/* * 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) 2003, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * Copyright 2018 Nexenta Systems, Inc. * Copyright (c) 2015, Joyent, Inc. */ #include #include #include #include #include #define PSEUDOFS_SUFFIX " (pseudo)" /* * A version of VOP_FID that deals with a remote VOP_FID for nfs. * If vp is an nfs node, nfs4_fid() returns EREMOTE, nfs3_fid() and nfs_fid() * returns the filehandle of vp as its fid. When nfs uses fid to set the * exportinfo filehandle template, a remote nfs filehandle would be too big for * the fid of the exported directory. This routine remaps the value of the * attribute va_nodeid of vp to be the fid of vp, so that the fid can fit. * * We need this fid mainly for setting up NFSv4 server namespace where an * nfs filesystem is also part of it. Thus, need to be able to setup a pseudo * exportinfo for an nfs node. * * e.g. mount a filesystem on top of a nfs dir, and then share the new mount * (like exporting a local disk from a "diskless" client) */ int vop_fid_pseudo(vnode_t *vp, fid_t *fidp) { struct vattr va; int error; error = VOP_FID(vp, fidp, NULL); /* * XXX nfs4_fid() does nothing and returns EREMOTE. * XXX nfs3_fid()/nfs_fid() returns nfs filehandle as its fid * which has a bigger length than local fid. * NFS_FH4MAXDATA is the size of * fhandle4_t.fh_xdata[NFS_FH4MAXDATA]. * * Note: nfs[2,3,4]_fid() only gets called for diskless clients. */ if (error == EREMOTE || (error == 0 && fidp->fid_len > NFS_FH4MAXDATA)) { va.va_mask = AT_NODEID; error = VOP_GETATTR(vp, &va, 0, CRED(), NULL); if (error) return (error); fidp->fid_len = sizeof (va.va_nodeid); bcopy(&va.va_nodeid, fidp->fid_data, fidp->fid_len); return (0); } return (error); } /* * Get an nfsv4 vnode of the given fid from the visible list of an * nfs filesystem or get the exi_vp if it is the root node. */ int nfs4_vget_pseudo(struct exportinfo *exi, vnode_t **vpp, fid_t *fidp) { fid_t exp_fid; struct exp_visible *visp; int error; /* check if the given fid is in the visible list */ for (visp = exi->exi_visible; visp; visp = visp->vis_next) { if (EQFID(fidp, &visp->vis_fid)) { VN_HOLD(visp->vis_vp); *vpp = visp->vis_vp; return (0); } } /* check if the given fid is the same as the exported node */ bzero(&exp_fid, sizeof (exp_fid)); exp_fid.fid_len = MAXFIDSZ; error = vop_fid_pseudo(exi->exi_vp, &exp_fid); if (error) return (error); if (EQFID(fidp, &exp_fid)) { VN_HOLD(exi->exi_vp); *vpp = exi->exi_vp; return (0); } return (ENOENT); } /* * Create a pseudo export entry * * This is an export entry that's created as the * side-effect of a "real" export. As a part of * a real export, the pathname to the export is * checked to see if all the directory components * are accessible via an NFSv4 client, i.e. are * exported. If treeclimb_export() finds an unexported * mountpoint along the path, then it calls this * function to export it. * * This pseudo export differs from a real export in that * it only allows read-only access. A "visible" list of * directories is added to filter lookup and readdir results * to only contain dirnames which lead to descendant shares. * * A visible list has a per-file-system scope. Any exportinfo * struct (real or pseudo) can have a visible list as long as * a) its export root is VROOT, or is the zone's root for in-zone NFS service * b) a descendant of the export root is shared */ struct exportinfo * pseudo_exportfs(nfs_export_t *ne, vnode_t *vp, fid_t *fid, struct exp_visible *vis_head, struct exportdata *exdata) { struct exportinfo *exi; struct exportdata *kex; fsid_t fsid; int vpathlen; int i; ASSERT(RW_WRITE_HELD(&ne->exported_lock)); fsid = vp->v_vfsp->vfs_fsid; exi = kmem_zalloc(sizeof (*exi), KM_SLEEP); exi->exi_fsid = fsid; exi->exi_fid = *fid; exi->exi_vp = vp; VN_HOLD(exi->exi_vp); exi->exi_visible = vis_head; exi->exi_count = 1; exi->exi_zoneid = ne->ne_globals->nfs_zoneid; exi->exi_volatile_dev = (vfssw[vp->v_vfsp->vfs_fstype].vsw_flag & VSW_VOLATILEDEV) ? 