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samba-mirror/source3/passdb/pdb_ldap.c

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/*
Unix SMB/CIFS implementation.
LDAP protocol helper functions for SAMBA
Copyright (C) Jean Fran<EFBFBD>ois Micouleau 1998
Copyright (C) Gerald Carter 2001-2003
Copyright (C) Shahms King 2001
Copyright (C) Andrew Bartlett 2002-2003
Copyright (C) Stefan (metze) Metzmacher 2002-2003
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 2 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, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/* TODO:
* persistent connections: if using NSS LDAP, many connections are made
* however, using only one within Samba would be nice
*
* Clean up SSL stuff, compile on OpenLDAP 1.x, 2.x, and Netscape SDK
*
* Other LDAP based login attributes: accountExpires, etc.
* (should be the domain of Samba proper, but the sam_password/SAM_ACCOUNT
* structures don't have fields for some of these attributes)
*
* SSL is done, but can't get the certificate based authentication to work
* against on my test platform (Linux 2.4, OpenLDAP 2.x)
*/
/* NOTE: this will NOT work against an Active Directory server
* due to the fact that the two password fields cannot be retrieved
* from a server; recommend using security = domain in this situation
* and/or winbind
*/
#include "includes.h"
#undef DBGC_CLASS
#define DBGC_CLASS DBGC_PASSDB
#include <lber.h>
#include <ldap.h>
/*
* Work around versions of the LDAP client libs that don't have the OIDs
* defined, or have them defined under the old name.
* This functionality is really a factor of the server, not the client
*
*/
#if defined(LDAP_EXOP_X_MODIFY_PASSWD) && !defined(LDAP_EXOP_MODIFY_PASSWD)
#define LDAP_EXOP_MODIFY_PASSWD LDAP_EXOP_X_MODIFY_PASSWD
#elif !defined(LDAP_EXOP_MODIFY_PASSWD)
#define LDAP_EXOP_MODIFY_PASSWD "1.3.6.1.4.1.4203.1.11.1"
#endif
#if defined(LDAP_EXOP_X_MODIFY_PASSWD_ID) && !defined(LDAP_EXOP_MODIFY_PASSWD_ID)
#define LDAP_TAG_EXOP_MODIFY_PASSWD_ID LDAP_EXOP_X_MODIFY_PASSWD_ID
#elif !defined(LDAP_EXOP_MODIFY_PASSWD_ID)
#define LDAP_TAG_EXOP_MODIFY_PASSWD_ID ((ber_tag_t) 0x80U)
#endif
#if defined(LDAP_EXOP_X_MODIFY_PASSWD_NEW) && !defined(LDAP_EXOP_MODIFY_PASSWD_NEW)
#define LDAP_TAG_EXOP_MODIFY_PASSWD_NEW LDAP_EXOP_X_MODIFY_PASSWD_NEW
#elif !defined(LDAP_EXOP_MODIFY_PASSWD_NEW)
#define LDAP_TAG_EXOP_MODIFY_PASSWD_NEW ((ber_tag_t) 0x82U)
#endif
#ifndef SAM_ACCOUNT
#define SAM_ACCOUNT struct sam_passwd
#endif
#include "smbldap.h"
/**********************************************************************
Free a LDAPMessage (one is stored on the SAM_ACCOUNT).
**********************************************************************/
void private_data_free_fn(void **result)
{
ldap_msgfree(*result);
*result = NULL;
}
/**********************************************************************
Get the attribute name given a user schame version.
**********************************************************************/
static const char* get_userattr_key2string( int schema_ver, int key )
{
switch ( schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
return get_attr_key2string( attrib_map_v22, key );
case SCHEMAVER_SAMBASAMACCOUNT:
return get_attr_key2string( attrib_map_v30, key );
default:
DEBUG(0,("get_userattr_key2string: unknown schema version specified\n"));
break;
}
return NULL;
}
/**********************************************************************
Return the list of attribute names given a user schema version.
**********************************************************************/
const char** get_userattr_list( int schema_ver )
{
switch ( schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
return get_attr_list( attrib_map_v22 );
case SCHEMAVER_SAMBASAMACCOUNT:
return get_attr_list( attrib_map_v30 );
default:
DEBUG(0,("get_userattr_list: unknown schema version specified!\n"));
break;
}
return NULL;
}
/**************************************************************************
Return the list of attribute names to delete given a user schema version.
**************************************************************************/
static const char** get_userattr_delete_list( int schema_ver )
{
switch ( schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
return get_attr_list( attrib_map_to_delete_v22 );
case SCHEMAVER_SAMBASAMACCOUNT:
return get_attr_list( attrib_map_to_delete_v30 );
default:
DEBUG(0,("get_userattr_delete_list: unknown schema version specified!\n"));
break;
}
return NULL;
}
/*******************************************************************
Generate the LDAP search filter for the objectclass based on the
version of the schema we are using.
******************************************************************/
static const char* get_objclass_filter( int schema_ver )
{
static fstring objclass_filter;
switch( schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
fstr_sprintf( objclass_filter, "(objectclass=%s)", LDAP_OBJ_SAMBAACCOUNT );
break;
case SCHEMAVER_SAMBASAMACCOUNT:
fstr_sprintf( objclass_filter, "(objectclass=%s)", LDAP_OBJ_SAMBASAMACCOUNT );
break;
default:
DEBUG(0,("get_objclass_filter: Invalid schema version specified!\n"));
break;
}
return objclass_filter;
}
/*******************************************************************
Run the search by name.
******************************************************************/
int ldapsam_search_suffix_by_name(struct ldapsam_privates *ldap_state,
const char *user,
LDAPMessage ** result,
const char **attr)
{
pstring filter;
char *escape_user = escape_ldap_string_alloc(user);
if (!escape_user) {
return LDAP_NO_MEMORY;
}
/*
* in the filter expression, replace %u with the real name
* so in ldap filter, %u MUST exist :-)
*/
pstr_sprintf(filter, "(&%s%s)", lp_ldap_filter(),
get_objclass_filter(ldap_state->schema_ver));
/*
* have to use this here because $ is filtered out
* in pstring_sub
*/
all_string_sub(filter, "%u", escape_user, sizeof(pstring));
SAFE_FREE(escape_user);
return smbldap_search_suffix(ldap_state->smbldap_state, filter, attr, result);
}
/*******************************************************************
Run the search by rid.
******************************************************************/
static int ldapsam_search_suffix_by_rid (struct ldapsam_privates *ldap_state,
uint32 rid, LDAPMessage ** result,
const char **attr)
{
pstring filter;
int rc;
pstr_sprintf(filter, "(&(rid=%i)%s)", rid,
get_objclass_filter(ldap_state->schema_ver));
rc = smbldap_search_suffix(ldap_state->smbldap_state, filter, attr, result);
return rc;
}
/*******************************************************************
Run the search by SID.
******************************************************************/
static int ldapsam_search_suffix_by_sid (struct ldapsam_privates *ldap_state,
const DOM_SID *sid, LDAPMessage ** result,
const char **attr)
{
pstring filter;
int rc;
fstring sid_string;
pstr_sprintf(filter, "(&(%s=%s)%s)",
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID),
sid_to_string(sid_string, sid),
get_objclass_filter(ldap_state->schema_ver));
rc = smbldap_search_suffix(ldap_state->smbldap_state, filter, attr, result);
return rc;
}
/*******************************************************************
Delete complete object or objectclass and attrs from
object found in search_result depending on lp_ldap_delete_dn
******************************************************************/
static NTSTATUS ldapsam_delete_entry(struct ldapsam_privates *ldap_state,
LDAPMessage *result,
const char *objectclass,
const char **attrs)
{
int rc;
LDAPMessage *entry = NULL;
LDAPMod **mods = NULL;
char *name, *dn;
BerElement *ptr = NULL;
rc = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (rc != 1) {
DEBUG(0, ("ldapsam_delete_entry: Entry must exist exactly once!\n"));
return NT_STATUS_UNSUCCESSFUL;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!dn) {
return NT_STATUS_UNSUCCESSFUL;
}
if (lp_ldap_delete_dn()) {
NTSTATUS ret = NT_STATUS_OK;
rc = smbldap_delete(ldap_state->smbldap_state, dn);
if (rc != LDAP_SUCCESS) {
DEBUG(0, ("ldapsam_delete_entry: Could not delete object %s\n", dn));
ret = NT_STATUS_UNSUCCESSFUL;
}
SAFE_FREE(dn);
return ret;
}
/* Ok, delete only the SAM attributes */
for (name = ldap_first_attribute(ldap_state->smbldap_state->ldap_struct, entry, &ptr);
name != NULL;
name = ldap_next_attribute(ldap_state->smbldap_state->ldap_struct, entry, ptr)) {
const char **attrib;
/* We are only allowed to delete the attributes that
really exist. */
for (attrib = attrs; *attrib != NULL; attrib++) {
/* Don't delete LDAP_ATTR_MOD_TIMESTAMP attribute. */
if (strequal(*attrib, get_userattr_key2string(ldap_state->schema_ver,
LDAP_ATTR_MOD_TIMESTAMP))) {
continue;
}
if (strequal(*attrib, name)) {
DEBUG(10, ("ldapsam_delete_entry: deleting "
"attribute %s\n", name));
smbldap_set_mod(&mods, LDAP_MOD_DELETE, name,
NULL);
}
}
ldap_memfree(name);
}
if (ptr != NULL) {
ber_free(ptr, 0);
}
smbldap_set_mod(&mods, LDAP_MOD_DELETE, "objectClass", objectclass);
rc = smbldap_modify(ldap_state->smbldap_state, dn, mods);
ldap_mods_free(mods, True);
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0, ("ldapsam_delete_entry: Could not delete attributes for %s, error: %s (%s)\n",
dn, ldap_err2string(rc), ld_error?ld_error:"unknown"));
SAFE_FREE(ld_error);
SAFE_FREE(dn);
return NT_STATUS_UNSUCCESSFUL;
}
SAFE_FREE(dn);
return NT_STATUS_OK;
}
/* New Interface is being implemented here */
#if 0 /* JERRY - not uesed anymore */
/**********************************************************************
Initialize SAM_ACCOUNT from an LDAP query (unix attributes only)
*********************************************************************/
static BOOL get_unix_attributes (struct ldapsam_privates *ldap_state,
SAM_ACCOUNT * sampass,
LDAPMessage * entry,
gid_t *gid)
{
pstring homedir;
pstring temp;
char **ldap_values;
char **values;
if ((ldap_values = ldap_get_values (ldap_state->smbldap_state->ldap_struct, entry, "objectClass")) == NULL) {
DEBUG (1, ("get_unix_attributes: no objectClass! \n"));
return False;
}
for (values=ldap_values;*values;values++) {
if (strequal(*values, LDAP_OBJ_POSIXACCOUNT )) {
break;
}
}
if (!*values) { /*end of array, no posixAccount */
DEBUG(10, ("user does not have %s attributes\n", LDAP_OBJ_POSIXACCOUNT));
ldap_value_free(ldap_values);
return False;
}
ldap_value_free(ldap_values);
if ( !smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_UNIX_HOME), homedir) )
{
return False;
}
if ( !smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_GIDNUMBER), temp) )
{
return False;
}
*gid = (gid_t)atol(temp);
pdb_set_unix_homedir(sampass, homedir, PDB_SET);
DEBUG(10, ("user has %s attributes\n", LDAP_OBJ_POSIXACCOUNT));
return True;
}
#endif
static time_t ldapsam_get_entry_timestamp(
struct ldapsam_privates *ldap_state,
LDAPMessage * entry)
{
pstring temp;
struct tm tm;
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver,LDAP_ATTR_MOD_TIMESTAMP),
temp))
return (time_t) 0;
strptime(temp, "%Y%m%d%H%M%SZ", &tm);
tzset();
return timegm(&tm);
}
/**********************************************************************
Initialize SAM_ACCOUNT from an LDAP query.
(Based on init_sam_from_buffer in pdb_tdb.c)
*********************************************************************/
static BOOL init_sam_from_ldap(struct ldapsam_privates *ldap_state,
SAM_ACCOUNT * sampass,
LDAPMessage * entry)
{
time_t logon_time,
logoff_time,
kickoff_time,
pass_last_set_time,
pass_can_change_time,
pass_must_change_time,
ldap_entry_time,
bad_password_time;
pstring username,
domain,
nt_username,
fullname,
homedir,
dir_drive,
logon_script,
profile_path,
acct_desc,
workstations;
char munged_dial[2048];
uint32 user_rid;
uint8 smblmpwd[LM_HASH_LEN],
smbntpwd[NT_HASH_LEN];
BOOL use_samba_attrs = True;
uint16 acct_ctrl = 0,
logon_divs;
uint16 bad_password_count = 0,
logon_count = 0;
uint32 hours_len;
uint8 hours[MAX_HOURS_LEN];
pstring temp;
LOGIN_CACHE *cache_entry = NULL;
uint32 pwHistLen;
pstring tmpstring;
/*
* do a little initialization
*/
username[0] = '\0';
domain[0] = '\0';
nt_username[0] = '\0';
fullname[0] = '\0';
homedir[0] = '\0';
dir_drive[0] = '\0';
logon_script[0] = '\0';
profile_path[0] = '\0';
acct_desc[0] = '\0';
munged_dial[0] = '\0';
workstations[0] = '\0';
if (sampass == NULL || ldap_state == NULL || entry == NULL) {
DEBUG(0, ("init_sam_from_ldap: NULL parameters found!\n"));
return False;
}
if (ldap_state->smbldap_state->ldap_struct == NULL) {
DEBUG(0, ("init_sam_from_ldap: ldap_state->smbldap_state->ldap_struct is NULL!\n"));
return False;
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry, "uid", username)) {
DEBUG(1, ("init_sam_from_ldap: No uid attribute found for this user!\n"));
return False;
}
DEBUG(2, ("init_sam_from_ldap: Entry found for user: %s\n", username));
pstrcpy(nt_username, username);
pstrcpy(domain, ldap_state->domain_name);
pdb_set_username(sampass, username, PDB_SET);
pdb_set_domain(sampass, domain, PDB_DEFAULT);
pdb_set_nt_username(sampass, nt_username, PDB_SET);
/* deal with different attributes between the schema first */
if ( ldap_state->schema_ver == SCHEMAVER_SAMBASAMACCOUNT ) {
if (smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID), temp)) {
pdb_set_user_sid_from_string(sampass, temp, PDB_SET);
}
if (smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PRIMARY_GROUP_SID), temp)) {
pdb_set_group_sid_from_string(sampass, temp, PDB_SET);
} else {
pdb_set_group_sid_from_rid(sampass, DOMAIN_GROUP_RID_USERS, PDB_DEFAULT);
}
} else {
if (smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_RID), temp)) {
user_rid = (uint32)atol(temp);
pdb_set_user_sid_from_rid(sampass, user_rid, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PRIMARY_GROUP_RID), temp)) {
pdb_set_group_sid_from_rid(sampass, DOMAIN_GROUP_RID_USERS, PDB_DEFAULT);
} else {
uint32 group_rid;
group_rid = (uint32)atol(temp);
/* for some reason, we often have 0 as a primary group RID.
