| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Paulo Alcantara | 1178 | 24.00% | 33 | 16.92% |
| Steve French | 751 | 15.30% | 53 | 27.18% |
| Aurelien Aptel | 674 | 13.73% | 5 | 2.56% |
| Rohith Surabattula | 608 | 12.39% | 8 | 4.10% |
| Shyam Prasad N | 315 | 6.42% | 8 | 4.10% |
| Pavel Shilovsky | 293 | 5.97% | 16 | 8.21% |
| Sachin S. Prabhu | 217 | 4.42% | 2 | 1.03% |
| Meetakshi Setiya | 113 | 2.30% | 1 | 0.51% |
| Jeff Layton | 100 | 2.04% | 17 | 8.72% |
| Ronnie Sahlberg | 98 | 2.00% | 10 | 5.13% |
| Eugene Korenevsky | 94 | 1.92% | 1 | 0.51% |
| David Howells | 81 | 1.65% | 7 | 3.59% |
| Bharath SM | 81 | 1.65% | 2 | 1.03% |
| Shirish Pargaonkar | 67 | 1.37% | 6 | 3.08% |
| Enzo Matsumiya | 59 | 1.20% | 3 | 1.54% |
| Joe Perches | 52 | 1.06% | 4 | 2.05% |
| Thomas Gleixner | 22 | 0.45% | 1 | 0.51% |
| Gleb Korobeynikov | 19 | 0.39% | 1 | 0.51% |
| ZhangXiaoxu | 15 | 0.31% | 1 | 0.51% |
| Andy Shevchenko | 10 | 0.20% | 1 | 0.51% |
| Kees Cook | 9 | 0.18% | 1 | 0.51% |
| Winston Wen | 7 | 0.14% | 1 | 0.51% |
| Christoph Hellwig | 6 | 0.12% | 1 | 0.51% |
| Miklos Szeredi | 6 | 0.12% | 1 | 0.51% |
| Hongbo Li | 6 | 0.12% | 1 | 0.51% |
| ZhaoLong Wang | 6 | 0.12% | 1 | 0.51% |
| Waiman Long | 4 | 0.08% | 1 | 0.51% |
| Eric W. Biedermann | 4 | 0.08% | 1 | 0.51% |
| Al Viro | 4 | 0.08% | 2 | 1.03% |
| Mateusz Guzik | 4 | 0.08% | 1 | 0.51% |
| Christoph Lameter | 2 | 0.04% | 1 | 0.51% |
| Dave Wysochanski | 1 | 0.02% | 1 | 0.51% |
| Jiangshan Yi | 1 | 0.02% | 1 | 0.51% |
| Thiago Rafael Becker | 1 | 0.02% | 1 | 0.51% |
| Total | 4908 | 195 |
// SPDX-License-Identifier: LGPL-2.1 /* * * Copyright (C) International Business Machines Corp., 2002,2008 * Author(s): Steve French (sfrench@us.ibm.com) * */ #include <linux/slab.h> #include <linux/ctype.h> #include <linux/mempool.h> #include <linux/vmalloc.h> #include "cifsglob.h" #include "cifsproto.h" #include "cifs_debug.h" #include "smberr.h" #include "nterr.h" #include "cifs_unicode.h" #include "smb2pdu.h" #include "smb2proto.h" #include "smb1proto.h" #include "cifsfs.h" #ifdef CONFIG_CIFS_DFS_UPCALL #include "dns_resolve.h" #include "dfs_cache.h" #include "dfs.h" #endif #include "fs_context.h" #include "cached_dir.h" struct tcon_list { struct list_head entry; struct cifs_tcon *tcon; }; /* The xid serves as a useful identifier for each incoming vfs request, in a similar way to the mid which is useful to track each sent smb, and CurrentXid can also provide a running counter (although it will eventually wrap past zero) of the total vfs operations handled since the cifs fs was mounted */ unsigned int _get_xid(void) { unsigned int xid; spin_lock(&GlobalMid_Lock); GlobalTotalActiveXid++; /* keep high water mark for number of simultaneous ops in filesystem */ if (GlobalTotalActiveXid > GlobalMaxActiveXid) GlobalMaxActiveXid = GlobalTotalActiveXid; if (GlobalTotalActiveXid > 65000) cifs_dbg(FYI, "warning: more than 65000 requests active\n"); xid = GlobalCurrentXid++; spin_unlock(&GlobalMid_Lock); return xid; } void _free_xid(unsigned int xid) { spin_lock(&GlobalMid_Lock); /* if (GlobalTotalActiveXid == 0) BUG(); */ GlobalTotalActiveXid--; spin_unlock(&GlobalMid_Lock); } struct cifs_ses * sesInfoAlloc(void) { struct cifs_ses *ret_buf; ret_buf = kzalloc_obj(struct cifs_ses); if (ret_buf) { atomic_inc(&sesInfoAllocCount); spin_lock_init(&ret_buf->ses_lock); ret_buf->ses_status = SES_NEW; ++ret_buf->ses_count; INIT_LIST_HEAD(&ret_buf->smb_ses_list); INIT_LIST_HEAD(&ret_buf->tcon_list); mutex_init(&ret_buf->session_mutex); spin_lock_init(&ret_buf->iface_lock); INIT_LIST_HEAD(&ret_buf->iface_list); spin_lock_init(&ret_buf->chan_lock); } return ret_buf; } void sesInfoFree(struct cifs_ses *buf_to_free) { struct