/* Unix SMB/CIFS implementation. SMB NT Security Descriptor / Unix permission conversion. Copyright (C) Jeremy Allison 1994-2009. Copyright (C) Andreas Gruenbacher 2002. Copyright (C) Simo Sorce 2009. 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 "../libcli/security/dom_sid.h" extern const struct generic_mapping file_generic_mapping; #undef DBGC_CLASS #define DBGC_CLASS DBGC_ACLS /**************************************************************************** Data structures representing the internal ACE format. ****************************************************************************/ enum ace_owner {UID_ACE, GID_ACE, WORLD_ACE}; enum ace_attribute {ALLOW_ACE, DENY_ACE}; /* Used for incoming NT ACLS. */ typedef union posix_id { uid_t uid; gid_t gid; int world; } posix_id; typedef struct canon_ace { struct canon_ace *next, *prev; SMB_ACL_TAG_T type; mode_t perms; /* Only use S_I(R|W|X)USR mode bits here. */ struct dom_sid trustee; enum ace_owner owner_type; enum ace_attribute attr; posix_id unix_ug; uint8_t ace_flags; /* From windows ACE entry. */ } canon_ace; #define ALL_ACE_PERMS (S_IRUSR|S_IWUSR|S_IXUSR) /* * EA format of user.SAMBA_PAI (Samba_Posix_Acl_Interitance) * attribute on disk - version 1. * All values are little endian. * * | 1 | 1 | 2 | 2 | .... * +------+------+-------------+---------------------+-------------+--------------------+ * | vers | flag | num_entries | num_default_entries | ..entries.. | default_entries... | * +------+------+-------------+---------------------+-------------+--------------------+ * * Entry format is : * * | 1 | 4 | * +------+-------------------+ * | value| uid/gid or world | * | type | value | * +------+-------------------+ * * Version 2 format. Stores extra Windows metadata about an ACL. * * | 1 | 2 | 2 | 2 | .... * +------+----------+-------------+---------------------+-------------+--------------------+ * | vers | ace | num_entries | num_default_entries | ..entries.. | default_entries... | * | 2 | type | | | | | * +------+----------+-------------+---------------------+-------------+--------------------+ * * Entry format is : * * | 1 | 1 | 4 | * +------+------+-------------------+ * | ace | value| uid/gid or world | * | flag | type | value | * +------+-------------------+------+ * */ #define PAI_VERSION_OFFSET 0 #define PAI_V1_FLAG_OFFSET 1 #define PAI_V1_NUM_ENTRIES_OFFSET 2 #define PAI_V1_NUM_DEFAULT_ENTRIES_OFFSET 4 #define PAI_V1_ENTRIES_BASE 6 #define PAI_V1_ACL_FLAG_PROTECTED 0x1 #define PAI_V1_ENTRY_LENGTH 5 #define PAI_V1_VERSION 1 #define PAI_V2_TYPE_OFFSET 1 #define PAI_V2_NUM_ENTRIES_OFFSET 3 #define PAI_V2_NUM_DEFAULT_ENTRIES_OFFSET 5 #define PAI_V2_ENTRIES_BASE 7 #define PAI_V2_ENTRY_LENGTH 6 #define PAI_V2_VERSION 2 /* * In memory format of user.SAMBA_PAI attribute. */ struct pai_entry { struct pai_entry *next, *prev; uint8_t ace_flags; enum ace_owner owner_type; posix_id unix_ug; }; struct pai_val { uint16_t sd_type; unsigned int num_entries; struct pai_entry *entry_list; unsigned int num_def_entries; struct pai_entry *def_entry_list; }; /************************************************************************ Return a uint32 of the pai_entry principal. ************************************************************************/ static uint32_t get_pai_entry_val(struct pai_entry *paie) { switch (paie->owner_type) { case UID_ACE: DEBUG(10,("get_pai_entry_val: uid = %u\n", (unsigned int)paie->unix_ug.uid )); return (uint32_t)paie->unix_ug.uid; case GID_ACE: DEBUG(10,("get_pai_entry_val: gid = %u\n", (unsigned int)paie->unix_ug.gid )); return (uint32_t)paie->unix_ug.gid; case WORLD_ACE: default: DEBUG(10,("get_pai_entry_val: world ace\n")); return (uint32_t)-1; } } /************************************************************************ Return a uint32 of the entry principal. ************************************************************************/ static uint32_t get_entry_val(canon_ace *ace_entry) { switch (ace_entry->owner_type) { case UID_ACE: DEBUG(10,("get_entry_val: uid = %u\n", (unsigned int)ace_entry->unix_ug.uid )); return (uint32_t)ace_entry->unix_ug.uid; case GID_ACE: DEBUG(10,("get_entry_val: gid = %u\n", (unsigned int)ace_entry->unix_ug.gid )); return (uint32_t)ace_entry->unix_ug.gid; case WORLD_ACE: default: DEBUG(10,("get_entry_val: world ace\n")); return (uint32_t)-1; } } /************************************************************************ Create the on-disk format (always v2 now). Caller must free. ************************************************************************/ static char *create_pai_buf_v2(canon_ace *file_ace_list, canon_ace *dir_ace_list, uint16_t sd_type, size_t *store_size) { char *pai_buf = NULL; canon_ace *ace_list = NULL; char *entry_offset = NULL; unsigned int num_entries = 0; unsigned int num_def_entries = 0; unsigned int i; for (ace_list = file_ace_list; ace_list; ace_list = ace_list->next) { num_entries++; } for (ace_list = dir_ace_list; ace_list; ace_list = ace_list->next) { num_def_entries++; } DEBUG(10,("create_pai_buf_v2: num_entries = %u, num_def_entries = %u\n", num_entries, num_def_entries )); *store_size = PAI_V2_ENTRIES_BASE + ((num_entries + num_def_entries)*PAI_V2_ENTRY_LENGTH); pai_buf = (char *)SMB_MALLOC(*store_size); if (!pai_buf) { return NULL; } /* Set up the header. */ memset(pai_buf, '\0', PAI_V2_ENTRIES_BASE); SCVAL(pai_buf,PAI_VERSION_OFFSET,PAI_V2_VERSION); SSVAL(pai_buf,PAI_V2_TYPE_OFFSET, sd_type); SSVAL(pai_buf,PAI_V2_NUM_ENTRIES_OFFSET,num_entries); SSVAL(pai_buf,PAI_V2_NUM_DEFAULT_ENTRIES_OFFSET,num_def_entries); DEBUG(10,("create_pai_buf_v2: sd_type = 0x%x\n", (unsigned int)sd_type )); entry_offset = pai_buf + PAI_V2_ENTRIES_BASE; i = 0; for (ace_list = file_ace_list; ace_list; ace_list = ace_list->next) { uint8_t type_val = (uint8_t)ace_list->owner_type; uint32_t entry_val = get_entry_val(ace_list); SCVAL(entry_offset,0,ace_list->ace_flags); SCVAL(entry_offset,1,type_val); SIVAL(entry_offset,2,entry_val); DEBUG(10,("create_pai_buf_v2: entry %u [0x%x] [0x%x] [0x%x]\n", i, (unsigned int)ace_list->ace_flags, (unsigned int)type_val, (unsigned int)entry_val )); i++; entry_offset += PAI_V2_ENTRY_LENGTH; } for (ace_list = dir_ace_list; ace_list; ace_list = ace_list->next) { uint8_t type_val = (uint8_t)ace_list->owner_type; uint32_t entry_val = get_entry_val(ace_list); SCVAL(entry_offset,0,ace_list->ace_flags); SCVAL(entry_offset,1,type_val); SIVAL(entry_offset,2,entry_val); DEBUG(10,("create_pai_buf_v2: entry %u [0x%x] [0x%x] [0x%x]\n", i, (unsigned int)ace_list->ace_flags, (unsigned int)type_val, (unsigned int)entry_val )); i++; entry_offset += PAI_V2_ENTRY_LENGTH; } return pai_buf; } /************************************************************************ Store the user.SAMBA_PAI attribute on disk. ************************************************************************/ static void store_inheritance_attributes(files_struct *fsp, canon_ace *file_ace_list, canon_ace *dir_ace_list, uint16_t sd_type) { int ret; size_t store_size; char *pai_buf; if (!lp_map_acl_inherit(SNUM(fsp->conn))) { return; } pai_buf = create_pai_buf_v2(file_ace_list, dir_ace_list, sd_type, &store_size); if (fsp->fh->fd != -1) { ret = SMB_VFS_FSETXATTR(fsp, SAMBA_POSIX_INHERITANCE_EA_NAME, pai_buf, store_size, 0); } else { ret = SMB_VFS_SETXATTR(fsp->conn, fsp->fsp_name->base_name, SAMBA_POSIX_INHERITANCE_EA_NAME, pai_buf, store_size, 0); } SAFE_FREE(pai_buf); DEBUG(10,("store_inheritance_attribute: type 0x%x for file %s\n", (unsigned int)sd_type, fsp_str_dbg(fsp))); if (ret == -1 && !no_acl_syscall_error(errno)) { DEBUG(1,("store_inheritance_attribute: Error %s\n", strerror(errno) )); } } /************************************************************************ Delete the in memory inheritance info. ************************************************************************/ static void free_inherited_info(struct pai_val *pal) { if (pal) { struct pai_entry *paie, *paie_next; for (paie = pal->entry_list; paie; paie = paie_next) { paie_next = paie->next; SAFE_FREE(paie); } for (paie = pal->def_entry_list; paie; paie = paie_next) { paie_next = paie->next; SAFE_FREE(paie); } SAFE_FREE(pal); } } /************************************************************************ Get any stored ACE flags. ************************************************************************/ static uint16_t get_pai_flags(struct pai_val *pal, canon_ace *ace_entry, bool default_ace) { struct pai_entry *paie; if (!pal) { return 0; } /* If the entry exists it is inherited. */ for (paie = (default_ace ? pal->def_entry_list : pal->entry_list); paie; paie = paie->next) { if (ace_entry->owner_type == paie->owner_type && get_entry_val(ace_entry) == get_pai_entry_val(paie)) return paie->ace_flags; } return 0; } /************************************************************************ Ensure an attribute just read is valid - v1. ************************************************************************/ static bool check_pai_ok_v1(const char *pai_buf, size_t pai_buf_data_size) { uint16 num_entries; uint16 num_def_entries; if (pai_buf_data_size < PAI_V1_ENTRIES_BASE) { /* Corrupted - too small. */ return false; } if (CVAL(pai_buf,PAI_VERSION_OFFSET) != PAI_V1_VERSION) { return false; } num_entries = SVAL(pai_buf,PAI_V1_NUM_ENTRIES_OFFSET); num_def_entries = SVAL(pai_buf,PAI_V1_NUM_DEFAULT_ENTRIES_OFFSET); /* Check the entry lists match. */ /* Each entry is 5 bytes (type plus 4 bytes of uid or gid). */ if (((num_entries + num_def_entries)*PAI_V1_ENTRY_LENGTH) + PAI_V1_ENTRIES_BASE != pai_buf_data_size) { return false; } return true; } /************************************************************************ Ensure an attribute just read is valid - v2. ************************************************************************/ static bool check_pai_ok_v2(const char *pai_buf, size_t pai_buf_data_size) { uint16 num_entries; uint16 num_def_entries; if (pai_buf_data_size < PAI_V2_ENTRIES_BASE) { /* Corrupted - too small. */ return false; } if (CVAL(pai_buf,PAI_VERSION_OFFSET) != PAI_V2_VERSION) { return false; } num_entries = SVAL(pai_buf,PAI_V2_NUM_ENTRIES_OFFSET); num_def_entries = SVAL(pai_buf,PAI_V2_NUM_DEFAULT_ENTRIES_OFFSET); /* Check the entry lists match. */ /* Each entry is 6 bytes (flags + type + 4 bytes of uid or gid). */ if (((num_entries + num_def_entries)*PAI_V2_ENTRY_LENGTH) + PAI_V2_ENTRIES_BASE != pai_buf_data_size) { return false; } return true; } /************************************************************************ Decode the owner. ************************************************************************/ static bool get_pai_owner_type(struct pai_entry *paie, const char *entry_offset) { paie->owner_type = (enum ace_owner)CVAL(entry_offset,0); switch( paie->owner_type) { case UID_ACE: paie->unix_ug.uid = (uid_t)IVAL(entry_offset,1); DEBUG(10,("get_pai_owner_type: uid = %u\n", (unsigned int)paie->unix_ug.uid )); break; case GID_ACE: paie->unix_ug.gid = (gid_t)IVAL(entry_offset,1); DEBUG(10,("get_pai_owner_type: gid = %u\n", (unsigned int)paie->unix_ug.gid )); break; case WORLD_ACE: paie->unix_ug.world = -1; DEBUG(10,("get_pai_owner_type: world ace\n")); break; default: DEBUG(10,("get_pai_owner_type: unknown type %u\n", (unsigned int)paie->owner_type )); return false; } return true; } /************************************************************************ Process v2 entries. ************************************************************************/ static const char *create_pai_v1_entries(struct pai_val *paiv, const char *entry_offset, bool def_entry) { int i; for (i = 0; i < paiv->num_entries; i++) { struct pai_entry *paie = SMB_MALLOC_P(struct pai_entry); if (!paie) { return NULL; } paie->ace_flags = SEC_ACE_FLAG_INHERITED_ACE; if (!get_pai_owner_type(paie, entry_offset)) { return NULL; } if (!def_entry) { DLIST_ADD(paiv->entry_list, paie); } else { DLIST_ADD(paiv->def_entry_list, paie); } entry_offset += PAI_V1_ENTRY_LENGTH; } return entry_offset; } /************************************************************************ Convert to in-memory format from version 1. ************************************************************************/ static struct pai_val *create_pai_val_v1(const char *buf, size_t size) { const char *entry_offset; struct pai_val *paiv = NULL; if (!check_pai_ok_v1(buf, size)) { return NULL; } paiv = SMB_MALLOC_P(struct pai_val); if (!paiv) { return NULL; } memset(paiv, '\0', sizeof(struct pai_val)); paiv->sd_type = (CVAL(buf,PAI_V1_FLAG_OFFSET) == PAI_V1_ACL_FLAG_PROTECTED) ? SEC_DESC_DACL_PROTECTED : 0; paiv->num_entries = SVAL(buf,PAI_V1_NUM_ENTRIES_OFFSET); paiv->num_def_entries = SVAL(buf,PAI_V1_NUM_DEFAULT_ENTRIES_OFFSET); entry_offset = buf + PAI_V1_ENTRIES_BASE; DEBUG(10,("create_pai_val: num_entries = %u, num_def_entries = %u\n", paiv->num_entries, paiv->num_def_entries )); entry_offset = create_pai_v1_entries(paiv, entry_offset, false); if (entry_offset == NULL) { free_inherited_info(paiv); return NULL; } entry_offset = create_pai_v1_entries(paiv, entry_offset, true); if (entry_offset == NULL) { free_inherited_info(paiv); return NULL; } return paiv; } /************************************************************************ Process v2 entries. ************************************************************************/ static const char *create_pai_v2_entries(struct pai_val *paiv, unsigned int num_entries, const char *entry_offset, bool def_entry) { unsigned int i; for (i = 0; i < num_entries; i++) { struct pai_entry *paie = SMB_MALLOC_P(struct pai_entry); if (!paie) { return NULL; } paie->ace_flags = CVAL(entry_offset,0); if (!get_pai_owner_type(paie, entry_offset+1)) { return NULL; } if (!def_entry) { DLIST_ADD(paiv->entry_list, paie); } else { DLIST_ADD(paiv->def_entry_list, paie); } entry_offset += PAI_V2_ENTRY_LENGTH; } return entry_offset; } /************************************************************************ Convert to in-memory format from version 2. ************************************************************************/ static struct pai_val *create_pai_val_v2(const char *buf, size_t size) { const char *entry_offset; struct pai_val *paiv = NULL; if (!check_pai_ok_v2(buf, size)) { return NULL; } paiv = SMB_MALLOC_P(struct pai_val); if (!paiv) { return NULL; } memset(paiv, '\0', sizeof(struct pai_val)); paiv->sd_type = SVAL(buf,PAI_V2_TYPE_OFFSET); paiv->num_entries = SVAL(buf,PAI_V2_NUM_ENTRIES_OFFSET); paiv->num_def_entries = SVAL(buf,PAI_V2_NUM_DEFAULT_ENTRIES_OFFSET); entry_offset = buf + PAI_V2_ENTRIES_BASE; DEBUG(10,("create_pai_val_v2: sd_type = 0x%x num_entries = %u, num_def_entries = %u\n", (unsigned int)paiv->sd_type, paiv->num_entries, paiv->num_def_entries )); entry_offset = create_pai_v2_entries(paiv, paiv->num_entries, entry_offset, false); if (entry_offset == NULL) { free_inherited_info(paiv); return NULL; } entry_offset = create_pai_v2_entries(paiv, paiv->num_def_entries, entry_offset, true); if (entry_offset == NULL) { free_inherited_info(paiv); return NULL; } return paiv; } /************************************************************************ Convert to in-memory format - from either version 1 or 2. ************************************************************************/ static struct pai_val *create_pai_val(const char *buf, size_t size) { if (size < 1) { return NULL; } if (CVAL(buf,PAI_VERSION_OFFSET) == PAI_V1_VERSION) { return create_pai_val_v1(buf, size); } else if (CVAL(buf,PAI_VERSION_OFFSET) == PAI_V2_VERSION) { return create_pai_val_v2(buf, size); } else { return NULL; } } /************************************************************************ Load the user.SAMBA_PAI attribute. ************************************************************************/ static struct pai_val *fload_inherited_info(files_struct *fsp) { char *pai_buf; size_t pai_buf_size = 1024; struct pai_val *paiv = NULL; ssize_t ret; if (!lp_map_acl_inherit(SNUM(fsp->conn))) { return NULL; } if ((pai_buf = (char *)SMB_MALLOC(pai_buf_size)) == NULL) { return NULL; } do { if (fsp->fh->fd != -1) { ret = SMB_VFS_FGETXATTR(fsp, SAMBA_POSIX_INHERITANCE_EA_NAME, pai_buf, pai_buf_size); } else { ret = SMB_VFS_GETXATTR(fsp->conn, fsp->fsp_name->base_name, SAMBA_POSIX_INHERITANCE_EA_NAME, pai_buf, pai_buf_size); } if (ret == -1) { if (errno != ERANGE) { break; } /* Buffer too small - enlarge