Make sure that we treat this just as a 'default' value */
if ( group_rid > 0 )
pdb_set_group_sid_from_rid(sampass, group_rid, PDB_SET);
else
pdb_set_group_sid_from_rid(sampass, DOMAIN_GROUP_RID_USERS, PDB_DEFAULT);
}
}
if (pdb_get_init_flags(sampass,PDB_USERSID) == PDB_DEFAULT) {
DEBUG(1, ("init_sam_from_ldap: no %s or %s attribute found for this user %s\n",
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID),
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_RID),
username));
return False;
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_LAST_SET), temp)) {
/* leave as default */
} else {
pass_last_set_time = (time_t) atol(temp);
pdb_set_pass_last_set_time(sampass, pass_last_set_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_TIME), temp)) {
/* leave as default */
} else {
logon_time = (time_t) atol(temp);
pdb_set_logon_time(sampass, logon_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGOFF_TIME), temp)) {
/* leave as default */
} else {
logoff_time = (time_t) atol(temp);
pdb_set_logoff_time(sampass, logoff_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_KICKOFF_TIME), temp)) {
/* leave as default */
} else {
kickoff_time = (time_t) atol(temp);
pdb_set_kickoff_time(sampass, kickoff_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_CAN_CHANGE), temp)) {
/* leave as default */
} else {
pass_can_change_time = (time_t) atol(temp);
pdb_set_pass_can_change_time(sampass, pass_can_change_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_MUST_CHANGE), temp)) {
/* leave as default */
} else {
pass_must_change_time = (time_t) atol(temp);
pdb_set_pass_must_change_time(sampass, pass_must_change_time, PDB_SET);
}
/* recommend that 'gecos' and 'displayName' should refer to the same
* attribute OID. userFullName depreciated, only used by Samba
* primary rules of LDAP: don't make a new attribute when one is already defined
* that fits your needs; using cn then displayName rather than 'userFullName'
*/
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_DISPLAY_NAME), fullname)) {
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_CN), fullname)) {
/* leave as default */
} else {
pdb_set_fullname(sampass, fullname, PDB_SET);
}
} else {
pdb_set_fullname(sampass, fullname, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_HOME_DRIVE), dir_drive))
{
pdb_set_dir_drive( sampass, lp_logon_drive(), PDB_DEFAULT );
} else {
pdb_set_dir_drive(sampass, dir_drive, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_HOME_PATH), homedir))
{
pdb_set_homedir( sampass,
talloc_sub_basic(sampass->mem_ctx, username, lp_logon_home()),
PDB_DEFAULT );
} else {
pstrcpy( tmpstring, homedir );
standard_sub_basic( username, tmpstring, sizeof(tmpstring) );
pdb_set_homedir(sampass, tmpstring, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_SCRIPT), logon_script))
{
pdb_set_logon_script( sampass,
talloc_sub_basic(sampass->mem_ctx, username, lp_logon_script()),
PDB_DEFAULT );
} else {
pstrcpy( tmpstring, logon_script );
standard_sub_basic( username, tmpstring, sizeof(tmpstring) );
pdb_set_logon_script(sampass, tmpstring, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PROFILE_PATH), profile_path))
{
pdb_set_profile_path( sampass,
talloc_sub_basic( sampass->mem_ctx, username, lp_logon_path()),
PDB_DEFAULT );
} else {
pstrcpy( tmpstring, profile_path );
standard_sub_basic( username, tmpstring, sizeof(tmpstring) );
pdb_set_profile_path(sampass, tmpstring, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_DESC), acct_desc))
{
/* leave as default */
} else {
pdb_set_acct_desc(sampass, acct_desc, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_WKS), workstations)) {
/* leave as default */;
} else {
pdb_set_workstations(sampass, workstations, PDB_SET);
}
if (!smbldap_get_single_attribute(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_MUNGED_DIAL), munged_dial, sizeof(munged_dial))) {
/* leave as default */;
} else {
pdb_set_munged_dial(sampass, munged_dial, PDB_SET);
}
/* FIXME: hours stuff should be cleaner */
logon_divs = 168;
hours_len = 21;
memset(hours, 0xff, hours_len);
if (ldap_state->is_nds_ldap) {
char *user_dn;
int pwd_len;
char clear_text_pw[512];
/* Make call to Novell eDirectory ldap extension to get clear text password.
NOTE: This will only work if we have an SSL connection to eDirectory. */
user_dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (user_dn != NULL) {
DEBUG(3, ("init_sam_from_ldap: smbldap_get_dn(%s) returned '%s'\n", username, user_dn));
pwd_len = sizeof(clear_text_pw);
if (pdb_nds_get_password(ldap_state->smbldap_state, user_dn, &pwd_len, clear_text_pw) == LDAP_SUCCESS) {
nt_lm_owf_gen(clear_text_pw, smbntpwd, smblmpwd);
if (!pdb_set_lanman_passwd(sampass, smblmpwd, PDB_SET))
return False;
ZERO_STRUCT(smblmpwd);
if (!pdb_set_nt_passwd(sampass, smbntpwd, PDB_SET))
return False;
ZERO_STRUCT(smbntpwd);
use_samba_attrs = False;
}
} else {
DEBUG(0, ("init_sam_from_ldap: failed to get user_dn for '%s'\n", username));
}
}
if (use_samba_attrs) {
if (!smbldap_get_single_pstring (ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LMPW), temp)) {
/* leave as default */
} else {
pdb_gethexpwd(temp, smblmpwd);
memset((char *)temp, '\0', strlen(temp)+1);
if (!pdb_set_lanman_passwd(sampass, smblmpwd, PDB_SET))
return False;
ZERO_STRUCT(smblmpwd);
}
if (!smbldap_get_single_pstring (ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_NTPW), temp)) {
/* leave as default */
} else {
pdb_gethexpwd(temp, smbntpwd);
memset((char *)temp, '\0', strlen(temp)+1);
if (!pdb_set_nt_passwd(sampass, smbntpwd, PDB_SET))
return False;
ZERO_STRUCT(smbntpwd);
}
}
account_policy_get(AP_PASSWORD_HISTORY, &pwHistLen);
if (pwHistLen > 0){
uint8 *pwhist = NULL;
int i;
/* We can only store (sizeof(pstring)-1)/64 password history entries. */
pwHistLen = MIN(pwHistLen, ((sizeof(temp)-1)/64));
if ((pwhist = SMB_MALLOC(pwHistLen * PW_HISTORY_ENTRY_LEN)) == NULL){
DEBUG(0, ("init_sam_from_ldap: malloc failed!\n"));
return False;
}
memset(pwhist, '\0', pwHistLen * PW_HISTORY_ENTRY_LEN);
if (!smbldap_get_single_pstring (ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_HISTORY), temp)) {
/* leave as default - zeros */
} else {
BOOL hex_failed = False;
for (i = 0; i < pwHistLen; i++){
/* Get the 16 byte salt. */
if (!pdb_gethexpwd(&temp[i*64], &pwhist[i*PW_HISTORY_ENTRY_LEN])) {
hex_failed = True;
break;
}
/* Get the 16 byte MD5 hash of salt+passwd. */
if (!pdb_gethexpwd(&temp[(i*64)+32],
&pwhist[(i*PW_HISTORY_ENTRY_LEN)+PW_HISTORY_SALT_LEN])) {
hex_failed = True;
break;
}
}
if (hex_failed) {
DEBUG(0,("init_sam_from_ldap: Failed to get password history for user %s\n",
username));
memset(pwhist, '\0', pwHistLen * PW_HISTORY_ENTRY_LEN);
}
}
if (!pdb_set_pw_history(sampass, pwhist, pwHistLen, PDB_SET)){
SAFE_FREE(pwhist);
return False;
}
SAFE_FREE(pwhist);
}
if (!smbldap_get_single_pstring (ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_ACB_INFO), temp)) {
acct_ctrl |= ACB_NORMAL;
} else {
acct_ctrl = pdb_decode_acct_ctrl(temp);
if (acct_ctrl == 0)
acct_ctrl |= ACB_NORMAL;
pdb_set_acct_ctrl(sampass, acct_ctrl, PDB_SET);
}
pdb_set_hours_len(sampass, hours_len, PDB_SET);
pdb_set_logon_divs(sampass, logon_divs, PDB_SET);
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_BAD_PASSWORD_COUNT), temp)) {
/* leave as default */
} else {
bad_password_count = (uint32) atol(temp);
pdb_set_bad_password_count(sampass, bad_password_count, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_BAD_PASSWORD_TIME), temp)) {
/* leave as default */
} else {
bad_password_time = (time_t) atol(temp);
pdb_set_bad_password_time(sampass, bad_password_time, PDB_SET);
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_COUNT), temp)) {
/* leave as default */
} else {
logon_count = (uint32) atol(temp);
pdb_set_logon_count(sampass, logon_count, PDB_SET);
}
/* pdb_set_unknown_6(sampass, unknown6, PDB_SET); */
if(!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_HOURS), temp)) {
/* leave as default */
} else {
pdb_gethexhours(temp, hours);
memset((char *)temp, '\0', strlen(temp) +1);
pdb_set_hours(sampass, hours, PDB_SET);
ZERO_STRUCT(hours);
}
/* check the timestamp of the cache vs ldap entry */
if (!(ldap_entry_time = ldapsam_get_entry_timestamp(ldap_state,
entry)))
return True;
/* see if we have newer updates */
if (!(cache_entry = login_cache_read(sampass))) {
DEBUG (9, ("No cache entry, bad count = %u, bad time = %u\n",
(unsigned int)pdb_get_bad_password_count(sampass),
(unsigned int)pdb_get_bad_password_time(sampass)));
return True;
}
DEBUG(7, ("ldap time is %u, cache time is %u, bad time = %u\n",
(unsigned int)ldap_entry_time, (unsigned int)cache_entry->entry_timestamp,
(unsigned int)cache_entry->bad_password_time));
if (ldap_entry_time > cache_entry->entry_timestamp) {
/* cache is older than directory , so
we need to delete the entry but allow the
fields to be written out */
login_cache_delentry(sampass);
} else {
/* read cache in */
pdb_set_acct_ctrl(sampass,
pdb_get_acct_ctrl(sampass) |
(cache_entry->acct_ctrl & ACB_AUTOLOCK),
PDB_SET);
pdb_set_bad_password_count(sampass,
cache_entry->bad_password_count,
PDB_SET);
pdb_set_bad_password_time(sampass,
cache_entry->bad_password_time,
PDB_SET);
}
SAFE_FREE(cache_entry);
return True;
}
/**********************************************************************
Initialize the ldap db from a SAM_ACCOUNT. Called on update.
(Based on init_buffer_from_sam in pdb_tdb.c)
*********************************************************************/
static BOOL init_ldap_from_sam (struct ldapsam_privates *ldap_state,
LDAPMessage *existing,
LDAPMod *** mods, SAM_ACCOUNT * sampass,
BOOL (*need_update)(const SAM_ACCOUNT *,
enum pdb_elements))
{
pstring temp;
uint32 rid;
if (mods == NULL || sampass == NULL) {
DEBUG(0, ("init_ldap_from_sam: NULL parameters found!\n"));
return False;
}
*mods = NULL;
/*
* took out adding "objectclass: sambaAccount"
* do this on a per-mod basis
*/
if (need_update(sampass, PDB_USERNAME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
"uid", pdb_get_username(sampass));
DEBUG(2, ("init_ldap_from_sam: Setting entry for user: %s\n", pdb_get_username(sampass)));
/* only update the RID if we actually need to */
if (need_update(sampass, PDB_USERSID)) {
fstring sid_string;
fstring dom_sid_string;
const DOM_SID *user_sid = pdb_get_user_sid(sampass);
switch ( ldap_state->schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if (!sid_peek_check_rid(&ldap_state->domain_sid, user_sid, &rid)) {
DEBUG(1, ("init_ldap_from_sam: User's SID (%s) is not for this domain (%s), cannot add to LDAP!\n",
sid_to_string(sid_string, user_sid),
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
sid_to_string(dom_sid_string, &ldap_state->domain_sid)));
return False;
}
slprintf(temp, sizeof(temp) - 1, "%i", rid);
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_RID),
temp);
break;
case SCHEMAVER_SAMBASAMACCOUNT:
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID),
sid_to_string(sid_string, user_sid));
break;
default:
DEBUG(0,("init_ldap_from_sam: unknown schema version specified\n"));
break;
}
}
/* we don't need to store the primary group RID - so leaving it
'free' to hang off the unix primary group makes life easier */
if (need_update(sampass, PDB_GROUPSID)) {
fstring sid_string;
fstring dom_sid_string;
const DOM_SID *group_sid = pdb_get_group_sid(sampass);
switch ( ldap_state->schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if (!sid_peek_check_rid(&ldap_state->domain_sid, group_sid, &rid)) {
DEBUG(1, ("init_ldap_from_sam: User's Primary Group SID (%s) is not for this domain (%s), cannot add to LDAP!\n",
sid_to_string(sid_string, group_sid),
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
sid_to_string(dom_sid_string, &ldap_state->domain_sid)));
return False;
}
slprintf(temp, sizeof(temp) - 1, "%i", rid);
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver,
LDAP_ATTR_PRIMARY_GROUP_RID), temp);
break;
case SCHEMAVER_SAMBASAMACCOUNT:
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver,
LDAP_ATTR_PRIMARY_GROUP_SID), sid_to_string(sid_string, group_sid));
break;
default:
DEBUG(0,("init_ldap_from_sam: unknown schema version specified\n"));
break;
}
}
/* displayName, cn, and gecos should all be the same
* most easily accomplished by giving them the same OID
* gecos isn't set here b/c it should be handled by the
* add-user script
* We change displayName only and fall back to cn if
* it does not exist.
