/* * Handle passing Access Control Lists between systems. * * Copyright (C) 1996 Andrew Tridgell * Copyright (C) 1996 Paul Mackerras * Copyright (C) 2006-2008 Wayne Davison * * 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, visit the http://fsf.org website. */ #include "rsync.h" #include "lib/sysacls.h" #ifdef SUPPORT_ACLS extern int dry_run; extern int am_root; extern int read_only; extern int list_only; extern int orig_umask; extern int numeric_ids; extern int inc_recurse; /* Flags used to indicate what items are being transmitted for an entry. */ #define XMIT_USER_OBJ (1<<0) #define XMIT_GROUP_OBJ (1<<1) #define XMIT_MASK_OBJ (1<<2) #define XMIT_OTHER_OBJ (1<<3) #define XMIT_NAME_LIST (1<<4) #define NO_ENTRY ((uchar)0x80) /* Default value of a NON-name-list entry. */ #define NAME_IS_USER (1u<<31) /* Bit used only on a name-list entry. */ /* When we send the access bits over the wire, we shift them 2 bits to the * left and use the lower 2 bits as flags (relevant only to a name entry). * This makes the protocol more efficient than sending a value that would * be likely to have its hightest bits set. */ #define XFLAG_NAME_FOLLOWS 0x0001u #define XFLAG_NAME_IS_USER 0x0002u /* === ACL structures === */ typedef struct { id_t id; uint32 access; } id_access; typedef struct { id_access *idas; int count; } ida_entries; typedef struct { char *name; uchar len; } idname; typedef struct rsync_acl { ida_entries names; /* These will be NO_ENTRY if there's no such entry. */ uchar user_obj; uchar group_obj; uchar mask_obj; uchar other_obj; } rsync_acl; typedef struct { rsync_acl racl; SMB_ACL_T sacl; } acl_duo; static const rsync_acl empty_rsync_acl = { {NULL, 0}, NO_ENTRY, NO_ENTRY, NO_ENTRY, NO_ENTRY }; static item_list access_acl_list = EMPTY_ITEM_LIST; static item_list default_acl_list = EMPTY_ITEM_LIST; /* === Calculations on ACL types === */ static const char *str_acl_type(SMB_ACL_TYPE_T type) { switch (type) { case SMB_ACL_TYPE_ACCESS: #ifdef HAVE_OSX_ACLS return "ACL_TYPE_EXTENDED"; #else return "ACL_TYPE_ACCESS"; #endif case SMB_ACL_TYPE_DEFAULT: return "ACL_TYPE_DEFAULT"; default: break; } return "unknown ACL type!"; } static int calc_sacl_entries(const rsync_acl *racl) { /* A System ACL always gets user/group/other permission entries. */ return racl->names.count #ifdef ACLS_NEED_MASK + 4; #else + (racl->mask_obj != NO_ENTRY) + 3; #endif } /* Extracts and returns the permission bits from the ACL. This cannot be * called on an rsync_acl that has NO_ENTRY in any spot but the mask. */ static int rsync_acl_get_perms(const rsync_acl *racl) { return (racl->user_obj << 6) + ((racl->mask_obj != NO_ENTRY ? racl->mask_obj : racl->group_obj) << 3) + racl->other_obj; } /* Removes the permission-bit entries from the ACL because these * can be reconstructed from the file's mode. */ static void rsync_acl_strip_perms(rsync_acl *racl) { racl->user_obj = NO_ENTRY; if (racl->mask_obj == NO_ENTRY) racl->group_obj = NO_ENTRY; else { if (racl->group_obj == racl->mask_obj) racl->group_obj = NO_ENTRY; racl->mask_obj = NO_ENTRY; } racl->other_obj = NO_ENTRY; } /* Given an empty rsync_acl, fake up the permission bits. */ static void rsync_acl_fake_perms(rsync_acl *racl, mode_t mode) { racl->user_obj = (mode >> 6) & 7; racl->group_obj = (mode >> 3) & 7; racl->other_obj = mode & 7; } /* === Rsync ACL functions === */ static rsync_acl *create_racl(void) { rsync_acl *racl = new(rsync_acl); if (!racl) out_of_memory("create_racl"); *racl = empty_rsync_acl; return racl; } static BOOL ida_entries_equal(const ida_entries *ial1, const ida_entries *ial2) { id_access *ida1, *ida2; int count = ial1->count; if (count != ial2->count) return False; ida1 = ial1->idas; ida2 = ial2->idas; for (; count--; ida1++, ida2++) { if (ida1->access != ida2->access || ida1->id != ida2->id) return False; } return True; } static BOOL rsync_acl_equal(const rsync_acl *racl1, const rsync_acl *racl2) { return racl1->user_obj == racl2->user_obj && racl1->group_obj == racl2->group_obj && racl1->mask_obj == racl2->mask_obj && racl1->other_obj == racl2->other_obj && ida_entries_equal(&racl1->names, &racl2->names); } /* Are the extended (non-permission-bit) entries equal? If so, the rest of * the ACL will be handled by the normal mode-preservation code. This is * only meaningful for access ACLs! Note: the 1st arg is a fully-populated * rsync_acl, but the 2nd parameter can be a condensed rsync_acl, which means * that it might have several of its permission objects set to NO_ENTRY. */ static BOOL rsync_acl_equal_enough(const rsync_acl *racl1, const rsync_acl *racl2, mode_t m) { if ((racl1->mask_obj ^ racl2->mask_obj) & NO_ENTRY) return False; /* One has a mask and the other doesn't */ /* When there's a mask, the group_obj becomes an extended entry. */ if (racl1->mask_obj != NO_ENTRY) { /* A condensed rsync_acl with a mask can only have no * group_obj when it was identical to the mask. This * means that it was also identical to the group attrs * from the mode. */ if (racl2->group_obj == NO_ENTRY) { if (racl1->group_obj != ((m >> 3) & 7)) return False; } else if (racl1->group_obj != racl2->group_obj) return False; } return ida_entries_equal(&racl1->names, &racl2->names); } static void rsync_acl_free(rsync_acl *racl) { if (racl->names.idas) free(racl->names.idas); *racl = empty_rsync_acl; } void free_acl(stat_x *sxp) { if (sxp->acc_acl) { rsync_acl_free(sxp->acc_acl); free(sxp->acc_acl); sxp->acc_acl = NULL; } if (sxp->def_acl) { rsync_acl_free(sxp->def_acl); free(sxp->def_acl); sxp->def_acl = NULL; } } #ifdef SMB_ACL_NEED_SORT static int id_access_sorter(const void *r1, const void *r2) { id_access *ida1 = (id_access *)r1; id_access *ida2 = (id_access *)r2; id_t rid1 = ida1->id, rid2 = ida2->id; if ((ida1->access ^ ida2->access) & NAME_IS_USER) return ida1->access & NAME_IS_USER ? -1 : 1; return rid1 == rid2 ? 0 : rid1 < rid2 ? -1 : 1; } #endif /* === System ACLs === */ /* Unpack system ACL -> rsync ACL verbatim. Return whether we succeeded. */ static BOOL unpack_smb_acl(SMB_ACL_T sacl, rsync_acl *racl) { static item_list temp_ida_list = EMPTY_ITEM_LIST; SMB_ACL_ENTRY_T entry; const char *errfun; int rc; errfun = "sys_acl_get_entry"; for (rc = sys_acl_get_entry(sacl, SMB_ACL_FIRST_ENTRY, &entry); rc == 1; rc = sys_acl_get_entry(sacl, SMB_ACL_NEXT_ENTRY, &entry)) { SMB_ACL_TAG_T tag_type; uint32 access; id_t g_u_id; id_access *ida; if ((rc = sys_acl_get_info(entry, &tag_type, &access, &g_u_id)) != 0) { errfun = "sys_acl_get_info"; break; } /* continue == done with entry; break == store in temporary ida list */ switch (tag_type) { #ifndef HAVE_OSX_ACLS case SMB_ACL_USER_OBJ: if (racl->user_obj == NO_ENTRY) racl->user_obj = access; else rprintf(FINFO, "unpack_smb_acl: warning: duplicate USER_OBJ entry ignored\n"); continue; case SMB_ACL_GROUP_OBJ: if (racl->group_obj == NO_ENTRY) racl->group_obj = access; else rprintf(FINFO, "unpack_smb_acl: warning: duplicate GROUP_OBJ entry ignored\n"); continue; case SMB_ACL_MASK: if (racl->mask_obj == NO_ENTRY) racl->mask_obj = access; else rprintf(FINFO, "unpack_smb_acl: warning: duplicate MASK entry ignored\n"); continue; case SMB_ACL_OTHER: if (racl->other_obj == NO_ENTRY) racl->other_obj = access; else rprintf(FINFO, "unpack_smb_acl: warning: duplicate OTHER entry ignored\n"); continue; #endif case SMB_ACL_USER: access |= NAME_IS_USER; break; case SMB_ACL_GROUP: break; default: rprintf(FINFO, "unpack_smb_acl: warning: entry with unrecognized tag type ignored\n"); continue; } ida = EXPAND_ITEM_LIST(&temp_ida_list, id_access, -10); ida->id = g_u_id; ida->access = access; } if (rc) { rsyserr(FERROR_XFER, errno, "unpack_smb_acl: %s()", errfun); rsync_acl_free(racl); return False; } /* Transfer the count id_access items out of the temp_ida_list * into the names ida_entries list in racl. */ if (temp_ida_list.count) { #ifdef SMB_ACL_NEED_SORT if (temp_ida_list.count > 1) { qsort(temp_ida_list.items, temp_ida_list.count, sizeof (id_access), id_access_sorter); } #endif if (!(racl->names.idas = new_array(id_access, temp_ida_list.count))) out_of_memory("unpack_smb_acl"); memcpy(racl->names.idas, temp_ida_list.items, temp_ida_list.count * sizeof (id_access)); } else racl->names.idas = NULL; racl->names.count = temp_ida_list.count; /* Truncate the temporary list now that its idas have been saved. */ temp_ida_list.count = 0; #ifdef ACLS_NEED_MASK if (!racl->names.count && racl->mask_obj != NO_ENTRY) { /* Throw away a superfluous mask, but mask off the * group perms with it first. */ racl->group_obj &= racl->mask_obj; racl->mask_obj = NO_ENTRY; } #endif return True; } /* Synactic sugar for system calls */ #define CALL_OR_ERROR(func,args,str) \ do { \ if (func args) { \ errfun = str; \ goto error_exit; \ } \ } while (0) #define COE(func,args) CALL_OR_ERROR(func,args,#func) #define COE2(func,args) CALL_OR_ERROR(func,args,NULL) #ifndef HAVE_OSX_ACLS /* Store the permissions in the system ACL entry. */ static int store_access_in_entry(uint32 access, SMB_ACL_ENTRY_T entry) { if (sys_acl_set_access_bits(entry, access)) { rsyserr(FERROR_XFER, errno, "store_access_in_entry sys_acl_set_access_bits()"); return -1; } return 0; } #endif /* Pack rsync ACL -> system ACL verbatim. Return whether we succeeded. */ static BOOL pack_smb_acl(SMB_ACL_T *smb_acl, const rsync_acl *racl) { #ifdef ACLS_NEED_MASK uchar mask_bits; #endif size_t count; id_access *ida; const char *errfun = NULL; SMB_ACL_ENTRY_T entry; if (!(*smb_acl = sys_acl_init(calc_sacl_entries(racl)))) { rsyserr(FERROR_XFER, errno, "pack_smb_acl: sys_acl_init()"); return False; } #ifndef HAVE_OSX_ACLS COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_USER_OBJ, racl->user_obj & ~NO_ENTRY, 0) ); #endif for (ida = racl->names.idas, count = racl->names.count; count; ida++, count--) { #ifdef SMB_ACL_NEED_SORT if (!