it. */ pai_buf_size *= 2; SAFE_FREE(pai_buf); if (pai_buf_size > 1024*1024) { return NULL; /* Limit malloc to 1mb. */ } if ((pai_buf = (char *)SMB_MALLOC(pai_buf_size)) == NULL) return NULL; } } while (ret == -1); DEBUG(10,("load_inherited_info: ret = %lu for file %s\n", (unsigned long)ret, fsp_str_dbg(fsp))); if (ret == -1) { /* No attribute or not supported. */ #if defined(ENOATTR) if (errno != ENOATTR) DEBUG(10,("load_inherited_info: Error %s\n", strerror(errno) )); #else if (errno != ENOSYS) DEBUG(10,("load_inherited_info: Error %s\n", strerror(errno) )); #endif SAFE_FREE(pai_buf); return NULL; } paiv = create_pai_val(pai_buf, ret); if (paiv) { DEBUG(10,("load_inherited_info: ACL type is 0x%x for file %s\n", (unsigned int)paiv->sd_type, fsp_str_dbg(fsp))); } SAFE_FREE(pai_buf); return paiv; } /************************************************************************ Load the user.SAMBA_PAI attribute. ************************************************************************/ static struct pai_val *load_inherited_info(const struct connection_struct *conn, const char *fname) { char *pai_buf; size_t pai_buf_size = 1024; struct pai_val *paiv = NULL; ssize_t ret; if (!lp_map_acl_inherit(SNUM(conn))) { return NULL; } if ((pai_buf = (char *)SMB_MALLOC(pai_buf_size)) == NULL) { return NULL; } do { ret = SMB_VFS_GETXATTR(conn, fname, SAMBA_POSIX_INHERITANCE_EA_NAME, pai_buf, pai_buf_size); if (ret == -1) { if (errno != ERANGE) { break; } /* Buffer too small - enlarge it. */ pai_buf_size *= 2; SAFE_FREE(pai_buf); if (pai_buf_size > 1024*1024) { return NULL; /* Limit malloc to 1mb. */ } if ((pai_buf = (char *)SMB_MALLOC(pai_buf_size)) == NULL) return NULL; } } while (ret == -1); DEBUG(10,("load_inherited_info: ret = %lu for file %s\n", (unsigned long)ret, fname)); if (ret == -1) { /* No attribute or not supported. */ #if defined(ENOATTR) if (errno != ENOATTR) DEBUG(10,("load_inherited_info: Error %s\n", strerror(errno) )); #else if (errno != ENOSYS) DEBUG(10,("load_inherited_info: Error %s\n", strerror(errno) )); #endif SAFE_FREE(pai_buf); return NULL; } paiv = create_pai_val(pai_buf, ret); if (paiv) { DEBUG(10,("load_inherited_info: ACL type 0x%x for file %s\n", (unsigned int)paiv->sd_type, fname)); } SAFE_FREE(pai_buf); return paiv; } /**************************************************************************** Functions to manipulate the internal ACE format. ****************************************************************************/ /**************************************************************************** Count a linked list of canonical ACE entries. ****************************************************************************/ static size_t count_canon_ace_list( canon_ace *l_head ) { size_t count = 0; canon_ace *ace; for (ace = l_head; ace; ace = ace->next) count++; return count; } /**************************************************************************** Free a linked list of canonical ACE entries. ****************************************************************************/ static void free_canon_ace_list( canon_ace *l_head ) { canon_ace *list, *next; for (list = l_head; list; list = next) { next = list->next; DLIST_REMOVE(l_head, list); SAFE_FREE(list); } } /**************************************************************************** Function to duplicate a canon_ace entry. ****************************************************************************/ static canon_ace *dup_canon_ace( canon_ace *src_ace) { canon_ace *dst_ace = SMB_MALLOC_P(canon_ace); if (dst_ace == NULL) return NULL; *dst_ace = *src_ace; dst_ace->prev = dst_ace->next = NULL; return dst_ace; } /**************************************************************************** Print out a canon ace. ****************************************************************************/ static void print_canon_ace(canon_ace *pace, int num) { dbgtext( "canon_ace index %d. Type = %s ", num, pace->attr == ALLOW_ACE ? "allow" : "deny" ); dbgtext( "SID = %s ", sid_string_dbg(&pace->trustee)); if (pace->owner_type == UID_ACE) { const char *u_name = uidtoname(pace->unix_ug.uid); dbgtext( "uid %u (%s) ", (unsigned int)pace->unix_ug.uid, u_name ); } else if (pace->owner_type == GID_ACE) { char *g_name = gidtoname(pace->unix_ug.gid); dbgtext( "gid %u (%s) ", (unsigned int)pace->unix_ug.gid, g_name ); } else dbgtext( "other "); switch (pace->type) { case SMB_ACL_USER: dbgtext( "SMB_ACL_USER "); break; case SMB_ACL_USER_OBJ: dbgtext( "SMB_ACL_USER_OBJ "); break; case SMB_ACL_GROUP: dbgtext( "SMB_ACL_GROUP "); break; case SMB_ACL_GROUP_OBJ: dbgtext( "SMB_ACL_GROUP_OBJ "); break; case SMB_ACL_OTHER: dbgtext( "SMB_ACL_OTHER "); break; default: dbgtext( "MASK " ); break; } dbgtext( "ace_flags = 0x%x ", (unsigned int)pace->ace_flags); dbgtext( "perms "); dbgtext( "%c", pace->perms & S_IRUSR ? 'r' : '-'); dbgtext( "%c", pace->perms & S_IWUSR ? 'w' : '-'); dbgtext( "%c\n", pace->perms & S_IXUSR ? 'x' : '-'); } /**************************************************************************** Print out a canon ace list. ****************************************************************************/ static void print_canon_ace_list(const char *name, canon_ace *ace_list) { int count = 0; if( DEBUGLVL( 10 )) { dbgtext( "print_canon_ace_list: %s\n", name ); for (;ace_list; ace_list = ace_list->next, count++) print_canon_ace(ace_list, count ); } } /**************************************************************************** Map POSIX ACL perms to canon_ace permissions (a mode_t containing only S_(R|W|X)USR bits). ****************************************************************************/ static mode_t convert_permset_to_mode_t(connection_struct *conn, SMB_ACL_PERMSET_T permset) { mode_t ret = 0; ret |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_READ) ? S_IRUSR : 0); ret |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_WRITE) ? S_IWUSR : 0); ret |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_EXECUTE) ? S_IXUSR : 0); return ret; } /**************************************************************************** Map generic UNIX permissions to canon_ace permissions (a mode_t containing only S_(R|W|X)USR bits). ****************************************************************************/ static mode_t unix_perms_to_acl_perms(mode_t mode, int r_mask, int w_mask, int x_mask) { mode_t ret = 0; if (mode & r_mask) ret |= S_IRUSR; if (mode & w_mask) ret |= S_IWUSR; if (mode & x_mask) ret |= S_IXUSR; return ret; } /**************************************************************************** Map canon_ace permissions (a mode_t containing only S_(R|W|X)USR bits) to an SMB_ACL_PERMSET_T. ****************************************************************************/ static int map_acl_perms_to_permset(connection_struct *conn, mode_t mode, SMB_ACL_PERMSET_T *p_permset) { if (SMB_VFS_SYS_ACL_CLEAR_PERMS(conn, *p_permset) == -1) return -1; if (mode & S_IRUSR) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_READ) == -1) return -1; } if (mode & S_IWUSR) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_WRITE) == -1) return -1; } if (mode & S_IXUSR) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_EXECUTE) == -1) return -1; } return 0; } /**************************************************************************** Function to create owner and group SIDs from a SMB_STRUCT_STAT. ****************************************************************************/ void create_file_sids(const SMB_STRUCT_STAT *psbuf, struct dom_sid *powner_sid, struct dom_sid *pgroup_sid) { uid_to_sid( powner_sid, psbuf->st_ex_uid ); gid_to_sid( pgroup_sid, psbuf->st_ex_gid ); } /**************************************************************************** Merge aces with a common sid - if both are allow or deny, OR the permissions together and delete the second one. If the first is deny, mask the permissions off and delete the allow if the permissions become zero, delete the deny if the permissions are non zero. ****************************************************************************/ static void merge_aces( canon_ace **pp_list_head, bool dir_acl) { canon_ace *l_head = *pp_list_head; canon_ace *curr_ace_outer; canon_ace *curr_ace_outer_next; /* * First, merge allow entries with identical SIDs, and deny entries * with identical SIDs. */ for (curr_ace_outer = l_head; curr_ace_outer; curr_ace_outer = curr_ace_outer_next) { canon_ace *curr_ace; canon_ace *curr_ace_next; curr_ace_outer_next = curr_ace_outer->next; /* Save the link in case we delete. */ for (curr_ace = curr_ace_outer->next; curr_ace; curr_ace = curr_ace_next) { bool can_merge = false; curr_ace_next = curr_ace->next; /* Save the link in case of delete. */ /* For file ACLs we can merge if the SIDs and ALLOW/DENY * types are the same. For directory acls we must also * ensure the POSIX ACL types are the same. */ if (!dir_acl) { can_merge = (dom_sid_equal(&curr_ace->trustee, &curr_ace_outer->trustee) && (curr_ace->attr == curr_ace_outer->attr)); } else { can_merge = (dom_sid_equal(&curr_ace->trustee, &curr_ace_outer->trustee) && (curr_ace->type == curr_ace_outer->type) && (curr_ace->attr == curr_ace_outer->attr)); } if (can_merge) { if( DEBUGLVL( 10 )) { dbgtext("merge_aces: Merging ACE's\n"); print_canon_ace( curr_ace_outer, 0); print_canon_ace( curr_ace, 0); } /* Merge two allow or two deny ACE's. */ /* Theoretically we shouldn't merge a dir ACE if * one ACE has the CI flag set, and the other * ACE has the OI flag set, but this is rare * enough we can ignore it. */ curr_ace_outer->perms |= curr_ace->perms; curr_ace_outer->ace_flags |= curr_ace->ace_flags; DLIST_REMOVE(l_head, curr_ace); SAFE_FREE(curr_ace); curr_ace_outer_next = curr_ace_outer->next; /* We may have deleted the link. */ } } } /* * Now go through and mask off allow permissions with deny permissions. * We can delete either the allow or deny here as we know that each SID * appears only once in the list. */ for (curr_ace_outer = l_head; curr_ace_outer; curr_ace_outer = curr_ace_outer_next) { canon_ace *curr_ace; canon_ace *curr_ace_next; curr_ace_outer_next = curr_ace_outer->next; /* Save the link in case we delete. */ for (curr_ace = curr_ace_outer->next; curr_ace; curr_ace = curr_ace_next) { curr_ace_next = curr_ace->next; /* Save the link in case of delete. */ /* * Subtract ACE's with different entries. Due to the ordering constraints * we've put on the ACL, we know the deny must be the first one. */ if (dom_sid_equal(&curr_ace->trustee, &curr_ace_outer->trustee) && (curr_ace_outer->attr == DENY_ACE) && (curr_ace->attr == ALLOW_ACE)) { if( DEBUGLVL( 10 )) { dbgtext("merge_aces: Masking ACE's\n"); print_canon_ace( curr_ace_outer, 0); print_canon_ace( curr_ace, 0); } curr_ace->perms &= ~curr_ace_outer->perms; if (curr_ace->perms == 0) { /* * The deny overrides the allow. Remove the allow. */ DLIST_REMOVE(l_head, curr_ace); SAFE_FREE(curr_ace); curr_ace_outer_next = curr_ace_outer->next; /* We may have deleted the link. */ } else { /* * Even after removing permissions, there * are still allow permissions - delete the deny. * It is safe to delete the deny here, * as we are guarenteed by the deny first * ordering that all the deny entries for * this SID have already been merged into one * before we can get to an allow ace. */ DLIST_REMOVE(l_head, curr_ace_outer); SAFE_FREE(curr_ace_outer); break; } } } /* end for curr_ace */ } /* end for curr_ace_outer */ /* We may have modified the list. */ *pp_list_head = l_head; } /**************************************************************************** Check if we need to return NT4.x compatible ACL entries. ****************************************************************************/ bool nt4_compatible_acls(void) { int compat = lp_acl_compatibility(); if (compat == ACL_COMPAT_AUTO) { enum remote_arch_types ra_type = get_remote_arch(); /* Automatically adapt to client */ return (ra_type <= RA_WINNT); } else return (compat == ACL_COMPAT_WINNT); } /**************************************************************************** Map canon_ace perms to permission bits NT. The attr element is not used here - we only process deny entries on set, not get. Deny entries are implicit on get with ace->perms = 0. ****************************************************************************/ uint32_t map_canon_ace_perms(int snum, enum security_ace_type *pacl_type, mode_t perms, bool directory_ace) { uint32_t nt_mask = 0; *pacl_type = SEC_ACE_TYPE_ACCESS_ALLOWED; if (lp_acl_map_full_control(snum) && ((perms & ALL_ACE_PERMS) == ALL_ACE_PERMS)) { if (directory_ace) { nt_mask = UNIX_DIRECTORY_ACCESS_RWX; } else { nt_mask = (UNIX_ACCESS_RWX & ~DELETE_ACCESS); } } else if ((perms & ALL_ACE_PERMS) == (mode_t)0) { /* * Windows NT refuses to display ACEs with no permissions in them (but * they are perfectly legal with Windows 2000). If the ACE has empty * permissions we cannot use 0, so we use the otherwise unused * WRITE_OWNER permission, which we ignore when we set an ACL. * We abstract this into a #define of UNIX_ACCESS_NONE to allow this * to be changed in the future. */ if (nt4_compatible_acls()) nt_mask = UNIX_ACCESS_NONE; else nt_mask = 0; } else { if (directory_ace) { nt_mask |= ((perms & S_IRUSR) ? UNIX_DIRECTORY_ACCESS_R : 0 ); nt_mask |= ((perms & S_IWUSR) ? UNIX_DIRECTORY_ACCESS_W : 0 ); nt_mask |= ((perms & S_IXUSR) ? UNIX_DIRECTORY_ACCESS_X : 0 ); } else { nt_mask |= ((perms & S_IRUSR) ? UNIX_ACCESS_R : 0 ); nt_mask |= ((perms & S_IWUSR) ? UNIX_ACCESS_W : 0 ); nt_mask |= ((perms & S_IXUSR) ? UNIX_ACCESS_X : 0 ); } } if ((perms & S_IWUSR) && lp_dos_filemode(snum)) { nt_mask |= (SEC_STD_WRITE_DAC|SEC_STD_WRITE_OWNER|DELETE_ACCESS); } DEBUG(10,("map_canon_ace_perms: Mapped (UNIX) %x to (NT) %x\n", (unsigned int)perms, (unsigned int)nt_mask )); return nt_mask; } /**************************************************************************** Map NT perms to a UNIX mode_t. ****************************************************************************/ #define FILE_SPECIFIC_READ_BITS (FILE_READ_DATA|FILE_READ_EA|FILE_READ_ATTRIBUTES) #define FILE_SPECIFIC_WRITE_BITS (FILE_WRITE_DATA|FILE_APPEND_DATA|FILE_WRITE_EA|FILE_WRITE_ATTRIBUTES) #define FILE_SPECIFIC_EXECUTE_BITS (FILE_EXECUTE) static mode_t map_nt_perms( uint32 *mask, int type) { mode_t mode = 0; switch(type) { case S_IRUSR: if((*mask) & GENERIC_ALL_ACCESS) mode = S_IRUSR|S_IWUSR|S_IXUSR; else { mode |= ((*mask) & (GENERIC_READ_ACCESS|FILE_SPECIFIC_READ_BITS)) ? S_IRUSR : 0; mode |= ((*mask) & (GENERIC_WRITE_ACCESS|FILE_SPECIFIC_WRITE_BITS)) ? S_IWUSR : 0; mode |= ((*mask) & (GENERIC_EXECUTE_ACCESS|FILE_SPECIFIC_EXECUTE_BITS)) ? S_IXUSR : 0; } break; case S_IRGRP: if((*mask) & GENERIC_ALL_ACCESS) mode = S_IRGRP|S_IWGRP|S_IXGRP; else { mode |= ((*mask) & (GENERIC_READ_ACCESS|FILE_SPECIFIC_READ_BITS)) ? S_IRGRP : 0; mode |= ((*mask) & (GENERIC_WRITE_ACCESS|FILE_SPECIFIC_WRITE_BITS)) ? S_IWGRP : 0; mode |= ((*mask) & (GENERIC_EXECUTE_ACCESS|FILE_SPECIFIC_EXECUTE_BITS)) ? S_IXGRP : 0; } break; case S_IROTH: if((*mask) & GENERIC_ALL_ACCESS) mode = S_IROTH|S_IWOTH|S_IXOTH; else { mode |= ((*mask) & (GENERIC_READ_ACCESS|FILE_SPECIFIC_READ_BITS)) ? S_IROTH : 0; mode |= ((*mask) & (GENERIC_WRITE_ACCESS|FILE_SPECIFIC_WRITE_BITS)) ? S_IWOTH : 0; mode |= ((*mask) & (GENERIC_EXECUTE_ACCESS|FILE_SPECIFIC_EXECUTE_BITS)) ? S_IXOTH : 0; } break; } return mode; } /**************************************************************************** Unpack a struct security_descriptor into a UNIX owner and group. ****************************************************************************/ NTSTATUS unpack_nt_owners(struct connection_struct *conn, uid_t *puser, gid_t *pgrp, uint32 security_info_sent, const struct security_descriptor *psd) { struct dom_sid owner_sid; struct dom_sid grp_sid; *puser = (uid_t)-1; *pgrp = (gid_t)-1; if(security_info_sent == 0) { DEBUG(0,("unpack_nt_owners: no security info sent !\n")); return NT_STATUS_OK; } /* * Validate the owner and group SID's. */ memset(&owner_sid, '\0', sizeof(owner_sid)); memset(&grp_sid, '\0', sizeof(grp_sid)); DEBUG(5,("unpack_nt_owners: validating owner_sids.