1 : 0; mutex_init(&exi->exi_lock, NULL, MUTEX_DEFAULT, NULL); /* * Build up the template fhandle */ exi->exi_fh.fh_fsid = fsid; ASSERT(exi->exi_fid.fid_len <= sizeof (exi->exi_fh.fh_xdata)); exi->exi_fh.fh_xlen = exi->exi_fid.fid_len; bcopy(exi->exi_fid.fid_data, exi->exi_fh.fh_xdata, exi->exi_fid.fid_len); exi->exi_fh.fh_len = sizeof (exi->exi_fh.fh_data); kex = &exi->exi_export; kex->ex_flags = EX_PSEUDO; vpathlen = strlen(vp->v_path); kex->ex_pathlen = vpathlen + strlen(PSEUDOFS_SUFFIX); kex->ex_path = kmem_alloc(kex->ex_pathlen + 1, KM_SLEEP); if (vpathlen) (void) strncpy(kex->ex_path, vp->v_path, vpathlen); (void) strcpy(kex->ex_path + vpathlen, PSEUDOFS_SUFFIX); /* Transfer the secinfo data from exdata to this new pseudo node */ if (exdata) srv_secinfo_exp2pseu(&exi->exi_export, exdata); /* * Initialize auth cache and auth cache lock */ for (i = 0; i < AUTH_TABLESIZE; i++) { exi->exi_cache[i] = kmem_alloc(sizeof (avl_tree_t), KM_SLEEP); avl_create(exi->exi_cache[i], nfsauth_cache_clnt_compar, sizeof (struct auth_cache_clnt), offsetof(struct auth_cache_clnt, authc_link)); } rw_init(&exi->exi_cache_lock, NULL, RW_DEFAULT, NULL); /* * Insert the new entry at the front of the export list */ export_link(ne, exi); /* * Initialize exi_id and exi_kstats */ mutex_enter(&nfs_exi_id_lock); exi->exi_id = exi_id_get_next(); avl_add(&exi_id_tree, exi); mutex_exit(&nfs_exi_id_lock); return (exi); } /* * Free a list of visible directories */ void free_visible(struct exp_visible *head) { struct exp_visible *visp, *next; for (visp = head; visp; visp = next) { if (visp->vis_vp != NULL) VN_RELE(visp->vis_vp); next = visp->vis_next; srv_secinfo_list_free(visp->vis_secinfo, visp->vis_seccnt); kmem_free(visp, sizeof (*visp)); } } /* * Connects newchild (or subtree with newchild in head) * to the parent node. We always add it to the beginning * of sibling list. */ static void tree_add_child(treenode_t *parent, treenode_t *newchild) { newchild->tree_parent = parent; newchild->tree_sibling = parent->tree_child_first; parent->tree_child_first = newchild; } /* Look up among direct children a node with the exact tree_vis pointer */ static treenode_t * tree_find_child_by_vis(treenode_t *t, exp_visible_t *vis) { for (t = t->tree_child_first; t; t = t->tree_sibling) if (t->tree_vis == vis) return (t); return (NULL); } /* * Add new node to the head of subtree pointed by 'n'. n can be NULL. * Interconnects the new treenode with exp_visible and exportinfo * if needed. */ static treenode_t * tree_prepend_node(treenode_t *n, exp_visible_t *v, exportinfo_t *e) { treenode_t *tnode = kmem_zalloc(sizeof (*tnode), KM_SLEEP); if (n) { tnode->tree_child_first = n; n->tree_parent = tnode; } if (v) { tnode->tree_vis = v; } if (e) { tnode->tree_exi = e; e->exi_tree = tnode; } return (tnode); } /* * Removes node from the tree and frees the treenode struct. * Does not free structures pointed by tree_exi and tree_vis, * they should be already freed. */ static void tree_remove_node(nfs_export_t *ne, treenode_t *node) { treenode_t *parent = node->tree_parent; treenode_t *s; /* s for sibling */ if (parent == NULL) { kmem_free(node, sizeof (*node)); ne->ns_root = NULL; return; } /* This node is first child */ if (parent->tree_child_first == node) { parent->tree_child_first = node->tree_sibling; /* This node is not first child */ } else { s = parent->tree_child_first; while (s->tree_sibling != node) s = s->tree_sibling; s->tree_sibling = s->tree_sibling->tree_sibling; } kmem_free(node, sizeof (*node)); } /* * When we export a new directory we need to add a new * path segment through the pseudofs to reach the new * directory. This new path is reflected in a list of * directories added to the "visible" list. * * Here there are two lists of visible fids: one hanging off the * pseudo exportinfo, and the one we want to add. It's possible * that the two lists share a common path segment * and have some common directories. We need to combine * the lists so there's no duplicate entries. Where a common * path component is found, the vis_count field is bumped. * * This example shows that the treenode chain (tree_head) and * exp_visible chain (vis_head) can differ in length. The latter * can be shorter. The outer loop must loop over the vis_head chain. * * share /x/a * mount -F ufs /dev/dsk/... /x/y * mkdir -p /x/y/a/b * share /x/y/a/b * * When more_visible() is called during the second share, * the existing namespace is following: * exp_visible_t * treenode_t exportinfo_t v0 v1 * ns_root+---+ +------------+ +---+ +---+ * t0| / |........| E0 pseudo |->| x |->| a | * +---+ +------------+ +---+ +---+ * | / / * +---+ / / * t1| x |------------------------ / * +---+ / * | / * +---+ / * t2| a |------------------------- * +---+........+------------+ * | E1 real | * +------------+ * * This is being added: * * tree_head vis_head * +---+ +---+ * t3| x |->| x |v2 * +---+ +---+ * | | * +---+ +---+ v4 v5 * t4| y |->| y |v3 +------------+ +---+ +---+ * +---+\ +---+ | E2 pseudo |->| a |->| b | * | \....... >+------------+ +---+ +---+ * +---+ / / * t5| a |--------------------------- / * +---+ / * | / * +---+------------------------------- * t6| b | +------------+ * +---+..........>| E3 real | * +------------+ * * more_visible() will: * - kmem_free() t3 and v2 * - add t4, t5, t6 as a child of t1 (t4 will become sibling of t2) * - add v3 to the end of E0->exi_visible * * Note that v4 and v5 were already processed in pseudo_exportfs() and * added to E2. The outer loop of more_visible() will loop only over v2 * and v3. The inner loop of more_visible() always loops over v0 and v1. * * Illustration for this scenario: * * mkdir -p /v/a/b/c * share /v/a/b/c * mkdir /v/a/b/c1 * mkdir -p /v/a1 * mv /v/a/b /v/a1 * share /v/a1/b/c1 * * EXISTING * treenode * namespace: +-----------+ visibles * |exportinfo |-->v->a->b->c * connect_point->+---+--->+-----------+ * | / |T0 * +---+ * | NEW treenode chain: * child->+---+ * | v |T1 +---+<-curr * +---+ N1| v | * | +---+ * +---+ | * | a |T2 +---+<-tree_head * +---+ N2| a1| * | +---+ * +---+ | * | b |T3 +---+ * +---+ N3| b | * | +---+ * +---+ | * | c |T4 +---+ * +---+ N4| c1| * +---+ * * The picture above illustrates the position of following pointers after line * 'child = tree_find_child_by_vis(connect_point, curr->tree_vis);' * was executed for the first time in the outer 'for' loop: * * connect_point..parent treenode in the EXISTING namespace to which the 'curr' * should be connected. If 'connect_point' already has a child * with the same value of tree_vis as the curr->tree_vis is, * the 'curr' will not be added, but kmem_free()d. * child..........the result of tree_find_child_by_vis() * curr...........currently processed treenode from the NEW treenode chain * tree_head......current head of the NEW treenode chain, in this case it was * already moved down to its child - preparation for another loop * * What will happen to NEW treenodes N1, N2, N3, N4 in more_visible() later: * * N1: is merged - i.e. N1 is kmem_free()d. T0 has a child T1 with the same * tree_vis as N1 * N2: is added as a new child of T1 * Note: not just N2, but the whole chain N2->N3->N4 is added * N3: not processed separately (it was added together with N2) * Even that N3 and T3 have same tree_vis, they are NOT merged, but will * become duplicates. * N4: not processed separately */ static void more_visible(struct exportinfo *exi, treenode_t *tree_head) { struct exp_visible *vp1, *vp2, *vis_head, *tail, *next; int found; treenode_t *child, *curr, *connect_point; nfs_export_t *ne = nfs_get_export(); vis_head = tree_head->tree_vis; connect_point = exi->exi_tree; /* * If exportinfo doesn't already have a visible * list just assign the entire supplied list. */ if (exi->exi_visible == NULL) { tree_add_child(connect_point, tree_head); exi->exi_visible = vis_head; /* Update the change timestamp */ tree_update_change(ne, connect_point, &vis_head->vis_change); return; } /* The outer loop traverses the supplied list. */ for (vp1 = vis_head; vp1; vp1 = next) { found = 0; next = vp1->vis_next; /* The inner loop searches the exportinfo visible list. */ for (vp2 = exi->exi_visible; vp2; vp2 = vp2->vis_next) { tail = vp2; if (EQFID(&vp1->vis_fid, &vp2->vis_fid)) { found = 1; vp2->vis_count++; VN_RELE(vp1->vis_vp); /* Transfer vis_exported from vp1 to vp2. */ if (vp1->vis_exported && !vp2->vis_exported) vp2->vis_exported = 1; kmem_free(vp1, sizeof (*vp1)); tree_head->tree_vis = vp2; break; } } /* If not found - add to the end of the list */ if (! found) { tail->vis_next = vp1; vp1->vis_next = NULL; } curr = tree_head; tree_head = tree_head->tree_child_first; if (! connect_point) /* No longer merging */ continue; /* * The inner loop could set curr->tree_vis to the EXISTING * exp_visible vp2, so we can search among the children of * connect_point for the curr->tree_vis. No need for EQFID. */ child = tree_find_child_by_vis(connect_point, curr->tree_vis); /* * Merging cannot be done if a valid child->tree_exi would * be overwritten by a new curr->tree_exi. */ if (child && (child->tree_exi == NULL || curr->tree_exi == NULL)) { if (curr->tree_exi) { /* Transfer the exportinfo */ child->tree_exi = curr->tree_exi; child->tree_exi->exi_tree = child; } kmem_free(curr, sizeof (treenode_t)); connect_point = child; } else { /* Branching */ tree_add_child(connect_point, curr); /* Update the change timestamp */ tree_update_change(ne, connect_point, &curr->tree_vis->vis_change); connect_point = NULL; } } } /* * Remove one visible entry from the pseudo exportfs. * * When we unexport a directory, we have to remove path * components from the visible list in the pseudo exportfs * entry. The supplied visible contains one fid of one path * component. The visible list of the export * is checked against provided visible, matching fid has its * reference count decremented. If a reference count drops to * zero, then it means no paths now use this directory, so its * fid can be removed from the visible list. * * When the last path is removed, the visible list will be null. */ static void less_visible(struct exportinfo *exi, struct exp_visible *vp1) { struct exp_visible *vp2; struct exp_visible *prev, *next; for (vp2 = exi->exi_visible, prev = NULL; vp2; vp2 = next) { next = vp2->vis_next; if (vp1 == vp2) { /* * Decrement the ref count. * Remove the entry if it's zero. */ if (--vp2->vis_count <= 0) { if (prev == NULL) exi->exi_visible = next; else prev->vis_next = next; VN_RELE(vp2->vis_vp); srv_secinfo_list_free(vp2->vis_secinfo, vp2->vis_seccnt); kmem_free(vp2, sizeof (*vp1)); } break; } prev = vp2; } } /* * This function checks the path to a new export to * check whether all the pathname components are * exported. It works by climbing the file tree one * component at a time via "..", crossing mountpoints * if necessary until an export entry is found, or the * system root is reached. * * If an unexported mountpoint is found, then * a new pseudo export is added and the pathname from * the mountpoint down to the export is added to the * visible list for the new pseudo export. If an existing * pseudo export is found, then the pathname is added * to its visible list. * * Note that there's some tests for exportdir. * The exportinfo entry that's passed as a parameter * is that of the real export and exportdir is set * for this case. * * Here is an example of a possible setup: * * () - a new fs; fs mount point * EXPORT - a