(ida->access & NAME_IS_USER)) break; #endif COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info, (entry, ida->access & NAME_IS_USER ? SMB_ACL_USER : SMB_ACL_GROUP, ida->access & ~NAME_IS_USER, ida->id) ); } #ifndef HAVE_OSX_ACLS COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_GROUP_OBJ, racl->group_obj & ~NO_ENTRY, 0) ); #ifdef SMB_ACL_NEED_SORT for ( ; count; ida++, count--) { COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_GROUP, ida->access, ida->id) ); } #endif #ifdef ACLS_NEED_MASK mask_bits = racl->mask_obj == NO_ENTRY ? racl->group_obj & ~NO_ENTRY : racl->mask_obj; COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_MASK, mask_bits, NULL) ); #else if (racl->mask_obj != NO_ENTRY) { COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_MASK, racl->mask_obj, 0) ); } #endif COE( sys_acl_create_entry,(smb_acl, &entry) ); COE( sys_acl_set_info,(entry, SMB_ACL_OTHER, racl->other_obj & ~NO_ENTRY, 0) ); #endif #ifdef DEBUG if (sys_acl_valid(*smb_acl) < 0) rprintf(FERROR_XFER, "pack_smb_acl: warning: system says the ACL I packed is invalid\n"); #endif return True; error_exit: if (errfun) { rsyserr(FERROR_XFER, errno, "pack_smb_acl %s()", errfun); } sys_acl_free_acl(*smb_acl); return False; } static int find_matching_rsync_acl(const rsync_acl *racl, SMB_ACL_TYPE_T type, const item_list *racl_list) { static int access_match = -1, default_match = -1; int *match = type == SMB_ACL_TYPE_ACCESS ? &access_match : &default_match; size_t count = racl_list->count; /* If this is the first time through or we didn't match the last * time, then start at the end of the list, which should be the * best place to start hunting. */ if (*match == -1) *match = racl_list->count - 1; while (count--) { rsync_acl *base = racl_list->items; if (rsync_acl_equal(base + *match, racl)) return *match; if (!(*match)--) *match = racl_list->count - 1; } *match = -1; return *match; } static int get_rsync_acl(const char *fname, rsync_acl *racl, SMB_ACL_TYPE_T type, mode_t mode) { SMB_ACL_T sacl; #ifdef SUPPORT_XATTRS /* --fake-super support: load ACLs from an xattr. */ if (am_root < 0) { char *buf; size_t len; int cnt; if ((buf = get_xattr_acl(fname, type == SMB_ACL_TYPE_ACCESS, &len)) == NULL) return 0; cnt = (len - 4*4) / (4+4); if (len < 4*4 || len != (size_t)cnt*(4+4) + 4*4) { free(buf); return -1; } racl->user_obj = IVAL(buf, 0); racl->group_obj = IVAL(buf, 4); racl->mask_obj = IVAL(buf, 8); racl->other_obj = IVAL(buf, 12); if (cnt) { char *bp = buf + 4*4; id_access *ida; if (!(ida = racl->names.idas = new_array(id_access, cnt))) out_of_memory("get_rsync_acl"); racl->names.count = cnt; for ( ; cnt--; ida++, bp += 4+4) { ida->id = IVAL(bp, 0); ida->access = IVAL(bp, 4); } } free(buf); return 0; } #endif if ((sacl = sys_acl_get_file(fname, type)) != 0) { BOOL ok = unpack_smb_acl(sacl, racl); sys_acl_free_acl(sacl); if (!ok) { return -1; } } else if (no_acl_syscall_error(errno)) { /* ACLs are not supported, so pretend we have a basic ACL. */ if (type == SMB_ACL_TYPE_ACCESS) rsync_acl_fake_perms(racl, mode); } else { rsyserr(FERROR_XFER, errno, "get_acl: sys_acl_get_file(%s, %s)", fname, str_acl_type(type)); return -1; } return 0; } /* Return the Access Control List for the given filename. */ int get_acl(const char *fname, stat_x *sxp) { sxp->acc_acl = create_racl(); if (get_rsync_acl(fname, sxp->acc_acl, SMB_ACL_TYPE_ACCESS, sxp->st.st_mode) < 0) { free_acl(sxp); return -1; } if (S_ISDIR(sxp->st.st_mode)) { sxp->def_acl = create_racl(); if (get_rsync_acl(fname, sxp->def_acl, SMB_ACL_TYPE_DEFAULT, sxp->st.st_mode) < 0) { free_acl(sxp); return -1; } } return 0; } /* === Send