void sa_update_sharetab_ts(sa_handle_t); /* * File system specific code for ZFS. The original code was stolen * from the "zfs" command and modified to better suit this library's * usage. */ typedef struct get_all_cbdata { zfs_handle_t **cb_handles; size_t cb_alloc; size_t cb_used; uint_t cb_types; } get_all_cbdata_t; /* * sa_zfs_init(impl_handle) * * Initialize an access handle into libzfs. The handle needs to stay * around until sa_zfs_fini() in order to maintain the cache of * mounts. */ int sa_zfs_init(sa_handle_impl_t impl_handle) { impl_handle->zfs_libhandle = libzfs_init(); if (impl_handle->zfs_libhandle != NULL) { libzfs_print_on_error(impl_handle->zfs_libhandle, B_TRUE); return (B_TRUE); } return (B_FALSE); } /* * sa_zfs_fini(impl_handle) * * cleanup data structures and the libzfs handle used for accessing * zfs file share info. */ void sa_zfs_fini(sa_handle_impl_t impl_handle) { if (impl_handle->zfs_libhandle != NULL) { if (impl_handle->zfs_list != NULL) { zfs_handle_t **zhp = impl_handle->zfs_list; size_t i; /* * Contents of zfs_list need to be freed so we * don't lose ZFS handles. */ for (i = 0; i < impl_handle->zfs_list_count; i++) { zfs_close(zhp[i]); } free(impl_handle->zfs_list); impl_handle->zfs_list = NULL; impl_handle->zfs_list_count = 0; } libzfs_fini(impl_handle->zfs_libhandle); impl_handle->zfs_libhandle = NULL; } } /* * get_one_filesystem(zfs_handle_t, data) * * an iterator function called while iterating through the ZFS * root. It accumulates into an array of file system handles that can * be used to derive info about those file systems. * * Note that as this function is called, we close all zhp handles that * are not going to be places into the cp_handles list. We don't want * to close the ones we are keeping, but all others would be leaked if * not closed here. */ static int get_one_filesystem(zfs_handle_t *zhp, void *data) { get_all_cbdata_t *cbp = data; zfs_type_t type = zfs_get_type(zhp); /* * Interate over any nested datasets. */ if (type == ZFS_TYPE_FILESYSTEM && zfs_iter_filesystems(zhp, get_one_filesystem, data) != 0) { zfs_close(zhp); return (1); } /* * Skip any datasets whose type does not match. */ if ((type & cbp->cb_types) == 0) { zfs_close(zhp); return (0); } if (cbp->cb_alloc == cbp->cb_used) { zfs_handle_t **handles; if (cbp->cb_alloc == 0) cbp->cb_alloc = 64; else cbp->cb_alloc *= 2; handles = (zfs_handle_t **)calloc(1, cbp->cb_alloc * sizeof (void *)); if (handles == NULL) { zfs_close(zhp); return (0); } if (cbp->cb_handles) { bcopy(cbp->cb_handles, handles, cbp->cb_used * sizeof (void *)); free(cbp->cb_handles); } cbp->cb_handles = handles; } cbp->cb_handles[cbp->cb_used++] = zhp; return (0); } /* * get_all_filesystems(zfs_handle_t ***fslist, size_t *count) * * iterate through all ZFS file systems starting at the root. Returns * a count and an array of handle pointers. Allocating is only done * once. The caller does not need to free since it will be done at * sa_zfs_fini() time. */ static void get_all_filesystems(sa_handle_impl_t impl_handle, zfs_handle_t ***fslist, size_t *count) { get_all_cbdata_t cb = { 0 }; cb.cb_types = ZFS_TYPE_FILESYSTEM; if (impl_handle->zfs_list != NULL) { *fslist = impl_handle->zfs_list; *count = impl_handle->zfs_list_count; return; } (void) zfs_iter_root(impl_handle->zfs_libhandle, get_one_filesystem, &cb); impl_handle->zfs_list = *fslist = cb.cb_handles; impl_handle->zfs_list_count = *count = cb.cb_used; } /* * mountpoint_compare(a, b) * * compares the mountpoint on two zfs file systems handles. * returns values following strcmp() model. */ static int mountpoint_compare(const void *a, const void *b) { zfs_handle_t **za = (zfs_handle_t **)a; zfs_handle_t **zb = (zfs_handle_t **)b; char mounta[MAXPATHLEN]; char mountb[MAXPATHLEN]; verify(zfs_prop_get(*za, ZFS_PROP_MOUNTPOINT, mounta, sizeof (mounta), NULL, NULL, 0, B_FALSE) == 0); verify(zfs_prop_get(*zb, ZFS_PROP_MOUNTPOINT, mountb, sizeof (mountb), NULL, NULL, 0, B_FALSE) == 0); return (strcmp(mounta, mountb)); } /* * return legacy mountpoint. Caller provides space for mountpoint and * dataset. */ int get_legacy_mountpoint(char *path, char *dataset, size_t dlen, char *mountpoint, size_t mlen) { FILE *fp; struct mnttab entry; if ((fp = fopen(MNTTAB, "r")) == NULL) { return (1); } while (getmntent(fp, &entry) == 0) { if (entry.mnt_fstype == NULL || strcmp(entry.mnt_fstype, MNTTYPE_ZFS) != 0) continue; if (strcmp(entry.mnt_mountp, path) == 0) { if (mlen > 0) (void) strlcpy(mountpoint, entry.mnt_mountp, mlen); if (dlen > 0) (void) strlcpy(dataset, entry.mnt_special, dlen); break; } } (void) fclose(fp); return (1); } /* * get_zfs_dataset(impl_handle, path) * * get the name of the ZFS dataset the path is equivalent to. The * dataset name is used for get/set of ZFS properties since libzfs * requires a dataset to do a zfs_open(). */ static char * get_zfs_dataset(sa_handle_impl_t impl_handle, char *path, boolean_t search_mnttab) { size_t i, count = 0; char *dataset = NULL; zfs_handle_t **zlist; char mountpoint[ZFS_MAXPROPLEN]; char canmount[ZFS_MAXPROPLEN]; get_all_filesystems(impl_handle, &zlist, &count); for (i = 0; i < count; i++) { /* must have a mountpoint */ if (zfs_prop_get(zlist[i], ZFS_PROP_MOUNTPOINT, mountpoint, sizeof (mountpoint), NULL, NULL, 0, B_FALSE) != 0) { /* no mountpoint */ continue; } /* mountpoint must be a path */ if (strcmp(mountpoint, ZFS_MOUNTPOINT_NONE) == 0 || strcmp(mountpoint, ZFS_MOUNTPOINT_LEGACY) == 0) { /* * Search mmttab for mountpoint and get dataset. */ if (search_mnttab == B_TRUE && get_legacy_mountpoint(path, mountpoint, sizeof (mountpoint), NULL, 0) == 0) { dataset = mountpoint; break; } continue; } /* canmount must be set */ canmount[0] = '\0'; if (zfs_prop_get(zlist[i], ZFS_PROP_CANMOUNT, canmount, sizeof (canmount), NULL, NULL, 0, B_FALSE) != 0 || strcmp(canmount, "off") == 0) continue; /* * have a mountable handle but want to skip those marked none * and legacy */ if (strcmp(mountpoint, path) == 0) { dataset = (char *)zfs_get_name(zlist[i]); break; } } if (dataset != NULL) dataset = strdup(dataset); return (dataset); } /* * get_zfs_property(dataset, property) * * Get the file system property specified from the ZFS dataset. */ static char * get_zfs_property(char *dataset, zfs_prop_t property) { zfs_handle_t *handle = NULL; char shareopts[ZFS_MAXPROPLEN]; libzfs_handle_t *libhandle; libhandle = libzfs_init(); if (libhandle != NULL) { handle = zfs_open(libhandle, dataset, ZFS_TYPE_FILESYSTEM); if (handle != NULL) { if (zfs_prop_get(handle, property, shareopts, sizeof (shareopts), NULL, NULL, 0, B_FALSE) == 0) { zfs_close(handle); libzfs_fini(libhandle); return (strdup(shareopts)); } zfs_close(handle); } libzfs_fini(libhandle); } return (NULL); } /* * sa_zfs_is_shared(handle, path) * * Check to see if the ZFS path provided has the sharenfs option set * or not. */ int sa_zfs_is_shared(sa_handle_t sahandle, char *path) { int ret = 0; char *dataset; zfs_handle_t *handle = NULL; char shareopts[ZFS_MAXPROPLEN]; libzfs_handle_t *libhandle; dataset = get_zfs_dataset((sa_handle_t)sahandle, path, B_FALSE); if (dataset != NULL) { libhandle = libzfs_init(); if (libhandle != NULL) { handle = zfs_open(libhandle, dataset, ZFS_TYPE_FILESYSTEM); if (handle != NULL) { if (zfs_prop_get(handle, ZFS_PROP_SHARENFS, shareopts, sizeof (shareopts), NULL, NULL, 0, B_FALSE) == 0 && strcmp(shareopts, "off") != 0) { ret = 1; /* it is shared */ } zfs_close(handle); } libzfs_fini(libhandle); } free(dataset); } return (ret); } /* * find_or_create_group(handle, groupname, proto, *err) * * While walking the ZFS tree, we need to add shares to a defined * group. If the group doesn't exist, create it first, making sure it * is marked as a ZFS group. * * Note that all ZFS shares are in a subgroup of the top level group * called "zfs". */ static sa_group_t find_or_create_group(sa_handle_t handle, char *groupname, char *proto, int *err) { sa_group_t group; sa_optionset_t optionset; int ret = SA_OK; /* * we check to see if the "zfs" group exists. Since this * should be the top level group, we don't want the * parent. This is to make sure the zfs group has been created * and to created if it hasn't been. */ group = sa_get_group(handle, groupname); if (group == NULL) { group = sa_create_group(handle, groupname, &ret); /* make sure this is flagged as a ZFS group */ if (group != NULL) ret = sa_set_group_attr(group, "zfs", "true"); } if (group != NULL) { if (proto != NULL) { optionset = sa_get_optionset(group, proto); if (optionset == NULL) optionset = sa_create_optionset(group, proto); } } if (err != NULL) *err = ret; return (group); } /* * find_or_create_zfs_subgroup(groupname, optstring, *err) * * ZFS