cifs_server_iface *iface = NULL, *niface = NULL; if (buf_to_free == NULL) { cifs_dbg(FYI, "Null buffer passed to sesInfoFree\n"); return; } unload_nls(buf_to_free->local_nls); atomic_dec(&sesInfoAllocCount); kfree(buf_to_free->serverOS); kfree(buf_to_free->serverDomain); kfree(buf_to_free->serverNOS); kfree_sensitive(buf_to_free->password); kfree_sensitive(buf_to_free->password2); kfree(buf_to_free->user_name); kfree(buf_to_free->domainName); kfree(buf_to_free->dns_dom); kfree_sensitive(buf_to_free->auth_key.response); spin_lock(&buf_to_free->iface_lock); list_for_each_entry_safe(iface, niface, &buf_to_free->iface_list, iface_head) kref_put(&iface->refcount, release_iface); spin_unlock(&buf_to_free->iface_lock); kfree_sensitive(buf_to_free); } struct cifs_tcon * tcon_info_alloc(bool dir_leases_enabled, enum smb3_tcon_ref_trace trace) { struct cifs_tcon *ret_buf; static atomic_t tcon_debug_id; ret_buf = kzalloc_obj(*ret_buf); if (!ret_buf) return NULL; if (dir_leases_enabled == true) { ret_buf->cfids = init_cached_dirs(); if (!ret_buf->cfids) { kfree(ret_buf); return NULL; } } /* else ret_buf->cfids is already set to NULL above */ atomic_inc(&tconInfoAllocCount); ret_buf->status = TID_NEW; ret_buf->debug_id = atomic_inc_return(&tcon_debug_id); ret_buf->tc_count = 1; spin_lock_init(&ret_buf->tc_lock); INIT_LIST_HEAD(&ret_buf->openFileList); INIT_LIST_HEAD(&ret_buf->tcon_list); INIT_LIST_HEAD(&ret_buf->cifs_sb_list); spin_lock_init(&ret_buf->open_file_lock); spin_lock_init(&ret_buf->stat_lock); spin_lock_init(&ret_buf->sb_list_lock); atomic_set(&ret_buf->num_local_opens, 0); atomic_set(&ret_buf->num_remote_opens, 0); ret_buf->stats_from_time = ktime_get_real_seconds(); #ifdef CONFIG_CIFS_FSCACHE mutex_init(&ret_buf->fscache_lock); #endif trace_smb3_tcon_ref(ret_buf->debug_id, ret_buf->tc_count, trace); #ifdef CONFIG_CIFS_DFS_UPCALL INIT_LIST_HEAD(&ret_buf->dfs_ses_list); #endif INIT_LIST_HEAD(&ret_buf->pending_opens); INIT_DELAYED_WORK(&ret_buf->query_interfaces, smb2_query_server_interfaces); #ifdef CONFIG_CIFS_DFS_UPCALL INIT_DELAYED_WORK(&ret_buf->dfs_cache_work, dfs_cache_refresh); #endif return ret_buf; } void tconInfoFree(struct cifs_tcon *tcon, enum smb3_tcon_ref_trace trace) { if (tcon == NULL) { cifs_dbg(FYI, "Null buffer passed to tconInfoFree\n"); return; } trace_smb3_tcon_ref(tcon->debug_id, tcon->tc_count, trace); free_cached_dirs(tcon->cfids); atomic_dec(&tconInfoAllocCount); kfree(tcon->nativeFileSystem); kfree_sensitive(tcon->password); kfree(tcon->origin_fullpath); kfree(tcon); } void * cifs_buf_get(void) { void *ret_buf = NULL; /* * SMB2 header is bigger than CIFS one - no problems to clean some * more bytes for CIFS. */ size_t buf_size = sizeof(struct smb2_hdr); /* * We could use negotiated size instead of max_msgsize - * but it may be more efficient to always alloc same size * albeit slightly larger than necessary and maxbuffersize * defaults to this and can not be bigger. */ ret_buf = mempool_alloc(cifs_req_poolp, GFP_NOFS); /* clear the first few header bytes */ /* for most paths, more is cleared in header_assemble */ memset(ret_buf, 0, buf_size + 3); atomic_inc(&buf_alloc_count); #ifdef CONFIG_CIFS_STATS2 atomic_inc(&total_buf_alloc_count); #endif /* CONFIG_CIFS_STATS2 */ return ret_buf; } void cifs_buf_release(void *buf_to_free) { if (buf_to_free == NULL) { /* cifs_dbg(FYI, "Null buffer passed to cifs_buf_release\n");*/ return; } mempool_free(buf_to_free, cifs_req_poolp); atomic_dec(&buf_alloc_count); return; } void * cifs_small_buf_get(void) { void *ret_buf = NULL; /* We could use negotiated size instead of max_msgsize - but it may be more efficient to always alloc same size albeit slightly larger than necessary and maxbuffersize