functions === */ /* Send the ida list over the file descriptor. */ static void send_ida_entries(const ida_entries *idal, int f) { id_access *ida; size_t count = idal->count; write_varint(f, idal->count); for (ida = idal->idas; count--; ida++) { uint32 xbits = ida->access << 2; const char *name; if (ida->access & NAME_IS_USER) { xbits |= XFLAG_NAME_IS_USER; name = add_uid(ida->id); } else name = add_gid(ida->id); write_varint(f, ida->id); if (inc_recurse && name) { int len = strlen(name); write_varint(f, xbits | XFLAG_NAME_FOLLOWS); write_byte(f, len); write_buf(f, name, len); } else write_varint(f, xbits); } } static void send_rsync_acl(rsync_acl *racl, SMB_ACL_TYPE_T type, item_list *racl_list, int f) { int ndx = find_matching_rsync_acl(racl, type, racl_list); /* Send 0 (-1 + 1) to indicate that literal ACL data follows. */ write_varint(f, ndx + 1); if (ndx < 0) { rsync_acl *new_racl = EXPAND_ITEM_LIST(racl_list, rsync_acl, 1000); uchar flags = 0; if (racl->user_obj != NO_ENTRY) flags |= XMIT_USER_OBJ; if (racl->group_obj != NO_ENTRY) flags |= XMIT_GROUP_OBJ; if (racl->mask_obj != NO_ENTRY) flags |= XMIT_MASK_OBJ; if (racl->other_obj != NO_ENTRY) flags |= XMIT_OTHER_OBJ; if (racl->names.count) flags |= XMIT_NAME_LIST; write_byte(f, flags); if (flags & XMIT_USER_OBJ) write_varint(f, racl->user_obj); if (flags & XMIT_GROUP_OBJ) write_varint(f, racl->group_obj); if (flags & XMIT_MASK_OBJ) write_varint(f, racl->mask_obj); if (flags & XMIT_OTHER_OBJ) write_varint(f, racl->other_obj); if (flags & XMIT_NAME_LIST) send_ida_entries(&racl->names, f); /* Give the allocated data to the new list object. */ *new_racl = *racl; *racl = empty_rsync_acl; } } /* Send the ACL from the stat_x structure down the indicated file descriptor. * This also frees the ACL data. */ void send_acl(stat_x *sxp, int f) { if (!sxp->acc_acl) { sxp->acc_acl = create_racl(); rsync_acl_fake_perms(sxp->acc_acl, sxp->st.st_mode); } /* Avoid sending values that can be inferred from other data. */ rsync_acl_strip_perms(sxp->acc_acl); send_rsync_acl(sxp->acc_acl, SMB_ACL_TYPE_ACCESS, &access_acl_list, f); if (S_ISDIR(sxp->st.st_mode)) { if (!sxp->def_acl) sxp->def_acl = create_racl(); send_rsync_acl(sxp->def_acl, SMB_ACL_TYPE_DEFAULT, &default_acl_list, f); } } /* === Receive functions === */ static uint32 recv_acl_access(uchar *name_follows_ptr, int f) { uint32 access = read_varint(f); if (name_follows_ptr) { int flags = access & 3; access >>= 2; if (am_root >= 0 && access & ~SMB_ACL_VALID_NAME_BITS) goto value_error; if (flags & XFLAG_NAME_FOLLOWS) *name_follows_ptr = 1; else *name_follows_ptr = 0; if (flags & XFLAG_NAME_IS_USER) access |= NAME_IS_USER; } else if (am_root >= 0 && access & ~SMB_ACL_VALID_OBJ_BITS) { value_error: rprintf(FERROR_XFER, "recv_acl_access: value out of range: %x\n", access); exit_cleanup(RERR_STREAMIO); } return access; } static uchar recv_ida_entries(ida_entries *ent, int f) { uchar computed_mask_bits = 0; int i, count = read_varint(f); if (count) { if (!