real exported node * PSEUDO - a pseudo node * vis - visible list * f# - security flavor# * (f#) - security flavor# propagated from its descendents * "" - covered vnode * * * / * | * (a) PSEUDO (f1,f2) * | vis: b,b,"c","n" * | * b * ---------|------------------ * | | * (c) EXPORT,f1(f2) (n) PSEUDO (f1,f2) * | vis: "e","d" | vis: m,m,,p,q,"o" * | | * ------------------ ------------------- * | | | | | * (d) (e) f m EXPORT,f1(f2) p * EXPORT EXPORT | | * f1 f2 | | * | | | * j (o) EXPORT,f2 q EXPORT f2 * */ int treeclimb_export(struct exportinfo *exip) { vnode_t *dvp, *vp; fid_t fid; int error; int exportdir; struct exportinfo *new_exi = exip; struct exp_visible *visp; struct exp_visible *vis_head = NULL; struct vattr va; treenode_t *tree_head = NULL; timespec_t now; nfs_export_t *ne; ne = exip->exi_ne; ASSERT3P(ne, ==, nfs_get_export()); /* curzone reality check */ ASSERT(RW_WRITE_HELD(&ne->exported_lock)); gethrestime(&now); vp = exip->exi_vp; VN_HOLD(vp); exportdir = 1; for (;;) { bzero(&fid, sizeof (fid)); fid.fid_len = MAXFIDSZ; error = vop_fid_pseudo(vp, &fid); if (error) break; ASSERT3U(exip->exi_zoneid, ==, curzone->zone_id); /* * The root of the file system, or the zone's root for * in-zone NFS service needs special handling */ if (vp->v_flag & VROOT || vp == EXI_TO_ZONEROOTVP(exip)) { if (!exportdir) { struct exportinfo *exi; /* * Check if this VROOT dir is already exported. * If so, then attach the pseudonodes. If not, * then continue .. traversal until we hit a * VROOT export (pseudo or real). */ exi = checkexport4(&vp->v_vfsp->vfs_fsid, &fid, vp); if (exi != NULL) { /* * Found an export info * * Extend the list of visible * directories whether it's a pseudo * or a real export. */ more_visible(exi, tree_head); break; /* and climb no further */ } /* * Found the root directory of a filesystem * that isn't exported. Need to export * this as a pseudo export so that an NFS v4 * client can do lookups in it. */ new_exi = pseudo_exportfs(ne, vp, &fid, vis_head, NULL); vis_head = NULL; } if (VN_IS_CURZONEROOT(vp)) { /* at system root */ /* * If sharing "/", new_exi is shared exportinfo * (exip). Otherwise, new_exi is exportinfo * created by pseudo_exportfs() above. */ ne->ns_root = tree_prepend_node(tree_head, NULL, new_exi); /* Update the change timestamp */ tree_update_change(ne, ne->ns_root, &now); break; } /* * Traverse across the mountpoint and continue the * climb on the mounted-on filesystem. */ vp = untraverse(vp, ne->exi_root->exi_vp); exportdir = 0; continue; } /* * Do a getattr to obtain the nodeid (inode num) * for this vnode. */ va.va_mask = AT_NODEID; error = VOP_GETATTR(vp, &va, 0, CRED(), NULL); if (error) break; /* * Add this directory fid to visible list */ visp = kmem_alloc(sizeof (*visp), KM_SLEEP); VN_HOLD(vp); visp->vis_vp = vp; visp->vis_fid = fid; /* structure copy */ visp->vis_ino = va.va_nodeid; visp->vis_count = 1; visp->vis_exported = exportdir; visp->vis_secinfo = NULL; visp->vis_seccnt = 0; visp->vis_change = now; /* structure copy */ visp->vis_next = vis_head; vis_head = visp; /* * Will set treenode's pointer to exportinfo to * 1. shared exportinfo (exip) - if first visit here * 2. freshly allocated pseudo export (if any) * 3. null otherwise */ tree_head = tree_prepend_node(tree_head, visp, new_exi); new_exi = NULL; /* * Now, do a ".." to find parent dir of vp. */ error = VOP_LOOKUP(vp, "..", &dvp, NULL, 0, NULL, CRED(), NULL, NULL, NULL); if (error == ENOTDIR && exportdir) { dvp = exip->exi_dvp; ASSERT(dvp != NULL); VN_HOLD(dvp); error = 0; } if (error) break; exportdir = 0; VN_RELE(vp); vp = dvp; } VN_RELE(vp); /* * We can have set error due to error in: * 1. vop_fid_pseudo() * 2. VOP_GETATTR() * 3. VOP_LOOKUP() * We must free pseudo exportinfos, visibles and treenodes. * Visibles are referenced from treenode_t::tree_vis and * exportinfo_t::exi_visible. To