shares will be in a subgroup of the "zfs" master group. This * function looks to see if the groupname exists and returns it if it * does or else creates a new one with the specified name and returns * that. The "zfs" group will exist before we get here, but we make * sure just in case. * * err must be a valid pointer. */ static sa_group_t find_or_create_zfs_subgroup(sa_handle_t handle, char *groupname, char *proto, char *optstring, int *err) { sa_group_t group = NULL; sa_group_t zfs; char *name; char *options; /* start with the top-level "zfs" group */ zfs = sa_get_group(handle, "zfs"); *err = SA_OK; if (zfs != NULL) { for (group = sa_get_sub_group(zfs); group != NULL; group = sa_get_next_group(group)) { name = sa_get_group_attr(group, "name"); if (name != NULL && strcmp(name, groupname) == 0) { /* have the group so break out of here */ sa_free_attr_string(name); break; } if (name != NULL) sa_free_attr_string(name); } if (group == NULL) { /* * Need to create the sub-group since it doesn't exist */ group = _sa_create_zfs_group(zfs, groupname); if (group == NULL) { *err = SA_NO_MEMORY; return (NULL); } set_node_attr(group, "zfs", "true"); } if (strcmp(optstring, "on") == 0) optstring = "rw"; options = strdup(optstring); if (options != NULL) { *err = sa_parse_legacy_options(group, options, proto); /* If no optionset, add one. */ if (sa_get_optionset(group, proto) == NULL) (void) sa_create_optionset(group, proto); /* * Do not forget to update an optionset of * the parent group so that it contains * all protocols its subgroups have. */ if (sa_get_optionset(zfs, proto) == NULL) (void) sa_create_optionset(zfs, proto); free(options); } else { *err = SA_NO_MEMORY; } } return (group); } /* * zfs_construct_resource(share, name, base, dataset) * * Add a resource to the share using name as a template. If name == * NULL, then construct a name based on the dataset value. * name. */ static void zfs_construct_resource(sa_share_t share, char *dataset) { char buff[SA_MAX_RESOURCE_NAME + 1]; int ret = SA_OK; (void) snprintf(buff, SA_MAX_RESOURCE_NAME, "%s", dataset); sa_fix_resource_name(buff); (void) sa_add_resource(share, buff, SA_SHARE_TRANSIENT, &ret); } /* * zfs_inherited(handle, source, sourcestr) * * handle case of inherited share{nfs,smb}. Pulled out of sa_get_zfs_shares * for readability. */ static int zfs_inherited(sa_handle_t handle, sa_share_t share, char *sourcestr, char *shareopts, char *mountpoint, char *proto, char *dataset) { int doshopt = 0; int err = SA_OK; sa_group_t group; sa_resource_t resource; uint64_t features; /* * Need to find the "real" parent sub-group. It may not be * mounted, but it was identified in the "sourcestr" * variable. The real parent not mounted can occur if * "canmount=off and sharenfs=on". */ group = find_or_create_zfs_subgroup(handle, sourcestr, proto, shareopts, &doshopt); if (group != NULL) { /* * We may need the first share for resource * prototype. We only care about it if it has a * resource that sets a prefix value. */ if (share == NULL) share = _sa_add_share(group, mountpoint, SA_SHARE_TRANSIENT, &err, (uint64_t)SA_FEATURE_NONE); /* * some options may only be on shares. If the opt * string contains one of those, we put it just on the * share. */ if (share != NULL && doshopt == SA_PROP_SHARE_ONLY) { char *options; options = strdup(shareopts); if (options != NULL) { set_node_attr(share, "dataset", dataset); err = sa_parse_legacy_options(share, options, proto); set_node_attr(share, "dataset", NULL); free(options); } if (sa_get_optionset(group, proto) == NULL) (void) sa_create_optionset(group, proto); } features = sa_proto_get_featureset(proto); if (share != NULL && features & SA_FEATURE_RESOURCE) { /* * We have a share and the protocol requires * that at least one resource exist (probably * SMB). We need to make sure that there is at * least one. */ resource = sa_get_share_resource(share, NULL); if (resource == NULL) { zfs_construct_resource(share, dataset); } } } else { err = SA_NO_MEMORY; } return (err); } /* * zfs_notinherited(group, share, mountpoint, shareopts, proto, dataset, * grouperr) * * handle case where this is the top of a sub-group in ZFS. Pulled out * of sa_get_zfs_shares for readability. We need the grouperr from the * creation of the subgroup to know whether to add