/* Unix SMB/CIFS implementation. Wrap VxFS calls in vfs functions. This module is for ACL and XATTR handling. Copyright (C) Symantec Corporation 2014 Copyright (C) Veritas Technologies LLC 2016 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "includes.h" #include "smbd/smbd.h" #include "librpc/gen_ndr/ndr_xattr.h" #include "../libcli/security/security.h" #include "../librpc/gen_ndr/ndr_security.h" #include "system/filesys.h" #include "vfs_vxfs.h" #undef strcasecmp #undef DBGC_CLASS #define DBGC_CLASS DBGC_VFS #define MODULE_NAME "vxfs" /* * WARNING !! WARNING !! * * DO NOT CHANGE THIS FROM "system." space to * "user." space unless you are shipping a product * that RESTRICTS access to extended attributes * to smbd-only. "system." space is restricted * to root access only, "user." space is available * to ANY USER. * * If this is changed to "user." and access * to extended attributes is available via * local processes or other remote file system * (e.g. NFS) then the security of the system * WILL BE COMPROMISED. i.e. non-root users * WILL be able to overwrite Samba ACLs on * the file system. * * If you need to modify this define, do * so using CFLAGS on your build command * line. * e.g. CFLAGS=-DXATTR_USER_NTACL="user.NTACL" * * Added by: 17 Sept. 2014. * */ #ifndef XATTR_USER_NTACL #define XATTR_USER_NTACL "system.NTACL" #endif /* type values */ #define VXFS_ACL_UNDEFINED_TYPE 0 #define VXFS_ACL_USER_OBJ 1 #define VXFS_ACL_GROUP_OBJ 2 #define VXFS_ACL_USER 3 #define VXFS_ACL_GROUP 4 #define VXFS_ACL_OTHER 5 #define VXFS_ACL_MASK 6 /* * Compare aces * This will compare two ace entries for sorting * each entry contains: type, perms and id * Sort by type first, if type is same sort by id. */ static int vxfs_ace_cmp(const void *ace1, const void *ace2) { int ret = 0; uint16_t type_a1, type_a2; uint32_t id_a1, id_a2; /* Type must be compared first */ type_a1 = SVAL(ace1, 0); type_a2 = SVAL(ace2, 0); ret = (type_a1 - type_a2); if (!ret) { /* Compare ID under type */ /* skip perm thus take offset as 4*/ id_a1 = IVAL(ace1, 4); id_a2 = IVAL(ace2, 4); ret = id_a1 - id_a2; } return ret; } static void vxfs_print_ace_buf(char *buf, int count) { int i, offset = 0; uint16_t type, perm; uint32_t id; DEBUG(10, ("vfs_vxfs: Printing aces:\n")); for (i = 0; i < count; i++) { type = SVAL(buf, offset); offset += 2; perm = SVAL(buf, offset); offset += 2; id = IVAL(buf, offset); offset += 4; DEBUG(10, ("vfs_vxfs: type = %u, perm = %u, id = %u\n", (unsigned int)type, (unsigned int)perm, (unsigned int)id)); } } /* * Sort aces so that comparing 2 ACLs will be straight forward. * This function will fill buffer as follows: * For each ace: * 1. ace->a_type will be filled as first 2 bytes in buf. * 2. ace->a_perm will be filled as next 2 bytes. * 3. ace->xid will be filled as next 4 bytes. * Thus each ace entry in buf is equal to 8 bytes. * Also a_type is mapped to VXFS_ACL_* so that ordering aces * becomes easy. */ static char * vxfs_sort_acl(SMB_ACL_T theacl, TALLOC_CTX *mem_ctx, uint32_t o_uid, uint32_t o_gid) { struct smb_acl_entry *smb_ace; int i, count; uint16_t