avoid double freeing, only * exi_visible pointer is used, via exi_rele(), for the clean-up. */ if (error) { /* Free unconnected visibles, if there are any. */ if (vis_head) free_visible(vis_head); /* Connect unconnected exportinfo, if there is any. */ if (new_exi && new_exi != exip) tree_head = tree_prepend_node(tree_head, NULL, new_exi); while (tree_head) { treenode_t *t2 = tree_head; exportinfo_t *e = tree_head->tree_exi; /* exip will be freed in exportfs() */ if (e && e != exip) { mutex_enter(&nfs_exi_id_lock); avl_remove(&exi_id_tree, e); mutex_exit(&nfs_exi_id_lock); export_unlink(ne, e); exi_rele(e); } tree_head = tree_head->tree_child_first; kmem_free(t2, sizeof (*t2)); } } return (error); } /* * Walk up the tree and: * 1. release pseudo exportinfo if it has no child * 2. release visible in parent's exportinfo * 3. delete non-exported leaf nodes from tree * * Deleting of nodes will start only if the unshared * node was a leaf node. * Deleting of nodes will finish when we reach a node which * has children or is a real export, then we might still need * to continue releasing visibles, until we reach VROOT or zone's root node. */ void treeclimb_unexport(nfs_export_t *ne, struct exportinfo *exip) { treenode_t *tnode, *old_nd; treenode_t *connect_point = NULL; ASSERT(RW_WRITE_HELD(&ne->exported_lock)); ASSERT(curzone->zone_id == exip->exi_zoneid || curzone->zone_id == global_zone->zone_id); /* * exi_tree can be null for the zone root * which means we're already at the "top" * and there's nothing more to "climb". */ tnode = exip->exi_tree; if (tnode == NULL) { /* Should only happen for... */ ASSERT(exip == ne->exi_root); return; } /* * The unshared exportinfo was unlinked in unexport(). * Zeroing tree_exi ensures that we will skip it. */ tnode->tree_exi = NULL; if (tnode->tree_vis != NULL) /* system root has tree_vis == NULL */ tnode->tree_vis->vis_exported = 0; while (tnode != NULL) { /* * Stop at VROOT (or zone root) node which is exported or has * child. */ if (TREE_ROOT(tnode) && (TREE_EXPORTED(tnode) || tnode->tree_child_first != NULL)) break; /* Release pseudo export if it has no child */ if (TREE_ROOT(tnode) && !TREE_EXPORTED(tnode) && tnode->tree_child_first == NULL) { mutex_enter(&nfs_exi_id_lock); avl_remove(&exi_id_tree, tnode->tree_exi); mutex_exit(&nfs_exi_id_lock); export_unlink(ne, tnode->tree_exi); exi_rele(tnode->tree_exi); tnode->tree_exi = NULL; } /* Release visible in parent's exportinfo */ if (tnode->tree_vis != NULL) less_visible(vis2exi(tnode), tnode->tree_vis); /* Continue with parent */ old_nd = tnode; tnode = tnode->tree_parent; /* Remove itself, if this is a leaf and non-exported node */ if (old_nd->tree_child_first == NULL && !TREE_EXPORTED(old_nd)) { tree_remove_node(ne, old_nd); connect_point = tnode; } } /* Update the change timestamp */ if (connect_point != NULL) tree_update_change(ne, connect_point, NULL); } /* * Traverse backward across mountpoint from the * root vnode of a filesystem to its mounted-on * vnode. */ vnode_t * untraverse(vnode_t *vp, vnode_t *zone_rootvp) { vnode_t *tvp, *nextvp; tvp = vp; for (;;) { if (!(tvp->v_flag & VROOT) && !VN_CMP(tvp, zone_rootvp)) break; /* lock vfs to prevent unmount of this vfs */ vfs_lock_wait(tvp->v_vfsp); if ((nextvp = tvp->v_vfsp->vfs_vnodecovered) == NULL) { vfs_unlock(tvp->v_vfsp); break; } /* * Hold nextvp to prevent unmount. After unlock vfs and * rele tvp, any number of overlays could be unmounted. * Putting a hold on vfs_vnodecovered will only allow * tvp's vfs to be unmounted. Of course if caller placed * extra hold on vp before calling untraverse, the following * hold would not be needed. Since prev actions of caller * are unknown, we need to hold here just to be safe. */ VN_HOLD(nextvp); vfs_unlock(tvp->v_vfsp); VN_RELE(tvp); tvp = nextvp; } return (tvp); } /* * Given an exportinfo, climb