\n")); /* * Don't immediately fail if the owner sid cannot be validated. * This may be a group chown only set. */ if (security_info_sent & SECINFO_OWNER) { sid_copy(&owner_sid, psd->owner_sid); if (!sid_to_uid(&owner_sid, puser)) { if (lp_force_unknown_acl_user(SNUM(conn))) { /* this allows take ownership to work * reasonably */ *puser = get_current_uid(conn); } else { DEBUG(3,("unpack_nt_owners: unable to validate" " owner sid for %s\n", sid_string_dbg(&owner_sid))); return NT_STATUS_INVALID_OWNER; } } DEBUG(3,("unpack_nt_owners: owner sid mapped to uid %u\n", (unsigned int)*puser )); } /* * Don't immediately fail if the group sid cannot be validated. * This may be an owner chown only set. */ if (security_info_sent & SECINFO_GROUP) { sid_copy(&grp_sid, psd->group_sid); if (!sid_to_gid( &grp_sid, pgrp)) { if (lp_force_unknown_acl_user(SNUM(conn))) { /* this allows take group ownership to work * reasonably */ *pgrp = get_current_gid(conn); } else { DEBUG(3,("unpack_nt_owners: unable to validate" " group sid.\n")); return NT_STATUS_INVALID_OWNER; } } DEBUG(3,("unpack_nt_owners: group sid mapped to gid %u\n", (unsigned int)*pgrp)); } DEBUG(5,("unpack_nt_owners: owner_sids validated.\n")); return NT_STATUS_OK; } /**************************************************************************** Ensure the enforced permissions for this share apply. ****************************************************************************/ static void apply_default_perms(const struct share_params *params, const bool is_directory, canon_ace *pace, mode_t type) { mode_t and_bits = (mode_t)0; mode_t or_bits = (mode_t)0; /* Get the initial bits to apply. */ if (is_directory) { and_bits = lp_dir_security_mask(params->service); or_bits = lp_force_dir_security_mode(params->service); } else { and_bits = lp_security_mask(params->service); or_bits = lp_force_security_mode(params->service); } /* Now bounce them into the S_USR space. */ switch(type) { case S_IRUSR: /* Ensure owner has read access. */ pace->perms |= S_IRUSR; if (is_directory) pace->perms |= (S_IWUSR|S_IXUSR); and_bits = unix_perms_to_acl_perms(and_bits, S_IRUSR, S_IWUSR, S_IXUSR); or_bits = unix_perms_to_acl_perms(or_bits, S_IRUSR, S_IWUSR, S_IXUSR); break; case S_IRGRP: and_bits = unix_perms_to_acl_perms(and_bits, S_IRGRP, S_IWGRP, S_IXGRP); or_bits = unix_perms_to_acl_perms(or_bits, S_IRGRP, S_IWGRP, S_IXGRP); break; case S_IROTH: and_bits = unix_perms_to_acl_perms(and_bits, S_IROTH, S_IWOTH, S_IXOTH); or_bits = unix_perms_to_acl_perms(or_bits, S_IROTH, S_IWOTH, S_IXOTH); break; } pace->perms = ((pace->perms & and_bits)|or_bits); } /**************************************************************************** Check if a given uid/SID is in a group gid/SID. This is probably very expensive and will need optimisation. A *lot* of optimisation :-). JRA. ****************************************************************************/ static bool uid_entry_in_group(connection_struct *conn, canon_ace *uid_ace, canon_ace *group_ace ) { const char *u_name = NULL; /* "Everyone" always matches every uid. */ if (dom_sid_equal(&group_ace->trustee, &global_sid_World)) return True; /* * if it's the current user, we already have the unix token * and don't need to do the complex user_in_group_sid() call */ if (uid_ace->unix_ug.uid == get_current_uid(conn)) { const UNIX_USER_TOKEN *curr_utok = NULL; size_t i; if (group_ace->unix_ug.gid == get_current_gid(conn)) { return True; } curr_utok = get_current_utok(conn); for (i=0; i < curr_utok->ngroups; i++) { if (group_ace->unix_ug.gid == curr_utok->groups[i]) { return True; } } } /* u_name talloc'ed off tos. */ u_name = uidtoname(uid_ace->unix_ug.uid); if (!u_name) { return False; } /* * user_in_group_sid() uses create_token_from_username() * which creates an artificial NT token given just a username, * so this is not reliable for users from foreign domains * exported by winbindd! */ return user_in_group_sid(u_name, &group_ace->trustee); } /**************************************************************************** A well formed POSIX file or default ACL has at least 3 entries, a SMB_ACL_USER_OBJ, SMB_ACL_GROUP_OBJ, SMB_ACL_OTHER_OBJ. In addition, the owner must always have at least read access. When using this call on get_acl, the pst struct is valid and contains the mode of the file. When using this call on set_acl, the pst struct has been modified to have a mode containing the default for this file or directory type. ****************************************************************************/ static bool ensure_canon_entry_valid(connection_struct *conn, canon_ace **pp_ace, const struct share_params *params, const bool is_directory, const struct dom_sid *pfile_owner_sid, const struct dom_sid *pfile_grp_sid, const SMB_STRUCT_STAT *pst, bool setting_acl) { canon_ace *pace; bool got_user = False; bool got_grp = False; bool got_other = False; canon_ace *pace_other = NULL; for (pace = *pp_ace; pace; pace = pace->next) { if (pace->type == SMB_ACL_USER_OBJ) { if (setting_acl) apply_default_perms(params, is_directory, pace, S_IRUSR); got_user = True; } else if (pace->type == SMB_ACL_GROUP_OBJ) { /* * Ensure create mask/force create mode is respected on set. */ if (setting_acl) apply_default_perms(params, is_directory, pace, S_IRGRP); got_grp = True; } else if (pace->type == SMB_ACL_OTHER) { /* * Ensure create mask/force create mode is respected on set. */ if (setting_acl) apply_default_perms(params, is_directory, pace, S_IROTH); got_other = True; pace_other = pace; } } if (!got_user) { if ((pace = SMB_MALLOC_P(canon_ace)) == NULL) { DEBUG(0,("ensure_canon_entry_valid: malloc fail.\n")); return False; } ZERO_STRUCTP(pace); pace->type = SMB_ACL_USER_OBJ; pace->owner_type = UID_ACE; pace->unix_ug.uid = pst->st_ex_uid; pace->trustee = *pfile_owner_sid; pace->attr = ALLOW_ACE; if (setting_acl) { /* See if the owning user is in any of the other groups in the ACE. If so, OR in the permissions from that group. */ bool group_matched = False; canon_ace *pace_iter; for (pace_iter = *pp_ace; pace_iter; pace_iter = pace_iter->next) { if (pace_iter->type == SMB_ACL_GROUP_OBJ || pace_iter->type == SMB_ACL_GROUP) { if (uid_entry_in_group(conn, pace, pace_iter)) { pace->perms |= pace_iter->perms; group_matched = True; } } } /* If we only got an "everyone" perm, just use that. */ if (!group_matched) { if (got_other) pace->perms = pace_other->perms; else pace->perms = 0; } apply_default_perms(params, is_directory, pace, S_IRUSR); } else { pace->perms = unix_perms_to_acl_perms(pst->st_ex_mode, S_IRUSR, S_IWUSR, S_IXUSR); } DLIST_ADD(*pp_ace, pace); } if (!got_grp) { if ((pace = SMB_MALLOC_P(canon_ace)) == NULL) { DEBUG(0,("ensure_canon_entry_valid: malloc fail.\n")); return False; } ZERO_STRUCTP(pace); pace->type = SMB_ACL_GROUP_OBJ; pace->owner_type = GID_ACE; pace->unix_ug.uid = pst->st_ex_gid; pace->trustee = *pfile_grp_sid; pace->attr = ALLOW_ACE; if (setting_acl) { /* If we only got an "everyone" perm, just use that. */ if (got_other) pace->perms = pace_other->perms; else pace->perms = 0; apply_default_perms(params, is_directory, pace, S_IRGRP); } else { pace->perms = unix_perms_to_acl_perms(pst->st_ex_mode, S_IRGRP, S_IWGRP, S_IXGRP); } DLIST_ADD(*pp_ace, pace); } if (!got_other) { if ((pace = SMB_MALLOC_P(canon_ace)) == NULL) { DEBUG(0,("ensure_canon_entry_valid: malloc fail.\n")); return False; } ZERO_STRUCTP(pace); pace->type = SMB_ACL_OTHER; pace->owner_type = WORLD_ACE; pace->unix_ug.world = -1; pace->trustee = global_sid_World; pace->attr = ALLOW_ACE; if (setting_acl) { pace->perms = 0; apply_default_perms(params, is_directory, pace, S_IROTH); } else pace->perms = unix_perms_to_acl_perms(pst->st_ex_mode, S_IROTH, S_IWOTH, S_IXOTH); DLIST_ADD(*pp_ace, pace); } return True; } /**************************************************************************** Check if a POSIX ACL has the required SMB_ACL_USER_OBJ and SMB_ACL_GROUP_OBJ entries. If it does not have them, check if there are any entries where the trustee is the file owner or the owning group, and map these to SMB_ACL_USER_OBJ and SMB_ACL_GROUP_OBJ. ****************************************************************************/ static void check_owning_objs(canon_ace *ace, struct dom_sid *pfile_owner_sid, struct dom_sid *pfile_grp_sid) { bool got_user_obj, got_group_obj; canon_ace *current_ace; int i, entries; entries = count_canon_ace_list(ace); got_user_obj = False; got_group_obj = False; for (i=0, current_ace = ace; i < entries; i++, current_ace = current_ace->next) { if (current_ace->type == SMB_ACL_USER_OBJ) got_user_obj = True; else if (current_ace->type == SMB_ACL_GROUP_OBJ) got_group_obj = True; } if (got_user_obj && got_group_obj) { DEBUG(10,("check_owning_objs: ACL had owning user/group entries.\n")); return; } for (i=0, current_ace = ace; i < entries; i++, current_ace = current_ace->next) { if (!got_user_obj && current_ace->owner_type == UID_ACE && dom_sid_equal(¤t_ace->trustee, pfile_owner_sid)) { current_ace->type = SMB_ACL_USER_OBJ; got_user_obj = True; } if (!got_group_obj && current_ace->owner_type == GID_ACE && dom_sid_equal(¤t_ace->trustee, pfile_grp_sid)) { current_ace->type = SMB_ACL_GROUP_OBJ; got_group_obj = True; } } if (!got_user_obj) DEBUG(10,("check_owning_objs: ACL is missing an owner entry.\n")); if (!got_group_obj) DEBUG(10,("check_owning_objs: ACL is missing an owning group entry.\n")); } /**************************************************************************** If an ACE entry is SMB_ACL_USER_OBJ and not CREATOR_OWNER, map to SMB_ACL_USER. If an ACE entry is SMB_ACL_GROUP_OBJ and not CREATOR_GROUP, map to SMB_ACL_GROUP ****************************************************************************/ static bool dup_owning_ace(canon_ace *dir_ace, canon_ace *ace) { /* dir ace must be followings. SMB_ACL_USER_OBJ : trustee(CREATOR_OWNER) -> Posix ACL d:u::perm SMB_ACL_USER : not trustee -> Posix ACL u:user:perm SMB_ACL_USER_OBJ : trustee -> convert to SMB_ACL_USER : trustee Posix ACL u:trustee:perm SMB_ACL_GROUP_OBJ: trustee(CREATOR_GROUP) -> Posix ACL d:g::perm SMB_ACL_GROUP : not trustee -> Posix ACL g:group:perm SMB_ACL_GROUP_OBJ: trustee -> convert to SMB_ACL_GROUP : trustee Posix ACL g:trustee:perm */ if (ace->type == SMB_ACL_USER_OBJ && !(dom_sid_equal(&ace->trustee, &global_sid_Creator_Owner))) { canon_ace *dup_ace = dup_canon_ace(ace); if (dup_ace == NULL) { return false; } dup_ace->type = SMB_ACL_USER; DLIST_ADD_END(dir_ace, dup_ace, canon_ace *); } if (ace->type == SMB_ACL_GROUP_OBJ && !(dom_sid_equal(&ace->trustee, &global_sid_Creator_Group))) { canon_ace *dup_ace = dup_canon_ace(ace); if (dup_ace == NULL) { return false; } dup_ace->type = SMB_ACL_GROUP; DLIST_ADD_END(dir_ace, dup_ace, canon_ace *); } return true; } /**************************************************************************** Unpack a struct security_descriptor into two canonical ace lists. ****************************************************************************/ static bool create_canon_ace_lists(files_struct *fsp, const SMB_STRUCT_STAT *pst, struct dom_sid *pfile_owner_sid, struct dom_sid *pfile_grp_sid, canon_ace **ppfile_ace, canon_ace **ppdir_ace, const struct security_acl *dacl) { bool all_aces_are_inherit_only = (fsp->is_directory ? True : False); canon_ace *file_ace = NULL; canon_ace *dir_ace = NULL; canon_ace *current_ace = NULL; bool got_dir_allow = False; bool got_file_allow = False; int i, j; *ppfile_ace = NULL; *ppdir_ace = NULL; /* * Convert the incoming ACL into a more regular form. */ for(i = 0; i < dacl->num_aces; i++) { struct security_ace *psa = &dacl->aces[i]; if((psa->type != SEC_ACE_TYPE_ACCESS_ALLOWED) && (psa->type != SEC_ACE_TYPE_ACCESS_DENIED)) { DEBUG(3,("create_canon_ace_lists: unable to set anything but an ALLOW or DENY ACE.\n")); return False; } if (nt4_compatible_acls()) { /* * The security mask may be UNIX_ACCESS_NONE which should map into * no permissions (we overload the WRITE_OWNER bit for this) or it * should be one of the ALL/EXECUTE/READ/WRITE bits. Arrange for this * to be so. Any other bits override the UNIX_ACCESS_NONE bit. */ /* * Convert GENERIC bits to specific bits. */ se_map_generic(&psa->access_mask, &file_generic_mapping); psa->access_mask &= (UNIX_ACCESS_NONE|FILE_ALL_ACCESS); if(psa->access_mask != UNIX_ACCESS_NONE) psa->access_mask &= ~UNIX_ACCESS_NONE; } } /* * Deal with the fact that NT 4.x re-writes the canonical format * that we return for default ACLs. If a directory ACE is identical * to a inherited directory ACE then NT changes the bits so that the * first ACE is set to OI|IO and the second ACE for this SID is set * to CI. We need to repair this. JRA. */ for(i = 0; i < dacl->num_aces; i++) { struct security_ace *psa1 = &dacl->aces[i]; for (j = i + 1; j < dacl->num_aces; j++) { struct security_ace *psa2 = &dacl->aces[j]; if (psa1->access_mask != psa2->access_mask) continue; if (!dom_sid_equal(&psa1->trustee, &psa2->trustee)) continue; /* * Ok - permission bits and SIDs are equal. * Check if flags were re-written. */ if (psa1->flags & SEC_ACE_FLAG_INHERIT_ONLY) { psa1->flags |= (psa2->flags & (SEC_ACE_FLAG_CONTAINER_INHERIT|SEC_ACE_FLAG_OBJECT_INHERIT)); psa2->flags &= ~(SEC_ACE_FLAG_CONTAINER_INHERIT|SEC_ACE_FLAG_OBJECT_INHERIT); } else if (psa2->flags & SEC_ACE_FLAG_INHERIT_ONLY) { psa2->flags |= (psa1->flags & (SEC_ACE_FLAG_CONTAINER_INHERIT|SEC_ACE_FLAG_OBJECT_INHERIT)); psa1->flags &= ~(SEC_ACE_FLAG_CONTAINER_INHERIT|SEC_ACE_FLAG_OBJECT_INHERIT); } } } for(i = 0; i < dacl->num_aces; i++) { struct security_ace *psa = &dacl->aces[i]; /* * Create a canon_ace entry representing this NT DACL ACE. */ if ((current_ace = SMB_MALLOC_P(canon_ace)) == NULL) { free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); DEBUG(0,("create_canon_ace_lists: malloc fail.\n")); return False; } ZERO_STRUCTP(current_ace); sid_copy(¤t_ace->trustee, &psa->trustee); /* * Try and work out if the SID is a user or group * as we need to flag these differently for POSIX. * Note what kind of a POSIX ACL this should map to. */ if( dom_sid_equal(¤t_ace->trustee, &global_sid_World)) { current_ace->owner_type = WORLD_ACE; current_ace->unix_ug.world = -1; current_ace->type = SMB_ACL_OTHER; } else if (dom_sid_equal(¤t_ace->trustee, &global_sid_Creator_Owner)) { current_ace->owner_type = UID_ACE; current_ace->unix_ug.uid = pst->st_ex_uid; current_ace->type = SMB_ACL_USER_OBJ; /* * The Creator Owner entry only specifies inheritable permissions, * never access permissions. WinNT doesn't always set the ACE to * INHERIT_ONLY, though. */ psa->flags |= SEC_ACE_FLAG_INHERIT_ONLY; } else if (dom_sid_equal(¤t_ace->trustee, &global_sid_Creator_Group)) { current_ace->owner_type = GID_ACE; current_ace->unix_ug.gid = pst->st_ex_gid; current_ace->type = SMB_ACL_GROUP_OBJ; /* * The Creator Group entry only specifies inheritable permissions, * never access permissions. WinNT doesn't always set the ACE to * INHERIT_ONLY, though. */ psa->flags |= SEC_ACE_FLAG_INHERIT_ONLY; } else if (sid_to_uid( ¤t_ace->trustee, ¤t_ace->unix_ug.uid)) { current_ace->owner_type = UID_ACE; /* If it's the owning user, this is a user_obj, not * a user. */ if (current_ace->unix_ug.uid == pst->st_ex_uid) { current_ace->type = SMB_ACL_USER_OBJ; } else { current_ace->type = SMB_ACL_USER; } } else if (sid_to_gid( ¤t_ace->trustee, ¤t_ace->unix_ug.gid)) { current_ace->owner_type = GID_ACE; /* If it's the primary group, this is a group_obj, not * a group. */ if (current_ace->unix_ug.gid == pst->st_ex_gid) { current_ace->type = SMB_ACL_GROUP_OBJ; } else { current_ace->type = SMB_ACL_GROUP; } } else { /* * Silently ignore map failures in non-mappable SIDs (NT Authority, BUILTIN etc). */ if (non_mappable_sid(&psa->trustee)) { DEBUG(10, ("create_canon_ace_lists: ignoring " "non-mappable SID %s\n", sid_string_dbg(&psa->trustee))); SAFE_FREE(current_ace); continue; } free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); DEBUG(0, ("create_canon_ace_lists: unable to map SID " "%s to uid or gid.