*/
if (need_update(sampass, PDB_FULLNAME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_DISPLAY_NAME),
pdb_get_fullname(sampass));
if (need_update(sampass, PDB_ACCTDESC))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_DESC),
pdb_get_acct_desc(sampass));
if (need_update(sampass, PDB_WORKSTATIONS))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_WKS),
pdb_get_workstations(sampass));
if (need_update(sampass, PDB_MUNGEDDIAL))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_MUNGED_DIAL),
pdb_get_munged_dial(sampass));
if (need_update(sampass, PDB_SMBHOME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_HOME_PATH),
pdb_get_homedir(sampass));
if (need_update(sampass, PDB_DRIVE))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_HOME_DRIVE),
pdb_get_dir_drive(sampass));
if (need_update(sampass, PDB_LOGONSCRIPT))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_SCRIPT),
pdb_get_logon_script(sampass));
if (need_update(sampass, PDB_PROFILE))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PROFILE_PATH),
pdb_get_profile_path(sampass));
slprintf(temp, sizeof(temp) - 1, "%li", pdb_get_logon_time(sampass));
if (need_update(sampass, PDB_LOGONTIME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGON_TIME), temp);
slprintf(temp, sizeof(temp) - 1, "%li", pdb_get_logoff_time(sampass));
if (need_update(sampass, PDB_LOGOFFTIME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LOGOFF_TIME), temp);
slprintf (temp, sizeof (temp) - 1, "%li", pdb_get_kickoff_time(sampass));
if (need_update(sampass, PDB_KICKOFFTIME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_KICKOFF_TIME), temp);
slprintf (temp, sizeof (temp) - 1, "%li", pdb_get_pass_can_change_time(sampass));
if (need_update(sampass, PDB_CANCHANGETIME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_CAN_CHANGE), temp);
slprintf (temp, sizeof (temp) - 1, "%li", pdb_get_pass_must_change_time(sampass));
if (need_update(sampass, PDB_MUSTCHANGETIME))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_MUST_CHANGE), temp);
if ((pdb_get_acct_ctrl(sampass)&(ACB_WSTRUST|ACB_SVRTRUST|ACB_DOMTRUST))
|| (lp_ldap_passwd_sync()!=LDAP_PASSWD_SYNC_ONLY)) {
if (need_update(sampass, PDB_LMPASSWD)) {
const uchar *lm_pw = pdb_get_lanman_passwd(sampass);
if (lm_pw) {
pdb_sethexpwd(temp, lm_pw,
pdb_get_acct_ctrl(sampass));
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LMPW),
temp);
} else {
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_LMPW),
NULL);
}
}
if (need_update(sampass, PDB_NTPASSWD)) {
const uchar *nt_pw = pdb_get_nt_passwd(sampass);
if (nt_pw) {
pdb_sethexpwd(temp, nt_pw,
pdb_get_acct_ctrl(sampass));
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_NTPW),
temp);
} else {
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_NTPW),
NULL);
}
}
if (need_update(sampass, PDB_PWHISTORY)) {
uint32 pwHistLen = 0;
account_policy_get(AP_PASSWORD_HISTORY, &pwHistLen);
if (pwHistLen == 0) {
/* Remove any password history from the LDAP store. */
memset(temp, '0', 64); /* NOTE !!!! '0' *NOT '\0' */
temp[64] = '\0';
} else {
int i;
uint32 currHistLen = 0;
const uint8 *pwhist = pdb_get_pw_history(sampass, &currHistLen);
if (pwhist != NULL) {
/* We can only store (sizeof(pstring)-1)/64 password history entries. */
pwHistLen = MIN(pwHistLen, ((sizeof(temp)-1)/64));
for (i=0; i< pwHistLen && i < currHistLen; i++) {
/* Store the salt. */
pdb_sethexpwd(&temp[i*64], &pwhist[i*PW_HISTORY_ENTRY_LEN], 0);
/* Followed by the md5 hash of salt + md4 hash */
pdb_sethexpwd(&temp[(i*64)+32],
&pwhist[(i*PW_HISTORY_ENTRY_LEN)+PW_HISTORY_SALT_LEN], 0);
DEBUG(100, ("temp=%s\n", temp));
}
}
}
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_HISTORY),
temp);
}
if (need_update(sampass, PDB_PASSLASTSET)) {
slprintf (temp, sizeof (temp) - 1, "%li", pdb_get_pass_last_set_time(sampass));
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_PWD_LAST_SET),
temp);
}
}
if (need_update(sampass, PDB_HOURS)) {
const uint8 *hours = pdb_get_hours(sampass);
if (hours) {
pdb_sethexhours(temp, hours);
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct,
existing,
mods,
get_userattr_key2string(ldap_state->schema_ver,
LDAP_ATTR_LOGON_HOURS),
temp);
}
}
if (need_update(sampass, PDB_ACCTCTRL))
smbldap_make_mod(ldap_state->smbldap_state->ldap_struct, existing, mods,
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_ACB_INFO),
pdb_encode_acct_ctrl (pdb_get_acct_ctrl(sampass), NEW_PW_FORMAT_SPACE_PADDED_LEN));
/* password lockout cache:
- If we are now autolocking or clearing, we write to ldap
- If we are clearing, we delete the cache entry
- If the count is > 0, we update the cache
This even means when autolocking, we cache, just in case the
update doesn't work, and we have to cache the autolock flag */
if (need_update(sampass, PDB_BAD_PASSWORD_COUNT)) /* &&
need_update(sampass, PDB_BAD_PASSWORD_TIME)) */ {
uint16 badcount = pdb_get_bad_password_count(sampass);
time_t badtime = pdb_get_bad_password_time(sampass);
uint32 pol;
account_policy_get(AP_BAD_ATTEMPT_LOCKOUT, &pol);
DEBUG(3, ("updating bad password fields, policy=%u, count=%u, time=%u\n",
(unsigned int)pol, (unsigned int)badcount, (unsigned int)badtime));
if ((badcount >= pol) || (badcount == 0)) {
DEBUG(7, ("making mods to update ldap, count=%u, time=%u\n",
(unsigned int)badcount, (unsigned int)badtime));
slprintf (temp, sizeof (temp) - 1, "%li", (long)badcount);
smbldap_make_mod(
ldap_state->smbldap_state->ldap_struct,
existing, mods,
get_userattr_key2string(
ldap_state->schema_ver,
LDAP_ATTR_BAD_PASSWORD_COUNT),
temp);
slprintf (temp, sizeof (temp) - 1, "%li", badtime);
smbldap_make_mod(
ldap_state->smbldap_state->ldap_struct,
existing, mods,
get_userattr_key2string(
ldap_state->schema_ver,
LDAP_ATTR_BAD_PASSWORD_TIME),
temp);
}
if (badcount == 0) {
DEBUG(7, ("bad password count is reset, deleting login cache entry for %s\n", pdb_get_nt_username(sampass)));
login_cache_delentry(sampass);
} else {
LOGIN_CACHE cache_entry;
cache_entry.entry_timestamp = time(NULL);
cache_entry.acct_ctrl = pdb_get_acct_ctrl(sampass);
cache_entry.bad_password_count = badcount;
cache_entry.bad_password_time = badtime;
DEBUG(7, ("Updating bad password count and time in login cache\n"));
login_cache_write(sampass, cache_entry);
}
}
return True;
}
/**********************************************************************
Connect to LDAP server for password enumeration.
*********************************************************************/
static NTSTATUS ldapsam_setsampwent(struct pdb_methods *my_methods, BOOL update, uint16 acb_mask)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
int rc;
pstring filter, suffix;
const char **attr_list;
BOOL machine_mask = False, user_mask = False;
pstr_sprintf( filter, "(&%s%s)", lp_ldap_filter(),
get_objclass_filter(ldap_state->schema_ver));
all_string_sub(filter, "%u", "*", sizeof(pstring));
machine_mask = ((acb_mask != 0) && (acb_mask & (ACB_WSTRUST|ACB_SVRTRUST|ACB_DOMTRUST)));
user_mask = ((acb_mask != 0) && (acb_mask & ACB_NORMAL));
if (machine_mask) {
pstrcpy(suffix, lp_ldap_machine_suffix());
} else if (user_mask) {
pstrcpy(suffix, lp_ldap_user_suffix());
} else {
pstrcpy(suffix, lp_ldap_suffix());
}
DEBUG(10,("ldapsam_setsampwent: LDAP Query for acb_mask 0x%x will use suffix %s\n",
acb_mask, suffix));
attr_list = get_userattr_list(ldap_state->schema_ver);
rc = smbldap_search(ldap_state->smbldap_state, suffix, LDAP_SCOPE_SUBTREE, filter,
attr_list, 0, &ldap_state->result);
free_attr_list( attr_list );
if (rc != LDAP_SUCCESS) {
DEBUG(0, ("ldapsam_setsampwent: LDAP search failed: %s\n", ldap_err2string(rc)));
DEBUG(3, ("ldapsam_setsampwent: Query was: %s, %s\n", suffix, filter));
ldap_msgfree(ldap_state->result);
ldap_state->result = NULL;
return NT_STATUS_UNSUCCESSFUL;
}
DEBUG(2, ("ldapsam_setsampwent: %d entries in the base %s\n",
ldap_count_entries(ldap_state->smbldap_state->ldap_struct,
ldap_state->result), suffix));
ldap_state->entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct,
ldap_state->result);
ldap_state->index = 0;
return NT_STATUS_OK;
}
/**********************************************************************
End enumeration of the LDAP password list.
*********************************************************************/
static void ldapsam_endsampwent(struct pdb_methods *my_methods)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
if (ldap_state->result) {
ldap_msgfree(ldap_state->result);
ldap_state->result = NULL;
}
}
/**********************************************************************
Get the next entry in the LDAP password database.