up to find the exportinfo for the VROOT * (or zone root) of the filesystem. * * e.g. / * | * a (VROOT) pseudo-exportinfo * | * b * | * c #share /a/b/c * | * d * * where c is in the same filesystem as a. * So, get_root_export(*exportinfo_for_c) returns exportinfo_for_a * * If d is shared, then c will be put into a's visible list. * Note: visible list is per filesystem and is attached to the * VROOT exportinfo. Returned exi does NOT have a new hold. */ struct exportinfo * get_root_export(struct exportinfo *exip) { treenode_t *tnode = exip->exi_tree; exportinfo_t *exi = NULL; while (tnode) { if (TREE_ROOT(tnode)) { exi = tnode->tree_exi; break; } tnode = tnode->tree_parent; } ASSERT(exi); return (exi); } /* * Return true if the supplied vnode has a sub-directory exported. */ int has_visible(struct exportinfo *exi, vnode_t *vp) { struct exp_visible *visp; fid_t fid; bool_t vp_is_exported; vp_is_exported = VN_CMP(vp, exi->exi_vp); /* * An exported root vnode has a sub-dir shared if it has a visible * list. i.e. if it does not have a visible list, then there is no * node in this filesystem leads to any other shared node. */ ASSERT3P(curzone->zone_id, ==, exi->exi_zoneid); if (vp_is_exported && ((vp->v_flag & VROOT) || VN_IS_CURZONEROOT(vp))) { return (exi->exi_visible ? 1 : 0); } /* * Only the exportinfo of a fs root node may have a visible list. * Either it is a pseudo root node, or a real exported root node. */ exi = get_root_export(exi); if (!exi->exi_visible) return (0); /* Get the fid of the vnode */ bzero(&fid, sizeof (fid)); fid.fid_len = MAXFIDSZ; if (vop_fid_pseudo(vp, &fid) != 0) { return (0); } /* * See if vp is in the visible list of the root node exportinfo. */ for (visp = exi->exi_visible; visp; visp = visp->vis_next) { if (EQFID(&fid, &visp->vis_fid)) { /* * If vp is an exported non-root node with only 1 path * count (for itself), it indicates no sub-dir shared * using this vp as a path. */ if (vp_is_exported && visp->vis_count < 2) break; return (1); } } return (0); } /* * Returns true if the supplied vnode is visible * in this export. If vnode is visible, return * vis_exported in expseudo. */ int nfs_visible(struct exportinfo *exi, vnode_t *vp, int *expseudo) { struct exp_visible *visp; fid_t fid; /* * First check to see if vp is export root. * * A pseudo export root can never be exported * (it would be a real export then); however, * it is always visible. If a pseudo root object * was exported by server admin, then the entire * pseudo exportinfo (and all visible entries) would * be destroyed. A pseudo exportinfo only exists * to provide access to real (descendant) export(s). * * Previously, rootdir was special cased here; however, * the export root special case handles the rootdir * case also. */ if (VN_CMP(vp, exi->exi_vp)) { *expseudo = 0; return (1); } /* * Only a PSEUDO node has a visible list or an exported VROOT * node may have a visible list. */ if (!PSEUDO(exi)) exi = get_root_export(exi); /* Get the fid of the vnode */ bzero(&fid, sizeof (fid)); fid.fid_len = MAXFIDSZ; if (vop_fid_pseudo(vp, &fid) != 0) { *expseudo = 0; return (0); } /* * We can't trust VN_CMP() above because of LOFS. * Even though VOP_CMP will do the right thing for LOFS * objects, VN_CMP will short circuit out early when the * vnode ops ptrs are different. Just in case we're dealing * with LOFS, compare exi_fid/fsid here. * * expseudo is not set because this is not an export */ if (EQFID(&exi->exi_fid, &fid) && EQFSID(&exi->exi_fsid, &vp->v_vfsp->vfs_fsid)) { *expseudo = 0; return (1); } /* See if it matches any fid in the visible list */ for (visp = exi->exi_visible; visp; visp = visp->vis_next) { if (EQFID(&fid, &visp->vis_fid)) { *expseudo = visp->vis_exported; return (1); } } *expseudo = 0; return (0); } /* * Returns true if the supplied vnode is the * directory of an export point. */ int