\n", sid_string_dbg(¤t_ace->trustee))); SAFE_FREE(current_ace); return False; } /* * Map the given NT permissions into a UNIX mode_t containing only * S_I(R|W|X)USR bits. */ current_ace->perms |= map_nt_perms( &psa->access_mask, S_IRUSR); current_ace->attr = (psa->type == SEC_ACE_TYPE_ACCESS_ALLOWED) ? ALLOW_ACE : DENY_ACE; /* Store the ace_flag. */ current_ace->ace_flags = psa->flags; /* * Now add the created ace to either the file list, the directory * list, or both. We *MUST* preserve the order here (hence we use * DLIST_ADD_END) as NT ACLs are order dependent. */ if (fsp->is_directory) { /* * We can only add to the default POSIX ACE list if the ACE is * designed to be inherited by both files and directories. */ if ((psa->flags & (SEC_ACE_FLAG_OBJECT_INHERIT|SEC_ACE_FLAG_CONTAINER_INHERIT)) == (SEC_ACE_FLAG_OBJECT_INHERIT|SEC_ACE_FLAG_CONTAINER_INHERIT)) { DLIST_ADD_END(dir_ace, current_ace, canon_ace *); /* * Note if this was an allow ace. We can't process * any further deny ace's after this. */ if (current_ace->attr == ALLOW_ACE) got_dir_allow = True; if ((current_ace->attr == DENY_ACE) && got_dir_allow) { DEBUG(0,("create_canon_ace_lists: " "malformed ACL in " "inheritable ACL! Deny entry " "after Allow entry. Failing " "to set on file %s.\n", fsp_str_dbg(fsp))); free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return False; } if( DEBUGLVL( 10 )) { dbgtext("create_canon_ace_lists: adding dir ACL:\n"); print_canon_ace( current_ace, 0); } /* * We have a lossy mapping: directory ACE entries * CREATOR_OWNER ------\ * (map to) +---> SMB_ACL_USER_OBJ * owning sid ------/ * * CREATOR_GROUP ------\ * (map to) +---> SMB_ACL_GROUP_OBJ * primary group sid --/ * * on set. And on read of a directory ACL * * SMB_ACL_USER_OBJ ----> CREATOR_OWNER * SMB_ACL_GROUP_OBJ ---> CREATOR_GROUP. * * Deal with this on set by duplicating * owning sid and primary group sid ACE * entries into the directory ACL. * Fix from Tsukasa Hamano . */ if (!dup_owning_ace(dir_ace, current_ace)) { DEBUG(0,("create_canon_ace_lists: malloc fail !\n")); free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return false; } /* * If this is not an inherit only ACE we need to add a duplicate * to the file acl. */ if (!(psa->flags & SEC_ACE_FLAG_INHERIT_ONLY)) { canon_ace *dup_ace = dup_canon_ace(current_ace); if (!dup_ace) { DEBUG(0,("create_canon_ace_lists: malloc fail !\n")); free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return False; } /* * We must not free current_ace here as its * pointer is now owned by the dir_ace list. */ current_ace = dup_ace; /* We've essentially split this ace into two, * and added the ace with inheritance request * bits to the directory ACL. Drop those bits for * the ACE we're adding to the file list. */ current_ace->ace_flags &= ~(SEC_ACE_FLAG_OBJECT_INHERIT| SEC_ACE_FLAG_CONTAINER_INHERIT| SEC_ACE_FLAG_INHERIT_ONLY); } else { /* * We must not free current_ace here as its * pointer is now owned by the dir_ace list. */ current_ace = NULL; } } } /* * Only add to the file ACL if not inherit only. */ if (current_ace && !(psa->flags & SEC_ACE_FLAG_INHERIT_ONLY)) { DLIST_ADD_END(file_ace, current_ace, canon_ace *); /* * Note if this was an allow ace. We can't process * any further deny ace's after this. */ if (current_ace->attr == ALLOW_ACE) got_file_allow = True; if ((current_ace->attr == DENY_ACE) && got_file_allow) { DEBUG(0,("create_canon_ace_lists: malformed " "ACL in file ACL ! Deny entry after " "Allow entry. Failing to set on file " "%s.\n", fsp_str_dbg(fsp))); free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return False; } if( DEBUGLVL( 10 )) { dbgtext("create_canon_ace_lists: adding file ACL:\n"); print_canon_ace( current_ace, 0); } all_aces_are_inherit_only = False; /* * We must not free current_ace here as its * pointer is now owned by the file_ace list. */ current_ace = NULL; } /* * Free if ACE was not added. */ SAFE_FREE(current_ace); } if (fsp->is_directory && all_aces_are_inherit_only) { /* * Windows 2000 is doing one of these weird 'inherit acl' * traverses to conserve NTFS ACL resources. Just pretend * there was no DACL sent. JRA. */ DEBUG(10,("create_canon_ace_lists: Win2k inherit acl traverse. Ignoring DACL.\n")); free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); file_ace = NULL; dir_ace = NULL; } else { /* * Check if we have SMB_ACL_USER_OBJ and SMB_ACL_GROUP_OBJ entries in each * ACL. If we don't have them, check if any SMB_ACL_USER/SMB_ACL_GROUP * entries can be converted to *_OBJ. Usually we will already have these * entries in the Default ACL, and the Access ACL will not have them. */ if (file_ace) { check_owning_objs(file_ace, pfile_owner_sid, pfile_grp_sid); } if (dir_ace) { check_owning_objs(dir_ace, pfile_owner_sid, pfile_grp_sid); } } *ppfile_ace = file_ace; *ppdir_ace = dir_ace; return True; } /**************************************************************************** ASCII art time again... JRA :-). We have 4 cases to process when moving from an NT ACL to a POSIX ACL. Firstly, we insist the ACL is in canonical form (ie. all DENY entries preceede ALLOW entries). Secondly, the merge code has ensured that all duplicate SID entries for allow or deny have been merged, so the same SID can only appear once in the deny list or once in the allow list. We then process as follows : --------------------------------------------------------------------------- First pass - look for a Everyone DENY entry. If it is deny all (rwx) trunate the list at this point. Else, walk the list from this point and use the deny permissions of this entry as a mask on all following allow entries. Finally, delete the Everyone DENY entry (we have applied it to everything possible). In addition, in this pass we remove any DENY entries that have no permissions (ie. they are a DENY nothing). --------------------------------------------------------------------------- Second pass - only deal with deny user entries. DENY user1 (perms XXX) new_perms = 0 for all following allow group entries where user1 is in group new_perms |= group_perms; user1 entry perms = new_perms & ~ XXX; Convert the deny entry to an allow entry with the new perms and push to the end of the list. Note if the user was in no groups this maps to a specific allow nothing entry for this user. The common case from the NT ACL choser (userX deny all) is optimised so we don't do the group lookup - we just map to an allow nothing entry. What we're doing here is inferring the allow permissions the person setting the ACE on user1 wanted by looking at the allow permissions on the groups the user is currently in. This will be a snapshot, depending on group membership but is the best we can do and has the advantage of failing closed rather than open. --------------------------------------------------------------------------- Third pass - only deal with deny group entries. DENY group1 (perms XXX) for all following allow user entries where user is in group1 user entry perms = user entry perms & ~ XXX; If there is a group Everyone allow entry with permissions YYY, convert the group1 entry to an allow entry and modify its permissions to be : new_perms = YYY & ~ XXX and push to the end of the list. If there is no group Everyone allow entry then convert the group1 entry to a allow nothing entry and push to the end of the list. Note that the common case from the NT ACL choser (groupX deny all) cannot be optimised here as we need to modify user entries who are in the group to change them to a deny all also. What we're doing here is modifying the allow permissions of user entries (which are more specific in POSIX ACLs) to mask out the explicit deny set on the group they are in. This will be a snapshot depending on current group membership but is the best we can do and has the advantage of failing closed rather than open. --------------------------------------------------------------------------- Fourth pass - cope with cumulative permissions. for all allow user entries, if there exists an allow group entry with more permissive permissions, and the user is in that group, rewrite the allow user permissions to contain both sets of permissions. Currently the code for this is #ifdef'ed out as these semantics make no sense to me. JRA. --------------------------------------------------------------------------- Note we *MUST* do the deny user pass first as this will convert deny user entries into allow user entries which can then be processed by the deny group pass. The above algorithm took a *lot* of thinking about - hence this explaination :-). JRA. ****************************************************************************/ /**************************************************************************** Process a canon_ace list entries. This is very complex code. We need to go through and remove the "deny" permissions from any allow entry that matches the id of this entry. We have already refused any NT ACL that wasn't in correct order (DENY followed by ALLOW). If any allow entry ends up with zero permissions, we just remove it (to fail safe). We have already removed any duplicate ace entries. Treat an "Everyone" DENY_ACE as a special case - use it to mask all allow entries. ****************************************************************************/ static void process_deny_list(connection_struct *conn, canon_ace **pp_ace_list ) { canon_ace *ace_list = *pp_ace_list; canon_ace *curr_ace = NULL; canon_ace *curr_ace_next = NULL; /* Pass 1 above - look for an Everyone, deny entry. */ for (curr_ace = ace_list; curr_ace; curr_ace = curr_ace_next) { canon_ace *allow_ace_p; curr_ace_next = curr_ace->next; /* So we can't lose the link. */ if (curr_ace->attr != DENY_ACE) continue; if (curr_ace->perms == (mode_t)0) { /* Deny nothing entry - delete. */ DLIST_REMOVE(ace_list, curr_ace); continue; } if (!dom_sid_equal(&curr_ace->trustee, &global_sid_World)) continue; /* JRATEST - assert. */ SMB_ASSERT(curr_ace->owner_type == WORLD_ACE); if (curr_ace->perms == ALL_ACE_PERMS) { /* * Optimisation. This is a DENY_ALL to Everyone. Truncate the * list at this point including this entry. */ canon_ace *prev_entry = DLIST_PREV(curr_ace); free_canon_ace_list( curr_ace ); if (prev_entry) DLIST_REMOVE(ace_list, prev_entry); else { /* We deleted the entire list. */ ace_list = NULL; } break; } for (allow_ace_p = curr_ace->next; allow_ace_p; allow_ace_p = allow_ace_p->next) { /* * Only mask off allow entries. */ if (allow_ace_p->attr != ALLOW_ACE) continue; allow_ace_p->perms &= ~curr_ace->perms; } /* * Now it's been applied, remove it. */ DLIST_REMOVE(ace_list, curr_ace); } /* Pass 2 above - deal with deny user entries. */ for (curr_ace = ace_list; curr_ace; curr_ace = curr_ace_next) { mode_t new_perms = (mode_t)0; canon_ace *allow_ace_p; curr_ace_next = curr_ace->next; /* So we can't lose the link. */ if (curr_ace->attr != DENY_ACE) continue; if (curr_ace->owner_type != UID_ACE) continue; if (curr_ace->perms == ALL_ACE_PERMS) { /* * Optimisation - this is a deny everything to this user. * Convert to an allow nothing and push to the end of the list. */ curr_ace->attr = ALLOW_ACE; curr_ace->perms = (mode_t)0; DLIST_DEMOTE(ace_list, curr_ace, canon_ace *); continue; } for (allow_ace_p = curr_ace->next; allow_ace_p; allow_ace_p = allow_ace_p->next) { if (allow_ace_p->attr != ALLOW_ACE) continue; /* We process GID_ACE and WORLD_ACE entries only. */ if (allow_ace_p->owner_type == UID_ACE) continue; if (uid_entry_in_group(conn, curr_ace, allow_ace_p)) new_perms |= allow_ace_p->perms; } /* * Convert to a allow entry, modify the perms and push to the end * of the list. */ curr_ace->attr = ALLOW_ACE; curr_ace->perms = (new_perms & ~curr_ace->perms); DLIST_DEMOTE(ace_list, curr_ace, canon_ace *); } /* Pass 3 above - deal with deny group entries. */ for (curr_ace = ace_list; curr_ace; curr_ace = curr_ace_next) { canon_ace *allow_ace_p; canon_ace *allow_everyone_p = NULL; curr_ace_next = curr_ace->next; /* So we can't lose the link. */ if (curr_ace->attr != DENY_ACE) continue; if (curr_ace->owner_type != GID_ACE) continue; for (allow_ace_p = curr_ace->next; allow_ace_p; allow_ace_p = allow_ace_p->next) { if (allow_ace_p->attr != ALLOW_ACE) continue; /* Store a pointer to the Everyone allow, if it exists. */ if (allow_ace_p->owner_type == WORLD_ACE) allow_everyone_p = allow_ace_p; /* We process UID_ACE entries only. */ if (allow_ace_p->owner_type != UID_ACE) continue; /* Mask off the deny group perms. */ if (uid_entry_in_group(conn, allow_ace_p, curr_ace)) allow_ace_p->perms &= ~curr_ace->perms; } /* * Convert the deny to an allow with the correct perms and * push to the end of the list. */ curr_ace->attr = ALLOW_ACE; if (allow_everyone_p) curr_ace->perms = allow_everyone_p->perms & ~curr_ace->perms; else curr_ace->perms = (mode_t)0; DLIST_DEMOTE(ace_list, curr_ace, canon_ace *); } /* Doing this fourth pass allows Windows semantics to be layered * on top of POSIX semantics. I'm not sure if this is desirable. * For example, in W2K ACLs there is no way to say, "Group X no * access, user Y full access" if user Y is a member of group X. * This seems completely broken semantics to me.... JRA. */ #if 0 /* Pass 4 above - deal with allow entries. */ for (curr_ace = ace_list; curr_ace; curr_ace = curr_ace_next) { canon_ace *allow_ace_p; curr_ace_next = curr_ace->next; /* So we can't lose the link. */ if (curr_ace->attr != ALLOW_ACE) continue; if (curr_ace->owner_type != UID_ACE) continue; for (allow_ace_p = ace_list; allow_ace_p; allow_ace_p = allow_ace_p->next) { if (allow_ace_p->attr != ALLOW_ACE) continue; /* We process GID_ACE entries only. */ if (allow_ace_p->owner_type != GID_ACE) continue; /* OR in the group perms. */ if (uid_entry_in_group(conn, curr_ace, allow_ace_p)) curr_ace->perms |= allow_ace_p->perms; } } #endif *pp_ace_list = ace_list; } /**************************************************************************** Create a default mode that will be used if a security descriptor entry has no user/group/world entries. ****************************************************************************/ static mode_t create_default_mode(files_struct *fsp, bool interitable_mode) { int snum = SNUM(fsp->conn); mode_t and_bits = (mode_t)0; mode_t or_bits = (mode_t)0; mode_t mode; if (interitable_mode) { mode = unix_mode(fsp->conn, FILE_ATTRIBUTE_ARCHIVE, fsp->fsp_name, NULL); } else { mode = S_IRUSR; } if (fsp->is_directory) mode |= (S_IWUSR|S_IXUSR); /* * Now AND with the create mode/directory mode bits then OR with the * force create mode/force directory mode bits. */ if (fsp->is_directory) { and_bits = lp_dir_security_mask(snum); or_bits = lp_force_dir_security_mode(snum); } else { and_bits = lp_security_mask(snum); or_bits = lp_force_security_mode(snum); } return ((mode & and_bits)|or_bits); } /**************************************************************************** Unpack a struct security_descriptor into two canonical ace lists. We don't depend on this succeeding. ****************************************************************************/ static bool unpack_canon_ace(files_struct *fsp, const SMB_STRUCT_STAT *pst, struct dom_sid *pfile_owner_sid, struct dom_sid *pfile_grp_sid, canon_ace **ppfile_ace, canon_ace **ppdir_ace, uint32 security_info_sent, const struct security_descriptor *psd) { SMB_STRUCT_STAT st; canon_ace *file_ace = NULL; canon_ace *dir_ace = NULL; *ppfile_ace = NULL; *ppdir_ace = NULL; if(security_info_sent == 0) { DEBUG(0,("unpack_canon_ace: no security info sent !\n")); return False; } /* * If no DACL then this is a chown only security descriptor. */ if(!