*********************************************************************/
static NTSTATUS ldapsam_getsampwent(struct pdb_methods *my_methods, SAM_ACCOUNT *user)
{
NTSTATUS ret = NT_STATUS_UNSUCCESSFUL;
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
BOOL bret = False;
while (!bret) {
if (!ldap_state->entry)
return ret;
ldap_state->index++;
bret = init_sam_from_ldap(ldap_state, user, ldap_state->entry);
ldap_state->entry = ldap_next_entry(ldap_state->smbldap_state->ldap_struct,
ldap_state->entry);
}
return NT_STATUS_OK;
}
static void append_attr(const char ***attr_list, const char *new_attr)
r1108: Index: pdb_ldap.c =================================================================== --- pdb_ldap.c (revision 1095) +++ pdb_ldap.c (working copy) @@ -1134,6 +1134,19 @@ return NT_STATUS_OK; } +static void append_attr(char ***attr_list, const char *new_attr) +{ + int i; + + for (i=0; (*attr_list)[i] != NULL; i++) + ; + + (*attr_list) = Realloc((*attr_list), sizeof(**attr_list) * (i+2)); + SMB_ASSERT((*attr_list) != NULL); + (*attr_list)[i] = strdup(new_attr); + (*attr_list)[i+1] = NULL; +} + /********************************************************************** Get SAM_ACCOUNT entry from LDAP by username. *********************************************************************/ @@ -1149,6 +1162,7 @@ int rc; attr_list = get_userattr_list( ldap_state->schema_ver ); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list); free_attr_list( attr_list ); @@ -1194,6 +1208,7 @@ switch ( ldap_state->schema_ver ) { case SCHEMAVER_SAMBASAMACCOUNT: attr_list = get_userattr_list(ldap_state->schema_ver); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list); free_attr_list( attr_list ); Index: login_cache.c =================================================================== --- login_cache.c (revision 1095) +++ login_cache.c (working copy) @@ -95,10 +95,13 @@ &entry->bad_password_count, &entry->bad_password_time) == -1) { DEBUG(7, ("No cache entry found\n")); + SAFE_FREE(entry); SAFE_FREE(databuf.dptr); return NULL; } + SAFE_FREE(databuf.dptr); + DEBUG(5, ("Found login cache entry: timestamp %12u, flags 0x%x, count %d, time %12u\n", (unsigned int)entry->entry_timestamp, entry->acct_ctrl, entry->bad_password_count, (unsigned int)entry->bad_password_time)); (This used to be commit c0bf8425f4b9ee30ffc878704bde980d8c51ed05)
2004-06-10 21:42:16 +04:00
{
int i;
if (new_attr == NULL) {
return;
}
for (i=0; (*attr_list)[i] != NULL; i++) {
r1108: Index: pdb_ldap.c =================================================================== --- pdb_ldap.c (revision 1095) +++ pdb_ldap.c (working copy) @@ -1134,6 +1134,19 @@ return NT_STATUS_OK; } +static void append_attr(char ***attr_list, const char *new_attr) +{ + int i; + + for (i=0; (*attr_list)[i] != NULL; i++) + ; + + (*attr_list) = Realloc((*attr_list), sizeof(**attr_list) * (i+2)); + SMB_ASSERT((*attr_list) != NULL); + (*attr_list)[i] = strdup(new_attr); + (*attr_list)[i+1] = NULL; +} + /********************************************************************** Get SAM_ACCOUNT entry from LDAP by username. *********************************************************************/ @@ -1149,6 +1162,7 @@ int rc; attr_list = get_userattr_list( ldap_state->schema_ver ); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list); free_attr_list( attr_list ); @@ -1194,6 +1208,7 @@ switch ( ldap_state->schema_ver ) { case SCHEMAVER_SAMBASAMACCOUNT: attr_list = get_userattr_list(ldap_state->schema_ver); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list); free_attr_list( attr_list ); Index: login_cache.c =================================================================== --- login_cache.c (revision 1095) +++ login_cache.c (working copy) @@ -95,10 +95,13 @@ &entry->bad_password_count, &entry->bad_password_time) == -1) { DEBUG(7, ("No cache entry found\n")); + SAFE_FREE(entry); SAFE_FREE(databuf.dptr); return NULL; } + SAFE_FREE(databuf.dptr); + DEBUG(5, ("Found login cache entry: timestamp %12u, flags 0x%x, count %d, time %12u\n", (unsigned int)entry->entry_timestamp, entry->acct_ctrl, entry->bad_password_count, (unsigned int)entry->bad_password_time)); (This used to be commit c0bf8425f4b9ee30ffc878704bde980d8c51ed05)
2004-06-10 21:42:16 +04:00
;
}
r1108: Index: pdb_ldap.c =================================================================== --- pdb_ldap.c (revision 1095) +++ pdb_ldap.c (working copy) @@ -1134,6 +1134,19 @@ return NT_STATUS_OK; } +static void append_attr(char ***attr_list, const char *new_attr) +{ + int i; + + for (i=0; (*attr_list)[i] != NULL; i++) + ; + + (*attr_list) = Realloc((*attr_list), sizeof(**attr_list) * (i+2)); + SMB_ASSERT((*attr_list) != NULL); + (*attr_list)[i] = strdup(new_attr); + (*attr_list)[i+1] = NULL; +} + /********************************************************************** Get SAM_ACCOUNT entry from LDAP by username. *********************************************************************/ @@ -1149,6 +1162,7 @@ int rc; attr_list = get_userattr_list( ldap_state->schema_ver ); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list); free_attr_list( attr_list ); @@ -1194,6 +1208,7 @@ switch ( ldap_state->schema_ver ) { case SCHEMAVER_SAMBASAMACCOUNT: attr_list = get_userattr_list(ldap_state->schema_ver); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list); free_attr_list( attr_list ); Index: login_cache.c =================================================================== --- login_cache.c (revision 1095) +++ login_cache.c (working copy) @@ -95,10 +95,13 @@ &entry->bad_password_count, &entry->bad_password_time) == -1) { DEBUG(7, ("No cache entry found\n")); + SAFE_FREE(entry); SAFE_FREE(databuf.dptr); return NULL; } + SAFE_FREE(databuf.dptr); + DEBUG(5, ("Found login cache entry: timestamp %12u, flags 0x%x, count %d, time %12u\n", (unsigned int)entry->entry_timestamp, entry->acct_ctrl, entry->bad_password_count, (unsigned int)entry->bad_password_time)); (This used to be commit c0bf8425f4b9ee30ffc878704bde980d8c51ed05)
2004-06-10 21:42:16 +04:00
(*attr_list) = SMB_REALLOC_ARRAY((*attr_list), const char *, i+2);
r1108: Index: pdb_ldap.c =================================================================== --- pdb_ldap.c (revision 1095) +++ pdb_ldap.c (working copy) @@ -1134,6 +1134,19 @@ return NT_STATUS_OK; } +static void append_attr(char ***attr_list, const char *new_attr) +{ + int i; + + for (i=0; (*attr_list)[i] != NULL; i++) + ; + + (*attr_list) = Realloc((*attr_list), sizeof(**attr_list) * (i+2)); + SMB_ASSERT((*attr_list) != NULL); + (*attr_list)[i] = strdup(new_attr); + (*attr_list)[i+1] = NULL; +} + /********************************************************************** Get SAM_ACCOUNT entry from LDAP by username. *********************************************************************/ @@ -1149,6 +1162,7 @@ int rc; attr_list = get_userattr_list( ldap_state->schema_ver ); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list); free_attr_list( attr_list ); @@ -1194,6 +1208,7 @@ switch ( ldap_state->schema_ver ) { case SCHEMAVER_SAMBASAMACCOUNT: attr_list = get_userattr_list(ldap_state->schema_ver); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list); free_attr_list( attr_list ); Index: login_cache.c =================================================================== --- login_cache.c (revision 1095) +++ login_cache.c (working copy) @@ -95,10 +95,13 @@ &entry->bad_password_count, &entry->bad_password_time) == -1) { DEBUG(7, ("No cache entry found\n")); + SAFE_FREE(entry); SAFE_FREE(databuf.dptr); return NULL; } + SAFE_FREE(databuf.dptr); + DEBUG(5, ("Found login cache entry: timestamp %12u, flags 0x%x, count %d, time %12u\n", (unsigned int)entry->entry_timestamp, entry->acct_ctrl, entry->bad_password_count, (unsigned int)entry->bad_password_time)); (This used to be commit c0bf8425f4b9ee30ffc878704bde980d8c51ed05)
2004-06-10 21:42:16 +04:00
SMB_ASSERT((*attr_list) != NULL);
(*attr_list)[i] = SMB_STRDUP(new_attr);
r1108: Index: pdb_ldap.c =================================================================== --- pdb_ldap.c (revision 1095) +++ pdb_ldap.c (working copy) @@ -1134,6 +1134,19 @@ return NT_STATUS_OK; } +static void append_attr(char ***attr_list, const char *new_attr) +{ + int i; + + for (i=0; (*attr_list)[i] != NULL; i++) + ; + + (*attr_list) = Realloc((*attr_list), sizeof(**attr_list) * (i+2)); + SMB_ASSERT((*attr_list) != NULL); + (*attr_list)[i] = strdup(new_attr); + (*attr_list)[i+1] = NULL; +} + /********************************************************************** Get SAM_ACCOUNT entry from LDAP by username. *********************************************************************/ @@ -1149,6 +1162,7 @@ int rc; attr_list = get_userattr_list( ldap_state->schema_ver ); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list); free_attr_list( attr_list ); @@ -1194,6 +1208,7 @@ switch ( ldap_state->schema_ver ) { case SCHEMAVER_SAMBASAMACCOUNT: attr_list = get_userattr_list(ldap_state->schema_ver); + append_attr(&attr_list, MODIFY_TIMESTAMP_STRING); rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list); free_attr_list( attr_list ); Index: login_cache.c =================================================================== --- login_cache.c (revision 1095) +++ login_cache.c (working copy) @@ -95,10 +95,13 @@ &entry->bad_password_count, &entry->bad_password_time) == -1) { DEBUG(7, ("No cache entry found\n")); + SAFE_FREE(entry); SAFE_FREE(databuf.dptr); return NULL; } + SAFE_FREE(databuf.dptr); + DEBUG(5, ("Found login cache entry: timestamp %12u, flags 0x%x, count %d, time %12u\n", (unsigned int)entry->entry_timestamp, entry->acct_ctrl, entry->bad_password_count, (unsigned int)entry->bad_password_time)); (This used to be commit c0bf8425f4b9ee30ffc878704bde980d8c51ed05)
2004-06-10 21:42:16 +04:00
(*attr_list)[i+1] = NULL;
}
/**********************************************************************
Get SAM_ACCOUNT entry from LDAP by username.
*********************************************************************/
static NTSTATUS ldapsam_getsampwnam(struct pdb_methods *my_methods, SAM_ACCOUNT *user, const char *sname)
{
NTSTATUS ret = NT_STATUS_UNSUCCESSFUL;
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
int count;
const char ** attr_list;
int rc;
attr_list = get_userattr_list( ldap_state->schema_ver );
append_attr(&attr_list, get_userattr_key2string(ldap_state->schema_ver,LDAP_ATTR_MOD_TIMESTAMP));
rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list);
free_attr_list( attr_list );
if ( rc != LDAP_SUCCESS )
return NT_STATUS_NO_SUCH_USER;
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (count < 1) {
DEBUG(4, ("ldapsam_getsampwnam: Unable to locate user [%s] count=%d\n", sname, count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
} else if (count > 1) {
DEBUG(1, ("ldapsam_getsampwnam: Duplicate entries for this user [%s] Failing. count=%d\n", sname, count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
if (entry) {
if (!init_sam_from_ldap(ldap_state, user, entry)) {
DEBUG(1,("ldapsam_getsampwnam: init_sam_from_ldap failed for user '%s'!\n", sname));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
}
pdb_set_backend_private_data(user, result,
private_data_free_fn,
my_methods, PDB_CHANGED);
ret = NT_STATUS_OK;
} else {
ldap_msgfree(result);
}
return ret;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
static int ldapsam_get_ldap_user_by_sid(struct ldapsam_privates *ldap_state,
const DOM_SID *sid, LDAPMessage **result)
{
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
int rc = -1;
const char ** attr_list;
uint32 rid;
switch ( ldap_state->schema_ver ) {
case SCHEMAVER_SAMBASAMACCOUNT:
attr_list = get_userattr_list(ldap_state->schema_ver);
append_attr(&attr_list, get_userattr_key2string(ldap_state->schema_ver,LDAP_ATTR_MOD_TIMESTAMP));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
rc = ldapsam_search_suffix_by_sid(ldap_state, sid, result, attr_list);
free_attr_list( attr_list );
if ( rc != LDAP_SUCCESS )
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
return rc;
break;
case SCHEMAVER_SAMBAACCOUNT:
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if (!sid_peek_check_rid(&ldap_state->domain_sid, sid, &rid)) {
return rc;
}
attr_list = get_userattr_list(ldap_state->schema_ver);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
rc = ldapsam_search_suffix_by_rid(ldap_state, rid, result, attr_list );
free_attr_list( attr_list );
if ( rc != LDAP_SUCCESS )
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
return rc;
break;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
return rc;
}
/**********************************************************************
Get SAM_ACCOUNT entry from LDAP by SID.
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
*********************************************************************/
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
static NTSTATUS ldapsam_getsampwsid(struct pdb_methods *my_methods, SAM_ACCOUNT * user, const DOM_SID *sid)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
int count;
int rc;
fstring sid_string;
rc = ldapsam_get_ldap_user_by_sid(ldap_state,
sid, &result);
if (rc != LDAP_SUCCESS)
return NT_STATUS_NO_SUCH_USER;
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (count < 1) {
DEBUG(4, ("ldapsam_getsampwsid: Unable to locate SID [%s] count=%d\n", sid_to_string(sid_string, sid),
count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
} else if (count > 1) {
DEBUG(1, ("ldapsam_getsampwsid: More than one user with SID [%s]. Failing. count=%d\n", sid_to_string(sid_string, sid),
count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
if (!entry) {
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
}
if (!init_sam_from_ldap(ldap_state, user, entry)) {
DEBUG(1,("ldapsam_getsampwsid: init_sam_from_ldap failed!\n"));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_USER;
}
pdb_set_backend_private_data(user, result,
private_data_free_fn,
my_methods, PDB_CHANGED);
return NT_STATUS_OK;
}
static BOOL ldapsam_can_pwchange_exop(struct smbldap_state *ldap_state)
{
return smbldap_has_extension(ldap_state, LDAP_EXOP_MODIFY_PASSWD);
}
/********************************************************************
Do the actual modification - also change a plaintext passord if
it it set.
**********************************************************************/
static NTSTATUS ldapsam_modify_entry(struct pdb_methods *my_methods,
SAM_ACCOUNT *newpwd, char *dn,
LDAPMod **mods, int ldap_op,
BOOL (*need_update)(const SAM_ACCOUNT *, enum pdb_elements))
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
int rc;
if (!my_methods || !newpwd || !dn) {
return NT_STATUS_INVALID_PARAMETER;
}
if (!mods) {
DEBUG(5,("ldapsam_modify_entry: mods is empty: nothing to modify\n"));
/* may be password change below however */
} else {
switch(ldap_op) {
case LDAP_MOD_ADD:
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
smbldap_set_mod(&mods, LDAP_MOD_ADD,
"objectclass",
LDAP_OBJ_ACCOUNT);
rc = smbldap_add(ldap_state->smbldap_state,
dn, mods);
break;
case LDAP_MOD_REPLACE:
rc = smbldap_modify(ldap_state->smbldap_state,
dn ,mods);
break;
default:
DEBUG(0,("ldapsam_modify_entry: Wrong LDAP operation type: %d!\n",
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
ldap_op));
return NT_STATUS_INVALID_PARAMETER;
}
if (rc!=LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(1, ("ldapsam_modify_entry: Failed to %s user dn= %s with: %s\n\t%s\n",
ldap_op == LDAP_MOD_ADD ? "add" : "modify",
dn, ldap_err2string(rc),
ld_error?ld_error:"unknown"));
SAFE_FREE(ld_error);
return NT_STATUS_UNSUCCESSFUL;
}
}
if (!(pdb_get_acct_ctrl(newpwd)&(ACB_WSTRUST|ACB_SVRTRUST|ACB_DOMTRUST)) &&
(lp_ldap_passwd_sync() != LDAP_PASSWD_SYNC_OFF) &&
need_update(newpwd, PDB_PLAINTEXT_PW) &&
(pdb_get_plaintext_passwd(newpwd)!=NULL)) {
BerElement *ber;
struct berval *bv;
char *retoid = NULL;
struct berval *retdata = NULL;
char *utf8_password;
char *utf8_dn;
if (!ldap_state->is_nds_ldap) {
if (!ldapsam_can_pwchange_exop(ldap_state->smbldap_state)) {
DEBUG(2, ("ldap password change requested, but LDAP "
"server does not support it -- ignoring\n"));
return NT_STATUS_OK;
}
}
if (push_utf8_allocate(&utf8_password, pdb_get_plaintext_passwd(newpwd)) == (size_t)-1) {
return NT_STATUS_NO_MEMORY;
}
if (push_utf8_allocate(&utf8_dn, dn) == (size_t)-1) {
return NT_STATUS_NO_MEMORY;
}
if ((ber = ber_alloc_t(LBER_USE_DER))==NULL) {
DEBUG(0,("ber_alloc_t returns NULL\n"));
SAFE_FREE(utf8_password);
return NT_STATUS_UNSUCCESSFUL;
}
ber_printf (ber, "{");
ber_printf (ber, "ts", LDAP_TAG_EXOP_MODIFY_PASSWD_ID, utf8_dn);
ber_printf (ber, "ts", LDAP_TAG_EXOP_MODIFY_PASSWD_NEW, utf8_password);
ber_printf (ber, "N}");
if ((rc = ber_flatten (ber, &bv))<0) {
DEBUG(0,("ldapsam_modify_entry: ber_flatten returns a value <0\n"));
ber_free(ber,1);
SAFE_FREE(utf8_dn);
SAFE_FREE(utf8_password);
return NT_STATUS_UNSUCCESSFUL;
}
SAFE_FREE(utf8_dn);
SAFE_FREE(utf8_password);
ber_free(ber, 1);
if (!ldap_state->is_nds_ldap) {
rc = smbldap_extended_operation(ldap_state->smbldap_state,
LDAP_EXOP_MODIFY_PASSWD,
bv, NULL, NULL, &retoid,
&retdata);
} else {
rc = pdb_nds_set_password(ldap_state->smbldap_state, dn,
pdb_get_plaintext_passwd(newpwd));
}
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
if (rc == LDAP_OBJECT_CLASS_VIOLATION) {
DEBUG(3, ("Could not set userPassword "
"attribute due to an objectClass "
"violation -- ignoring\n"));
ber_bvfree(bv);
return NT_STATUS_OK;
}
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0,("ldapsam_modify_entry: LDAP Password could not be changed for user %s: %s\n\t%s\n",
pdb_get_username(newpwd), ldap_err2string(rc), ld_error?ld_error:"unknown"));
SAFE_FREE(ld_error);
ber_bvfree(bv);
return NT_STATUS_UNSUCCESSFUL;
} else {
DEBUG(3,("ldapsam_modify_entry: LDAP Password changed for user %s\n",pdb_get_username(newpwd)));
#ifdef DEBUG_PASSWORD
DEBUG(100,("ldapsam_modify_entry: LDAP Password changed to %s\n",pdb_get_plaintext_passwd(newpwd)));
#endif
if (retdata)
ber_bvfree(retdata);
if (retoid)
ber_memfree(retoid);
}
ber_bvfree(bv);
}
return NT_STATUS_OK;
}
/**********************************************************************
Delete entry from LDAP for username.