the public * property, etc. to the specific share. */ static int zfs_notinherited(sa_group_t group, sa_share_t share, char *mountpoint, char *shareopts, char *proto, char *dataset, int grouperr) { int err = SA_OK; sa_resource_t resource; uint64_t features; set_node_attr(group, "zfs", "true"); if (share == NULL) share = _sa_add_share(group, mountpoint, SA_SHARE_TRANSIENT, &err, (uint64_t)SA_FEATURE_NONE); if (err != SA_OK) return (err); if (strcmp(shareopts, "on") == 0) shareopts = ""; if (shareopts != NULL) { char *options; if (grouperr == SA_PROP_SHARE_ONLY) { /* * Some properties may only be on shares, but * due to the ZFS sub-groups being artificial, * we sometimes get this and have to deal with * it. We do it by attempting to put it on the * share. */ options = strdup(shareopts); if (options != NULL) { err = sa_parse_legacy_options(share, options, proto); free(options); } } /* Unmark the share's changed state */ set_node_attr(share, "changed", NULL); } features = sa_proto_get_featureset(proto); if (share != NULL && features & SA_FEATURE_RESOURCE) { /* * We have a share and the protocol requires that at * least one resource exist (probably SMB). We need to * make sure that there is at least one. */ resource = sa_get_share_resource(share, NULL); if (resource == NULL) { zfs_construct_resource(share, dataset); } } return (err); } /* * zfs_grp_error(err) * * Print group create error, but only once. If err is 0 do the * print else don't. */ static void zfs_grp_error(int err) { if (err == 0) { /* only print error once */ (void) fprintf(stderr, dgettext(TEXT_DOMAIN, "Cannot create ZFS subgroup during initialization:" " %s\n"), sa_errorstr(SA_SYSTEM_ERR)); } } /* * zfs_process_share(handle, share, mountpoint, proto, source, * shareopts, sourcestr) * * Creates the subgroup, if necessary and adds shares, resources * and properties. */ int sa_zfs_process_share(sa_handle_t handle, sa_group_t group, sa_share_t share, char *mountpoint, char *proto, zprop_source_t source, char *shareopts, char *sourcestr, char *dataset) { int err = SA_OK; if (source & ZPROP_SRC_INHERITED) { err = zfs_inherited(handle, share, sourcestr, shareopts, mountpoint, proto, dataset); } else { group = find_or_create_zfs_subgroup(handle, dataset, proto, shareopts, &err); if (group == NULL) { static boolean_t reported_error = B_FALSE; /* * There is a problem, but we can't do * anything about it at this point so we issue * a warning and move on. */ zfs_grp_error(reported_error); reported_error = B_TRUE; } set_node_attr(group, "zfs", "true"); /* * Add share with local opts via zfs_notinherited. */ err = zfs_notinherited(group, share, mountpoint, shareopts, proto, dataset, err); } return (err); } /* * sa_get_zfs_shares(handle, groupname) * * Walk the mnttab for all zfs mounts and determine which are * shared. Find or create the appropriate group/sub-group to contain * the shares. * * All shares are in a sub-group that will hold the properties. This * allows representing the inherited property model. * * One area of complication is if "sharenfs" is set at one level of * the directory tree and "sharesmb" is set at a different level, the * a sub-group must be formed at the lower level for both * protocols. That is the nature of the problem in CR 6667349. */ int sa_get_zfs_shares(sa_handle_t handle, char *groupname) { sa_group_t zfsgroup; boolean_t nfs; boolean_t nfs_inherited; boolean_t smb; boolean_t smb_inherited; zfs_handle_t **zlist; char nfsshareopts[ZFS_MAXPROPLEN]; char smbshareopts[ZFS_MAXPROPLEN]; sa_share_t share; zprop_source_t source; char nfssourcestr[ZFS_MAXPROPLEN]; char smbsourcestr[ZFS_MAXPROPLEN]; char mountpoint[ZFS_MAXPROPLEN]; size_t count = 0, i; libzfs_handle_t *zfs_libhandle; int err = SA_OK; /* * If we can't access libzfs, don't bother doing anything. */ zfs_libhandle = ((sa_handle_impl_t)handle)->zfs_libhandle; if (zfs_libhandle == NULL) return (SA_SYSTEM_ERR); zfsgroup = find_or_create_group(handle, groupname, NULL, &err); /* Not an error, this could be a legacy condition */ if (zfsgroup == NULL) return (SA_OK); /* * need to walk the mounted ZFS pools and datasets to * find shares that are possible. */ get_all_filesystems((sa_handle_impl_t)handle, &zlist, &count); qsort(zlist, count, sizeof (void *), mountpoint_compare); for (i = 0; i < count; i++) { char *dataset; source = ZPROP_SRC_ALL; /* If no mountpoint, skip. */ if (zfs_prop_get(zlist[i], ZFS_PROP_MOUNTPOINT, mountpoint, sizeof (mountpoint), NULL, NULL, 0, B_FALSE) != 0) continue; /* * zfs_get_name value must not be freed. It is just a * pointer to a value in the handle. */ if ((dataset = (char *)zfs_get_name(zlist[i])) == NULL) continue; /* * only deal with "mounted" file systems since * unmounted file systems can't actually be shared. */ if (!zfs_is_mounted(zlist[i], NULL)) continue; nfs = nfs_inherited = B_FALSE; if (zfs_prop_get(zlist[i], ZFS_PROP_SHARENFS, nfsshareopts, sizeof (nfsshareopts), &source, nfssourcestr, ZFS_MAXPROPLEN, B_FALSE) == 0 && strcmp(nfsshareopts, "off") != 0) { if (source & ZPROP_SRC_INHERITED) nfs_inherited = B_TRUE; else nfs = B_TRUE; } smb = smb_inherited = B_FALSE; if (zfs_prop_get(zlist[i], ZFS_PROP_SHARESMB, smbshareopts, sizeof (smbshareopts), &source, smbsourcestr, ZFS_MAXPROPLEN, B_FALSE) == 0 && strcmp(smbshareopts, "off") != 0) { if (source & ZPROP_SRC_INHERITED) smb_inherited = B_TRUE; else smb = B_TRUE; } /* * If the mountpoint is already shared, it must be a * non-ZFS share. We want to remove the share from its * parent group and reshare it under ZFS. */ share = sa_find_share(handle, mountpoint); if (share != NULL && (nfs || smb || nfs_inherited || smb_inherited)) { err = sa_remove_share(share); share = NULL; } /* * At this point, we have the information needed to * determine what to do with the share. * * If smb or nfs is set, we have a new sub-group. * If smb_inherit and/or nfs_inherit is set, then * place on an existing sub-group. If both are set, * the existing sub-group is the closest up the tree. */ if (nfs || smb) { /* * Non-inherited is the straightforward * case. sa_zfs_process_share handles it * directly. Make sure that if the "other" * protocol is inherited, that we treat it as * non-inherited as well. */ if (nfs || nfs_inherited) { err = sa_zfs_process_share(handle, zfsgroup, share, mountpoint, "nfs", 0, nfsshareopts, nfssourcestr, dataset); share = sa_find_share(handle, mountpoint); } if (smb || smb_inherited) { err = sa_zfs_process_share(handle, zfsgroup, share, mountpoint, "smb", 0, smbshareopts, smbsourcestr, dataset); } } else if (nfs_inherited || smb_inherited) { char *grpdataset; /* * If we only have inherited groups, it is * important to find the closer of the two if * the protocols are set at different * levels. The closest sub-group is the one we * want to work with. */ if (nfs_inherited && smb_inherited) { if (strcmp(nfssourcestr, smbsourcestr) <= 0) grpdataset = nfssourcestr; else grpdataset = smbsourcestr; } else if (nfs_inherited) { grpdataset = nfssourcestr; } else if (smb_inherited) { grpdataset = smbsourcestr; } if (nfs_inherited) { err = sa_zfs_process_share(handle, zfsgroup, share, mountpoint, "nfs", ZPROP_SRC_INHERITED, nfsshareopts, grpdataset, dataset); share = sa_find_share(handle, mountpoint); } if (smb_inherited) { err = sa_zfs_process_share(handle, zfsgroup, share, mountpoint, "smb", ZPROP_SRC_INHERITED, smbshareopts, grpdataset, dataset); } } } /* * Don't need to free the "zlist" variable since it is only a * pointer to a cached value that will be freed when * sa_fini() is called. */ return (err); } #define COMMAND "/usr/sbin/zfs" /* * sa_zfs_set_sharenfs(group, path, on) * * Update the "sharenfs" property on the path. If on is true, then set * to the properties on the group or "on" if no properties are * defined. Set to "off" if on is false. */ int sa_zfs_set_sharenfs(sa_group_t group, char *path, int on) { int ret = SA_NOT_IMPLEMENTED; char *command; command = malloc(ZFS_MAXPROPLEN * 2); if (command != NULL) { char *opts = NULL; char *dataset = NULL; FILE *pfile; sa_handle_impl_t impl_handle; /* for now, NFS is always available for "zfs" */ if (on) { opts = sa_proto_legacy_format("nfs", group, 1); if (opts != NULL && strlen(opts) == 0) { free(opts); opts = strdup("on"); } } impl_handle = (sa_handle_impl_t)sa_find_group_handle(group); assert(impl_handle != NULL); if (impl_handle != NULL) dataset = get_zfs_dataset(impl_handle, path, B_FALSE); else ret = SA_SYSTEM_ERR; if (dataset != NULL) { (void) snprintf(command, ZFS_MAXPROPLEN * 2, "%s set sharenfs=\"%s\" %s", COMMAND, opts != NULL ? opts : "off", dataset); pfile = popen(command, "r"); if (pfile != NULL) { ret = pclose(pfile); if (ret != 0) ret = SA_SYSTEM_ERR; } } if (opts != NULL) free(opts); if (dataset != NULL) free(dataset); free(command); } return (ret); } /* * add_resources(share, opt) * * Add resource properties to those in "opt". Resources are prefixed * with name=resourcename. */ static char * add_resources(sa_share_t share, char *opt) { char *newopt = NULL; char *propstr; sa_resource_t resource; newopt = strdup(opt); if (newopt == NULL) return (newopt); for (resource = sa_get_share_resource(share, NULL); resource != NULL; resource = sa_get_next_resource(resource)) { char *name; size_t size; name = sa_get_resource_attr(resource, "name"); if (name == NULL) { free(newopt); return (NULL); } size = strlen(name) + strlen(opt) + sizeof ("name=") + 1; newopt = calloc(1, size); if (newopt != NULL) (void) snprintf(newopt, size, "%s,name=%s", opt, name); sa_free_attr_string(name); free(opt); opt = newopt; propstr = sa_proto_legacy_format("smb", resource, 0); if (propstr == NULL) { free(opt); return (NULL); } size = strlen(propstr) + strlen(opt) + 2; newopt = calloc(1, size); if (newopt != NULL) (void) snprintf(newopt, size, "%s,%s", opt, propstr); free(opt); opt = newopt; } return (opt); } /* * sa_zfs_set_sharesmb(group, path, on) * * Update the "sharesmb" property on the path. If on is true, then set * to the properties on the group or "on" if no properties are * defined. Set to "off" if on is false. */ int sa_zfs_set_sharesmb(sa_group_t group, char *path, int on) { int ret = SA_NOT_IMPLEMENTED; char *command; sa_share_t share; /* In case SMB not enabled */ if (sa_get_optionset(group, "smb") == NULL) return (SA_NOT_SUPPORTED); command = malloc(ZFS_MAXPROPLEN * 2); if (command != NULL) { char *opts = NULL; char *dataset = NULL; FILE *pfile; sa_handle_impl_t impl_handle; if (on) { char *newopt; share = sa_get_share(group, NULL); opts = sa_proto_legacy_format("smb", share, 1); if (opts != NULL && strlen(opts) == 0) { free(opts); opts = strdup("on"); } newopt = add_resources(opts, share); free(opts); opts = newopt; } impl_handle = (sa_handle_impl_t)sa_find_group_handle(group); assert(impl_handle != NULL); if (impl_handle != NULL) dataset = get_zfs_dataset(impl_handle, path, B_FALSE); else ret = SA_SYSTEM_ERR; if (dataset != NULL) { (void) snprintf(command, ZFS_MAXPROPLEN * 2, "echo %s set sharesmb=\"%s\" %s", COMMAND, opts != NULL ? opts : "off", dataset); pfile = popen(command, "r"); if (pfile != NULL) { ret = pclose(pfile); if (ret != 0) ret = SA_SYSTEM_ERR; } } if (opts != NULL) free(opts); if (dataset != NULL) free(dataset); free(command); } return (ret); } /* * sa_zfs_update(group) * * call back to ZFS to update the share if necessary. * Don't do it if it isn't a real change. */ int sa_zfs_update(sa_group_t group) { sa_optionset_t protopt; sa_group_t parent; char *command; char *optstring; int ret = SA_OK; int doupdate = 0; FILE *pfile; if (sa_is_share(group)) parent = sa_get_parent_group(group); else parent = group; if (parent != NULL) { command = malloc(ZFS_MAXPROPLEN * 2); if (command == NULL) return (SA_NO_MEMORY); *command = '\0'; for (protopt = sa_get_optionset(parent, NULL); protopt != NULL; protopt = sa_get_next_optionset(protopt)) { char *proto = sa_get_optionset_attr(protopt, "type"); char *path; char *dataset = NULL; char *zfsopts = NULL; if (sa_is_share(group)) { path = sa_get_share_attr((sa_share_t)group, "path"); if (path != NULL) { sa_handle_impl_t impl_handle; impl_handle = sa_find_group_handle( group); if (impl_handle != NULL) dataset = get_zfs_dataset( impl_handle, path, B_FALSE); else ret = SA_SYSTEM_ERR; sa_free_attr_string(path); } } else { dataset = sa_get_group_attr(group, "name"); } /* update only when there is an optstring found */ doupdate = 0; if (proto != NULL && dataset != NULL) { optstring = sa_proto_legacy_format(proto, group, 1); zfsopts = get_zfs_property(dataset, ZFS_PROP_SHARENFS); if (optstring != NULL && zfsopts != NULL) { if (strcmp(optstring, zfsopts) != 0) doupdate++; } if (doupdate) { if (optstring != NULL && strlen(optstring) > 0) { (void) snprintf(command, ZFS_MAXPROPLEN * 2, "%s set share%s=%s %s", COMMAND, proto, optstring, dataset); } else { (void) snprintf(command, ZFS_MAXPROPLEN * 2, "%s set share%s=on %s", COMMAND, proto, dataset); } pfile = popen(command, "r"); if (pfile != NULL) ret = pclose(pfile); switch (ret) { default: case 1: ret = SA_SYSTEM_ERR; break; case 2: ret = SA_SYNTAX_ERR; break; case 0: break; } } if (optstring != NULL) free(optstring); if (zfsopts != NULL) free(zfsopts); } if (proto != NULL) sa_free_attr_string(proto); if (dataset != NULL) free(dataset); } free(command); } return (ret); } /* * sa_group_is_zfs(group) * * Given the group, determine if the zfs attribute is set. */ int sa_group_is_zfs(sa_group_t group) { char *zfs; int ret = 0; zfs = sa_get_group_attr(group, "zfs"); if (zfs != NULL) { ret = 1; sa_free_attr_string(zfs); } return (ret); } /* * sa_path_is_zfs(path) * * Check to see if the file system path represents is of type "zfs". */ int sa_path_is_zfs(char *path) { char *fstype; int ret = 0; fstype = sa_fstype(path); if (fstype != NULL && strcmp(fstype, "zfs") == 0) ret = 1; if (fstype != NULL) sa_free_fstype(fstype); return (ret); } int sa_sharetab_fill_zfs(sa_share_t share, share_t *sh, char *proto) { char *path; /* Make sure path is valid */ path = sa_get_share_attr(share, "path"); if (path != NULL) { (void) memset(sh, 0, sizeof (sh)); (void) sa_fillshare(share, proto, sh); sa_free_attr_string(path); return (0); } else return (1); } #define SMAX(i, j) \ if ((j) > (i)) { \ (i) = (j); \ } int sa_share_zfs(sa_share_t share, sa_resource_t resource, char *path, share_t *sh, void *exportdata, zfs_share_op_t operation) { libzfs_handle_t *libhandle; sa_group_t group; sa_handle_t sahandle; char *dataset; int err = EINVAL; int i, j; char newpath[MAXPATHLEN]; char *pathp; /* * First find the dataset name */ if ((group = sa_get_parent_group(share)) == NULL) { return (EINVAL); } if ((sahandle = sa_find_group_handle(group)) == NULL) { return (EINVAL); } /* * If get_zfs_dataset fails, see if it is a subdirectory */ pathp = path; while ((dataset = get_zfs_dataset(sahandle, pathp, B_TRUE)) == NULL) { char *p; if (pathp == path) { (void) strlcpy(newpath, path, sizeof (newpath)); pathp = newpath; } /* * Make sure only one leading '/' This condition came * about when using HAStoragePlus which insisted on * putting an extra leading '/' in the ZFS path * name. The problem is fixed in other areas, but this * will catch any other ways that a double slash might * get introduced. */ while (*pathp == '/' && *(pathp + 1) == '/') pathp++; /* * chop off part of path, but if we are at root then * make sure path is a / */ if ((strlen(pathp) > 1) && (p = strrchr(pathp, '/'))) { if (pathp == p) { *(p + 1) = '\0'; /* skip over /, root case */ } else { *p = '\0'; } } else { return (EINVAL); } } libhandle = libzfs_init(); if (libhandle != NULL) { char *resource_name; i = (sh->sh_path ? strlen(sh->sh_path) : 0); sh->sh_size = i; j = (sh->sh_res ? strlen(sh->sh_res) : 0); sh->sh_size += j; SMAX(i, j); j = (sh->sh_fstype ? strlen(sh->sh_fstype) : 0); sh->sh_size += j; SMAX(i, j); j = (sh->sh_opts ? strlen(sh->sh_opts) : 0); sh->sh_size += j; SMAX(i, j); j = (sh->sh_descr ? strlen(sh->sh_descr) : 0); sh->sh_size += j; SMAX(i, j); resource_name = sa_get_resource_attr(resource, "name"); err = zfs_deleg_share_nfs(libhandle, dataset, path, resource_name, exportdata, sh, i, operation); if (err == SA_OK) sa_update_sharetab_ts(sahandle); else err = errno; if (resource_name) sa_free_attr_string(resource_name); libzfs_fini(libhandle); } free(dataset); return (err); } /* * sa_get_zfs_handle(handle) * * Given an sa_handle_t, return the libzfs_handle_t *. This is only * used internally by libzfs. Needed in order to avoid including * libshare_impl.h in libzfs. */ libzfs_handle_t * sa_get_zfs_handle(sa_handle_t handle) { sa_handle_impl_t implhandle = (sa_handle_impl_t)handle; return (implhandle->zfs_libhandle); } /* * sa_get_zfs_info(libzfs, path, mountpoint, dataset) * * Find the ZFS dataset and mountpoint for a given path */ int sa_zfs_get_info(libzfs_handle_t *libzfs, char *path, char *mountpointp, char *datasetp) { get_all_cbdata_t cb = { 0 }; int i; char mountpoint[ZFS_MAXPROPLEN]; char dataset[ZFS_MAXPROPLEN]; char canmount[ZFS_MAXPROPLEN]; char *dp; int count; int ret = 0; cb.cb_types = ZFS_TYPE_FILESYSTEM; if (libzfs == NULL) return (0); (void) zfs_iter_root(libzfs, get_one_filesystem, &cb); count = cb.cb_used; qsort(cb.cb_handles, count, sizeof (void *), mountpoint_compare); for (i = 0; i < count; i++) { /* must have a mountpoint */ if (zfs_prop_get(cb.cb_handles[i], ZFS_PROP_MOUNTPOINT, mountpoint, sizeof (mountpoint), NULL, NULL, 0, B_FALSE) != 0) { /* no mountpoint */ continue; } /* mountpoint must be a path */ if (strcmp(mountpoint, ZFS_MOUNTPOINT_NONE) == 0 || strcmp(mountpoint, ZFS_MOUNTPOINT_LEGACY) == 0) { /* * Search mmttab for mountpoint */ if (get_legacy_mountpoint(path, dataset, ZFS_MAXPROPLEN, mountpoint, ZFS_MAXPROPLEN) == 0) { ret = 1; break; } continue; } /* canmount must be set */ canmount[0] = '\0'; if (zfs_prop_get(cb.cb_handles[i], ZFS_PROP_CANMOUNT, canmount, sizeof (canmount), NULL, NULL, 0, B_FALSE) != 0 || strcmp(canmount, "off") == 0) continue; /* * have a mountable handle but want to skip those marked none * and legacy */ if (strcmp(mountpoint, path) == 0) { dp = (char *)zfs_get_name(cb.cb_handles[i]); if (dp != NULL) { if (datasetp != NULL) (void) strcpy(datasetp, dp); if (mountpointp != NULL) (void) strcpy(mountpointp, mountpoint); ret = 1; } break; } } return (ret); } /* * This method builds values for "sharesmb" property from the * nvlist argument. The values are returned in sharesmb_val variable. */ static int sa_zfs_sprintf_new_prop(nvlist_t *nvl, char *sharesmb_val) { char cur_val[MAXPATHLEN]; char *name, *val; nvpair_t *cur; int err = 0; cur = nvlist_next_nvpair(nvl, NULL); while (cur != NULL) { name = nvpair_name(cur); err = nvpair_value_string(cur, &val); if ((err != 0) || (name == NULL) || (val == NULL)) return (-1); (void) snprintf(cur_val, MAXPATHLEN, "%s=%s,", name, val); (void) strlcat(sharesmb_val, cur_val, MAXPATHLEN); cur = nvlist_next_nvpair(nvl, cur); } return (0); } /* * This method builds values for "sharesmb" property from values * already existing on the share. The properties set via sa_zfs_sprint_new_prop * method are passed in sharesmb_val. If a existing property is already * set via sa_zfs_sprint_new_prop method, then they are not appended * to the sharesmb_val string. The returned sharesmb_val string is a combination * of new and existing values for 'sharesmb' property. */ static int sa_zfs_sprintf_existing_prop(zfs_handle_t *handle, char *sharesmb_val) { char shareopts[ZFS_MAXPROPLEN], cur_val[MAXPATHLEN]; char *token, *last, *value; if (zfs_prop_get(handle, ZFS_PROP_SHARESMB, shareopts, sizeof (shareopts), NULL, NULL, 0, B_FALSE) != 0) return (-1); if (strstr(shareopts, "=") == NULL) return (0); for (token = strtok_r(shareopts, ",", &last); token != NULL; token = strtok_r(NULL, ",", &last)) { value = strchr(token, '='); if (value == NULL) return (-1); *value++ = '\0'; (void) snprintf(cur_val, MAXPATHLEN, "%s=", token); if (strstr(sharesmb_val, cur_val) == NULL) { (void) strlcat(cur_val, value, MAXPATHLEN); (void) strlcat(cur_val, ",", MAXPATHLEN); (void) strlcat(sharesmb_val, cur_val, MAXPATHLEN); } } return (0); } /* * Sets the share properties on a ZFS share. For now, this method sets only * the "sharesmb" property. * * This method includes building a comma seperated name-value string to be * set on the "sharesmb" property of a ZFS share. This name-value string is * build in 2 steps: * - New property values given as name-value pair are set first. * - Existing optionset properties, which are not part of the new properties * passed in step 1, are appended to the newly set properties. */ int sa_zfs_setprop(sa_handle_t handle, char *path, nvlist_t *nvl) { zfs_handle_t *z_fs; libzfs_handle_t *z_lib; char sharesmb_val[MAXPATHLEN]; char *dataset, *lastcomma; if (nvlist_empty(nvl)) return (0); if ((handle == NULL) || (path == NULL)) return (-1); if ((dataset = get_zfs_dataset(handle, path, B_FALSE)) == NULL) return (-1); if ((z_lib = libzfs_init()) == NULL) { free(dataset); return (-1); } z_fs = zfs_open(z_lib, dataset, ZFS_TYPE_DATASET); if (z_fs == NULL) { free(dataset); libzfs_fini(z_lib); return (-1); } bzero(sharesmb_val, MAXPATHLEN); if (sa_zfs_sprintf_new_prop(nvl, sharesmb_val) != 0) { free(dataset); zfs_close(z_fs); libzfs_fini(z_lib); return (-1); } if (sa_zfs_sprintf_existing_prop(z_fs, sharesmb_val) != 0) { free(dataset); zfs_close(z_fs); libzfs_fini(z_lib); return (-1); } lastcomma = strrchr(sharesmb_val, ','); if ((lastcomma != NULL) && (lastcomma[1] == '\0')) *lastcomma = '\0'; (void) zfs_prop_set(z_fs, zfs_prop_to_name(ZFS_PROP_SHARESMB), sharesmb_val); free(dataset); zfs_close(z_fs); libzfs_fini(z_lib); return (0); }