defaults to this and can not be bigger */ ret_buf = mempool_alloc(cifs_sm_req_poolp, GFP_NOFS); /* No need to clear memory here, cleared in header assemble */ atomic_inc(&small_buf_alloc_count); #ifdef CONFIG_CIFS_STATS2 atomic_inc(&total_small_buf_alloc_count); #endif /* CONFIG_CIFS_STATS2 */ return ret_buf; } void cifs_small_buf_release(void *buf_to_free) { if (buf_to_free == NULL) { cifs_dbg(FYI, "Null buffer passed to cifs_small_buf_release\n"); return; } mempool_free(buf_to_free, cifs_sm_req_poolp); atomic_dec(&small_buf_alloc_count); return; } void free_rsp_buf(int resp_buftype, void *rsp) { if (resp_buftype == CIFS_SMALL_BUFFER) cifs_small_buf_release(rsp); else if (resp_buftype == CIFS_LARGE_BUFFER) cifs_buf_release(rsp); } void dump_smb(void *buf, int smb_buf_length) { if (traceSMB == 0) return; print_hex_dump(KERN_DEBUG, "", DUMP_PREFIX_NONE, 8, 2, buf, smb_buf_length, true); } void cifs_autodisable_serverino(struct cifs_sb_info *cifs_sb) { unsigned int sbflags = cifs_sb_flags(cifs_sb); if (sbflags & CIFS_MOUNT_SERVER_INUM) { struct cifs_tcon *tcon = NULL; if (cifs_sb->master_tlink) tcon = cifs_sb_master_tcon(cifs_sb); atomic_andnot(CIFS_MOUNT_SERVER_INUM, &cifs_sb->mnt_cifs_flags); cifs_sb->mnt_cifs_serverino_autodisabled = true; cifs_dbg(VFS, "Autodisabling the use of server inode numbers on %s\n", tcon ? tcon->tree_name : "new server"); cifs_dbg(VFS, "The server doesn't seem to support them properly or the files might be on different servers (DFS)\n"); cifs_dbg(VFS, "Hardlinks will not be recognized on this mount. Consider mounting with the \"noserverino\" option to silence this message.\n"); } } void cifs_set_oplock_level(struct cifsInodeInfo *cinode, __u32 oplock) { oplock &= 0xF; if (oplock == OPLOCK_EXCLUSIVE) { cinode->oplock = CIFS_CACHE_WRITE_FLG | CIFS_CACHE_READ_FLG; cifs_dbg(FYI, "Exclusive Oplock granted on inode %p\n", &cinode->netfs.inode); } else if (oplock == OPLOCK_READ) { cinode->oplock = CIFS_CACHE_READ_FLG; cifs_dbg(FYI, "Level II Oplock granted on inode %p\n", &cinode->netfs.inode); } else cinode->oplock = 0; } /* * We wait for oplock breaks to be processed before we attempt to perform * writes. */ int cifs_get_writer(struct cifsInodeInfo *cinode) { int rc; start: rc = wait_on_bit(&cinode->flags, CIFS_INODE_PENDING_OPLOCK_BREAK, TASK_KILLABLE); if (rc) return rc; spin_lock(&cinode->writers_lock); if (!cinode->writers) set_bit(CIFS_INODE_PENDING_WRITERS, &cinode->flags); cinode->writers++; /* Check to see if we have started servicing an oplock break */ if (test_bit(CIFS_INODE_PENDING_OPLOCK_BREAK, &cinode->flags)) { cinode->writers--; if (cinode->writers == 0) { clear_bit(CIFS_INODE_PENDING_WRITERS, &cinode->flags); wake_up_bit(&cinode->flags, CIFS_INODE_PENDING_WRITERS); } spin_unlock(&cinode->writers_lock); goto start; } spin_unlock(&cinode->writers_lock); return 0; } void cifs_put_writer(struct cifsInodeInfo *cinode) { spin_lock(&cinode->writers_lock); cinode->writers--; if (cinode->writers == 0) { clear_bit(CIFS_INODE_PENDING_WRITERS, &cinode->flags); wake_up_bit(&cinode->flags, CIFS_INODE_PENDING_WRITERS); } spin_unlock(&cinode->writers_lock); } /** * cifs_queue_oplock_break - queue the oplock break handler for cfile * @cfile: The file to break the oplock on * * This function is called from the demultiplex thread when it * receives an oplock break for @cfile. * * Assumes the tcon->open_file_lock is held. * Assumes cfile->file_info_lock is NOT held. */ void cifs_queue_oplock_break(struct cifsFileInfo *cfile) { /* * Bump the handle refcount now while we hold the * open_file_lock to enforce the validity of it for the oplock * break handler. The matching put is done at the end of the * handler. */ cifsFileInfo_get(cfile); queue_work(cifsoplockd_wq, &cfile->oplock_break); } void cifs_done_oplock_break(struct cifsInodeInfo *cinode) { clear_bit(CIFS_INODE_PENDING_OPLOCK_BREAK, &cinode->flags); wake_up_bit(&cinode->flags, CIFS_INODE_PENDING_OPLOCK_BREAK); } bool backup_cred(struct cifs_sb_info *cifs_sb) { unsigned int sbflags = cifs_sb_flags(cifs_sb); if (sbflags & CIFS_MOUNT_CIFS_BACKUPUID) { if (uid_eq(cifs_sb->ctx->backupuid, current_fsuid())) return true; } if (sbflags & CIFS_MOUNT_CIFS_BACKUPGID) { if (in_group_p(cifs_sb->ctx->backupgid)) return true; } return false; } void cifs_del_pending_open(struct cifs_pending_open *open) { spin_lock(&tlink_tcon(open->tlink)->open_file_lock); list_del(&open->olist); spin_unlock(&tlink_tcon(open->tlink)->open_file_lock); } void cifs_add_pending_open_locked(struct cifs_fid *fid, struct tcon_link *tlink, struct cifs_pending_open *open) { memcpy(open->lease_key, fid->lease_key, SMB2_LEASE_KEY_SIZE); open->oplock = CIFS_OPLOCK_NO_CHANGE; open->tlink = tlink; fid->pending_open = open; list_add_tail(&open->olist, &tlink_tcon(tlink)->pending_opens); } void cifs_add_pending_open(struct cifs_fid *fid, struct tcon_link *tlink, struct cifs_pending_open *open) { spin_lock(&tlink_tcon(tlink)->open_file_lock); cifs_add_pending_open_locked(fid, tlink, open); spin_unlock(&tlink_tcon(open->tlink)->open_file_lock); } /* * Critical section which runs after acquiring deferred_lock. * As there is no reference count on cifs_deferred_close, pdclose * should not be used outside deferred_lock. */ bool cifs_is_deferred_close(struct cifsFileInfo *cfile, struct cifs_deferred_close **pdclose) { struct cifs_deferred_close *dclose; list_for_each_entry(dclose, &CIFS_I(d_inode(cfile->dentry))->deferred_closes, dlist) { if ((dclose->netfid == cfile->fid.netfid) && (dclose->persistent_fid == cfile->fid.persistent_fid) && (dclose->volatile_fid == cfile->fid.volatile_fid)) { *pdclose = dclose; return true; } } return false; } /* * Critical section which runs after acquiring deferred_lock. */ void cifs_add_deferred_close(struct cifsFileInfo *cfile, struct cifs_deferred_close *dclose) { bool is_deferred = false; struct cifs_deferred_close *pdclose; is_deferred = cifs_is_deferred_close(cfile, &pdclose); if (is_deferred) { kfree(dclose); return; } dclose->tlink = cfile->tlink; dclose->netfid = cfile->fid.netfid; dclose->persistent_fid = cfile->fid.persistent_fid; dclose->volatile_fid = cfile->fid.volatile_fid; list_add_tail(&dclose->dlist, &CIFS_I(d_inode(cfile->dentry))->deferred_closes); } /* * Critical section which runs after acquiring deferred_lock. */ void cifs_del_deferred_close(struct cifsFileInfo *cfile) { bool is_deferred = false; struct cifs_deferred_close *dclose; is_deferred = cifs_is_deferred_close(cfile, &dclose); if (!is_deferred) return; list_del(&dclose->dlist); kfree(dclose); } void cifs_close_deferred_file(struct cifsInodeInfo *cifs_inode) { struct cifsFileInfo *cfile = NULL; struct file_list *tmp_list, *tmp_next_list; LIST_HEAD(file_head); if (cifs_inode == NULL) return; spin_lock(&cifs_inode->open_file_lock); list_for_each_entry(cfile, &cifs_inode->openFileList, flist) { if (delayed_work_pending(&cfile->deferred)) { if (cancel_delayed_work(&cfile->deferred)) { spin_lock(&cifs_inode->deferred_lock); cifs_del_deferred_close(cfile); spin_unlock(&cifs_inode->deferred_lock); tmp_list = kmalloc_obj(struct file_list, GFP_ATOMIC); if (tmp_list == NULL) break; tmp_list->cfile = cfile; list_add_tail(&tmp_list->list, &file_head); } } } spin_unlock(&cifs_inode->open_file_lock); list_for_each_entry_safe(tmp_list, tmp_next_list, &file_head, list) { _cifsFileInfo_put(tmp_list->cfile, false, false); list_del(&tmp_list->list); kfree(tmp_list); } } void