(ent->idas = new_array(id_access, count))) out_of_memory("recv_ida_entries"); } else ent->idas = NULL; ent->count = count; for (i = 0; i < count; i++) { uchar has_name; id_t id = read_varint(f); uint32 access = recv_acl_access(&has_name, f); if (has_name) { if (access & NAME_IS_USER) id = recv_user_name(f, id); else id = recv_group_name(f, id, NULL); } else if (access & NAME_IS_USER) { if (inc_recurse && am_root && !numeric_ids) id = match_uid(id); } else { if (inc_recurse && (!am_root || !numeric_ids)) id = match_gid(id, NULL); } ent->idas[i].id = id; ent->idas[i].access = access; computed_mask_bits |= access; } return computed_mask_bits & ~NO_ENTRY; } static int recv_rsync_acl(item_list *racl_list, SMB_ACL_TYPE_T type, int f) { uchar computed_mask_bits = 0; acl_duo *duo_item; uchar flags; int ndx = read_varint(f); if (ndx < 0 || (size_t)ndx > racl_list->count) { rprintf(FERROR_XFER, "recv_acl_index: %s ACL index %d > %d\n", str_acl_type(type), ndx, (int)racl_list->count); exit_cleanup(RERR_STREAMIO); } if (ndx != 0) return ndx - 1; ndx = racl_list->count; duo_item = EXPAND_ITEM_LIST(racl_list, acl_duo, 1000); duo_item->racl = empty_rsync_acl; flags = read_byte(f); if (flags & XMIT_USER_OBJ) duo_item->racl.user_obj = recv_acl_access(NULL, f); if (flags & XMIT_GROUP_OBJ) duo_item->racl.group_obj = recv_acl_access(NULL, f); if (flags & XMIT_MASK_OBJ) duo_item->racl.mask_obj = recv_acl_access(NULL, f); if (flags & XMIT_OTHER_OBJ) duo_item->racl.other_obj = recv_acl_access(NULL, f); if (flags & XMIT_NAME_LIST) computed_mask_bits |= recv_ida_entries(&duo_item->racl.names, f); #ifdef HAVE_OSX_ACLS /* If we received a superfluous mask, throw it away. */ duo_item->racl.mask_obj = NO_ENTRY; #else if (!duo_item->racl.names.count) { /* If we received a superfluous mask, throw it away. */ if (duo_item->racl.mask_obj != NO_ENTRY) { /* Mask off the group perms with it first. */ duo_item->racl.group_obj &= duo_item->racl.mask_obj | NO_ENTRY; duo_item->racl.mask_obj = NO_ENTRY; } } else if (duo_item->racl.mask_obj == NO_ENTRY) /* Must be non-empty with lists. */ duo_item->racl.mask_obj = (computed_mask_bits | duo_item->racl.group_obj) & ~NO_ENTRY; #endif duo_item->sacl = NULL; return ndx; } /* Receive the ACL info the sender has included for this file-list entry. */ void receive_acl(struct file_struct *file, int f) { F_ACL(file) = recv_rsync_acl(&access_acl_list, SMB_ACL_TYPE_ACCESS, f); if (S_ISDIR(file->mode)) F_DIR_DEFACL(file) = recv_rsync_acl(&default_acl_list, SMB_ACL_TYPE_DEFAULT, f); } static int cache_rsync_acl(rsync_acl *racl, SMB_ACL_TYPE_T type, item_list *racl_list) { int ndx; if (!racl) ndx = -1; else if ((ndx = find_matching_rsync_acl(racl, type, racl_list)) == -1) { acl_duo *new_duo; ndx = racl_list->count; new_duo = EXPAND_ITEM_LIST(racl_list, acl_duo, 1000); new_duo->racl = *racl; new_duo->sacl = NULL; *racl = empty_rsync_acl; } return ndx; } /* Turn the ACL data in stat_x into cached ACL data, setting the index * values in the file struct. */ void cache_acl(struct file_struct *file, stat_x *sxp) { F_ACL(file) = cache_rsync_acl(sxp->acc_acl, SMB_ACL_TYPE_ACCESS, &access_acl_list); if (S_ISDIR(sxp->st.st_mode)) { F_DIR_DEFACL(file) = cache_rsync_acl(sxp->def_acl, SMB_ACL_TYPE_DEFAULT, &default_acl_list); } } #ifndef HAVE_OSX_ACLS static mode_t change_sacl_perms(SMB_ACL_T sacl, rsync_acl *racl, mode_t old_mode, mode_t mode) { SMB_ACL_ENTRY_T entry; const char *errfun; int rc; if (S_ISDIR(mode)) { /* If the sticky bit is going on, it's not safe to allow all * the new ACL to go into effect before it gets set. */ #ifdef SMB_ACL_LOSES_SPECIAL_MODE_BITS if (mode & S_ISVTX) mode &= ~0077; #else if (mode & S_ISVTX && !