(security_info_sent & SECINFO_DACL) || !psd->dacl) return True; /* * Now go through the DACL and create the canon_ace lists. */ if (!create_canon_ace_lists( fsp, pst, pfile_owner_sid, pfile_grp_sid, &file_ace, &dir_ace, psd->dacl)) return False; if ((file_ace == NULL) && (dir_ace == NULL)) { /* W2K traverse DACL set - ignore. */ return True; } /* * Go through the canon_ace list and merge entries * belonging to identical users of identical allow or deny type. * We can do this as all deny entries come first, followed by * all allow entries (we have mandated this before accepting this acl). */ print_canon_ace_list( "file ace - before merge", file_ace); merge_aces( &file_ace, false); print_canon_ace_list( "dir ace - before merge", dir_ace); merge_aces( &dir_ace, true); /* * NT ACLs are order dependent. Go through the acl lists and * process DENY entries by masking the allow entries. */ print_canon_ace_list( "file ace - before deny", file_ace); process_deny_list(fsp->conn, &file_ace); print_canon_ace_list( "dir ace - before deny", dir_ace); process_deny_list(fsp->conn, &dir_ace); /* * A well formed POSIX file or default ACL has at least 3 entries, a * SMB_ACL_USER_OBJ, SMB_ACL_GROUP_OBJ, SMB_ACL_OTHER_OBJ * and optionally a mask entry. Ensure this is the case. */ print_canon_ace_list( "file ace - before valid", file_ace); st = *pst; /* * A default 3 element mode entry for a file should be r-- --- ---. * A default 3 element mode entry for a directory should be rwx --- ---. */ st.st_ex_mode = create_default_mode(fsp, False); if (!ensure_canon_entry_valid(fsp->conn, &file_ace, fsp->conn->params, fsp->is_directory, pfile_owner_sid, pfile_grp_sid, &st, True)) { free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return False; } print_canon_ace_list( "dir ace - before valid", dir_ace); /* * A default inheritable 3 element mode entry for a directory should be the * mode Samba will use to create a file within. Ensure user rwx bits are set if * it's a directory. */ st.st_ex_mode = create_default_mode(fsp, True); if (dir_ace && !ensure_canon_entry_valid(fsp->conn, &dir_ace, fsp->conn->params, fsp->is_directory, pfile_owner_sid, pfile_grp_sid, &st, True)) { free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); return False; } print_canon_ace_list( "file ace - return", file_ace); print_canon_ace_list( "dir ace - return", dir_ace); *ppfile_ace = file_ace; *ppdir_ace = dir_ace; return True; } /****************************************************************************** When returning permissions, try and fit NT display semantics if possible. Note the the canon_entries here must have been malloced. The list format should be - first entry = owner, followed by group and other user entries, last entry = other. Note that this doesn't exactly match the NT semantics for an ACL. As POSIX entries are not ordered, and match on the most specific entry rather than walking a list, then a simple POSIX permission of rw-r--r-- should really map to 5 entries, Entry 0: owner : deny all except read and write. Entry 1: owner : allow read and write. Entry 2: group : deny all except read. Entry 3: group : allow read. Entry 4: Everyone : allow read. But NT cannot display this in their ACL editor ! ********************************************************************************/ static void arrange_posix_perms(const char *filename, canon_ace **pp_list_head) { canon_ace *l_head = *pp_list_head; canon_ace *owner_ace = NULL; canon_ace *other_ace = NULL; canon_ace *ace = NULL; for (ace = l_head; ace; ace = ace->next) { if (ace->type == SMB_ACL_USER_OBJ) owner_ace = ace; else if (ace->type == SMB_ACL_OTHER) { /* Last ace - this is "other" */ other_ace = ace; } } if (!owner_ace || !other_ace) { DEBUG(0,("arrange_posix_perms: Invalid POSIX permissions for file %s, missing owner or other.\n", filename )); return; } /* * The POSIX algorithm applies to owner first, and other last, * so ensure they are arranged in this order. */ if (owner_ace) { DLIST_PROMOTE(l_head, owner_ace); } if (other_ace) { DLIST_DEMOTE(l_head, other_ace, canon_ace *); } /* We have probably changed the head of the list. */ *pp_list_head = l_head; } /**************************************************************************** Create a linked list of canonical ACE entries. ****************************************************************************/ static canon_ace *canonicalise_acl(struct connection_struct *conn, const char *fname, SMB_ACL_T posix_acl, const SMB_STRUCT_STAT *psbuf, const struct dom_sid *powner, const struct dom_sid *pgroup, struct pai_val *pal, SMB_ACL_TYPE_T the_acl_type) { mode_t acl_mask = (S_IRUSR|S_IWUSR|S_IXUSR); canon_ace *l_head = NULL; canon_ace *ace = NULL; canon_ace *next_ace = NULL; int entry_id = SMB_ACL_FIRST_ENTRY; SMB_ACL_ENTRY_T entry; size_t ace_count; while ( posix_acl && (SMB_VFS_SYS_ACL_GET_ENTRY(conn, posix_acl, entry_id, &entry) == 1)) { SMB_ACL_TAG_T tagtype; SMB_ACL_PERMSET_T permset; struct dom_sid sid; posix_id unix_ug; enum ace_owner owner_type; entry_id = SMB_ACL_NEXT_ENTRY; /* Is this a MASK entry ? */ if (SMB_VFS_SYS_ACL_GET_TAG_TYPE(conn, entry, &tagtype) == -1) continue; if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, entry, &permset) == -1) continue; /* Decide which SID to use based on the ACL type. */ switch(tagtype) { case SMB_ACL_USER_OBJ: /* Get the SID from the owner. */ sid_copy(&sid, powner); unix_ug.uid = psbuf->st_ex_uid; owner_type = UID_ACE; break; case SMB_ACL_USER: { uid_t *puid = (uid_t *)SMB_VFS_SYS_ACL_GET_QUALIFIER(conn, entry); if (puid == NULL) { DEBUG(0,("canonicalise_acl: Failed to get uid.\n")); continue; } uid_to_sid( &sid, *puid); unix_ug.uid = *puid; owner_type = UID_ACE; SMB_VFS_SYS_ACL_FREE_QUALIFIER(conn, (void *)puid,tagtype); break; } case SMB_ACL_GROUP_OBJ: /* Get the SID from the owning group. */ sid_copy(&sid, pgroup); unix_ug.gid = psbuf->st_ex_gid; owner_type = GID_ACE; break; case SMB_ACL_GROUP: { gid_t *pgid = (gid_t *)SMB_VFS_SYS_ACL_GET_QUALIFIER(conn, entry); if (pgid == NULL) { DEBUG(0,("canonicalise_acl: Failed to get gid.\n")); continue; } gid_to_sid( &sid, *pgid); unix_ug.gid = *pgid; owner_type = GID_ACE; SMB_VFS_SYS_ACL_FREE_QUALIFIER(conn, (void *)pgid,tagtype); break; } case SMB_ACL_MASK: acl_mask = convert_permset_to_mode_t(conn, permset); continue; /* Don't count the mask as an entry. */ case SMB_ACL_OTHER: /* Use the Everyone SID */ sid = global_sid_World; unix_ug.world = -1; owner_type = WORLD_ACE; break; default: DEBUG(0,("canonicalise_acl: Unknown tagtype %u\n", (unsigned int)tagtype)); continue; } /* * Add this entry to the list. */ if ((ace = SMB_MALLOC_P(canon_ace)) == NULL) goto fail; ZERO_STRUCTP(ace); ace->type = tagtype; ace->perms = convert_permset_to_mode_t(conn, permset); ace->attr = ALLOW_ACE; ace->trustee = sid; ace->unix_ug = unix_ug; ace->owner_type = owner_type; ace->ace_flags = get_pai_flags(pal, ace, (the_acl_type == SMB_ACL_TYPE_DEFAULT)); DLIST_ADD(l_head, ace); } /* * This next call will ensure we have at least a user/group/world set. */ if (!ensure_canon_entry_valid(conn, &l_head, conn->params, S_ISDIR(psbuf->st_ex_mode), powner, pgroup, psbuf, False)) goto fail; /* * Now go through the list, masking the permissions with the * acl_mask. Ensure all DENY Entries are at the start of the list. */ DEBUG(10,("canonicalise_acl: %s ace entries before arrange :\n", the_acl_type == SMB_ACL_TYPE_ACCESS ? "Access" : "Default" )); for ( ace_count = 0, ace = l_head; ace; ace = next_ace, ace_count++) { next_ace = ace->next; /* Masks are only applied to entries other than USER_OBJ and OTHER. */ if (ace->type != SMB_ACL_OTHER && ace->type != SMB_ACL_USER_OBJ) ace->perms &= acl_mask; if (ace->perms == 0) { DLIST_PROMOTE(l_head, ace); } if( DEBUGLVL( 10 ) ) { print_canon_ace(ace, ace_count); } } arrange_posix_perms(fname,&l_head ); print_canon_ace_list( "canonicalise_acl: ace entries after arrange", l_head ); return l_head; fail: free_canon_ace_list(l_head); return NULL; } /**************************************************************************** Check if the current user group list contains a given group. ****************************************************************************/ static bool current_user_in_group(connection_struct *conn, gid_t gid) { int i; const UNIX_USER_TOKEN *utok = get_current_utok(conn); for (i = 0; i < utok->ngroups; i++) { if (utok->groups[i] == gid) { return True; } } return False; } /**************************************************************************** Should we override a deny ? Check 'acl group control' and 'dos filemode'. ****************************************************************************/ static bool acl_group_override(connection_struct *conn, const struct smb_filename *smb_fname) { if ((errno != EPERM) && (errno != EACCES)) { return false; } /* file primary group == user primary or supplementary group */ if (lp_acl_group_control(SNUM(conn)) && current_user_in_group(conn, smb_fname->st.st_ex_gid)) { return true; } /* user has writeable permission */ if (lp_dos_filemode(SNUM(conn)) && can_write_to_file(conn, smb_fname)) { return true; } return false; } /**************************************************************************** Attempt to apply an ACL to a file or directory. ****************************************************************************/ static bool set_canon_ace_list(files_struct *fsp, canon_ace *the_ace, bool default_ace, const SMB_STRUCT_STAT *psbuf, bool *pacl_set_support) { connection_struct *conn = fsp->conn; bool ret = False; SMB_ACL_T the_acl = SMB_VFS_SYS_ACL_INIT(conn, (int)count_canon_ace_list(the_ace) + 1); canon_ace *p_ace; int i; SMB_ACL_ENTRY_T mask_entry; bool got_mask_entry = False; SMB_ACL_PERMSET_T mask_permset; SMB_ACL_TYPE_T the_acl_type = (default_ace ? SMB_ACL_TYPE_DEFAULT : SMB_ACL_TYPE_ACCESS); bool needs_mask = False; mode_t mask_perms = 0; /* Use the psbuf that was passed in. */ if (psbuf != &fsp->fsp_name->st) { fsp->fsp_name->st = *psbuf; } #if defined(POSIX_ACL_NEEDS_MASK) /* HP-UX always wants to have a mask (called "class" there). */ needs_mask = True; #endif if (the_acl == NULL) { if (!no_acl_syscall_error(errno)) { /* * Only print this error message if we have some kind of ACL * support that's not working. Otherwise we would always get this. */ DEBUG(0,("set_canon_ace_list: Unable to init %s ACL. (%s)\n", default_ace ? "default" : "file", strerror(errno) )); } *pacl_set_support = False; goto fail; } if( DEBUGLVL( 10 )) { dbgtext("set_canon_ace_list: setting ACL:\n"); for (i = 0, p_ace = the_ace; p_ace; p_ace = p_ace->next, i++ ) { print_canon_ace( p_ace, i); } } for (i = 0, p_ace = the_ace; p_ace; p_ace = p_ace->next, i++ ) { SMB_ACL_ENTRY_T the_entry; SMB_ACL_PERMSET_T the_permset; /* * ACLs only "need" an ACL_MASK entry if there are any named user or * named group entries. But if there is an ACL_MASK entry, it applies * to ACL_USER, ACL_GROUP, and ACL_GROUP_OBJ entries. Set the mask * so that it doesn't deny (i.e., mask off) any permissions. */ if (p_ace->type == SMB_ACL_USER || p_ace->type == SMB_ACL_GROUP) { needs_mask = True; mask_perms |= p_ace->perms; } else if (p_ace->type == SMB_ACL_GROUP_OBJ) { mask_perms |= p_ace->perms; } /* * Get the entry for this ACE. */ if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &the_acl, &the_entry) == -1) { DEBUG(0,("set_canon_ace_list: Failed to create entry %d. (%s)\n", i, strerror(errno) )); goto fail; } if (p_ace->type == SMB_ACL_MASK) { mask_entry = the_entry; got_mask_entry = True; } /* * Ok - we now know the ACL calls should be working, don't * allow fallback to chmod. */ *pacl_set_support = True; /* * Initialise the entry from the canon_ace. */ /* * First tell the entry what type of ACE this is. */ if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, the_entry, p_ace->type) == -1) { DEBUG(0,("set_canon_ace_list: Failed to set tag type on entry %d. (%s)\n", i, strerror(errno) )); goto fail; } /* * Only set the qualifier (user or group id) if the entry is a user * or group id ACE. */ if ((p_ace->type == SMB_ACL_USER) || (p_ace->type == SMB_ACL_GROUP)) { if (SMB_VFS_SYS_ACL_SET_QUALIFIER(conn, the_entry,(void *)&p_ace->unix_ug.uid) == -1) { DEBUG(0,("set_canon_ace_list: Failed to set qualifier on entry %d. (%s)\n", i, strerror(errno) )); goto fail; } } /* * Convert the mode_t perms in the canon_ace to a POSIX permset. */ if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, the_entry, &the_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to get permset on entry %d. (%s)\n", i, strerror(errno) )); goto fail; } if (map_acl_perms_to_permset(conn, p_ace->perms, &the_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to create permset for mode (%u) on entry %d. (%s)\n", (unsigned int)p_ace->perms, i, strerror(errno) )); goto fail; } /* * ..and apply them to the entry. */ if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, the_entry, the_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to add permset on entry %d. (%s)\n", i, strerror(errno) )); goto fail; } if( DEBUGLVL( 10 )) print_canon_ace( p_ace, i); } if (needs_mask && !got_mask_entry) { if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &the_acl, &mask_entry) == -1) { DEBUG(0,("set_canon_ace_list: Failed to create mask entry. (%s)\n", strerror(errno) )); goto fail; } if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, mask_entry, SMB_ACL_MASK) == -1) { DEBUG(0,("set_canon_ace_list: Failed to set tag type on mask entry. (%s)\n",strerror(errno) )); goto fail; } if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, mask_entry, &mask_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to get mask permset. (%s)\n", strerror(errno) )); goto fail; } if (map_acl_perms_to_permset(conn, S_IRUSR|S_IWUSR|S_IXUSR, &mask_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to create mask permset. (%s)\n", strerror(errno) )); goto fail; } if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, mask_entry, mask_permset) == -1) { DEBUG(0,("set_canon_ace_list: Failed to add mask permset. (%s)\n", strerror(errno) )); goto fail; } } /* * Finally apply it to the file or directory. */ if(default_ace || fsp->is_directory || fsp->fh->fd == -1) { if (SMB_VFS_SYS_ACL_SET_FILE(conn, fsp->fsp_name->base_name, the_acl_type, the_acl) == -1) { /* * Some systems allow all the above calls and only fail with no ACL support * when attempting to apply the acl. HPUX with HFS is an example of this. JRA. */ if (no_acl_syscall_error(errno)) { *pacl_set_support = False; } if (acl_group_override(conn, fsp->fsp_name)) { int sret; DEBUG(5,("set_canon_ace_list: acl group " "control on and current user in file " "%s primary group.\n", fsp_str_dbg(fsp))); become_root(); sret = SMB_VFS_SYS_ACL_SET_FILE(conn, fsp->fsp_name->base_name, the_acl_type, the_acl); unbecome_root(); if (sret == 0) { ret = True; } } if (ret == False) { DEBUG(2,("set_canon_ace_list: " "sys_acl_set_file type %s failed for " "file %s (%s).\n", the_acl_type == SMB_ACL_TYPE_DEFAULT ? "directory default" : "file", fsp_str_dbg(fsp), strerror(errno))); goto fail; } } } else { if (SMB_VFS_SYS_ACL_SET_FD(fsp, the_acl) == -1) { /* * Some systems allow all the above calls and only fail with no ACL support * when attempting to apply the acl. HPUX with HFS is an example of this. JRA. */ if (no_acl_syscall_error(errno)) { *pacl_set_support = False; } if (acl_group_override(conn, fsp->fsp_name)) { int sret; DEBUG(5,("set_canon_ace_list: acl group " "control on and current user in file " "%s primary group.\n", fsp_str_dbg(fsp))); become_root(); sret = SMB_VFS_SYS_ACL_SET_FD(fsp, the_acl); unbecome_root(); if (sret == 0) { ret = True; } } if (ret == False) { DEBUG(2,("set_canon_ace_list: " "sys_acl_set_file failed for file %s " "(%s).\n", fsp_str_dbg(fsp), strerror(errno))); goto fail; } } } ret = True; fail: if (the_acl != NULL) { SMB_VFS_SYS_ACL_FREE_ACL(conn, the_acl); } return ret; } /**************************************************************************** Find a particular canon_ace entry. ****************************************************************************/ static struct canon_ace *canon_ace_entry_for(struct canon_ace *list, SMB_ACL_TAG_T type, posix_id *id) { while (list) { if (list->type == type && ((type != SMB_ACL_USER && type != SMB_ACL_GROUP) || (type == SMB_ACL_USER && id && id->uid == list->unix_ug.uid) || (type == SMB_ACL_GROUP && id && id->gid == list->unix_ug.gid))) break; list = list->next; } return list; } /**************************************************************************** ****************************************************************************/ SMB_ACL_T free_empty_sys_acl(connection_struct *conn, SMB_ACL_T the_acl) { SMB_ACL_ENTRY_T entry; if (!the_acl) return NULL; if (SMB_VFS_SYS_ACL_GET_ENTRY(conn, the_acl, SMB_ACL_FIRST_ENTRY, &entry) != 1) { SMB_VFS_SYS_ACL_FREE_ACL(conn, the_acl); return NULL; } return the_acl; } /**************************************************************************** Convert a canon_ace to a generic 3 element permission - if possible. ****************************************************************************/ #define MAP_PERM(p,mask,result) (((p) & (mask)) ? (result) : 0 ) static bool convert_canon_ace_to_posix_perms( files_struct *fsp, canon_ace *file_ace_list, mode_t *posix_perms) { int snum = SNUM(fsp->conn); size_t ace_count = count_canon_ace_list(file_ace_list); canon_ace *ace_p; canon_ace *owner_ace = NULL; canon_ace *group_ace = NULL; canon_ace *other_ace = NULL; mode_t and_bits; mode_t or_bits; if (ace_count != 3) { DEBUG(3,("convert_canon_ace_to_posix_perms: Too many ACE " "entries for file %s to convert to posix perms.