cifs_close_all_deferred_files(struct cifs_tcon *tcon) { struct cifsFileInfo *cfile; struct file_list *tmp_list, *tmp_next_list; LIST_HEAD(file_head); spin_lock(&tcon->open_file_lock); list_for_each_entry(cfile, &tcon->openFileList, tlist) { if (delayed_work_pending(&cfile->deferred)) { if (cancel_delayed_work(&cfile->deferred)) { spin_lock(&CIFS_I(d_inode(cfile->dentry))->deferred_lock); cifs_del_deferred_close(cfile); spin_unlock(&CIFS_I(d_inode(cfile->dentry))->deferred_lock); tmp_list = kmalloc_obj(struct file_list, GFP_ATOMIC); if (tmp_list == NULL) break; tmp_list->cfile = cfile; list_add_tail(&tmp_list->list, &file_head); } } } spin_unlock(&tcon->open_file_lock); list_for_each_entry_safe(tmp_list, tmp_next_list, &file_head, list) { _cifsFileInfo_put(tmp_list->cfile, true, false); list_del(&tmp_list->list); kfree(tmp_list); } } void cifs_close_all_deferred_files_sb(struct cifs_sb_info *cifs_sb) { struct rb_root *root = &cifs_sb->tlink_tree; struct rb_node *node; struct cifs_tcon *tcon; struct tcon_link *tlink; struct tcon_list *tmp_list, *q; LIST_HEAD(tcon_head); spin_lock(&cifs_sb->tlink_tree_lock); for (node = rb_first(root); node; node = rb_next(node)) { tlink = rb_entry(node, struct tcon_link, tl_rbnode); tcon = tlink_tcon(tlink); if (IS_ERR(tcon)) continue; tmp_list = kmalloc_obj(struct tcon_list, GFP_ATOMIC); if (tmp_list == NULL) break; tmp_list->tcon = tcon; /* Take a reference on tcon to prevent it from being freed */ spin_lock(&tcon->tc_lock); ++tcon->tc_count; trace_smb3_tcon_ref(tcon->debug_id, tcon->tc_count, netfs_trace_tcon_ref_get_close_defer_files); spin_unlock(&tcon->tc_lock); list_add_tail(&tmp_list->entry, &tcon_head); } spin_unlock(&cifs_sb->tlink_tree_lock); list_for_each_entry_safe(tmp_list, q, &tcon_head, entry) { cifs_close_all_deferred_files(tmp_list->tcon); list_del(&tmp_list->entry); cifs_put_tcon(tmp_list->tcon, netfs_trace_tcon_ref_put_close_defer_files); kfree(tmp_list); } } void cifs_close_deferred_file_under_dentry(struct cifs_tcon *tcon, struct dentry *dentry) { struct file_list *tmp_list, *tmp_next_list; struct cifsFileInfo *cfile; LIST_HEAD(file_head); spin_lock(&tcon->open_file_lock); list_for_each_entry(cfile, &tcon->openFileList, tlist) { if ((cfile->dentry == dentry) && delayed_work_pending(&cfile->deferred) && cancel_delayed_work(&cfile->deferred)) { spin_lock(&CIFS_I(d_inode(cfile->dentry))->deferred_lock); cifs_del_deferred_close(cfile); spin_unlock(&CIFS_I(d_inode(cfile->dentry))->deferred_lock); tmp_list = kmalloc_obj(struct file_list, GFP_ATOMIC); if (tmp_list == NULL) break; tmp_list->cfile = cfile; list_add_tail(&tmp_list->list, &file_head); } } spin_unlock(&tcon->open_file_lock); list_for_each_entry_safe(tmp_list, tmp_next_list, &file_head, list) { _cifsFileInfo_put(tmp_list->cfile, true, false); list_del(&tmp_list->list); kfree(tmp_list); } } /* * If a dentry has been deleted, all corresponding open handles should know that * so that we do not defer close them. */ void cifs_mark_open_handles_for_deleted_file(struct inode *inode, const char *path) { struct cifsFileInfo *cfile; void *page; const char *full_path; struct cifsInodeInfo *cinode = CIFS_I(inode); page = alloc_dentry_path(); spin_lock(&cinode->open_file_lock); /* * note: we need to construct path from dentry and compare only if the * inode has any hardlinks. When number of hardlinks is 1, we can just * mark all open handles since they are going to be from the same file. */ if (inode->i_nlink > 1) { list_for_each_entry(cfile, &cinode->openFileList, flist) { full_path = build_path_from_dentry(cfile->dentry, page); if (!IS_ERR(full_path) && strcmp(full_path, path) == 0) cfile->status_file_deleted = true; } } else { list_for_each_entry(cfile, &cinode->openFileList, flist) cfile->status_file_deleted = true; } spin_unlock(&cinode->open_file_lock); free_dentry_path(page); } /* parses DFS referral V3 structure * caller is responsible for freeing target_nodes * returns: * - on success - 0 * - on failure - errno */ int parse_dfs_referrals(struct get_dfs_referral_rsp *rsp, u32 rsp_size, unsigned int *num_of_nodes, struct dfs_info3_param **target_nodes, const struct nls_table *nls_codepage, int remap, const char *searchName, bool is_unicode) { int i, rc = 0; char *data_end; struct dfs_referral_level_3 *ref; if (rsp_size < sizeof(*rsp)) { cifs_dbg(VFS | ONCE, "%s: header is malformed (size is %u, must be %zu)\n", __func__, rsp_size, sizeof(*rsp)); rc = -EINVAL; goto parse_DFS_referrals_exit; } *num_of_nodes = le16_to_cpu(rsp->NumberOfReferrals); if (*num_of_nodes < 1) { cifs_dbg(VFS | ONCE, "%s: [path=%s] num_referrals must be at least > 0, but we got %d\n", __func__, searchName, *num_of_nodes); rc = -ENOENT; goto parse_DFS_referrals_exit; } if (sizeof(*rsp) + *num_of_nodes * sizeof(REFERRAL3) > rsp_size) { cifs_dbg(VFS | ONCE, "%s: malformed buffer (size is %u, must be at least %zu)\n", __func__, rsp_size, sizeof(*rsp) + *num_of_nodes * sizeof(REFERRAL3)); rc = -EINVAL; goto parse_DFS_referrals_exit; } ref = (struct dfs_referral_level_3 *) &(rsp->referrals); if (ref->VersionNumber != cpu_to_le16(3)) { cifs_dbg(VFS, "Referrals of V%d version are not supported, should be V3\n", le16_to_cpu(ref->VersionNumber)); rc = -EINVAL; goto parse_DFS_referrals_exit; } /* get the upper boundary of the resp buffer */ data_end = (char *)rsp + rsp_size; cifs_dbg(FYI, "num_referrals: %d dfs flags: 0x%x ...\n", *num_of_nodes, le32_to_cpu(rsp->DFSFlags)); *target_nodes = kzalloc_objs(struct dfs_info3_param, *num_of_nodes); if (*target_nodes == NULL) { rc = -ENOMEM; goto parse_DFS_referrals_exit; } /* collect necessary data from referrals */ for (i = 0; i < *num_of_nodes; i++) { char *temp; int max_len; struct dfs_info3_param *node = (*target_nodes)+i; node->flags = le32_to_cpu(rsp->DFSFlags); if (is_unicode) { __le16 *tmp = kmalloc(strlen(searchName)*2 + 2, GFP_KERNEL); if (tmp == NULL) { rc = -ENOMEM; goto parse_DFS_referrals_exit; } cifsConvertToUTF16((__le16 *) tmp, searchName, PATH_MAX, nls_codepage, remap); node->path_consumed = cifs_utf16_bytes(tmp, le16_to_cpu(rsp->PathConsumed), nls_codepage); kfree(tmp); } else node->path_consumed = le16_to_cpu(rsp->PathConsumed); node->server_type = le16_to_cpu(ref->ServerType); node->ref_flag = le16_to_cpu(ref->ReferralEntryFlags); /* copy DfsPath */ temp = (char *)ref + le16_to_cpu(ref->DfsPathOffset); max_len = data_end - temp; node->path_name = cifs_strndup_from_utf16(temp, max_len, is_unicode, nls_codepage); if (!node->path_name) { rc = -ENOMEM; goto parse_DFS_referrals_exit; } /* copy link target UNC */ temp = (char *)ref + le16_to_cpu(ref->NetworkAddressOffset); max_len = data_end - temp; node->node_name = cifs_strndup_from_utf16(temp, max_len, is_unicode, nls_codepage); if (!node->node_name) { rc = -ENOMEM; goto parse_DFS_referrals_exit; } node->ttl = le32_to_cpu(ref->TimeToLive); ref++; } parse_DFS_referrals_exit: if (rc) { free_dfs_info_array(*target_nodes, *num_of_nodes); *target_nodes = NULL; *num_of_nodes = 0; } return rc; } /** * cifs_alloc_hash - allocate hash and hash context together * @name: The name of the crypto hash algo * @sdesc: SHASH descriptor where to put the pointer to the hash TFM * * The caller has to make sure @sdesc is initialized to either NULL or * a valid context. It can be freed via cifs_free_hash(). */ int cifs_alloc_hash(const char *name, struct shash_desc **sdesc) { int rc = 0; struct crypto_shash *alg = NULL; if (*sdesc) return 0; alg = crypto_alloc_shash(name, 0, 0); if (IS_ERR(alg)) { cifs_dbg(VFS, "Could not allocate shash TFM '%s'\n", name); rc = PTR_ERR(alg); *sdesc = NULL; return rc; } *sdesc = kmalloc(sizeof(struct shash_desc) + crypto_shash_descsize(alg), GFP_KERNEL); if (*sdesc == NULL) { cifs_dbg(VFS, "no memory left to allocate shash TFM '%s'\n", name); crypto_free_shash(alg); return -ENOMEM; } (*sdesc)->tfm = alg; return 0; } /** * cifs_free_hash - free hash and hash context together * @sdesc: Where to find the pointer to the hash TFM * * Freeing a NULL descriptor is safe. */ void cifs_free_hash(struct shash_desc **sdesc) { if (unlikely(!sdesc) || !*sdesc) return; if ((*sdesc)->tfm) { crypto_free_shash((*sdesc)->tfm); (*sdesc)->tfm = NULL; } kfree_sensitive(*sdesc); *sdesc = NULL; } void extract_unc_hostname(const char *unc, const char **h, size_t *len) { const char *end; /* skip initial slashes */ while (*unc && (*unc == '\\' || *unc == '/')) unc++; end = unc; while (*end && !(*end == '\\' || *end == '/')) end++; *h = unc; *len = end - unc; } /** * copy_path_name - copy src path to dst, possibly truncating * @dst: The destination buffer * @src: The source name * * returns number of bytes written (including trailing nul) */ int copy_path_name(char *dst, const char *src) { int name_len; /* * PATH_MAX includes nul, so if strlen(src) >= PATH_MAX it * will truncate and strlen(dst) will be PATH_MAX-1 */ name_len = strscpy(dst, src, PATH_MAX); if (WARN_ON_ONCE(name_len < 0)) name_len = PATH_MAX-1; /* we count the trailing nul */ name_len++; return name_len; } struct super_cb_data { void *data; struct super_block *sb; }; static void tcon_super_cb(struct super_block *sb, void *arg) { struct super_cb_data *sd = arg; struct cifs_sb_info *cifs_sb; struct cifs_tcon *t1 = sd->data, *t2; if (sd->sb) return; cifs_sb = CIFS_SB(sb); t2 = cifs_sb_master_tcon(cifs_sb); spin_lock(&t2->tc_lock); if ((t1->ses == t2->ses || t1->ses->dfs_root_ses == t2->ses->dfs_root_ses) && t1->ses->server == t2->ses->server && t2->origin_fullpath && dfs_src_pathname_equal(t2->origin_fullpath, t1->origin_fullpath)) sd->sb = sb; spin_unlock(&t2->tc_lock); } static struct super_block *__cifs_get_super(void (*f)(struct super_block *, void *), void *data) { struct super_cb_data sd = { .data = data, .sb = NULL, }; struct file_system_type **fs_type = (struct file_system_type *[]) { &cifs_fs_type, &smb3_fs_type, NULL, }; for (; *fs_type; fs_type++) { iterate_supers_type(*fs_type, f, &sd); if (sd.sb) { /* * Grab an active reference in order to prevent automounts (DFS links) * of expiring and then freeing up our cifs superblock pointer while * we're doing failover. */ cifs_sb_active(sd.sb); return sd.sb; } } pr_warn_once("%s: could not find dfs superblock\n", __func__); return ERR_PTR(-EINVAL); } static void __cifs_put_super(struct super_block *sb) { if (!IS_ERR_OR_NULL(sb)) cifs_sb_deactive(sb); } struct super_block *cifs_get_dfs_tcon_super(struct cifs_tcon *tcon) { spin_lock(&tcon->tc_lock); if (!tcon->origin_fullpath) { spin_unlock(&tcon->tc_lock); return ERR_PTR(-ENOENT); } spin_unlock(&tcon->tc_lock); return __cifs_get_super(tcon_super_cb, tcon); } void cifs_put_tcp_super(struct super_block *sb) { __cifs_put_super(sb); } #ifdef CONFIG_CIFS_DFS_UPCALL int match_target_ip(struct TCP_Server_Info *server, const char *host, size_t hostlen, bool *result) { struct sockaddr_storage ss; int rc; cifs_dbg(FYI, "%s: hostname=%.