*********************************************************************/
static NTSTATUS ldapsam_delete_sam_account(struct pdb_methods *my_methods, SAM_ACCOUNT * sam_acct)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
This is another *BIG* change... Samba now features a pluggable passdb interface, along the same lines as the one in use in the auth subsystem. In this case, only one backend may be active at a time by the 'normal' interface, and only one backend per passdb_context is permitted outside that. This pluggable interface is designed to allow any number of passdb backends to be compiled in, with the selection at runtime. The 'passdb backend' paramater has been created (and documented!) to support this. As such, configure has been modfied to allow (for example) --with-ldap and the old smbpasswd to be selected at the same time. This patch also introduces two new backends: smbpasswd_nua and tdbsam_nua. These two backends accept 'non unix accounts', where the user does *not* exist in /etc/passwd. These accounts' don't have UIDs in the unix sense, but to avoid conflicts in the algroitmic mapping of RIDs, they use the values specified in the 'non unix account range' paramter - in the same way as the winbind ranges are specifed. While I was at it, I cleaned up some of the code in pdb_tdb (code copied directly from smbpasswd and not really considered properly). Most of this was to do with % macro expansion on stored data. It isn't easy to get the macros into the tdb, and the first password change will 'expand' them. tdbsam needs to use a similar system to pdb_ldap in this regard. This patch only makes minor adjustments to pdb_nisplus and pdb_ldap, becouse I don't have the test facilities for these. I plan to incoroprate at least pdb_ldap into this scheme after consultation with Jerry. Each (converted) passdb module now no longer has any 'static' variables, and only exports 1 init function outside its .c file. The non-unix-account support in this patch has been proven! It is now possible to join a win2k machine to a Samba PDC without an account in /etc/passwd! Other changes: Minor interface adjustments: pdb_delete_sam_account() now takes a SAM_ACCOUNT, not a char*. pdb_update_sam_account() no longer takes the 'override' argument that was being ignored so often (every other passdb backend). Extra checks have been added in some places. Minor code changes: smbpasswd no longer attempts to initialise the passdb at startup, this is now done on first use. pdbedit has lost some of its 'machine account' logic, as this behaviour is now controlled by the passdb subsystem directly. The samr subsystem no longer calls 'local password change', but does the pdb interactions directly. This allow the ACB_ flags specifed to be transferred direct to the backend, without interference. Doco: I've updated the doco to reflect some of the changes, and removed some paramters no longer applicable to HEAD. (This used to be commit ff354c99c585068af6dc1ff35a1f109a806b326b)
2002-01-20 17:30:58 +03:00
const char *sname;
int rc;
LDAPMessage *result = NULL;
NTSTATUS ret;
const char **attr_list;
fstring objclass;
This is another *BIG* change... Samba now features a pluggable passdb interface, along the same lines as the one in use in the auth subsystem. In this case, only one backend may be active at a time by the 'normal' interface, and only one backend per passdb_context is permitted outside that. This pluggable interface is designed to allow any number of passdb backends to be compiled in, with the selection at runtime. The 'passdb backend' paramater has been created (and documented!) to support this. As such, configure has been modfied to allow (for example) --with-ldap and the old smbpasswd to be selected at the same time. This patch also introduces two new backends: smbpasswd_nua and tdbsam_nua. These two backends accept 'non unix accounts', where the user does *not* exist in /etc/passwd. These accounts' don't have UIDs in the unix sense, but to avoid conflicts in the algroitmic mapping of RIDs, they use the values specified in the 'non unix account range' paramter - in the same way as the winbind ranges are specifed. While I was at it, I cleaned up some of the code in pdb_tdb (code copied directly from smbpasswd and not really considered properly). Most of this was to do with % macro expansion on stored data. It isn't easy to get the macros into the tdb, and the first password change will 'expand' them. tdbsam needs to use a similar system to pdb_ldap in this regard. This patch only makes minor adjustments to pdb_nisplus and pdb_ldap, becouse I don't have the test facilities for these. I plan to incoroprate at least pdb_ldap into this scheme after consultation with Jerry. Each (converted) passdb module now no longer has any 'static' variables, and only exports 1 init function outside its .c file. The non-unix-account support in this patch has been proven! It is now possible to join a win2k machine to a Samba PDC without an account in /etc/passwd! Other changes: Minor interface adjustments: pdb_delete_sam_account() now takes a SAM_ACCOUNT, not a char*. pdb_update_sam_account() no longer takes the 'override' argument that was being ignored so often (every other passdb backend). Extra checks have been added in some places. Minor code changes: smbpasswd no longer attempts to initialise the passdb at startup, this is now done on first use. pdbedit has lost some of its 'machine account' logic, as this behaviour is now controlled by the passdb subsystem directly. The samr subsystem no longer calls 'local password change', but does the pdb interactions directly. This allow the ACB_ flags specifed to be transferred direct to the backend, without interference. Doco: I've updated the doco to reflect some of the changes, and removed some paramters no longer applicable to HEAD. (This used to be commit ff354c99c585068af6dc1ff35a1f109a806b326b)
2002-01-20 17:30:58 +03:00
if (!sam_acct) {
DEBUG(0, ("ldapsam_delete_sam_account: sam_acct was NULL!\n"));
return NT_STATUS_INVALID_PARAMETER;
This is another *BIG* change... Samba now features a pluggable passdb interface, along the same lines as the one in use in the auth subsystem. In this case, only one backend may be active at a time by the 'normal' interface, and only one backend per passdb_context is permitted outside that. This pluggable interface is designed to allow any number of passdb backends to be compiled in, with the selection at runtime. The 'passdb backend' paramater has been created (and documented!) to support this. As such, configure has been modfied to allow (for example) --with-ldap and the old smbpasswd to be selected at the same time. This patch also introduces two new backends: smbpasswd_nua and tdbsam_nua. These two backends accept 'non unix accounts', where the user does *not* exist in /etc/passwd. These accounts' don't have UIDs in the unix sense, but to avoid conflicts in the algroitmic mapping of RIDs, they use the values specified in the 'non unix account range' paramter - in the same way as the winbind ranges are specifed. While I was at it, I cleaned up some of the code in pdb_tdb (code copied directly from smbpasswd and not really considered properly). Most of this was to do with % macro expansion on stored data. It isn't easy to get the macros into the tdb, and the first password change will 'expand' them. tdbsam needs to use a similar system to pdb_ldap in this regard. This patch only makes minor adjustments to pdb_nisplus and pdb_ldap, becouse I don't have the test facilities for these. I plan to incoroprate at least pdb_ldap into this scheme after consultation with Jerry. Each (converted) passdb module now no longer has any 'static' variables, and only exports 1 init function outside its .c file. The non-unix-account support in this patch has been proven! It is now possible to join a win2k machine to a Samba PDC without an account in /etc/passwd! Other changes: Minor interface adjustments: pdb_delete_sam_account() now takes a SAM_ACCOUNT, not a char*. pdb_update_sam_account() no longer takes the 'override' argument that was being ignored so often (every other passdb backend). Extra checks have been added in some places. Minor code changes: smbpasswd no longer attempts to initialise the passdb at startup, this is now done on first use. pdbedit has lost some of its 'machine account' logic, as this behaviour is now controlled by the passdb subsystem directly. The samr subsystem no longer calls 'local password change', but does the pdb interactions directly. This allow the ACB_ flags specifed to be transferred direct to the backend, without interference. Doco: I've updated the doco to reflect some of the changes, and removed some paramters no longer applicable to HEAD. (This used to be commit ff354c99c585068af6dc1ff35a1f109a806b326b)
2002-01-20 17:30:58 +03:00
}
sname = pdb_get_username(sam_acct);
DEBUG (3, ("ldapsam_delete_sam_account: Deleting user %s from LDAP.\n", sname));
attr_list= get_userattr_delete_list( ldap_state->schema_ver );
rc = ldapsam_search_suffix_by_name(ldap_state, sname, &result, attr_list);
if (rc != LDAP_SUCCESS) {
free_attr_list( attr_list );
return NT_STATUS_NO_SUCH_USER;
}
switch ( ldap_state->schema_ver ) {
case SCHEMAVER_SAMBASAMACCOUNT:
fstrcpy( objclass, LDAP_OBJ_SAMBASAMACCOUNT );
break;
case SCHEMAVER_SAMBAACCOUNT:
fstrcpy( objclass, LDAP_OBJ_SAMBAACCOUNT );
break;
default:
fstrcpy( objclass, "UNKNOWN" );
DEBUG(0,("ldapsam_delete_sam_account: Unknown schema version specified!\n"));
break;
}
ret = ldapsam_delete_entry(ldap_state, result, objclass, attr_list );
ldap_msgfree(result);
free_attr_list( attr_list );
return ret;
}
/**********************************************************************
Helper function to determine for update_sam_account whether
we need LDAP modification.
*********************************************************************/
static BOOL element_is_changed(const SAM_ACCOUNT *sampass,
enum pdb_elements element)
{
return IS_SAM_CHANGED(sampass, element);
}
/**********************************************************************
Update SAM_ACCOUNT.
*********************************************************************/
static NTSTATUS ldapsam_update_sam_account(struct pdb_methods *my_methods, SAM_ACCOUNT * newpwd)
{
NTSTATUS ret = NT_STATUS_UNSUCCESSFUL;
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
int rc = 0;
char *dn;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
LDAPMod **mods = NULL;
const char **attr_list;
result = pdb_get_backend_private_data(newpwd, my_methods);
if (!result) {
attr_list = get_userattr_list(ldap_state->schema_ver);
rc = ldapsam_search_suffix_by_name(ldap_state, pdb_get_username(newpwd), &result, attr_list );
free_attr_list( attr_list );
if (rc != LDAP_SUCCESS) {
return NT_STATUS_UNSUCCESSFUL;
}
pdb_set_backend_private_data(newpwd, result, private_data_free_fn, my_methods, PDB_CHANGED);
}
if (ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result) == 0) {
DEBUG(0, ("ldapsam_update_sam_account: No user to modify!\n"));
return NT_STATUS_UNSUCCESSFUL;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!dn) {
return NT_STATUS_UNSUCCESSFUL;
}
DEBUG(4, ("ldapsam_update_sam_account: user %s to be modified has dn: %s\n", pdb_get_username(newpwd), dn));
if (!init_ldap_from_sam(ldap_state, entry, &mods, newpwd,
element_is_changed)) {
DEBUG(0, ("ldapsam_update_sam_account: init_ldap_from_sam failed!\n"));
SAFE_FREE(dn);
if (mods != NULL)
ldap_mods_free(mods,True);
return NT_STATUS_UNSUCCESSFUL;
}
if (mods == NULL) {
DEBUG(4,("ldapsam_update_sam_account: mods is empty: nothing to update for user: %s\n",
pdb_get_username(newpwd)));
SAFE_FREE(dn);
return NT_STATUS_OK;
}
ret = ldapsam_modify_entry(my_methods,newpwd,dn,mods,LDAP_MOD_REPLACE, element_is_changed);
ldap_mods_free(mods,True);
SAFE_FREE(dn);
if (!NT_STATUS_IS_OK(ret)) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0,("ldapsam_update_sam_account: failed to modify user with uid = %s, error: %s (%s)\n",
pdb_get_username(newpwd), ld_error?ld_error:"(unknwon)", ldap_err2string(rc)));
SAFE_FREE(ld_error);
return ret;
}
DEBUG(2, ("ldapsam_update_sam_account: successfully modified uid = %s in the LDAP database\n",
pdb_get_username(newpwd)));
return NT_STATUS_OK;
}
/**********************************************************************
Helper function to determine for update_sam_account whether
we need LDAP modification.
*********************************************************************/
static BOOL element_is_set_or_changed(const SAM_ACCOUNT *sampass,
enum pdb_elements element)
{
return (IS_SAM_SET(sampass, element) ||
IS_SAM_CHANGED(sampass, element));
}
/**********************************************************************
Add SAM_ACCOUNT to LDAP.