\n", fsp_str_dbg(fsp))); return False; } for (ace_p = file_ace_list; ace_p; ace_p = ace_p->next) { if (ace_p->owner_type == UID_ACE) owner_ace = ace_p; else if (ace_p->owner_type == GID_ACE) group_ace = ace_p; else if (ace_p->owner_type == WORLD_ACE) other_ace = ace_p; } if (!owner_ace || !group_ace || !other_ace) { DEBUG(3,("convert_canon_ace_to_posix_perms: Can't get " "standard entries for file %s.\n", fsp_str_dbg(fsp))); return False; } *posix_perms = (mode_t)0; *posix_perms |= owner_ace->perms; *posix_perms |= MAP_PERM(group_ace->perms, S_IRUSR, S_IRGRP); *posix_perms |= MAP_PERM(group_ace->perms, S_IWUSR, S_IWGRP); *posix_perms |= MAP_PERM(group_ace->perms, S_IXUSR, S_IXGRP); *posix_perms |= MAP_PERM(other_ace->perms, S_IRUSR, S_IROTH); *posix_perms |= MAP_PERM(other_ace->perms, S_IWUSR, S_IWOTH); *posix_perms |= MAP_PERM(other_ace->perms, S_IXUSR, S_IXOTH); /* The owner must have at least read access. */ *posix_perms |= S_IRUSR; if (fsp->is_directory) *posix_perms |= (S_IWUSR|S_IXUSR); /* If requested apply the masks. */ /* Get the initial bits to apply. */ if (fsp->is_directory) { and_bits = lp_dir_security_mask(snum); or_bits = lp_force_dir_security_mode(snum); } else { and_bits = lp_security_mask(snum); or_bits = lp_force_security_mode(snum); } *posix_perms = (((*posix_perms) & and_bits)|or_bits); DEBUG(10,("convert_canon_ace_to_posix_perms: converted u=%o,g=%o,w=%o " "to perm=0%o for file %s.\n", (int)owner_ace->perms, (int)group_ace->perms, (int)other_ace->perms, (int)*posix_perms, fsp_str_dbg(fsp))); return True; } /**************************************************************************** Incoming NT ACLs on a directory can be split into a default POSIX acl (CI|OI|IO) and a normal POSIX acl. Win2k needs these split acls re-merging into one ACL with CI|OI set so it is inherited and also applies to the directory. Based on code from "Jim McDonough" . ****************************************************************************/ static size_t merge_default_aces( struct security_ace *nt_ace_list, size_t num_aces) { size_t i, j; for (i = 0; i < num_aces; i++) { for (j = i+1; j < num_aces; j++) { uint32 i_flags_ni = (nt_ace_list[i].flags & ~SEC_ACE_FLAG_INHERITED_ACE); uint32 j_flags_ni = (nt_ace_list[j].flags & ~SEC_ACE_FLAG_INHERITED_ACE); bool i_inh = (nt_ace_list[i].flags & SEC_ACE_FLAG_INHERITED_ACE) ? True : False; bool j_inh = (nt_ace_list[j].flags & SEC_ACE_FLAG_INHERITED_ACE) ? True : False; /* We know the lower number ACE's are file entries. */ if ((nt_ace_list[i].type == nt_ace_list[j].type) && (nt_ace_list[i].size == nt_ace_list[j].size) && (nt_ace_list[i].access_mask == nt_ace_list[j].access_mask) && dom_sid_equal(&nt_ace_list[i].trustee, &nt_ace_list[j].trustee) && (i_inh == j_inh) && (i_flags_ni == 0) && (j_flags_ni == (SEC_ACE_FLAG_OBJECT_INHERIT| SEC_ACE_FLAG_CONTAINER_INHERIT| SEC_ACE_FLAG_INHERIT_ONLY))) { /* * W2K wants to have access allowed zero access ACE's * at the end of the list. If the mask is zero, merge * the non-inherited ACE onto the inherited ACE. */ if (nt_ace_list[i].access_mask == 0) { nt_ace_list[j].flags = SEC_ACE_FLAG_OBJECT_INHERIT|SEC_ACE_FLAG_CONTAINER_INHERIT| (i_inh ? SEC_ACE_FLAG_INHERITED_ACE : 0); if (num_aces - i - 1 > 0) memmove(&nt_ace_list[i], &nt_ace_list[i+1], (num_aces-i-1) * sizeof(struct security_ace)); DEBUG(10,("merge_default_aces: Merging zero access ACE %u onto ACE %u.\n", (unsigned int)i, (unsigned int)j )); } else { /* * These are identical except for the flags. * Merge the inherited ACE onto the non-inherited ACE. */ nt_ace_list[i].flags = SEC_ACE_FLAG_OBJECT_INHERIT|SEC_ACE_FLAG_CONTAINER_INHERIT| (i_inh ? SEC_ACE_FLAG_INHERITED_ACE : 0); if (num_aces - j - 1 > 0) memmove(&nt_ace_list[j], &nt_ace_list[j+1], (num_aces-j-1) * sizeof(struct security_ace)); DEBUG(10,("merge_default_aces: Merging ACE %u onto ACE %u.\n", (unsigned int)j, (unsigned int)i )); } num_aces--; break; } } } return num_aces; } /* * Add or Replace ACE entry. * In some cases we need to add a specific ACE for compatibility reasons. * When doing that we must make sure we are not actually creating a duplicate * entry. So we need to search whether an ACE entry already exist and eventually * replacce the access mask, or add a completely new entry if none was found. * * This function assumes the array has enough space to add a new entry without * any reallocation of memory. */ static void add_or_replace_ace(struct security_ace *nt_ace_list, size_t *num_aces, const struct dom_sid *sid, enum security_ace_type type, uint32_t mask, uint8_t flags) { int i; /* first search for a duplicate */ for (i = 0; i < *num_aces; i++) { if (dom_sid_equal(&nt_ace_list[i].trustee, sid) && (nt_ace_list[i].flags == flags)) break; } if (i < *num_aces) { /* found */ nt_ace_list[i].type = type; nt_ace_list[i].access_mask = mask; DEBUG(10, ("Replacing ACE %d with SID %s and flags %02x\n", i, sid_string_dbg(sid), flags)); return; } /* not found, append it */ init_sec_ace(&nt_ace_list[(*num_aces)++], sid, type, mask, flags); } /**************************************************************************** Reply to query a security descriptor from an fsp. If it succeeds it allocates the space for the return elements and returns the size needed to return the security descriptor. This should be the only external function needed for the UNIX style get ACL. ****************************************************************************/ static NTSTATUS posix_get_nt_acl_common(struct connection_struct *conn, const char *name, const SMB_STRUCT_STAT *sbuf, struct pai_val *pal, SMB_ACL_T posix_acl, SMB_ACL_T def_acl, uint32_t security_info, struct security_descriptor **ppdesc) { struct dom_sid owner_sid; struct dom_sid group_sid; size_t sd_size = 0; struct security_acl *psa = NULL; size_t num_acls = 0; size_t num_def_acls = 0; size_t num_aces = 0; canon_ace *file_ace = NULL; canon_ace *dir_ace = NULL; struct security_ace *nt_ace_list = NULL; size_t num_profile_acls = 0; struct dom_sid orig_owner_sid; struct security_descriptor *psd = NULL; int i; /* * Get the owner, group and world SIDs. */ create_file_sids(sbuf, &owner_sid, &group_sid); if (lp_profile_acls(SNUM(conn))) { /* For WXP SP1 the owner must be administrators. */ sid_copy(&orig_owner_sid, &owner_sid); sid_copy(&owner_sid, &global_sid_Builtin_Administrators); sid_copy(&group_sid, &global_sid_Builtin_Users); num_profile_acls = 3; } if ((security_info & SECINFO_DACL) && !(security_info & SECINFO_PROTECTED_DACL)) { /* * In the optimum case Creator Owner and Creator Group would be used for * the ACL_USER_OBJ and ACL_GROUP_OBJ entries, respectively, but this * would lead to usability problems under Windows: The Creator entries * are only available in browse lists of directories and not for files; * additionally the identity of the owning group couldn't be determined. * We therefore use those identities only for Default ACLs. */ /* Create the canon_ace lists. */ file_ace = canonicalise_acl(conn, name, posix_acl, sbuf, &owner_sid, &group_sid, pal, SMB_ACL_TYPE_ACCESS); /* We must have *some* ACLS. */ if (count_canon_ace_list(file_ace) == 0) { DEBUG(0,("get_nt_acl : No ACLs on file (%s) !\n", name)); goto done; } if (S_ISDIR(sbuf->st_ex_mode) && def_acl) { dir_ace = canonicalise_acl(conn, name, def_acl, sbuf, &global_sid_Creator_Owner, &global_sid_Creator_Group, pal, SMB_ACL_TYPE_DEFAULT); } /* * Create the NT ACE list from the canonical ace lists. */ { canon_ace *ace; enum security_ace_type nt_acl_type; if (nt4_compatible_acls() && dir_ace) { /* * NT 4 chokes if an ACL contains an INHERIT_ONLY entry * but no non-INHERIT_ONLY entry for one SID. So we only * remove entries from the Access ACL if the * corresponding Default ACL entries have also been * removed. ACEs for CREATOR-OWNER and CREATOR-GROUP * are exceptions. We can do nothing * intelligent if the Default ACL contains entries that * are not also contained in the Access ACL, so this * case will still fail under NT 4. */ ace = canon_ace_entry_for(dir_ace, SMB_ACL_OTHER, NULL); if (ace && !ace->perms) { DLIST_REMOVE(dir_ace, ace); SAFE_FREE(ace); ace = canon_ace_entry_for(file_ace, SMB_ACL_OTHER, NULL); if (ace && !ace->perms) { DLIST_REMOVE(file_ace, ace); SAFE_FREE(ace); } } /* * WinNT doesn't usually have Creator Group * in browse lists, so we send this entry to * WinNT even if it contains no relevant * permissions. Once we can add * Creator Group to browse lists we can * re-enable this. */ #if 0 ace = canon_ace_entry_for(dir_ace, SMB_ACL_GROUP_OBJ, NULL); if (ace && !ace->perms) { DLIST_REMOVE(dir_ace, ace); SAFE_FREE(ace); } #endif ace = canon_ace_entry_for(file_ace, SMB_ACL_GROUP_OBJ, NULL); if (ace && !ace->perms) { DLIST_REMOVE(file_ace, ace); SAFE_FREE(ace); } } num_acls = count_canon_ace_list(file_ace); num_def_acls = count_canon_ace_list(dir_ace); /* Allocate the ace list. */ if ((nt_ace_list = SMB_MALLOC_ARRAY(struct security_ace,num_acls + num_profile_acls + num_def_acls)) == NULL) { DEBUG(0,("get_nt_acl: Unable to malloc space for nt_ace_list.\n")); goto done; } memset(nt_ace_list, '\0', (num_acls + num_def_acls) * sizeof(struct security_ace) ); /* * Create the NT ACE list from the canonical ace lists. */ for (ace = file_ace; ace != NULL; ace = ace->next) { uint32_t acc = map_canon_ace_perms(SNUM(conn), &nt_acl_type, ace->perms, S_ISDIR(sbuf->st_ex_mode)); init_sec_ace(&nt_ace_list[num_aces++], &ace->trustee, nt_acl_type, acc, ace->ace_flags); } /* The User must have access to a profile share - even * if we can't map the SID. */ if (lp_profile_acls(SNUM(conn))) { add_or_replace_ace(nt_ace_list, &num_aces, &global_sid_Builtin_Users, SEC_ACE_TYPE_ACCESS_ALLOWED, FILE_GENERIC_ALL, 0); } for (ace = dir_ace; ace != NULL; ace = ace->next) { uint32_t acc = map_canon_ace_perms(SNUM(conn), &nt_acl_type, ace->perms, S_ISDIR(sbuf->st_ex_mode)); init_sec_ace(&nt_ace_list[num_aces++], &ace->trustee, nt_acl_type, acc, ace->ace_flags | SEC_ACE_FLAG_OBJECT_INHERIT| SEC_ACE_FLAG_CONTAINER_INHERIT| SEC_ACE_FLAG_INHERIT_ONLY); } /* The User must have access to a profile share - even * if we can't map the SID. */ if (lp_profile_acls(SNUM(conn))) { add_or_replace_ace(nt_ace_list, &num_aces, &global_sid_Builtin_Users, SEC_ACE_TYPE_ACCESS_ALLOWED, FILE_GENERIC_ALL, SEC_ACE_FLAG_OBJECT_INHERIT | SEC_ACE_FLAG_CONTAINER_INHERIT | SEC_ACE_FLAG_INHERIT_ONLY); } /* * Merge POSIX default ACLs and normal ACLs into one NT ACE. * Win2K needs this to get the inheritance correct when replacing ACLs * on a directory tree. Based on work by Jim @ IBM. */ num_aces = merge_default_aces(nt_ace_list, num_aces); if (lp_profile_acls(SNUM(conn))) { for (i = 0; i < num_aces; i++) { if (dom_sid_equal(&nt_ace_list[i].trustee, &owner_sid)) { add_or_replace_ace(nt_ace_list, &num_aces, &orig_owner_sid, nt_ace_list[i].type, nt_ace_list[i].access_mask, nt_ace_list[i].flags); break; } } } } if (num_aces) { if((psa = make_sec_acl( talloc_tos(), NT4_ACL_REVISION, num_aces, nt_ace_list)) == NULL) { DEBUG(0,("get_nt_acl: Unable to malloc space for acl.\n")); goto done; } } } /* security_info & SECINFO_DACL */ psd = make_standard_sec_desc( talloc_tos(), (security_info & SECINFO_OWNER) ? &owner_sid : NULL, (security_info & SECINFO_GROUP) ? &group_sid : NULL, psa, &sd_size); if(!psd) { DEBUG(0,("get_nt_acl: Unable to malloc space for security descriptor.\n")); sd_size = 0; goto done; } /* * Windows 2000: The DACL_PROTECTED flag in the security * descriptor marks the ACL as non-inheriting, i.e., no * ACEs from higher level directories propagate to this * ACL. In the POSIX ACL model permissions are only * inherited at file create time, so ACLs never contain * any ACEs that are inherited dynamically. The DACL_PROTECTED * flag doesn't seem to bother Windows NT. * Always set this if map acl inherit is turned off. */ if (pal == NULL || !lp_map_acl_inherit(SNUM(conn))) { psd->type |= SEC_DESC_DACL_PROTECTED; } else { psd->type |= pal->sd_type; } if (psd->dacl) { dacl_sort_into_canonical_order(psd->dacl->aces, (unsigned int)psd->dacl->num_aces); } *ppdesc = psd; done: if (posix_acl) { SMB_VFS_SYS_ACL_FREE_ACL(conn, posix_acl); } if (def_acl) { SMB_VFS_SYS_ACL_FREE_ACL(conn, def_acl); } free_canon_ace_list(file_ace); free_canon_ace_list(dir_ace); free_inherited_info(pal); SAFE_FREE(nt_ace_list); return NT_STATUS_OK; } NTSTATUS posix_fget_nt_acl(struct files_struct *fsp, uint32_t security_info, struct security_descriptor **ppdesc) { SMB_STRUCT_STAT sbuf; SMB_ACL_T posix_acl = NULL; struct pai_val *pal; *ppdesc = NULL; DEBUG(10,("posix_fget_nt_acl: called for file %s\n", fsp_str_dbg(fsp))); /* can it happen that fsp_name == NULL ? */ if (fsp->is_directory || fsp->fh->fd == -1) { return posix_get_nt_acl(fsp->conn, fsp->fsp_name->base_name, security_info, ppdesc); } /* Get the stat struct for the owner info. */ if(SMB_VFS_FSTAT(fsp, &sbuf) != 0) { return map_nt_error_from_unix(errno); } /* Get the ACL from the fd. */ posix_acl = SMB_VFS_SYS_ACL_GET_FD(fsp); pal = fload_inherited_info(fsp); return posix_get_nt_acl_common(fsp->conn, fsp->fsp_name->base_name, &sbuf, pal, posix_acl, NULL, security_info, ppdesc); } NTSTATUS posix_get_nt_acl(struct connection_struct *conn, const char *name, uint32_t security_info, struct security_descriptor **ppdesc) { SMB_ACL_T posix_acl = NULL; SMB_ACL_T def_acl = NULL; struct pai_val *pal; struct smb_filename smb_fname; int ret; *ppdesc = NULL; DEBUG(10,("posix_get_nt_acl: called for file %s\n", name )); ZERO_STRUCT(smb_fname); smb_fname.base_name = discard_const_p(char, name); /* Get the stat struct for the owner info. */ if (lp_posix_pathnames()) { ret = SMB_VFS_LSTAT(conn, &smb_fname); } else { ret = SMB_VFS_STAT(conn, &smb_fname); } if (ret == -1) { return map_nt_error_from_unix(errno); } /* Get the ACL from the path. */ posix_acl = SMB_VFS_SYS_ACL_GET_FILE(conn, name, SMB_ACL_TYPE_ACCESS); /* If it's a directory get the default POSIX ACL. */ if(S_ISDIR(smb_fname.st.st_ex_mode)) { def_acl = SMB_VFS_SYS_ACL_GET_FILE(conn, name, SMB_ACL_TYPE_DEFAULT); def_acl = free_empty_sys_acl(conn, def_acl); } pal = load_inherited_info(conn, name); return posix_get_nt_acl_common(conn, name, &smb_fname.st, pal, posix_acl, def_acl, security_info, ppdesc); } /**************************************************************************** Try to chown a file. We will be able to chown it under the following conditions. 