(old_mode & S_ISVTX)) mode &= ~0077; } else { /* If setuid or setgid is going off, it's not safe to allow all * the new ACL to go into effect before they get cleared. */ if ((old_mode & S_ISUID && !(mode & S_ISUID)) || (old_mode & S_ISGID && !(mode & S_ISGID))) mode &= ~0077; #endif } errfun = "sys_acl_get_entry"; for (rc = sys_acl_get_entry(sacl, SMB_ACL_FIRST_ENTRY, &entry); rc == 1; rc = sys_acl_get_entry(sacl, SMB_ACL_NEXT_ENTRY, &entry)) { SMB_ACL_TAG_T tag_type; if ((rc = sys_acl_get_tag_type(entry, &tag_type)) != 0) { errfun = "sys_acl_get_tag_type"; break; } switch (tag_type) { case SMB_ACL_USER_OBJ: COE2( store_access_in_entry,((mode >> 6) & 7, entry) ); break; case SMB_ACL_GROUP_OBJ: /* group is only empty when identical to group perms. */ if (racl->group_obj != NO_ENTRY) break; COE2( store_access_in_entry,((mode >> 3) & 7, entry) ); break; case SMB_ACL_MASK: #ifndef ACLS_NEED_MASK /* mask is only empty when we don't need it. */ if (racl->mask_obj == NO_ENTRY) break; #endif COE2( store_access_in_entry,((mode >> 3) & 7, entry) ); break; case SMB_ACL_OTHER: COE2( store_access_in_entry,(mode & 7, entry) ); break; } } if (rc) { error_exit: if (errfun) { rsyserr(FERROR_XFER, errno, "change_sacl_perms: %s()", errfun); } return (mode_t)~0; } #ifdef SMB_ACL_LOSES_SPECIAL_MODE_BITS /* Ensure that chmod() will be called to restore any lost setid bits. */ if (old_mode & (S_ISUID | S_ISGID | S_ISVTX) && BITS_EQUAL(old_mode, mode, CHMOD_BITS)) old_mode &= ~(S_ISUID | S_ISGID | S_ISVTX); #endif /* Return the mode of the file on disk, as we will set them. */ return (old_mode & ~ACCESSPERMS) | (mode & ACCESSPERMS); } #endif static int set_rsync_acl(const char *fname, acl_duo *duo_item, SMB_ACL_TYPE_T type, stat_x *sxp, mode_t mode) { if (type == SMB_ACL_TYPE_DEFAULT && duo_item->racl.user_obj == NO_ENTRY) { int rc; #ifdef SUPPORT_XATTRS /* --fake-super support: delete default ACL from xattrs. */ if (am_root < 0) rc = del_def_xattr_acl(fname); else #endif rc = sys_acl_delete_def_file(fname); if (rc < 0) { rsyserr(FERROR_XFER, errno, "set_acl: sys_acl_delete_def_file(%s)", fname); return -1; } #ifdef SUPPORT_XATTRS } else if (am_root < 0) { /* --fake-super support: store ACLs in an xattr. */ int cnt = duo_item->racl.names.count; size_t len = 4*4 + cnt * (4+4); char *buf = new_array(char, len); int rc; SIVAL(buf, 0, duo_item->racl.user_obj); SIVAL(buf, 4, duo_item->racl.group_obj); SIVAL(buf, 8, duo_item->racl.mask_obj); SIVAL(buf, 12, duo_item->racl.other_obj); if (cnt) { char *bp = buf + 4*4; id_access *ida = duo_item->racl.names.idas; for ( ; cnt--; ida++, bp += 4+4) { SIVAL(bp, 0, ida->id); SIVAL(bp, 4, ida->access); } } rc = set_xattr_acl(fname, type == SMB_ACL_TYPE_ACCESS, buf, len); free(buf); return rc; #endif } else { mode_t cur_mode = sxp->st.st_mode; if (!duo_item->sacl && !pack_smb_acl(&duo_item->sacl, &duo_item->racl)) return -1; #ifdef HAVE_OSX_ACLS mode = 0; /* eliminate compiler warning */ #else if (type == SMB_ACL_TYPE_ACCESS) { cur_mode = change_sacl_perms(duo_item->sacl, &duo_item->racl, cur_mode, mode); if (cur_mode == (mode_t)~0) return 0; } #endif if (sys_acl_set_file(fname, type, duo_item->sacl) < 0) { rsyserr(FERROR_XFER, errno, "set_acl: sys_acl_set_file(%s, %s)", fname, str_acl_type(type)); return -1; } if (type == SMB_ACL_TYPE_ACCESS) sxp->st.st_mode = cur_mode; } return 0; } /* Set ACL on indicated