*********************************************************************/
static NTSTATUS ldapsam_add_sam_account(struct pdb_methods *my_methods, SAM_ACCOUNT * newpwd)
{
NTSTATUS ret = NT_STATUS_UNSUCCESSFUL;
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
int rc;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
pstring dn;
LDAPMod **mods = NULL;
int ldap_op = LDAP_MOD_REPLACE;
uint32 num_result;
const char **attr_list;
char *escape_user;
const char *username = pdb_get_username(newpwd);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
const DOM_SID *sid = pdb_get_user_sid(newpwd);
pstring filter;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
fstring sid_string;
if (!username || !*username) {
DEBUG(0, ("ldapsam_add_sam_account: Cannot add user without a username!\n"));
return NT_STATUS_INVALID_PARAMETER;
}
/* free this list after the second search or in case we exit on failure */
attr_list = get_userattr_list(ldap_state->schema_ver);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
rc = ldapsam_search_suffix_by_name (ldap_state, username, &result, attr_list);
if (rc != LDAP_SUCCESS) {
free_attr_list( attr_list );
return NT_STATUS_UNSUCCESSFUL;
}
if (ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result) != 0) {
DEBUG(0,("ldapsam_add_sam_account: User '%s' already in the base, with samba attributes\n",
username));
ldap_msgfree(result);
free_attr_list( attr_list );
return NT_STATUS_UNSUCCESSFUL;
}
ldap_msgfree(result);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
result = NULL;
if (element_is_set_or_changed(newpwd, PDB_USERSID)) {
rc = ldapsam_get_ldap_user_by_sid(ldap_state,
sid, &result);
if (rc == LDAP_SUCCESS) {
if (ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result) != 0) {
DEBUG(0,("ldapsam_add_sam_account: SID '%s' already in the base, with samba attributes\n",
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
sid_to_string(sid_string, sid)));
free_attr_list( attr_list );
ldap_msgfree(result);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
return NT_STATUS_UNSUCCESSFUL;
}
ldap_msgfree(result);
}
}
/* does the entry already exist but without a samba attributes?
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
we need to return the samba attributes here */
escape_user = escape_ldap_string_alloc( username );
pstrcpy( filter, lp_ldap_filter() );
all_string_sub( filter, "%u", escape_user, sizeof(filter) );
SAFE_FREE( escape_user );
rc = smbldap_search_suffix(ldap_state->smbldap_state,
filter, attr_list, &result);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if ( rc != LDAP_SUCCESS ) {
free_attr_list( attr_list );
return NT_STATUS_UNSUCCESSFUL;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
}
num_result = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (num_result > 1) {
DEBUG (0, ("ldapsam_add_sam_account: More than one user with that uid exists: bailing out!\n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
free_attr_list( attr_list );
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
/* Check if we need to update an existing entry */
if (num_result == 1) {
char *tmp;
DEBUG(3,("ldapsam_add_sam_account: User exists without samba attributes: adding them\n"));
ldap_op = LDAP_MOD_REPLACE;
entry = ldap_first_entry (ldap_state->smbldap_state->ldap_struct, result);
tmp = smbldap_get_dn (ldap_state->smbldap_state->ldap_struct, entry);
if (!tmp) {
free_attr_list( attr_list );
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
slprintf (dn, sizeof (dn) - 1, "%s", tmp);
SAFE_FREE(tmp);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
} else if (ldap_state->schema_ver == SCHEMAVER_SAMBASAMACCOUNT) {
/* There might be a SID for this account already - say an idmap entry */
pstr_sprintf(filter, "(&(%s=%s)(|(objectClass=%s)(objectClass=%s)))",
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID),
sid_to_string(sid_string, sid),
LDAP_OBJ_IDMAP_ENTRY,
LDAP_OBJ_SID_ENTRY);
/* free old result before doing a new search */
if (result != NULL) {
ldap_msgfree(result);
result = NULL;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
rc = smbldap_search_suffix(ldap_state->smbldap_state,
filter, attr_list, &result);
if ( rc != LDAP_SUCCESS ) {
free_attr_list( attr_list );
return NT_STATUS_UNSUCCESSFUL;
}
num_result = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (num_result > 1) {
DEBUG (0, ("ldapsam_add_sam_account: More than one user with that uid exists: bailing out!\n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
free_attr_list( attr_list );
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
/* Check if we need to update an existing entry */
if (num_result == 1) {
char *tmp;
DEBUG(3,("ldapsam_add_sam_account: User exists without samba attributes: adding them\n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
ldap_op = LDAP_MOD_REPLACE;
entry = ldap_first_entry (ldap_state->smbldap_state->ldap_struct, result);
tmp = smbldap_get_dn (ldap_state->smbldap_state->ldap_struct, entry);
if (!tmp) {
free_attr_list( attr_list );
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
slprintf (dn, sizeof (dn) - 1, "%s", tmp);
SAFE_FREE(tmp);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
}
}
free_attr_list( attr_list );
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if (num_result == 0) {
/* Check if we need to add an entry */
DEBUG(3,("ldapsam_add_sam_account: Adding new user\n"));
ldap_op = LDAP_MOD_ADD;
if (username[strlen(username)-1] == '$') {
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
slprintf (dn, sizeof (dn) - 1, "uid=%s,%s", username, lp_ldap_machine_suffix ());
} else {
slprintf (dn, sizeof (dn) - 1, "uid=%s,%s", username, lp_ldap_user_suffix ());
}
}
if (!init_ldap_from_sam(ldap_state, entry, &mods, newpwd,
element_is_set_or_changed)) {
DEBUG(0, ("ldapsam_add_sam_account: init_ldap_from_sam failed!\n"));
ldap_msgfree(result);
if (mods != NULL)
ldap_mods_free(mods,True);
return NT_STATUS_UNSUCCESSFUL;
}
ldap_msgfree(result);
if (mods == NULL) {
DEBUG(0,("ldapsam_add_sam_account: mods is empty: nothing to add for user: %s\n",pdb_get_username(newpwd)));
return NT_STATUS_UNSUCCESSFUL;
}
switch ( ldap_state->schema_ver ) {
case SCHEMAVER_SAMBAACCOUNT:
smbldap_set_mod(&mods, LDAP_MOD_ADD, "objectclass", LDAP_OBJ_SAMBAACCOUNT);
break;
case SCHEMAVER_SAMBASAMACCOUNT:
smbldap_set_mod(&mods, LDAP_MOD_ADD, "objectclass", LDAP_OBJ_SAMBASAMACCOUNT);
break;
default:
DEBUG(0,("ldapsam_add_sam_account: invalid schema version specified\n"));
break;
}
ret = ldapsam_modify_entry(my_methods,newpwd,dn,mods,ldap_op, element_is_set_or_changed);
if (!NT_STATUS_IS_OK(ret)) {
DEBUG(0,("ldapsam_add_sam_account: failed to modify/add user with uid = %s (dn = %s)\n",
pdb_get_username(newpwd),dn));
ldap_mods_free(mods, True);
return ret;
}
DEBUG(2,("ldapsam_add_sam_account: added: uid == %s in the LDAP database\n", pdb_get_username(newpwd)));
ldap_mods_free(mods, True);
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static int ldapsam_search_one_group (struct ldapsam_privates *ldap_state,
const char *filter,
LDAPMessage ** result)
{
int scope = LDAP_SCOPE_SUBTREE;
int rc;
const char **attr_list;
attr_list = get_attr_list(groupmap_attr_list);
rc = smbldap_search(ldap_state->smbldap_state,
lp_ldap_group_suffix (), scope,
filter, attr_list, 0, result);
free_attr_list( attr_list );
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0, ("ldapsam_search_one_group: "
"Problem during the LDAP search: LDAP error: %s (%s)\n",
ld_error?ld_error:"(unknown)", ldap_err2string(rc)));
DEBUGADD(3, ("ldapsam_search_one_group: Query was: %s, %s\n",
lp_ldap_group_suffix(), filter));
SAFE_FREE(ld_error);
}
return rc;
}
/**********************************************************************
*********************************************************************/
static BOOL init_group_from_ldap(struct ldapsam_privates *ldap_state,
GROUP_MAP *map, LDAPMessage *entry)
{
pstring temp;
if (ldap_state == NULL || map == NULL || entry == NULL ||
ldap_state->smbldap_state->ldap_struct == NULL) {
DEBUG(0, ("init_group_from_ldap: NULL parameters found!\n"));
return False;
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GIDNUMBER), temp)) {
DEBUG(0, ("init_group_from_ldap: Mandatory attribute %s not found\n",
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_GIDNUMBER)));
return False;
}
DEBUG(2, ("init_group_from_ldap: Entry found for group: %s\n", temp));
map->gid = (gid_t)atol(temp);
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_GROUP_SID), temp)) {
DEBUG(0, ("init_group_from_ldap: Mandatory attribute %s not found\n",
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_GROUP_SID)));
return False;
}
if (!string_to_sid(&map->sid, temp)) {
DEBUG(1, ("SID string [%s] could not be read as a valid SID\n", temp));
return False;
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_GROUP_TYPE), temp)) {
DEBUG(0, ("init_group_from_ldap: Mandatory attribute %s not found\n",
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_GROUP_TYPE)));
return False;
}
map->sid_name_use = (enum SID_NAME_USE)atol(temp);
if ((map->sid_name_use < SID_NAME_USER) ||
(map->sid_name_use > SID_NAME_UNKNOWN)) {
DEBUG(0, ("init_group_from_ldap: Unknown Group type: %d\n", map->sid_name_use));
return False;
}
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_DISPLAY_NAME), temp)) {
temp[0] = '\0';
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_CN), temp))
{
DEBUG(0, ("init_group_from_ldap: Attributes cn not found either \
for gidNumber(%lu)\n",(unsigned long)map->gid));
return False;
}
}
fstrcpy(map->nt_name, temp);
if (!smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_DESC), temp)) {
temp[0] = '\0';
}
fstrcpy(map->comment, temp);
return True;
}
/**********************************************************************
*********************************************************************/
static BOOL init_ldap_from_group(LDAP *ldap_struct,
LDAPMessage *existing,
LDAPMod ***mods,
const GROUP_MAP *map)
{
pstring tmp;
if (mods == NULL || map == NULL) {
DEBUG(0, ("init_ldap_from_group: NULL parameters found!\n"));
return False;
}
*mods = NULL;
sid_to_string(tmp, &map->sid);
smbldap_make_mod(ldap_struct, existing, mods,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GROUP_SID), tmp);
pstr_sprintf(tmp, "%i", map->sid_name_use);
smbldap_make_mod(ldap_struct, existing, mods,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GROUP_TYPE), tmp);
smbldap_make_mod(ldap_struct, existing, mods,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_DISPLAY_NAME), map->nt_name);
smbldap_make_mod(ldap_struct, existing, mods,
get_attr_key2string( groupmap_attr_list, LDAP_ATTR_DESC), map->comment);
return True;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_getgroup(struct pdb_methods *methods,
const char *filter,
GROUP_MAP *map)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
int count;
if (ldapsam_search_one_group(ldap_state, filter, &result)
!= LDAP_SUCCESS) {
return NT_STATUS_NO_SUCH_GROUP;
}
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if (count < 1) {
DEBUG(4, ("ldapsam_getgroup: Did not find group\n"));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_GROUP;
}
if (count > 1) {
DEBUG(1, ("ldapsam_getgroup: Duplicate entries for filter %s: count=%d\n",
filter, count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_GROUP;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
if (!entry) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
if (!init_group_from_ldap(ldap_state, map, entry)) {
DEBUG(1, ("ldapsam_getgroup: init_group_from_ldap failed for group filter %s\n",
filter));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_GROUP;
}
ldap_msgfree(result);
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_getgrsid(struct pdb_methods *methods, GROUP_MAP *map,
DOM_SID sid)
{
pstring filter;
pstr_sprintf(filter, "(&(objectClass=%s)(%s=%s))",
LDAP_OBJ_GROUPMAP,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GROUP_SID),
sid_string_static(&sid));
return ldapsam_getgroup(methods, filter, map);
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_getgrgid(struct pdb_methods *methods, GROUP_MAP *map,
gid_t gid)
{
pstring filter;
pstr_sprintf(filter, "(&(objectClass=%s)(%s=%d))",
LDAP_OBJ_GROUPMAP,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GIDNUMBER),
gid);
return ldapsam_getgroup(methods, filter, map);