1) If we have root privileges, then it will just work. 2) If we have SeTakeOwnershipPrivilege we can change the user to the current user. 3) If we have SeRestorePrivilege we can change the user to any other user. 4) If we have write permission to the file and dos_filemodes is set then allow chown to the currently authenticated user. ****************************************************************************/ int try_chown(connection_struct *conn, struct smb_filename *smb_fname, uid_t uid, gid_t gid) { int ret; files_struct *fsp; if(!CAN_WRITE(conn)) { return -1; } /* Case (1). */ /* try the direct way first */ if (lp_posix_pathnames()) { ret = SMB_VFS_LCHOWN(conn, smb_fname->base_name, uid, gid); } else { ret = SMB_VFS_CHOWN(conn, smb_fname->base_name, uid, gid); } if (ret == 0) return 0; /* Case (2) / (3) */ if (lp_enable_privileges()) { bool has_take_ownership_priv = security_token_has_privilege(get_current_nttok(conn), SEC_PRIV_TAKE_OWNERSHIP); bool has_restore_priv = security_token_has_privilege(get_current_nttok(conn), SEC_PRIV_RESTORE); /* Case (2) */ if ( ( has_take_ownership_priv && ( uid == get_current_uid(conn) ) ) || /* Case (3) */ ( has_restore_priv ) ) { become_root(); /* Keep the current file gid the same - take ownership doesn't imply group change. */ if (lp_posix_pathnames()) { ret = SMB_VFS_LCHOWN(conn, smb_fname->base_name, uid, (gid_t)-1); } else { ret = SMB_VFS_CHOWN(conn, smb_fname->base_name, uid, (gid_t)-1); } unbecome_root(); return ret; } } /* Case (4). */ if (!lp_dos_filemode(SNUM(conn))) { errno = EPERM; return -1; } /* only allow chown to the current user. This is more secure, and also copes with the case where the SID in a take ownership ACL is a local SID on the users workstation */ if (uid != get_current_uid(conn)) { errno = EPERM; return -1; } if (lp_posix_pathnames()) { ret = SMB_VFS_LSTAT(conn, smb_fname); } else { ret = SMB_VFS_STAT(conn, smb_fname); } if (ret == -1) { return -1; } if (!NT_STATUS_IS_OK(open_file_fchmod(NULL, conn, smb_fname, &fsp))) { return -1; } become_root(); /* Keep the current file gid the same. */ if (fsp->fh->fd == -1) { if (lp_posix_pathnames()) { ret = SMB_VFS_LCHOWN(conn, smb_fname->base_name, uid, (gid_t)-1); } else { ret = SMB_VFS_CHOWN(conn, smb_fname->base_name, uid, (gid_t)-1); } } else { ret = SMB_VFS_FCHOWN(fsp, uid, (gid_t)-1); } unbecome_root(); close_file_fchmod(NULL, fsp); return ret; } #if 0 /* Disable this - prevents ACL inheritance from the ACL editor. JRA. */ /**************************************************************************** Take care of parent ACL inheritance. ****************************************************************************/ NTSTATUS append_parent_acl(files_struct *fsp, const struct security_descriptor *pcsd, struct security_descriptor **pp_new_sd) { struct smb_filename *smb_dname = NULL; struct security_descriptor *parent_sd = NULL; files_struct *parent_fsp = NULL; TALLOC_CTX *mem_ctx = talloc_tos(); char *parent_name = NULL; struct security_ace *new_ace = NULL; unsigned int num_aces = pcsd->dacl->num_aces; NTSTATUS status; int info; unsigned int i, j; struct security_descriptor *psd = dup_sec_desc(talloc_tos(), pcsd); bool is_dacl_protected = (pcsd->type & SEC_DESC_DACL_PROTECTED); if (psd == NULL) { return NT_STATUS_NO_MEMORY; } if (!parent_dirname(mem_ctx, fsp->fsp_name->base_name, &parent_name, NULL)) { return NT_STATUS_NO_MEMORY; } status = create_synthetic_smb_fname(mem_ctx, parent_name, NULL, NULL, &smb_dname); if (!NT_STATUS_IS_OK(status)) { goto fail; } status = SMB_VFS_CREATE_FILE( fsp->conn, /* conn */ NULL, /* req */ 0, /* root_dir_fid */ smb_dname, /* fname */ FILE_READ_ATTRIBUTES, /* access_mask */ FILE_SHARE_NONE, /* share_access */ FILE_OPEN, /* create_disposition*/ FILE_DIRECTORY_FILE, /* create_options */ 0, /* file_attributes */ INTERNAL_OPEN_ONLY, /* oplock_request */ 0, /* allocation_size */ NULL, /* sd */ NULL, /* ea_list */ &parent_fsp, /* result */ &info); /* pinfo */ if (!NT_STATUS_IS_OK(status)) { TALLOC_FREE(smb_dname); return status; } status = SMB_VFS_GET_NT_ACL(parent_fsp->conn, smb_dname->base_name, SECINFO_DACL, &parent_sd ); close_file(NULL, parent_fsp, NORMAL_CLOSE); TALLOC_FREE(smb_dname); if (!NT_STATUS_IS_OK(status)) { return status; } /* * Make room for potentially all the ACLs from * the parent. We used to add the ugw triple here, * as we knew we were dealing with POSIX ACLs. * We no longer need to do so as we can guarentee * that a default ACL from the parent directory will * be well formed for POSIX ACLs if it came from a * POSIX ACL source, and if we're not writing to a * POSIX ACL sink then we don't care if it's not well * formed. JRA. */ num_aces += parent_sd->dacl->num_aces; if((new_ace = TALLOC_ZERO_ARRAY(mem_ctx, struct security_ace, num_aces)) == NULL) { return NT_STATUS_NO_MEMORY; } /* Start by copying in all the given ACE entries. */ for (i = 0; i < psd->dacl->num_aces; i++) { sec_ace_copy(&new_ace[i], &psd->dacl->aces[i]); } /* * Note that we're ignoring "inherit permissions" here * as that really only applies to newly created files. JRA. */ /* Finally append any inherited ACEs. */ for (j = 0; j < parent_sd->dacl->num_aces; j++) { struct security_ace *se = &parent_sd->dacl->aces[j]; if (fsp->is_directory) { if (!(se->flags & SEC_ACE_FLAG_CONTAINER_INHERIT)) { /* Doesn't apply to a directory - ignore. */ DEBUG(10,("append_parent_acl: directory %s " "ignoring non container " "inherit flags %u on ACE with sid %s " "from parent %s\n", fsp_str_dbg(fsp), (unsigned int)se->flags, sid_string_dbg(&se->trustee), parent_name)); continue; } } else { if (!(se->flags & SEC_ACE_FLAG_OBJECT_INHERIT)) { /* Doesn't apply to a file - ignore. */ DEBUG(10,("append_parent_acl: file %s " "ignoring non object " "inherit flags %u on ACE with sid %s " "from parent %s\n", fsp_str_dbg(fsp), (unsigned int)se->flags, sid_string_dbg(&se->trustee), parent_name)); continue; } } if (is_dacl_protected) { /* If the DACL is protected it means we must * not overwrite an existing ACE entry with the * same SID. This is order N^2. Ouch :-(. JRA. */ unsigned int k; for (k = 0; k < psd->dacl->num_aces; k++) { if (dom_sid_equal(&psd->dacl->aces[k].trustee, &se->trustee)) { break; } } if (k < psd->dacl->num_aces) { /* SID matched. Ignore. */ DEBUG(10,("append_parent_acl: path %s " "ignoring ACE with protected sid %s " "from parent %s\n", fsp_str_dbg(fsp), sid_string_dbg(&se->trustee), parent_name)); continue; } } sec_ace_copy(&new_ace[i], se); if (se->flags & SEC_ACE_FLAG_NO_PROPAGATE_INHERIT) { new_ace[i].flags &= ~(SEC_ACE_FLAG_VALID_INHERIT); } new_ace[i].flags |= SEC_ACE_FLAG_INHERITED_ACE; if (fsp->is_directory) { /* * Strip off any inherit only. It's applied. */ new_ace[i].flags &= ~(SEC_ACE_FLAG_INHERIT_ONLY); if (se->flags & SEC_ACE_FLAG_NO_PROPAGATE_INHERIT) { /* No further inheritance. */ new_ace[i].flags &= ~(SEC_ACE_FLAG_CONTAINER_INHERIT| SEC_ACE_FLAG_OBJECT_INHERIT); } } else { /* * Strip off any container or inherit * flags, they can't apply to objects. */ new_ace[i].flags &= ~(SEC_ACE_FLAG_CONTAINER_INHERIT| SEC_ACE_FLAG_INHERIT_ONLY| SEC_ACE_FLAG_NO_PROPAGATE_INHERIT); } i++; DEBUG(10,("append_parent_acl: path %s " "inheriting ACE with sid %s " "from parent %s\n", fsp_str_dbg(fsp), sid_string_dbg(&se->trustee), parent_name)); } psd->dacl->aces = new_ace; psd->dacl->num_aces = i; psd->type &= ~(SEC_DESC_DACL_AUTO_INHERITED| SEC_DESC_DACL_AUTO_INHERIT_REQ); *pp_new_sd = psd; return status; } #endif /**************************************************************************** Reply to set a security descriptor on an fsp. security_info_sent is the description of the following NT ACL. This should be the only external function needed for the UNIX style set ACL. We make a copy of psd_orig as internal functions modify the elements inside it, even though it's a const pointer. ****************************************************************************/ NTSTATUS set_nt_acl(files_struct *fsp, uint32 security_info_sent, const struct security_descriptor *psd_orig) { connection_struct *conn = fsp->conn; uid_t user = (uid_t)-1; gid_t grp = (gid_t)-1; struct dom_sid file_owner_sid; struct dom_sid file_grp_sid; canon_ace *file_ace_list = NULL; canon_ace *dir_ace_list = NULL; bool acl_perms = False; mode_t orig_mode = (mode_t)0; NTSTATUS status; bool set_acl_as_root = false; bool acl_set_support = false; bool ret = false; struct security_descriptor *psd = NULL; DEBUG(10,("set_nt_acl: called for file %s\n", fsp_str_dbg(fsp))); if (!CAN_WRITE(conn)) { DEBUG(10,("set acl rejected on read-only share\n")); return NT_STATUS_MEDIA_WRITE_PROTECTED; } if (!psd_orig) { return NT_STATUS_INVALID_PARAMETER; } psd = dup_sec_desc(talloc_tos(), psd_orig); if (!psd) { return NT_STATUS_NO_MEMORY; } if((security_info_sent & SECINFO_DACL) && (psd->type & SEC_DESC_DACL_PRESENT) && (psd->dacl == NULL)) { struct security_ace ace; /* We can't have NULL DACL in POSIX. Use Everyone -> full access. */ init_sec_ace(&ace, &global_sid_World, SEC_ACE_TYPE_ACCESS_ALLOWED, GENERIC_ALL_ACCESS, 0); psd->dacl = make_sec_acl(talloc_tos(), NT4_ACL_REVISION, 1, &ace); if (psd->dacl == NULL) { return NT_STATUS_NO_MEMORY; } security_acl_map_generic(psd->dacl, &file_generic_mapping); } /* * Get the current state of the file. */ status = vfs_stat_fsp(fsp); if (!NT_STATUS_IS_OK(status)) { return status; } /* Save the original element we check against. */ orig_mode = fsp->fsp_name->st.st_ex_mode; /* * Unpack the user/group/world id's. */ /* POSIX can't cope with missing owner/group. */ if ((security_info_sent & SECINFO_OWNER) && (psd->owner_sid == NULL)) { security_info_sent &= ~SECINFO_OWNER; } if ((security_info_sent & SECINFO_GROUP) && (psd->group_sid == NULL)) { security_info_sent &= ~SECINFO_GROUP; } status = unpack_nt_owners( conn, &user, &grp, security_info_sent, psd); if (!NT_STATUS_IS_OK(status)) { return status; } /* * Do we need to chown ? If so this must be done first as the incoming * CREATOR_OWNER acl will be relative to the *new* owner, not the old. * Noticed by Simo. */ if (((user != (uid_t)-1) && (fsp->fsp_name->st.st_ex_uid != user)) || (( grp != (gid_t)-1) && (fsp->fsp_name->st.st_ex_gid != grp))) { DEBUG(3,("set_nt_acl: chown %s. uid = %u, gid = %u.\n", fsp_str_dbg(fsp), (unsigned int)user, (unsigned int)grp)); if(try_chown(fsp->conn, fsp->fsp_name, user, grp) == -1) { DEBUG(3,("set_nt_acl: chown %s, %u, %u failed. Error " "= %s.\n", fsp_str_dbg(fsp), (unsigned int)user, (unsigned int)grp, strerror(errno))); if (errno == EPERM) { return NT_STATUS_INVALID_OWNER; } return map_nt_error_from_unix(errno); } /* * Recheck the current state of the file, which may have changed. * (suid/sgid bits, for instance) */ status = vfs_stat_fsp(fsp); if (!NT_STATUS_IS_OK(status)) { return status; } /* Save the original element we check against. */ orig_mode = fsp->fsp_name->st.st_ex_mode; /* If we successfully chowned, we know we must * be able to set the acl, so do it as root. */ set_acl_as_root = true; } create_file_sids(&fsp->fsp_name->st, &file_owner_sid, &file_grp_sid); acl_perms = unpack_canon_ace(fsp, &fsp->fsp_name->st, &file_owner_sid, &file_grp_sid, &file_ace_list, &dir_ace_list, security_info_sent, psd); /* Ignore W2K traverse DACL set. */ if (!file_ace_list && !dir_ace_list) { return NT_STATUS_OK; } if (!acl_perms) { DEBUG(3,("set_nt_acl: cannot set permissions\n")); free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return NT_STATUS_ACCESS_DENIED; } /* * Only change security if we got a DACL. */ if(!(security_info_sent & SECINFO_DACL) || (psd->dacl == NULL)) { free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return NT_STATUS_OK; } /* * Try using the POSIX ACL set first. Fall back to chmod if * we have no ACL support on this filesystem. */ if (acl_perms && file_ace_list) { if (set_acl_as_root) { become_root(); } ret = set_canon_ace_list(fsp, file_ace_list, false, &fsp->fsp_name->st, &acl_set_support); if (set_acl_as_root) { unbecome_root(); } if (acl_set_support && ret == false) { DEBUG(3,("set_nt_acl: failed to set file acl on file " "%s (%s).\n", fsp_str_dbg(fsp), strerror(errno))); free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return map_nt_error_from_unix(errno); } } if (acl_perms && acl_set_support && fsp->is_directory) { if (dir_ace_list) { if (set_acl_as_root) { become_root(); } ret = set_canon_ace_list(fsp, dir_ace_list, true, &fsp->fsp_name->st, &acl_set_support); if (set_acl_as_root) { unbecome_root(); } if (ret == false) { DEBUG(3,("set_nt_acl: failed to set default " "acl on directory %s (%s).\n", fsp_str_dbg(fsp), strerror(errno))); free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return map_nt_error_from_unix(errno); } } else { int sret = -1; /* * No default ACL - delete one if it exists. */ if (set_acl_as_root) { become_root(); } sret = SMB_VFS_SYS_ACL_DELETE_DEF_FILE(conn, fsp->fsp_name->base_name); if (set_acl_as_root) { unbecome_root(); } if (sret == -1) { if (acl_group_override(conn, fsp->fsp_name)) { DEBUG(5,("set_nt_acl: acl group " "control on and current user " "in file %s primary group. " "Override delete_def_acl\n", fsp_str_dbg(fsp))); become_root(); sret = SMB_VFS_SYS_ACL_DELETE_DEF_FILE( conn, fsp->fsp_name->base_name); unbecome_root(); } if (sret == -1) { DEBUG(3,("set_nt_acl: sys_acl_delete_def_file failed (%s)\n", strerror(errno))); free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return map_nt_error_from_unix(errno); } } } } if (acl_set_support) { if (set_acl_as_root) { become_root(); } store_inheritance_attributes(fsp, file_ace_list, dir_ace_list, psd->type); if (set_acl_as_root) { unbecome_root(); } } /* * If we cannot set using POSIX ACLs we fall back to checking if we need to chmod. */ if(!acl_set_support && acl_perms) { mode_t posix_perms; if (!convert_canon_ace_to_posix_perms( fsp, file_ace_list, &posix_perms)) { free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); DEBUG(3,("set_nt_acl: failed to convert file acl to " "posix permissions for file %s.\n", fsp_str_dbg(fsp))); return NT_STATUS_ACCESS_DENIED; } if (orig_mode != posix_perms) { int sret = -1; DEBUG(3,("set_nt_acl: chmod %s. perms = 0%o.\n", fsp_str_dbg(fsp), (unsigned int)posix_perms)); if (set_acl_as_root) { become_root(); } sret = SMB_VFS_CHMOD(conn, fsp->fsp_name->base_name, posix_perms); if (set_acl_as_root) { unbecome_root(); } if(sret == -1) { if (acl_group_override(conn, fsp->fsp_name)) { DEBUG(5,("set_nt_acl: acl group " "control on and current user " "in file %s primary group. " "Override chmod\n", fsp_str_dbg(fsp))); become_root(); sret = SMB_VFS_CHMOD(conn, fsp->fsp_name->base_name, posix_perms); unbecome_root(); } if (sret == -1) { DEBUG(3,("set_nt_acl: chmod %s, 0%o " "failed. Error = %s.\n", fsp_str_dbg(fsp), (unsigned int)posix_perms, strerror(errno))); free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); return map_nt_error_from_unix(errno); } } } } free_canon_ace_list(file_ace_list); free_canon_ace_list(dir_ace_list); /* Ensure the stat struct in the fsp is correct. */ status = vfs_stat_fsp(fsp); return NT_STATUS_OK; } /**************************************************************************** Get the actual group bits stored on a file with an ACL. Has no effect if the file has no ACL. Needed in dosmode code where the stat() will return the mask bits, not the real group bits, for a file with an ACL. ****************************************************************************/ int get_acl_group_bits( connection_struct *conn, const char *fname, mode_t *mode ) { int entry_id = SMB_ACL_FIRST_ENTRY; SMB_ACL_ENTRY_T entry; SMB_ACL_T posix_acl; int result = -1; posix_acl = SMB_VFS_SYS_ACL_GET_FILE(conn, fname, SMB_ACL_TYPE_ACCESS); if (posix_acl == (SMB_ACL_T)NULL) return -1; while (SMB_VFS_SYS_ACL_GET_ENTRY(conn, posix_acl, entry_id, &entry) == 1) { SMB_ACL_TAG_T tagtype; SMB_ACL_PERMSET_T permset; entry_id = SMB_ACL_NEXT_ENTRY; if (SMB_VFS_SYS_ACL_GET_TAG_TYPE(conn, entry, &tagtype) ==-1) break; if (tagtype == SMB_ACL_GROUP_OBJ) { if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, entry, &permset) == -1) { break; } else { *mode &= ~(S_IRGRP|S_IWGRP|S_IXGRP); *mode |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_READ) ? S_IRGRP : 0); *mode |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_WRITE) ? S_IWGRP : 0); *mode |= (SMB_VFS_SYS_ACL_GET_PERM(conn, permset, SMB_ACL_EXECUTE) ? S_IXGRP : 0); result = 0; break; } } } SMB_VFS_SYS_ACL_FREE_ACL(conn, posix_acl); return result; } /**************************************************************************** Do a chmod by setting the ACL USER_OBJ, GROUP_OBJ and OTHER bits in an ACL and set the mask to rwx. Needed to preserve complex ACLs set by NT. ****************************************************************************/ static int chmod_acl_internals( connection_struct *conn, SMB_ACL_T posix_acl, mode_t mode) { int entry_id = SMB_ACL_FIRST_ENTRY; SMB_ACL_ENTRY_T entry; int num_entries = 0; while ( SMB_VFS_SYS_ACL_GET_ENTRY(conn, posix_acl, entry_id, &entry) == 1) { SMB_ACL_TAG_T tagtype; SMB_ACL_PERMSET_T permset; mode_t perms; entry_id = SMB_ACL_NEXT_ENTRY; if (SMB_VFS_SYS_ACL_GET_TAG_TYPE(conn, entry, &tagtype) == -1) return -1; if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, entry, &permset) == -1) return -1; num_entries++; switch(tagtype) { case SMB_ACL_USER_OBJ: perms = unix_perms_to_acl_perms(mode, S_IRUSR, S_IWUSR, S_IXUSR); break; case SMB_ACL_GROUP_OBJ: perms = unix_perms_to_acl_perms(mode, S_IRGRP, S_IWGRP, S_IXGRP); break; case SMB_ACL_MASK: /* * FIXME: The ACL_MASK entry permissions should really be set to * the union of the permissions of all ACL_USER, * ACL_GROUP_OBJ, and ACL_GROUP entries. That's what * acl_calc_mask() does, but Samba ACLs doesn't provide it. */ perms = S_IRUSR|S_IWUSR|S_IXUSR; break; case SMB_ACL_OTHER: perms = unix_perms_to_acl_perms(mode, S_IROTH, S_IWOTH, S_IXOTH); break; default: continue; } if (map_acl_perms_to_permset(conn, perms, &permset) == -1) return -1; if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, entry, permset) == -1) return -1; } /* * If this is a simple 3 element ACL or no elements then it's a standard * UNIX permission set. Just use chmod... */ if ((num_entries == 3) || (num_entries == 0)) return -1; return 0; } /**************************************************************************** Get the access ACL of FROM, do a chmod by setting the ACL USER_OBJ, GROUP_OBJ and OTHER bits in an ACL and set the mask to rwx. Set the resulting ACL on TO. Note that name is in UNIX character set. ****************************************************************************/ static int copy_access_posix_acl(connection_struct *conn, const char *from, const char *to, mode_t mode) { SMB_ACL_T posix_acl = NULL; int ret = -1; if ((posix_acl = SMB_VFS_SYS_ACL_GET_FILE(conn, from, SMB_ACL_TYPE_ACCESS)) == NULL) return -1; if ((ret = chmod_acl_internals(conn, posix_acl, mode)) == -1) goto done; ret = SMB_VFS_SYS_ACL_SET_FILE(conn, to, SMB_ACL_TYPE_ACCESS, posix_acl); done: SMB_VFS_SYS_ACL_FREE_ACL(conn, posix_acl); return ret; } /**************************************************************************** Do a chmod by setting the ACL USER_OBJ, GROUP_OBJ and OTHER bits in an ACL and set the mask to rwx. Needed to preserve complex ACLs set by NT. Note that name is in UNIX character set. ****************************************************************************/ int chmod_acl(connection_struct *conn, const char *name, mode_t mode) { return copy_access_posix_acl(conn, name, name, mode); } /**************************************************************************** Check for an existing default POSIX ACL on a directory. ****************************************************************************/ static bool directory_has_default_posix_acl(connection_struct *conn, const char *fname) { SMB_ACL_T def_acl = SMB_VFS_SYS_ACL_GET_FILE( conn, fname, SMB_ACL_TYPE_DEFAULT); bool has_acl = False; SMB_ACL_ENTRY_T entry; if (def_acl != NULL && (SMB_VFS_SYS_ACL_GET_ENTRY(conn, def_acl, SMB_ACL_FIRST_ENTRY, &entry) == 1)) { has_acl = True; } if (def_acl) { SMB_VFS_SYS_ACL_FREE_ACL(conn, def_acl); } return has_acl; } /**************************************************************************** If the parent directory has no default ACL but it does have an Access ACL, inherit this Access ACL to file name. ****************************************************************************/ int inherit_access_posix_acl(connection_struct *conn, const char *inherit_from_dir, const char *name, mode_t mode) { if (directory_has_default_posix_acl(conn, inherit_from_dir)) return 0; return copy_access_posix_acl(conn, inherit_from_dir, name, mode); } /**************************************************************************** Do an fchmod by setting the ACL USER_OBJ, GROUP_OBJ and OTHER bits in an ACL and set the mask to rwx. Needed to preserve complex ACLs set by NT. ****************************************************************************/ int fchmod_acl(files_struct *fsp, mode_t mode) { connection_struct *conn = fsp->conn; SMB_ACL_T posix_acl = NULL; int ret = -1; if ((posix_acl = SMB_VFS_SYS_ACL_GET_FD(fsp)) == NULL) return -1; if ((ret = chmod_acl_internals(conn, posix_acl, mode)) == -1) goto done; ret = SMB_VFS_SYS_ACL_SET_FD(fsp, posix_acl); done: SMB_VFS_SYS_ACL_FREE_ACL(conn, posix_acl); return ret; } /**************************************************************************** Map from wire type to permset. ****************************************************************************/ static bool unix_ex_wire_to_permset(connection_struct *conn, unsigned char wire_perm, SMB_ACL_PERMSET_T *p_permset) { if (wire_perm & ~(SMB_POSIX_ACL_READ|SMB_POSIX_ACL_WRITE|SMB_POSIX_ACL_EXECUTE)) { return False; } if (SMB_VFS_SYS_ACL_CLEAR_PERMS(conn, *p_permset) == -1) { return False; } if (wire_perm & SMB_POSIX_ACL_READ) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_READ) == -1) { return False; } } if (wire_perm & SMB_POSIX_ACL_WRITE) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_WRITE) == -1) { return False; } } if (wire_perm & SMB_POSIX_ACL_EXECUTE) { if (SMB_VFS_SYS_ACL_ADD_PERM(conn, *p_permset, SMB_ACL_EXECUTE) == -1) { return False; } } return True; } /**************************************************************************** Map from wire type to tagtype. ****************************************************************************/ static bool unix_ex_wire_to_tagtype(unsigned char wire_tt, SMB_ACL_TAG_T *p_tt) { switch (wire_tt) { case SMB_POSIX_ACL_USER_OBJ: *p_tt = SMB_ACL_USER_OBJ; break; case SMB_POSIX_ACL_USER: *p_tt = SMB_ACL_USER; break; case SMB_POSIX_ACL_GROUP_OBJ: *p_tt = SMB_ACL_GROUP_OBJ; break; case SMB_POSIX_ACL_GROUP: *p_tt = SMB_ACL_GROUP; break; case SMB_POSIX_ACL_MASK: *p_tt = SMB_ACL_MASK; break; case SMB_POSIX_ACL_OTHER: *p_tt = SMB_ACL_OTHER; break; default: return False; } return True; } /**************************************************************************** Create a new POSIX acl from wire permissions. FIXME ! How does the share mask/mode fit into this.... ? ****************************************************************************/ static SMB_ACL_T create_posix_acl_from_wire(connection_struct *conn, uint16 num_acls, const char *pdata) { unsigned int i; SMB_ACL_T the_acl = SMB_VFS_SYS_ACL_INIT(conn, num_acls); if (the_acl == NULL) { return NULL; } for (i = 0; i < num_acls; i++) { SMB_ACL_ENTRY_T the_entry; SMB_ACL_PERMSET_T the_permset; SMB_ACL_TAG_T tag_type; if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &the_acl, &the_entry) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to create entry %u. (%s)\n", i, strerror(errno) )); goto fail; } if (!unix_ex_wire_to_tagtype(CVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE)), &tag_type)) { DEBUG(0,("create_posix_acl_from_wire: invalid wire tagtype %u on entry %u.\n", CVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE)), i )); goto fail; } if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, the_entry, tag_type) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to set tagtype on entry %u. (%s)\n", i, strerror(errno) )); goto fail; } /* Get the permset pointer from the new ACL entry. */ if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, the_entry, &the_permset) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to get permset on entry %u. (%s)\n", i, strerror(errno) )); goto fail; } /* Map from wire to permissions. */ if (!unix_ex_wire_to_permset(conn, CVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE)+1), &the_permset)) { DEBUG(0,("create_posix_acl_from_wire: invalid permset %u on entry %u.\n", CVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE) + 1), i )); goto fail; } /* Now apply to the new ACL entry. */ if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, the_entry, the_permset) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to add permset on entry %u. (%s)\n", i, strerror(errno) )); goto fail; } if (tag_type == SMB_ACL_USER) { uint32 uidval = IVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE)+2); uid_t uid = (uid_t)uidval; if (SMB_VFS_SYS_ACL_SET_QUALIFIER(conn, the_entry,(void *)&uid) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to set uid %u on entry %u. (%s)\n", (unsigned int)uid, i, strerror(errno) )); goto fail; } } if (tag_type == SMB_ACL_GROUP) { uint32 gidval = IVAL(pdata,(i*SMB_POSIX_ACL_ENTRY_SIZE)+2); gid_t gid = (uid_t)gidval; if (SMB_VFS_SYS_ACL_SET_QUALIFIER(conn, the_entry,(void *)&gid) == -1) { DEBUG(0,("create_posix_acl_from_wire: Failed to set gid %u on entry %u. (%s)\n", (unsigned int)gid, i, strerror(errno) )); goto fail; } } } return the_acl; fail: if (the_acl != NULL) { SMB_VFS_SYS_ACL_FREE_ACL(conn, the_acl); } return NULL; } /**************************************************************************** Calls from UNIX extensions - Default POSIX ACL set. If num_def_acls == 0 and not a directory just return. If it is a directory and num_def_acls == 0 then remove the default acl. Else set the default acl on the directory. ****************************************************************************/ bool set_unix_posix_default_acl(connection_struct *conn, const char *fname, const SMB_STRUCT_STAT *psbuf, uint16 num_def_acls, const char *pdata) { SMB_ACL_T def_acl = NULL; if (!S_ISDIR(psbuf->st_ex_mode)) { if (num_def_acls) { DEBUG(5,("set_unix_posix_default_acl: Can't set default ACL on non-directory file %s\n", fname )); errno = EISDIR; return False; } else { return True; } } if (!num_def_acls) { /* Remove the default ACL. */ if (SMB_VFS_SYS_ACL_DELETE_DEF_FILE(conn, fname) == -1) { DEBUG(5,("set_unix_posix_default_acl: acl_delete_def_file failed on directory %s (%s)\n", fname, strerror(errno) )); return False; } return True; } if ((def_acl = create_posix_acl_from_wire(conn, num_def_acls, pdata)) == NULL) { return False; } if (SMB_VFS_SYS_ACL_SET_FILE(conn, fname, SMB_ACL_TYPE_DEFAULT, def_acl) == -1) { DEBUG(5,("set_unix_posix_default_acl: acl_set_file failed on directory %s (%s)\n", fname, strerror(errno) )); SMB_VFS_SYS_ACL_FREE_ACL(conn, def_acl); return False; } DEBUG(10,("set_unix_posix_default_acl: set default acl for file %s\n", fname )); SMB_VFS_SYS_ACL_FREE_ACL(conn, def_acl); return True; } /**************************************************************************** Remove an ACL from a file. As we don't have acl_delete_entry() available we must read the current acl and copy all entries except MASK, USER and GROUP to a new acl, then set that. This (at least on Linux) causes any ACL to be removed. FIXME ! How does the share mask/mode fit into this.... ? ****************************************************************************/ static bool remove_posix_acl(connection_struct *conn, files_struct *fsp, const char *fname) { SMB_ACL_T file_acl = NULL; int entry_id = SMB_ACL_FIRST_ENTRY; SMB_ACL_ENTRY_T entry; bool ret = False; /* Create a new ACL with only 3 entries, u/g/w. */ SMB_ACL_T new_file_acl = SMB_VFS_SYS_ACL_INIT(conn, 3); SMB_ACL_ENTRY_T user_ent = NULL; SMB_ACL_ENTRY_T group_ent = NULL; SMB_ACL_ENTRY_T other_ent = NULL; if (new_file_acl == NULL) { DEBUG(5,("remove_posix_acl: failed to init new ACL with 3 entries for file %s.\n", fname)); return False; } /* Now create the u/g/w entries. */ if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &new_file_acl, &user_ent) == -1) { DEBUG(5,("remove_posix_acl: Failed to create user entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, user_ent, SMB_ACL_USER_OBJ) == -1) { DEBUG(5,("remove_posix_acl: Failed to set user entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &new_file_acl, &group_ent) == -1) { DEBUG(5,("remove_posix_acl: Failed to create group entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, group_ent, SMB_ACL_GROUP_OBJ) == -1) { DEBUG(5,("remove_posix_acl: Failed to set group entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_CREATE_ENTRY(conn, &new_file_acl, &other_ent) == -1) { DEBUG(5,("remove_posix_acl: Failed to create other entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_SET_TAG_TYPE(conn, other_ent, SMB_ACL_OTHER) == -1) { DEBUG(5,("remove_posix_acl: Failed to set other entry for file %s. (%s)\n", fname, strerror(errno) )); goto done; } /* Get the current file ACL. */ if (fsp && fsp->fh->fd != -1) { file_acl = SMB_VFS_SYS_ACL_GET_FD(fsp); } else { file_acl = SMB_VFS_SYS_ACL_GET_FILE( conn, fname, SMB_ACL_TYPE_ACCESS); } if (file_acl == NULL) { /* This is only returned if an error occurred. Even for a file with no acl a u/g/w acl should be returned. */ DEBUG(5,("remove_posix_acl: failed to get ACL from file %s (%s).\n", fname, strerror(errno) )); goto done; } while ( SMB_VFS_SYS_ACL_GET_ENTRY(conn, file_acl, entry_id, &entry) == 1) { SMB_ACL_TAG_T tagtype; SMB_ACL_PERMSET_T permset; entry_id = SMB_ACL_NEXT_ENTRY; if (SMB_VFS_SYS_ACL_GET_TAG_TYPE(conn, entry, &tagtype) == -1) { DEBUG(5,("remove_posix_acl: failed to get tagtype from ACL on file %s (%s).\n", fname, strerror(errno) )); goto done; } if (SMB_VFS_SYS_ACL_GET_PERMSET(conn, entry, &permset) == -1) { DEBUG(5,("remove_posix_acl: failed to get permset from ACL on file %s (%s).\n", fname, strerror(errno) )); goto done; } if (tagtype == SMB_ACL_USER_OBJ) { if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, user_ent, permset) == -1) { DEBUG(5,("remove_posix_acl: failed to set permset from ACL on file %s (%s).\n", fname, strerror(errno) )); } } else if (tagtype == SMB_ACL_GROUP_OBJ) { if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, group_ent, permset) == -1) { DEBUG(5,("remove_posix_acl: failed to set permset from ACL on file %s (%s).\n", fname, strerror(errno) )); } } else if (tagtype == SMB_ACL_OTHER) { if (SMB_VFS_SYS_ACL_SET_PERMSET(conn, other_ent, permset) == -1) { DEBUG(5,("remove_posix_acl: failed to set permset from ACL on file %s (%s).\n", fname, strerror(errno) )); } } } /* Set the new empty file ACL. */ if (fsp && fsp->fh->fd != -1) { if (SMB_VFS_SYS_ACL_SET_FD(fsp, new_file_acl) == -1) { DEBUG(5,("remove_posix_acl: acl_set_file failed on %s (%s)\n", fname, strerror(errno) )); goto done; } } else { if (SMB_VFS_SYS_ACL_SET_FILE(conn, fname, SMB_ACL_TYPE_ACCESS, new_file_acl) == -1) { DEBUG(5,("remove_posix_acl: acl_set_file failed on %s (%s)\n", fname, strerror(errno) )); goto done; } } ret = True; done: if (file_acl) { SMB_VFS_SYS_ACL_FREE_ACL(conn, file_acl); } if (new_file_acl) { SMB_VFS_SYS_ACL_FREE_ACL(conn, new_file_acl); } return ret; } /**************************************************************************** Calls from UNIX extensions - POSIX ACL set. If num_def_acls == 0 then read/modify/write acl after removing all entries except SMB_ACL_USER_OBJ, SMB_ACL_GROUP_OBJ, SMB_ACL_OTHER. ****************************************************************************/ bool set_unix_posix_acl(connection_struct *conn, files_struct *fsp, const char *fname, uint16 num_acls, const char *pdata) { SMB_ACL_T file_acl = NULL; if (!num_acls) { /* Remove the ACL from the file. */ return remove_posix_acl(conn, fsp, fname); } if ((file_acl = create_posix_acl_from_wire(conn, num_acls, pdata)) == NULL) { return False; } if (fsp && fsp->fh->fd != -1) { /* The preferred way - use an open fd. */ if (SMB_VFS_SYS_ACL_SET_FD(fsp, file_acl) == -1) { DEBUG(5,("set_unix_posix_acl: acl_set_file failed on %s (%s)\n", fname, strerror(errno) )); SMB_VFS_SYS_ACL_FREE_ACL(conn, file_acl); return False; } } else { if (SMB_VFS_SYS_ACL_SET_FILE(conn, fname, SMB_ACL_TYPE_ACCESS, file_acl) == -1) { DEBUG(5,("set_unix_posix_acl: acl_set_file failed on %s (%s)\n", fname, strerror(errno) )); SMB_VFS_SYS_ACL_FREE_ACL(conn, file_acl); return False; } } DEBUG(10,("set_unix_posix_acl: set acl for file %s\n", fname )); SMB_VFS_SYS_ACL_FREE_ACL(conn, file_acl); return True; } /******************************************************************** Pull the NT ACL from a file on disk or the OpenEventlog() access check. Caller is responsible for freeing the returned security descriptor via TALLOC_FREE(). This is designed for dealing with user space access checks in smbd outside of the VFS. For example, checking access rights in OpenEventlog(). Assume we are dealing with files (for now) ********************************************************************/ struct security_descriptor *get_nt_acl_no_snum( TALLOC_CTX *ctx, const char *fname) { struct security_descriptor *psd, *ret_sd; connection_struct *conn; files_struct finfo; struct fd_handle fh; NTSTATUS status; conn = TALLOC_ZERO_P(ctx, connection_struct); if (conn == NULL) { DEBUG(0, ("talloc failed\n")); return NULL; } if (!(conn->params = TALLOC_P(conn, struct share_params))) { DEBUG(0,("get_nt_acl_no_snum: talloc() failed!\n")); TALLOC_FREE(conn); return NULL; } conn->params->service = -1; set_conn_connectpath(conn, "/"); if (!smbd_vfs_init(conn)) { DEBUG(0,("get_nt_acl_no_snum: Unable to create a fake connection struct!\n")); conn_free(conn); return NULL; } ZERO_STRUCT( finfo ); ZERO_STRUCT( fh ); finfo.fnum = -1; finfo.conn = conn; finfo.fh = &fh; finfo.fh->fd = -1; status = create_synthetic_smb_fname(talloc_tos(), fname, NULL, NULL, &finfo.fsp_name); if (!NT_STATUS_IS_OK(status)) { conn_free(conn); return NULL; } if (!NT_STATUS_IS_OK(SMB_VFS_FGET_NT_ACL( &finfo, SECINFO_DACL, &psd))) { DEBUG(0,("get_nt_acl_no_snum: get_nt_acl returned zero.\n")); TALLOC_FREE(finfo.fsp_name); conn_free(conn); return NULL; } ret_sd = dup_sec_desc( ctx, psd ); TALLOC_FREE(finfo.fsp_name); conn_free(conn); return ret_sd; }