filename. * * This sets extended access ACL entries and default ACL. If convenient, * it sets permission bits along with the access ACL and signals having * done so by modifying sxp->st.st_mode. * * Returns 1 for unchanged, 0 for changed, -1 for failed. Call this * with fname set to NULL to just check if the ACL is unchanged. */ int set_acl(const char *fname, const struct file_struct *file, stat_x *sxp) { int unchanged = 1; int32 ndx; BOOL eq; if (!dry_run && (read_only || list_only)) { errno = EROFS; return -1; } ndx = F_ACL(file); if (ndx >= 0 && (size_t)ndx < access_acl_list.count) { acl_duo *duo_item = access_acl_list.items; duo_item += ndx; eq = sxp->acc_acl && rsync_acl_equal_enough(sxp->acc_acl, &duo_item->racl, file->mode); if (!eq) { unchanged = 0; if (!dry_run && fname && set_rsync_acl(fname, duo_item, SMB_ACL_TYPE_ACCESS, sxp, file->mode) < 0) unchanged = -1; } } if (!S_ISDIR(sxp->st.st_mode)) return unchanged; ndx = F_DIR_DEFACL(file); if (ndx >= 0 && (size_t)ndx < default_acl_list.count) { acl_duo *duo_item = default_acl_list.items; duo_item += ndx; eq = sxp->def_acl && rsync_acl_equal(sxp->def_acl, &duo_item->racl); if (!eq) { if (unchanged > 0) unchanged = 0; if (!dry_run && fname && set_rsync_acl(fname, duo_item, SMB_ACL_TYPE_DEFAULT, sxp, file->mode) < 0) unchanged = -1; } } return unchanged; } /* Non-incremental recursion needs to convert all the received IDs. * This is done in a single pass after receiving the whole file-list. */ static void match_racl_ids(const item_list *racl_list) { int list_cnt, name_cnt; acl_duo *duo_item = racl_list->items; for (list_cnt = racl_list->count; list_cnt--; duo_item++) { ida_entries *idal = &duo_item->racl.names; id_access *ida = idal->idas; for (name_cnt = idal->count; name_cnt--; ida++) { if (ida->access & NAME_IS_USER) ida->id = match_uid(ida->id); else ida->id = match_gid(ida->id, NULL); } } } void match_acl_ids(void) { match_racl_ids(&access_acl_list); match_racl_ids(&default_acl_list); } /* This is used by dest_mode(). */ int default_perms_for_dir(const char *dir) { rsync_acl racl; SMB_ACL_T sacl; BOOL ok; int perms; if (dir == NULL) dir = "."; perms = ACCESSPERMS & ~orig_umask; /* Read the directory's default ACL. If it has none, this will successfully return an empty ACL. */ sacl = sys_acl_get_file(dir, SMB_ACL_TYPE_DEFAULT); if (sacl == NULL) { /* Couldn't get an ACL. Darn. */ switch (errno) { #ifdef ENOTSUP case ENOTSUP: #endif case ENOSYS: /* No ACLs are available. */ break; case ENOENT: if (dry_run) { /* We're doing a dry run, so the containing directory * wasn't actually created. Don't worry about it. */ break; } /* Otherwise fall through. */ default: rprintf(FWARNING, "default_perms_for_dir: sys_acl_get_file(%s, %s): %s, falling back on umask\n", dir, str_acl_type(SMB_ACL_TYPE_DEFAULT), strerror(errno)); } return perms; } /* Convert it. */ racl = empty_rsync_acl; ok = unpack_smb_acl(sacl, &racl); sys_acl_free_acl(sacl); if (!ok) { rprintf(FWARNING, "default_perms_for_dir: unpack_smb_acl failed, falling back on umask\n"); return perms; } /* Apply the permission-bit entries of the default ACL, if any. */ if (racl.user_obj != NO_ENTRY) { perms = rsync_acl_get_perms(&racl); if (DEBUG_GTE(ACL, 1)) rprintf(FINFO, "got ACL-based default perms %o for directory %s\n", perms, dir); } rsync_acl_free(&racl); return perms; } #endif /* SUPPORT_ACLS */