*s\n", __func__, (int)hostlen, host); *result = false; rc = dns_resolve_name(server->dns_dom, host, hostlen, (struct sockaddr *)&ss); if (rc < 0) return rc; spin_lock(&server->srv_lock); *result = cifs_match_ipaddr((struct sockaddr *)&server->dstaddr, (struct sockaddr *)&ss); spin_unlock(&server->srv_lock); cifs_dbg(FYI, "%s: ip addresses matched: %s\n", __func__, str_yes_no(*result)); return 0; } int cifs_update_super_prepath(struct cifs_sb_info *cifs_sb, char *prefix) { int rc; kfree(cifs_sb->prepath); cifs_sb->prepath = NULL; if (prefix && *prefix) { cifs_sb->prepath = cifs_sanitize_prepath(prefix, GFP_ATOMIC); if (IS_ERR(cifs_sb->prepath)) { rc = PTR_ERR(cifs_sb->prepath); cifs_sb->prepath = NULL; return rc; } if (cifs_sb->prepath) convert_delimiter(cifs_sb->prepath, CIFS_DIR_SEP(cifs_sb)); } atomic_or(CIFS_MOUNT_USE_PREFIX_PATH, &cifs_sb->mnt_cifs_flags); return 0; } /* * Handle weird Windows SMB server behaviour. It responds with * STATUS_OBJECT_NAME_INVALID code to SMB2 QUERY_INFO request for * "\<server>\<dfsname>\<linkpath>" DFS reference, where <dfsname> contains * non-ASCII unicode symbols. */ int cifs_inval_name_dfs_link_error(const unsigned int xid, struct cifs_tcon *tcon, struct cifs_sb_info *cifs_sb, const char *full_path, bool *islink) { struct TCP_Server_Info *server = tcon->ses->server; struct cifs_ses *ses = tcon->ses; size_t len; char *path; char *ref_path; *islink = false; /* * Fast path - skip check when @full_path doesn't have a prefix path to * look up or tcon is not DFS. */ if (strlen(full_path) < 2 || !cifs_sb || (cifs_sb_flags(cifs_sb) & CIFS_MOUNT_NO_DFS) || !is_tcon_dfs(tcon)) return 0; spin_lock(&server->srv_lock); if (!server->leaf_fullpath) { spin_unlock(&server->srv_lock); return 0; } spin_unlock(&server->srv_lock); /* * Slow path - tcon is DFS and @full_path has prefix path, so attempt * to get a referral to figure out whether it is an DFS link. */ len = strnlen(tcon->tree_name, MAX_TREE_SIZE + 1) + strlen(full_path) + 1; path = kmalloc(len, GFP_KERNEL); if (!path) return -ENOMEM; scnprintf(path, len, "%s%s", tcon->tree_name, full_path); ref_path = dfs_cache_canonical_path(path + 1, cifs_sb->local_nls, cifs_remap(cifs_sb)); kfree(path); if (IS_ERR(ref_path)) { if (PTR_ERR(ref_path) != -EINVAL) return PTR_ERR(ref_path); } else { struct dfs_info3_param *refs = NULL; int num_refs = 0; /* * XXX: we are not using dfs_cache_find() here because we might * end up filling all the DFS cache and thus potentially * removing cached DFS targets that the client would eventually * need during failover. */ ses = CIFS_DFS_ROOT_SES(ses); if (ses->server->ops->get_dfs_refer && !ses->server->ops->get_dfs_refer(xid, ses, ref_path, &refs, &num_refs, cifs_sb->local_nls, cifs_remap(cifs_sb))) *islink = refs[0].server_type == DFS_TYPE_LINK; free_dfs_info_array(refs, num_refs); kfree(ref_path); } return 0; } #endif int cifs_wait_for_server_reconnect(struct TCP_Server_Info *server, bool retry) { int timeout = 10; int rc; spin_lock(&server->srv_lock); if (server->tcpStatus != CifsNeedReconnect) { spin_unlock(&server->srv_lock); return 0; } timeout *= server->nr_targets; spin_unlock(&server->srv_lock); /* * Give demultiplex thread up to 10 seconds to each target available for * reconnect -- should be greater than cifs socket timeout which is 7 * seconds. * * On "soft" mounts we wait once. Hard mounts keep retrying until * process is killed or server comes back on-line. */ do { rc = wait_event_interruptible_timeout(server->response_q, (server->tcpStatus != CifsNeedReconnect), timeout * HZ); if (rc < 0) { cifs_dbg(FYI, "%s: aborting reconnect due to received signal\n", __func__); return -ERESTARTSYS; } /* are we still trying to reconnect? */ spin_lock(&server->srv_lock); if (server->tcpStatus != CifsNeedReconnect) { spin_unlock(&server->srv_lock); return 0; } spin_unlock(&server->srv_lock); } while (retry); cifs_dbg(FYI, "%s: gave up waiting on reconnect\n", __func__); return -EHOSTDOWN; }
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