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_getgrnam(struct pdb_methods *methods, GROUP_MAP *map,
const char *name)
{
pstring filter;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
char *escape_name = escape_ldap_string_alloc(name);
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
if (!escape_name) {
return NT_STATUS_NO_MEMORY;
}
pstr_sprintf(filter, "(&(objectClass=%s)(|(%s=%s)(%s=%s)))",
LDAP_OBJ_GROUPMAP,
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_DISPLAY_NAME), escape_name,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_CN), escape_name);
SAFE_FREE(escape_name);
return ldapsam_getgroup(methods, filter, map);
}
static void add_rid_to_array_unique(TALLOC_CTX *mem_ctx,
uint32 rid, uint32 **rids, int *num)
{
int i;
for (i=0; i<*num; i++) {
if ((*rids)[i] == rid)
return;
}
*rids = TALLOC_REALLOC_ARRAY(mem_ctx, *rids, uint32, *num+1);
if (*rids == NULL)
return;
(*rids)[*num] = rid;
*num += 1;
}
static BOOL ldapsam_extract_rid_from_entry(LDAP *ldap_struct,
LDAPMessage *entry,
const DOM_SID *domain_sid,
uint32 *rid)
{
fstring str;
DOM_SID sid;
if (!smbldap_get_single_attribute(ldap_struct, entry, "sambaSID",
str, sizeof(str)-1)) {
DEBUG(10, ("Could not find sambaSID attribute\n"));
return False;
}
if (!string_to_sid(&sid, str)) {
DEBUG(10, ("Could not convert string %s to sid\n", str));
return False;
}
if (sid_compare_domain(&sid, domain_sid) != 0) {
DEBUG(10, ("SID %s is not in expected domain %s\n",
str, sid_string_static(domain_sid)));
return False;
}
if (!sid_peek_rid(&sid, rid)) {
DEBUG(10, ("Could not peek into RID\n"));
return False;
}
return True;
}
static NTSTATUS ldapsam_enum_group_members(struct pdb_methods *methods,
TALLOC_CTX *mem_ctx,
const DOM_SID *group,
uint32 **member_rids,
int *num_members)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
struct smbldap_state *conn = ldap_state->smbldap_state;
pstring filter;
int rc, count;
LDAPMessage *msg = NULL;
LDAPMessage *entry;
char **values = NULL;
char **memberuid;
char *sid_filter = NULL;
char *tmp;
NTSTATUS result = NT_STATUS_UNSUCCESSFUL;
if (!lp_parm_bool(-1, "ldapsam", "trusted", False))
return pdb_default_enum_group_members(methods, mem_ctx, group,
member_rids,
num_members);
*member_rids = NULL;
*num_members = 0;
pstr_sprintf(filter,
"(&(objectClass=sambaSamAccount)"
"(sambaPrimaryGroupSid=%s))",
sid_string_static(group));
{
const char *attrs[] = { "sambaSID", NULL };
rc = smbldap_search(conn, lp_ldap_user_suffix(),
LDAP_SCOPE_SUBTREE, filter, attrs, 0,
&msg);
}
if (rc != LDAP_SUCCESS)
goto done;
for (entry = ldap_first_entry(conn->ldap_struct, msg);
entry != NULL;
entry = ldap_next_entry(conn->ldap_struct, entry))
{
uint32 rid;
if (!ldapsam_extract_rid_from_entry(conn->ldap_struct,
entry,
get_global_sam_sid(),
&rid)) {
DEBUG(2, ("Could not find sid from ldap entry\n"));
continue;
}
add_rid_to_array_unique(mem_ctx, rid, member_rids,
num_members);
}
if (msg != NULL)
ldap_msgfree(msg);
pstr_sprintf(filter,
"(&(objectClass=sambaGroupMapping)"
"(objectClass=posixGroup)"
"(sambaSID=%s))",
sid_string_static(group));
{
const char *attrs[] = { "memberUid", NULL };
rc = smbldap_search(conn, lp_ldap_group_suffix(),
LDAP_SCOPE_SUBTREE, filter, attrs, 0,
&msg);
}
if (rc != LDAP_SUCCESS)
goto done;
count = ldap_count_entries(conn->ldap_struct, msg);
if (count > 1) {
DEBUG(1, ("Found more than one groupmap entry for %s\n",
sid_string_static(group)));
goto done;
}
if (count == 0) {
result = NT_STATUS_OK;
goto done;
}
entry = ldap_first_entry(conn->ldap_struct, msg);
if (entry == NULL)
goto done;
values = ldap_get_values(conn->ldap_struct, msg, "memberUid");
if (values == NULL) {
result = NT_STATUS_OK;
goto done;
}
sid_filter = strdup("(&(objectClass=sambaSamAccount)(|");
if (sid_filter == NULL) {
result = NT_STATUS_NO_MEMORY;
goto done;
}
for (memberuid = values; *memberuid != NULL; memberuid += 1) {
tmp = sid_filter;
asprintf(&sid_filter, "%s(uid=%s)", tmp, *memberuid);
free(tmp);
if (sid_filter == NULL) {
result = NT_STATUS_NO_MEMORY;
goto done;
}
}
tmp = sid_filter;
asprintf(&sid_filter, "%s))", sid_filter);
free(tmp);
if (sid_filter == NULL) {
result = NT_STATUS_NO_MEMORY;
goto done;
}
{
const char *attrs[] = { "sambaSID", NULL };
rc = smbldap_search(conn, lp_ldap_user_suffix(),
LDAP_SCOPE_SUBTREE, sid_filter, attrs, 0,
&msg);
}
if (rc != LDAP_SUCCESS)
goto done;
for (entry = ldap_first_entry(conn->ldap_struct, msg);
entry != NULL;
entry = ldap_next_entry(conn->ldap_struct, entry))
{
fstring str;
DOM_SID sid;
uint32 rid;
if (!smbldap_get_single_attribute(conn->ldap_struct,
entry, "sambaSID",
str, sizeof(str)-1))
continue;
if (!string_to_sid(&sid, str))
goto done;
if (!sid_check_is_in_our_domain(&sid)) {
DEBUG(1, ("Inconsistent SAM -- group member uid not "
"in our domain\n"));
continue;
}
sid_peek_rid(&sid, &rid);
add_rid_to_array_unique(mem_ctx, rid, member_rids,
num_members);
}
result = NT_STATUS_OK;
done:
SAFE_FREE(sid_filter);
if (values != NULL)
ldap_value_free(values);
if (msg != NULL)
ldap_msgfree(msg);
return result;
}
static NTSTATUS ldapsam_enum_group_memberships(struct pdb_methods *methods,
const char *username,
gid_t primary_gid,
DOM_SID **sids, gid_t **gids,
int *num_groups)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
struct smbldap_state *conn = ldap_state->smbldap_state;
pstring filter;
const char *attrs[] = { "gidNumber", "sambaSID", NULL };
char *escape_name;
int rc;
LDAPMessage *msg = NULL;
LDAPMessage *entry;
NTSTATUS result = NT_STATUS_UNSUCCESSFUL;
int num_sids, num_gids;
if (!lp_parm_bool(-1, "ldapsam", "trusted", False))
return pdb_default_enum_group_memberships(methods, username,
primary_gid, sids,
gids, num_groups);
*sids = NULL;
num_sids = 0;
escape_name = escape_ldap_string_alloc(username);
if (escape_name == NULL)
return NT_STATUS_NO_MEMORY;
pstr_sprintf(filter, "(&(objectClass=posixGroup)"
"(|(memberUid=%s)(gidNumber=%d)))",
username, primary_gid);
rc = smbldap_search(conn, lp_ldap_group_suffix(),
LDAP_SCOPE_SUBTREE, filter, attrs, 0, &msg);
if (rc != LDAP_SUCCESS)
goto done;
num_gids = 0;
*gids = NULL;
num_sids = 0;
*sids = NULL;
/* We need to add the primary group as the first gid/sid */
add_gid_to_array_unique(NULL, primary_gid, gids, &num_gids);
/* This sid will be replaced later */
add_sid_to_array_unique(NULL, &global_sid_NULL, sids, &num_sids);
for (entry = ldap_first_entry(conn->ldap_struct, msg);
entry != NULL;
entry = ldap_next_entry(conn->ldap_struct, entry))
{
fstring str;
DOM_SID sid;
gid_t gid;
char *end;
if (!smbldap_get_single_attribute(conn->ldap_struct,
entry, "sambaSID",
str, sizeof(str)-1))
continue;
if (!string_to_sid(&sid, str))
goto done;
if (!smbldap_get_single_attribute(conn->ldap_struct,
entry, "gidNumber",
str, sizeof(str)-1))
continue;
gid = strtoul(str, &end, 10);
if (PTR_DIFF(end, str) != strlen(str))
goto done;
if (gid == primary_gid) {
sid_copy(&(*sids)[0], &sid);
} else {
add_gid_to_array_unique(NULL, gid, gids, &num_gids);
add_sid_to_array_unique(NULL, &sid, sids, &num_sids);
}
}
if (sid_compare(&global_sid_NULL, &(*sids)[0]) == 0) {
DEBUG(3, ("primary group of [%s] not found\n", username));
goto done;
}
*num_groups = num_sids;
result = NT_STATUS_OK;
done:
SAFE_FREE(escape_name);
if (msg != NULL)
ldap_msgfree(msg);
return result;
}
/**********************************************************************
*********************************************************************/
static int ldapsam_search_one_group_by_gid(struct ldapsam_privates *ldap_state,
gid_t gid,
LDAPMessage **result)
{
pstring filter;
pstr_sprintf(filter, "(&(|(objectClass=%s)(objectclass=%s))(%s=%d))",
LDAP_OBJ_POSIXGROUP, LDAP_OBJ_IDMAP_ENTRY,
get_attr_key2string(groupmap_attr_list, LDAP_ATTR_GIDNUMBER),
gid);
return ldapsam_search_one_group(ldap_state, filter, result);
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_add_group_mapping_entry(struct pdb_methods *methods,
GROUP_MAP *map)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
LDAPMessage *result = NULL;
LDAPMod **mods = NULL;
int count;
char *tmp;
pstring dn;
LDAPMessage *entry;
GROUP_MAP dummy;
int rc;
if (NT_STATUS_IS_OK(ldapsam_getgrgid(methods, &dummy,
map->gid))) {
DEBUG(0, ("ldapsam_add_group_mapping_entry: Group %ld already exists in LDAP\n", (unsigned long)map->gid));
return NT_STATUS_UNSUCCESSFUL;
}
rc = ldapsam_search_one_group_by_gid(ldap_state, map->gid, &result);
if (rc != LDAP_SUCCESS) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if ( count == 0 ) {
/* There's no posixGroup account, let's try to find an
* appropriate idmap entry for aliases */
pstring suffix;
pstring filter;
const char **attr_list;
ldap_msgfree(result);
pstrcpy( suffix, lp_ldap_idmap_suffix() );
pstr_sprintf(filter, "(&(objectClass=%s)(%s=%d))",
LDAP_OBJ_IDMAP_ENTRY, LDAP_ATTRIBUTE_GIDNUMBER,
map->gid);
attr_list = get_attr_list( sidmap_attr_list );
rc = smbldap_search(ldap_state->smbldap_state, suffix,
LDAP_SCOPE_SUBTREE, filter, attr_list,
0, &result);
free_attr_list(attr_list);
if (rc != LDAP_SUCCESS) {
DEBUG(3,("Failure looking up entry (%s)\n",
ldap_err2string(rc) ));
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
}
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result);
if ( count == 0 ) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
if (count > 1) {
DEBUG(2, ("ldapsam_add_group_mapping_entry: Group %lu must exist exactly once in LDAP\n",
(unsigned long)map->gid));
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
tmp = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!tmp) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
pstrcpy(dn, tmp);
SAFE_FREE(tmp);
if (!init_ldap_from_group(ldap_state->smbldap_state->ldap_struct,
result, &mods, map)) {
DEBUG(0, ("ldapsam_add_group_mapping_entry: init_ldap_from_group failed!\n"));
ldap_mods_free(mods, True);
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
ldap_msgfree(result);
if (mods == NULL) {
DEBUG(0, ("ldapsam_add_group_mapping_entry: mods is empty\n"));
return NT_STATUS_UNSUCCESSFUL;
}
smbldap_set_mod(&mods, LDAP_MOD_ADD, "objectClass", LDAP_OBJ_GROUPMAP );
rc = smbldap_modify(ldap_state->smbldap_state, dn, mods);
ldap_mods_free(mods, True);
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0, ("ldapsam_add_group_mapping_entry: failed to add group %lu error: %s (%s)\n", (unsigned long)map->gid,
ld_error ? ld_error : "(unknown)", ldap_err2string(rc)));
SAFE_FREE(ld_error);
return NT_STATUS_UNSUCCESSFUL;
}
DEBUG(2, ("ldapsam_add_group_mapping_entry: successfully modified group %lu in LDAP\n", (unsigned long)map->gid));
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_update_group_mapping_entry(struct pdb_methods *methods,
GROUP_MAP *map)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
int rc;
char *dn = NULL;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
LDAPMod **mods = NULL;
rc = ldapsam_search_one_group_by_gid(ldap_state, map->gid, &result);
if (rc != LDAP_SUCCESS) {
return NT_STATUS_UNSUCCESSFUL;
}
if (ldap_count_entries(ldap_state->smbldap_state->ldap_struct, result) == 0) {
DEBUG(0, ("ldapsam_update_group_mapping_entry: No group to modify!\n"));
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
if (!init_ldap_from_group(ldap_state->smbldap_state->ldap_struct,
result, &mods, map)) {
DEBUG(0, ("ldapsam_update_group_mapping_entry: init_ldap_from_group failed\n"));
ldap_msgfree(result);
if (mods != NULL)
ldap_mods_free(mods,True);
return NT_STATUS_UNSUCCESSFUL;
}
if (mods == NULL) {
DEBUG(4, ("ldapsam_update_group_mapping_entry: mods is empty: nothing to do\n"));
ldap_msgfree(result);
return NT_STATUS_OK;
}
dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!dn) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
rc = smbldap_modify(ldap_state->smbldap_state, dn, mods);
SAFE_FREE(dn);
ldap_mods_free(mods, True);
ldap_msgfree(result);
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct, LDAP_OPT_ERROR_STRING,
&ld_error);
DEBUG(0, ("ldapsam_update_group_mapping_entry: failed to modify group %lu error: %s (%s)\n", (unsigned long)map->gid,
ld_error ? ld_error : "(unknown)", ldap_err2string(rc)));
SAFE_FREE(ld_error);
return NT_STATUS_UNSUCCESSFUL;
}
DEBUG(2, ("ldapsam_update_group_mapping_entry: successfully modified group %lu in LDAP\n", (unsigned long)map->gid));
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_delete_group_mapping_entry(struct pdb_methods *methods,