type, perm; uint32_t id; int offset = 0; char *buf = NULL; count = theacl->count; buf = talloc_zero_size(mem_ctx, count * 8); if (!buf) { return NULL; } smb_ace = theacl->acl; for (i = 0; i < count; i++) { /* Calculate type */ /* Map type to SMB_ACL_* to VXFS_ACL_* */ switch(smb_ace->a_type) { case SMB_ACL_USER: type = VXFS_ACL_USER; break; case SMB_ACL_USER_OBJ: type = VXFS_ACL_USER_OBJ; break; case SMB_ACL_GROUP: type = VXFS_ACL_GROUP; break; case SMB_ACL_GROUP_OBJ: type = VXFS_ACL_GROUP_OBJ; break; case SMB_ACL_OTHER: type = VXFS_ACL_OTHER; break; case SMB_ACL_MASK: type = VXFS_ACL_MASK; break; default: type = -1; talloc_free(buf); return NULL; } type = type & 0xff; /* Calculate id: * We get owner uid and owner group gid in o_uid and o_gid * Put these ids instead of -1 */ switch(smb_ace->a_type) { case SMB_ACL_USER: id = smb_ace->info.user.uid; break; case SMB_ACL_GROUP: id = smb_ace->info.group.gid; break; case SMB_ACL_USER_OBJ: id = o_uid; break; case SMB_ACL_GROUP_OBJ: id = o_gid; break; case SMB_ACL_MASK: case SMB_ACL_OTHER: id = -1; break; default: /* Can't happen.. */ id = -1; break; } /* Calculate perm */ perm = smb_ace->a_perm & 0xff; /* TYPE is the first 2 bytes of an entry */ SSVAL(buf, offset, type); offset += 2; /* PERM is the next 2 bytes of an entry */ SSVAL(buf, offset, perm); offset += 2; /* ID is the last 4 bytes of an entry */ SIVAL(buf, offset, id); offset += 4; smb_ace++; } qsort(buf, count, 8, vxfs_ace_cmp); DEBUG(10, ("vfs_vxfs: Print sorted aces:\n")); vxfs_print_ace_buf(buf, count); return buf; } /* This function gets e_buf as an arg which is sorted and created out of * existing ACL. This function will compact this e_buf to c_buf where USER * and GROUP aces matching with USER_OBJ and GROUP_OBJ will be merged * respectively. * This is similar to what posix_acls.c does. This will make sure existing * acls are converted much similar to what posix_acls calculates. */ static char * vxfs_compact_buf(char *e_buf, int *new_count, int count, TALLOC_CTX *mem_ctx) { int i, e_offset = 0, c_offset = 0; uint16_t type, perm, o_perm; uint32_t id, owner_id, group_id; char *c_buf = NULL; if (count < 2) { return NULL; } c_buf = talloc_zero_size(mem_ctx, count * 8); if (!c_buf) { return NULL; } /*Copy first two enries from e_buf to c_buf *These are USER_OBJ and GROUP_OBJ */ memcpy(c_buf, e_buf, 16); (*new_count) = 2; owner_id = IVAL(e_buf, 4); group_id = IVAL(e_buf, 12); c_offset = e_offset = 16; /* Start comparing other entries */ for (i = 2; i < count; i++) { type = SVAL(e_buf, e_offset); e_offset += 2; perm = SVAL(e_buf, e_offset); e_offset += 2; id = IVAL(e_buf, e_offset); e_offset += 4; switch(type) { case VXFS_ACL_USER: if (id == owner_id) { o_perm = SVAL(c_buf, 2); o_perm |= perm; SSVAL(c_buf, 2, o_perm); DEBUG(10, ("vfs_vxfs: merging with owner" "e_type = %u," "e_perm = %u," "e_id = %u\n", (unsigned int)type, (unsigned int)perm, (unsigned int)id)); continue; } break; case VXFS_ACL_GROUP: if (id == group_id) { o_perm = SVAL(c_buf, 10); o_perm |= perm; SSVAL(c_buf, 10, o_perm); DEBUG(10, ("vfs_vxfs: merging with owner group" "e_type = %u," "e_perm = %u," "e_id = %u\n", (unsigned int)type, (unsigned int)perm, (unsigned int)id)); continue; } break; } SSVAL(c_buf, c_offset, type); c_offset += 2; SSVAL(c_buf, c_offset, perm); c_offset += 2; SIVAL(c_buf, c_offset, id); c_offset += 4; (*new_count)++; } DEBUG(10, ("vfs_vxfs: new_count is %d\n", *new_count)); return c_buf; } /* Actually compare New ACL and existing ACL buf */ static bool vxfs_compare_acls(char *e_buf, char *n_buf, int n_count, int e_count) { uint16_t e_type, n_type; int offset = 0; if (!e_buf && !n_buf) { DEBUG(10, ("vfs_vxfs: Empty buffers!\n")); return false; } if ((e_count < 2) || (n_count < 2)) { return false; } /*Get type from last entry from both buffers. * It may or may not be ACL_MASK */ n_type = SVAL(n_buf, offset + (8 * (n_count-1))); e_type = SVAL(e_buf, offset + (8 * (e_count-1))); /* Check for ACL_MASK entry properly. Handle all 4 cases*/ /* If ACL_MASK entry is present in any of the buffers, * it will be always the last one. Calculate count to compare * based on if ACL_MASK is present on new and existing ACL */ if ((n_type != VXFS_ACL_MASK) && (e_type == VXFS_ACL_MASK)){ DEBUG(10, ("vfs_vxfs: New ACL does not have mask entry," "reduce count by 1 and compare\n")); e_count = e_count -1; } if ((n_type == VXFS_ACL_MASK) && (e_type != VXFS_ACL_MASK)){ DEBUG(10, ("vfs_vxfs: new ACL to be set contains mask" "existing ACL does not have mask entry\n" "Need to set New ACL\n")); return false; } if (memcmp(e_buf, n_buf, (e_count * 8)) != 0) { DEBUG(10, ("vfs_vxfs: Compare with memcmp," "buffers not same!\n")); return false; } return true; } /* In VxFS, POSIX ACLs are pointed by separate inode for each file/dir. * However, files/dir share same POSIX ACL inode if ACLs are inherited * from parent. * To retain this behaviour, below function avoids ACL set call if * underlying ACLs are already same and thus saves creating extra inode. * * This function will execute following steps: * 1. Get existing ACL * 2. Sort New ACL and existing ACL into buffers * 3. Compact existing ACL buf * 4. Finally compare New ACL buf and Compact buf * 5. If same, return true * 6. Else need to set New ACL */ static bool vxfs_compare(struct files_struct *fsp, SMB_ACL_T the_acl, SMB_ACL_TYPE_T the_acl_type) { SMB_ACL_T existing_acl = NULL; bool ret = false; int count = 0; TALLOC_CTX *mem_ctx = talloc_tos(); char *existing_buf = NULL, *new_buf = NULL, *compact_buf = NULL; int status; NTSTATUS ntstatus; DEBUG(10, ("vfs_vxfs: Getting existing ACL for %s\n", fsp_str_dbg(fsp))); existing_acl = SMB_VFS_SYS_ACL_GET_FD(fsp, the_acl_type, mem_ctx); if (existing_acl == NULL) { DEBUG(10, ("vfs_vxfs: Failed to get ACL\n")); goto out; } DEBUG(10, ("vfs_vxfs: Existing ACL count=%d\n", existing_acl->count)); DEBUG(10, ("vfs_vxfs: New ACL count=%d\n", the_acl->count)); if (existing_acl->count == 0) { DEBUG(10, ("vfs_vxfs: ACL count is 0, Need to set\n")); goto out; } ntstatus = vfs_stat_fsp(fsp); if (!NT_STATUS_IS_OK(ntstatus)) { DEBUG(10, ("vfs_vxfs: stat failed!