nfs_exported(struct exportinfo *exi, vnode_t *vp) { struct exp_visible *visp; fid_t fid; /* * First check to see if vp is the export root * This check required for the case of lookup .. * where .. is a V_ROOT vnode and a pseudo exportroot. * Pseudo export root objects do not have an entry * in the visible list even though every V_ROOT * pseudonode is visible. It is safe to compare * vp here because pseudo_exportfs put a hold on * it when exi_vp was initialized. * * Note: VN_CMP() won't match for LOFS shares, but they're * handled below w/EQFID/EQFSID. */ if (VN_CMP(vp, exi->exi_vp)) return (1); /* Get the fid of the vnode */ bzero(&fid, sizeof (fid)); fid.fid_len = MAXFIDSZ; if (vop_fid_pseudo(vp, &fid) != 0) return (0); if (EQFID(&fid, &exi->exi_fid) && EQFSID(&vp->v_vfsp->vfs_fsid, &exi->exi_fsid)) { return (1); } /* See if it matches any fid in the visible list */ for (visp = exi->exi_visible; visp; visp = visp->vis_next) { if (EQFID(&fid, &visp->vis_fid)) return (visp->vis_exported); } return (0); } /* * Returns true if the supplied inode is visible * in this export. This function is used by * readdir which uses inode numbers from the * directory. * * NOTE: this code does not match inode number for ".", * but it isn't required because NFS4 server rddir * skips . and .. entries. */ int nfs_visible_inode(struct exportinfo *exi, ino64_t ino, struct exp_visible **visp) { /* * Only a PSEUDO node has a visible list or an exported VROOT * node may have a visible list. */ if (!PSEUDO(exi)) exi = get_root_export(exi); for (*visp = exi->exi_visible; *visp != NULL; *visp = (*visp)->vis_next) if ((u_longlong_t)ino == (*visp)->vis_ino) { return (1); } return (0); } /* * Get the change attribute from visible and returns TRUE. * If the change value is not available returns FALSE. */ bool_t nfs_visible_change(struct exportinfo *exi, vnode_t *vp, timespec_t *change) { struct exp_visible *visp; fid_t fid; treenode_t *node; nfs_export_t *ne = nfs_get_export(); /* * First check to see if vp is export root. */ if (VN_CMP(vp, exi->exi_vp)) goto exproot; /* * Only a PSEUDO node has a visible list or an exported VROOT * node may have a visible list. */ if (!PSEUDO(exi)) exi = get_root_export(exi); /* Get the fid of the vnode */ bzero(&fid, sizeof (fid)); fid.fid_len = MAXFIDSZ; if (vop_fid_pseudo(vp, &fid) != 0) return (FALSE); /* * We can't trust VN_CMP() above because of LOFS. * Even though VOP_CMP will do the right thing for LOFS * objects, VN_CMP will short circuit out early when the * vnode ops ptrs are different. Just in case we're dealing * with LOFS, compare exi_fid/fsid here. */ if (EQFID(&exi->exi_fid, &fid) && EQFSID(&exi->exi_fsid, &vp->v_vfsp->vfs_fsid)) goto exproot; /* See if it matches any fid in the visible list */ for (visp = exi->exi_visible; visp; visp = visp->vis_next) { if (EQFID(&fid, &visp->vis_fid)) { *change = visp->vis_change; return (TRUE); } } return (FALSE); exproot: /* The VROOT export have its visible available through treenode */ node = exi->exi_tree; if (node != ne->ns_root) { ASSERT(node->tree_vis != NULL); *change = node->tree_vis->vis_change; } else { ASSERT(node->tree_vis == NULL); *change = ne->ns_root_change; } return (TRUE); } /* * Update the change attribute value for a particular treenode. The change * attribute value is stored in the visible attached to the treenode, or in the * ns_root_change. * * If the change value is not supplied, the current time is used. */ void tree_update_change(nfs_export_t *ne, treenode_t *tnode, timespec_t *change) { timespec_t *vis_change; ASSERT(tnode != NULL); ASSERT((tnode != ne->ns_root && tnode->tree_vis != NULL) || (tnode == ne->ns_root && tnode->tree_vis == NULL)); vis_change = tnode == ne->ns_root ? &ne->ns_root_change : &tnode->tree_vis->vis_change; if (change != NULL) *vis_change = *change; else gethrestime(vis_change); }