\n")); errno = map_errno_from_nt_status(ntstatus); goto out; } DEBUG(10, ("vfs_vxfs: Sorting existing ACL\n")); existing_buf = vxfs_sort_acl(existing_acl, mem_ctx, fsp->fsp_name->st.st_ex_uid, fsp->fsp_name->st.st_ex_gid); if (!existing_buf) goto out; DEBUG(10, ("vfs_vxfs: Sorting new ACL\n")); new_buf = vxfs_sort_acl(the_acl, mem_ctx, fsp->fsp_name->st.st_ex_uid, fsp->fsp_name->st.st_ex_gid); if (!new_buf) { goto out; } DEBUG(10, ("vfs_vxfs: Compact existing buf\n")); compact_buf = vxfs_compact_buf(existing_buf, &count, existing_acl->count, mem_ctx); if (!compact_buf) { goto out; } vxfs_print_ace_buf(compact_buf, count); /* COmpare ACLs only if count is same or mismatch by 1 */ if ((count == the_acl->count) || (count == the_acl->count + 1) || (count+1 == the_acl->count)) { if (vxfs_compare_acls(compact_buf, new_buf, the_acl->count, count)) { DEBUG(10, ("vfs_vxfs: ACLs matched. Not setting.\n")); ret = true; goto out; } else DEBUG(10, ("vfs_vxfs: ACLs NOT matched. Setting\n")); } else { DEBUG(10, ("vfs_vxfs: ACLs count does not match. Setting\n")); } out: TALLOC_FREE(existing_acl); TALLOC_FREE(existing_buf); TALLOC_FREE(compact_buf); TALLOC_FREE(new_buf); return ret; } #ifdef VXFS_ACL_SHARE static int vxfs_sys_acl_set_fd(vfs_handle_struct *handle, struct files_struct *fsp, SMB_ACL_TYPE_T type, SMB_ACL_T theacl) { if (vxfs_compare(fsp, theacl, type)) { return 0; } return SMB_VFS_NEXT_SYS_ACL_SET_FD(handle, fsp, type, theacl); } #endif static int vxfs_fset_xattr(struct vfs_handle_struct *handle, struct files_struct *fsp, const char *name, const void *value, size_t size, int flags){ int ret = 0; DEBUG(10, ("In vxfs_fset_xattr\n")); ret = vxfs_setxattr_fd(fsp_get_io_fd(fsp), name, value, size, flags); if ((ret == 0) || ((ret == -1) && (errno != ENOTSUP) && (errno != ENOSYS))) { SMB_VFS_NEXT_FREMOVEXATTR(handle, fsp, name); return ret; } DEBUG(10, ("Fallback to xattr")); if (strcmp(name, XATTR_NTACL_NAME) == 0) { return SMB_VFS_NEXT_FSETXATTR(handle, fsp, XATTR_USER_NTACL, value, size, flags); } /* Clients can't set XATTR_USER_NTACL directly. */ if (strcasecmp(name, XATTR_USER_NTACL) == 0) { errno = EACCES; return -1; } return SMB_VFS_NEXT_FSETXATTR(handle, fsp, name, value, size, flags); } static ssize_t vxfs_fget_xattr(struct vfs_handle_struct *handle, struct files_struct *fsp, const char *name, void *value, size_t size){ int ret; DEBUG(10, ("In vxfs_fget_xattr\n")); ret = vxfs_getxattr_fd(fsp_get_io_fd(fsp), name, value, size); if ((ret != -1) || ((errno != ENOTSUP) && (errno != ENOSYS) && (errno != ENODATA))) { return ret; } DEBUG(10, ("Fallback to xattr\n")); if (strcmp(name, XATTR_NTACL_NAME) == 0) { return SMB_VFS_NEXT_FGETXATTR(handle, fsp, XATTR_USER_NTACL, value, size); } /* Clients can't see XATTR_USER_NTACL directly. */ if (strcasecmp(name, XATTR_USER_NTACL) == 0) { errno = ENOATTR; return -1; } return SMB_VFS_NEXT_FGETXATTR(handle, fsp, name, value, size); } static int vxfs_fremove_xattr(struct vfs_handle_struct *handle, struct files_struct *fsp, const char *name){ int ret = 0, ret_new = 0, old_errno; DEBUG(10, ("In vxfs_fremove_xattr\n")); /* Remove with old way */ if (strcmp(name, XATTR_NTACL_NAME) == 0) { ret = SMB_VFS_NEXT_FREMOVEXATTR(handle, fsp, XATTR_USER_NTACL); } else { /* Clients can't remove XATTR_USER_NTACL directly. */ if (strcasecmp(name, XATTR_USER_NTACL) != 0) { ret = SMB_VFS_NEXT_FREMOVEXATTR(handle, fsp, name); } } old_errno = errno; /* Remove with new way */ ret_new = vxfs_removexattr_fd(fsp_get_io_fd(fsp), name); /* * If both fail, return failuer else return whichever succeeded */ if (errno == ENOTSUP || errno == ENOSYS) { errno = old_errno; } if ((ret_new != -1) && (ret == -1)) { ret = ret_new; } return ret; } static size_t vxfs_filter_list(char *list, size_t size) { char *str = list; while (str - list < size) { size_t element_len = strlen(str) + 1; if (strcasecmp(str, XATTR_USER_NTACL) == 0) { memmove(str, str + element_len, size - (str - list) - element_len); size -= element_len; continue; } str += element_len; } return size; } static ssize_t vxfs_flistxattr(struct vfs_handle_struct *handle, struct files_struct *fsp, char *list, size_t size) { ssize_t result; result = vxfs_listxattr_fd(fsp_get_io_fd(fsp), list, size); if (result >= 0 || ((errno != ENOTSUP) && (errno != ENOSYS))) { return result; } result = SMB_VFS_NEXT_FLISTXATTR(handle, fsp, list, size); if (result <= 0) { return result; } /* Remove any XATTR_USER_NTACL elements from the returned list. */ result = vxfs_filter_list(list, result); return result; } static NTSTATUS vxfs_fset_ea_dos_attributes(struct vfs_handle_struct *handle, struct files_struct *fsp, uint32_t dosmode) { NTSTATUS err; int ret = 0; bool attrset = false; DBG_DEBUG("Entered function\n"); if (!(dosmode & FILE_ATTRIBUTE_READONLY)) { ret = vxfs_checkwxattr_fd(fsp_get_io_fd(fsp)); if (ret == -1) { DBG_DEBUG("ret:%d\n", ret); if ((errno != EOPNOTSUPP) && (errno != ENOENT)) { return map_nt_error_from_unix(errno); } } } if (dosmode & FILE_ATTRIBUTE_READONLY) { ret = vxfs_setwxattr_fd(fsp_get_io_fd(fsp)); DBG_DEBUG("ret:%d\n", ret); if (ret == -1) { if ((errno != EOPNOTSUPP) && (errno != EINVAL)) { return map_nt_error_from_unix(errno); } } else { attrset = true; } } err = SMB_VFS_NEXT_FSET_DOS_ATTRIBUTES(handle, fsp, dosmode); if (!NT_STATUS_IS_OK(err)) { if (attrset) { ret = vxfs_clearwxattr_fd(fsp_get_io_fd(fsp)); DBG_DEBUG("ret:%d\n", ret); if ((ret == -1) && (errno != ENOENT)) { return map_nt_error_from_unix(errno); } } } return err; } static int vfs_vxfs_connect(struct vfs_handle_struct *handle, const char *service, const char *user) { int ret; ret = SMB_VFS_NEXT_CONNECT(handle, service, user); if (ret < 0) { return ret; } vxfs_init(); return 0; } static struct vfs_fn_pointers vfs_vxfs_fns = { .connect_fn = vfs_vxfs_connect, #ifdef VXFS_ACL_SHARE .sys_acl_set_fd_fn = vxfs_sys_acl_set_fd, #endif .fset_dos_attributes_fn = vxfs_fset_ea_dos_attributes, .getxattrat_send_fn = vfs_not_implemented_getxattrat_send, .getxattrat_recv_fn = vfs_not_implemented_getxattrat_recv, .fgetxattr_fn = vxfs_fget_xattr, .flistxattr_fn = vxfs_flistxattr, .fremovexattr_fn = vxfs_fremove_xattr, .fsetxattr_fn = vxfs_fset_xattr, }; static_decl_vfs; NTSTATUS vfs_vxfs_init(TALLOC_CTX *ctx) { return smb_register_vfs(SMB_VFS_INTERFACE_VERSION, "vxfs", &vfs_vxfs_fns); }