DOM_SID sid)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)methods->private_data;
pstring sidstring, filter;
LDAPMessage *result = NULL;
int rc;
NTSTATUS ret;
const char **attr_list;
sid_to_string(sidstring, &sid);
pstr_sprintf(filter, "(&(objectClass=%s)(%s=%s))",
LDAP_OBJ_GROUPMAP, LDAP_ATTRIBUTE_SID, sidstring);
rc = ldapsam_search_one_group(ldap_state, filter, &result);
if (rc != LDAP_SUCCESS) {
return NT_STATUS_NO_SUCH_GROUP;
}
attr_list = get_attr_list( groupmap_attr_list_to_delete );
ret = ldapsam_delete_entry(ldap_state, result, LDAP_OBJ_GROUPMAP, attr_list);
free_attr_list ( attr_list );
ldap_msgfree(result);
return ret;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_setsamgrent(struct pdb_methods *my_methods, BOOL update)
{
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
fstring filter;
int rc;
const char **attr_list;
pstr_sprintf( filter, "(objectclass=%s)", LDAP_OBJ_GROUPMAP);
attr_list = get_attr_list( groupmap_attr_list );
rc = smbldap_search(ldap_state->smbldap_state, lp_ldap_group_suffix(),
LDAP_SCOPE_SUBTREE, filter,
attr_list, 0, &ldap_state->result);
free_attr_list( attr_list );
if (rc != LDAP_SUCCESS) {
DEBUG(0, ("ldapsam_setsamgrent: LDAP search failed: %s\n", ldap_err2string(rc)));
DEBUG(3, ("ldapsam_setsamgrent: Query was: %s, %s\n", lp_ldap_group_suffix(), filter));
ldap_msgfree(ldap_state->result);
ldap_state->result = NULL;
return NT_STATUS_UNSUCCESSFUL;
}
DEBUG(2, ("ldapsam_setsamgrent: %d entries in the base!\n",
ldap_count_entries(ldap_state->smbldap_state->ldap_struct,
ldap_state->result)));
ldap_state->entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, ldap_state->result);
ldap_state->index = 0;
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static void ldapsam_endsamgrent(struct pdb_methods *my_methods)
{
ldapsam_endsampwent(my_methods);
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_getsamgrent(struct pdb_methods *my_methods,
GROUP_MAP *map)
{
NTSTATUS ret = NT_STATUS_UNSUCCESSFUL;
struct ldapsam_privates *ldap_state = (struct ldapsam_privates *)my_methods->private_data;
BOOL bret = False;
while (!bret) {
if (!ldap_state->entry)
return ret;
ldap_state->index++;
bret = init_group_from_ldap(ldap_state, map, ldap_state->entry);
ldap_state->entry = ldap_next_entry(ldap_state->smbldap_state->ldap_struct,
ldap_state->entry);
}
return NT_STATUS_OK;
}
/**********************************************************************
*********************************************************************/
static NTSTATUS ldapsam_enum_group_mapping(struct pdb_methods *methods,
enum SID_NAME_USE sid_name_use,
GROUP_MAP **rmap, int *num_entries,
BOOL unix_only)
{
GROUP_MAP map;
GROUP_MAP *mapt;
int entries = 0;
*num_entries = 0;
*rmap = NULL;
if (!NT_STATUS_IS_OK(ldapsam_setsamgrent(methods, False))) {
DEBUG(0, ("ldapsam_enum_group_mapping: Unable to open passdb\n"));
return NT_STATUS_ACCESS_DENIED;
}
while (NT_STATUS_IS_OK(ldapsam_getsamgrent(methods, &map))) {
if (sid_name_use != SID_NAME_UNKNOWN &&
sid_name_use != map.sid_name_use) {
DEBUG(11,("ldapsam_enum_group_mapping: group %s is not of the requested type\n", map.nt_name));
continue;
}
if (unix_only==ENUM_ONLY_MAPPED && map.gid==-1) {
DEBUG(11,("ldapsam_enum_group_mapping: group %s is non mapped\n", map.nt_name));
continue;
}
mapt=SMB_REALLOC_ARRAY((*rmap), GROUP_MAP, entries+1);
if (!mapt) {
DEBUG(0,("ldapsam_enum_group_mapping: Unable to enlarge group map!\n"));
SAFE_FREE(*rmap);
return NT_STATUS_UNSUCCESSFUL;
}
else
(*rmap) = mapt;
mapt[entries] = map;
entries += 1;
}
ldapsam_endsamgrent(methods);
*num_entries = entries;
return NT_STATUS_OK;
}
static NTSTATUS ldapsam_modify_aliasmem(struct pdb_methods *methods,
const DOM_SID *alias,
const DOM_SID *member,
int modop)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
char *dn;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
int count;
LDAPMod **mods = NULL;
int rc;
pstring filter;
pstr_sprintf(filter, "(&(|(objectClass=%s)(objectclass=%s))(%s=%s))",
LDAP_OBJ_GROUPMAP, LDAP_OBJ_IDMAP_ENTRY,
get_attr_key2string(groupmap_attr_list,
LDAP_ATTR_GROUP_SID),
sid_string_static(alias));
if (ldapsam_search_one_group(ldap_state, filter,
&result) != LDAP_SUCCESS)
return NT_STATUS_NO_SUCH_ALIAS;
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct,
result);
if (count < 1) {
DEBUG(4, ("ldapsam_modify_aliasmem: Did not find alias\n"));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_ALIAS;
}
if (count > 1) {
DEBUG(1, ("ldapsam_modify_aliasmem: Duplicate entries for filter %s: "
"count=%d\n", filter, count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_ALIAS;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct,
result);
if (!entry) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!dn) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
smbldap_set_mod(&mods, modop,
get_attr_key2string(groupmap_attr_list,
LDAP_ATTR_SID_LIST),
sid_string_static(member));
rc = smbldap_modify(ldap_state->smbldap_state, dn, mods);
ldap_mods_free(mods, True);
ldap_msgfree(result);
if (rc != LDAP_SUCCESS) {
char *ld_error = NULL;
ldap_get_option(ldap_state->smbldap_state->ldap_struct,
LDAP_OPT_ERROR_STRING,&ld_error);
DEBUG(0, ("ldapsam_modify_aliasmem: Could not modify alias "
"for %s, error: %s (%s)\n", dn, ldap_err2string(rc),
ld_error?ld_error:"unknown"));
SAFE_FREE(ld_error);
SAFE_FREE(dn);
return NT_STATUS_UNSUCCESSFUL;
}
SAFE_FREE(dn);
return NT_STATUS_OK;
}
static NTSTATUS ldapsam_add_aliasmem(struct pdb_methods *methods,
const DOM_SID *alias,
const DOM_SID *member)
{
return ldapsam_modify_aliasmem(methods, alias, member, LDAP_MOD_ADD);
}
static NTSTATUS ldapsam_del_aliasmem(struct pdb_methods *methods,
const DOM_SID *alias,
const DOM_SID *member)
{
return ldapsam_modify_aliasmem(methods, alias, member,
LDAP_MOD_DELETE);
}
static NTSTATUS ldapsam_enum_aliasmem(struct pdb_methods *methods,
const DOM_SID *alias, DOM_SID **members,
int *num_members)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
int count;
char **values;
int i;
pstring filter;
*members = NULL;
*num_members = 0;
pstr_sprintf(filter, "(&(|(objectClass=%s)(objectclass=%s))(%s=%s))",
LDAP_OBJ_GROUPMAP, LDAP_OBJ_IDMAP_ENTRY,
get_attr_key2string(groupmap_attr_list,
LDAP_ATTR_GROUP_SID),
sid_string_static(alias));
if (ldapsam_search_one_group(ldap_state, filter,
&result) != LDAP_SUCCESS)
return NT_STATUS_NO_SUCH_ALIAS;
count = ldap_count_entries(ldap_state->smbldap_state->ldap_struct,
result);
if (count < 1) {
DEBUG(4, ("ldapsam_enum_aliasmem: Did not find alias\n"));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_ALIAS;
}
if (count > 1) {
DEBUG(1, ("ldapsam_enum_aliasmem: Duplicate entries for filter %s: "
"count=%d\n", filter, count));
ldap_msgfree(result);
return NT_STATUS_NO_SUCH_ALIAS;
}
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct,
result);
if (!entry) {
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
values = ldap_get_values(ldap_state->smbldap_state->ldap_struct,
entry,
get_attr_key2string(groupmap_attr_list,
LDAP_ATTR_SID_LIST));
if (values == NULL) {
ldap_msgfree(result);
return NT_STATUS_OK;
}
count = ldap_count_values(values);
for (i=0; i<count; i++) {
DOM_SID member;
if (!string_to_sid(&member, values[i]))
continue;
add_sid_to_array(NULL, &member, members, num_members);
}
ldap_value_free(values);
ldap_msgfree(result);
return NT_STATUS_OK;
}
static NTSTATUS ldapsam_alias_memberships(struct pdb_methods *methods,
TALLOC_CTX *mem_ctx,
const DOM_SID *domain_sid,
const DOM_SID *members,
int num_members,
uint32 **alias_rids,
int *num_alias_rids)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
LDAP *ldap_struct;
const char *attrs[] = { LDAP_ATTRIBUTE_SID, NULL };
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
int i;
int rc;
char *filter;
/* This query could be further optimized by adding a
(&(sambaSID=<domain-sid>*)) so that only those aliases that are
asked for in the getuseraliases are returned. */
filter = talloc_asprintf(mem_ctx,
"(&(|(objectclass=%s)(objectclass=%s))(|",
LDAP_OBJ_GROUPMAP, LDAP_OBJ_IDMAP_ENTRY);
for (i=0; i<num_members; i++)
filter = talloc_asprintf(mem_ctx, "%s(sambaSIDList=%s)",
filter,
sid_string_static(&members[i]));
filter = talloc_asprintf(mem_ctx, "%s))", filter);
rc = smbldap_search(ldap_state->smbldap_state, lp_ldap_group_suffix(),
LDAP_SCOPE_SUBTREE, filter, attrs, 0, &result);
talloc_destroy(mem_ctx);
if (rc != LDAP_SUCCESS)
return NT_STATUS_UNSUCCESSFUL;
ldap_struct = ldap_state->smbldap_state->ldap_struct;
for (entry = ldap_first_entry(ldap_struct, result);
entry != NULL;
entry = ldap_next_entry(ldap_struct, entry))
{
fstring sid_str;
DOM_SID sid;
uint32 rid;
if (!smbldap_get_single_attribute(ldap_struct, entry,
LDAP_ATTRIBUTE_SID,
sid_str,
sizeof(sid_str)-1))
continue;
if (!string_to_sid(&sid, sid_str))
continue;
if (!sid_peek_check_rid(domain_sid, &sid, &rid))
continue;
add_rid_to_array_unique(mem_ctx, rid, alias_rids,
num_alias_rids);
}
ldap_msgfree(result);
return NT_STATUS_OK;
}
static NTSTATUS ldapsam_lookup_rids(struct pdb_methods *methods,
TALLOC_CTX *mem_ctx,
const DOM_SID *domain_sid,
int num_rids,
uint32 *rids,
const char ***names,
uint32 **attrs)
{
struct ldapsam_privates *ldap_state =
(struct ldapsam_privates *)methods->private_data;
LDAP *ldap_struct = ldap_state->smbldap_state->ldap_struct;
LDAPMessage *msg = NULL;
LDAPMessage *entry;
char *allsids = NULL;
char *tmp;
int i, rc, num_mapped;
NTSTATUS result = NT_STATUS_UNSUCCESSFUL;
if (!lp_parm_bool(-1, "ldapsam", "trusted", False))
return pdb_default_lookup_rids(methods, mem_ctx, domain_sid,
num_rids, rids, names, attrs);
if (!sid_equal(domain_sid, get_global_sam_sid())) {
/* TODO: Sooner or later we need to look up BUILTIN rids as
* well. -- vl */
goto done;
}
(*names) = TALLOC_ZERO_ARRAY(mem_ctx, const char *, num_rids);
(*attrs) = TALLOC_ARRAY(mem_ctx, uint32, num_rids);
if ((num_rids != 0) && (((*names) == NULL) || ((*attrs) == NULL)))
return NT_STATUS_NO_MEMORY;
for (i=0; i<num_rids; i++)
(*attrs)[i] = SID_NAME_UNKNOWN;
allsids = strdup("");
if (allsids == NULL) return NT_STATUS_NO_MEMORY;
for (i=0; i<num_rids; i++) {
DOM_SID sid;
sid_copy(&sid, domain_sid);
sid_append_rid(&sid, rids[i]);
tmp = allsids;
asprintf(&allsids, "%s(sambaSid=%s)", allsids,
sid_string_static(&sid));
if (allsids == NULL) return NT_STATUS_NO_MEMORY;
free(tmp);
}
/* First look for users */
{
char *filter;
const char *ldap_attrs[] = { "uid", "sambaSid", NULL };
asprintf(&filter, ("(&(objectClass=sambaSamAccount)(|%s))"),
allsids);
if (filter == NULL) return NT_STATUS_NO_MEMORY;
rc = smbldap_search(ldap_state->smbldap_state,
lp_ldap_user_suffix(),
LDAP_SCOPE_SUBTREE, filter, ldap_attrs, 0,
&msg);
SAFE_FREE(filter);
}
if (rc != LDAP_SUCCESS)
goto done;
num_mapped = 0;
for (entry = ldap_first_entry(ldap_struct, msg);
entry != NULL;
entry = ldap_next_entry(ldap_struct, entry))
{
uint32 rid;
int rid_index;
fstring str;
if (!ldapsam_extract_rid_from_entry(ldap_struct, entry,
get_global_sam_sid(),
&rid)) {
DEBUG(2, ("Could not find sid from ldap entry\n"));
continue;
}
if (!smbldap_get_single_attribute(ldap_struct, entry,
"uid", str, sizeof(str)-1)) {
DEBUG(2, ("Could not retrieve uid attribute\n"));
continue;
}
for (rid_index = 0; rid_index < num_rids; rid_index++) {
if (rid == rids[rid_index])
break;
}
if (rid_index == num_rids) {
DEBUG(2, ("Got a RID not asked for: %d\n", rid));
continue;
}
(*attrs)[rid_index] = SID_NAME_USER;
(*names)[rid_index] = talloc_strdup(mem_ctx, str);
if ((*names)[rid_index] == NULL) return NT_STATUS_NO_MEMORY;
num_mapped += 1;
}
if (num_mapped == num_rids) {
/* No need to look for groups anymore -- we're done */
result = NT_STATUS_OK;
goto done;
}
/* Same game for groups */
{
char *filter;
const char *ldap_attrs[] = { "cn", "sambaSid", NULL };
asprintf(&filter, ("(&(objectClass=sambaGroupMapping)(|%s))"),
allsids);
if (filter == NULL) return NT_STATUS_NO_MEMORY;
rc = smbldap_search(ldap_state->smbldap_state,
lp_ldap_group_suffix(),
LDAP_SCOPE_SUBTREE, filter, ldap_attrs, 0,
&msg);
SAFE_FREE(filter);
}
if (rc != LDAP_SUCCESS)
goto done;
for (entry = ldap_first_entry(ldap_struct, msg);
entry != NULL;
entry = ldap_next_entry(ldap_struct, entry))
{
uint32 rid;
int rid_index;
fstring str;
if (!ldapsam_extract_rid_from_entry(ldap_struct, entry,
get_global_sam_sid(),
&rid)) {
DEBUG(2, ("Could not find sid from ldap entry\n"));
continue;
}
if (!smbldap_get_single_attribute(ldap_struct, entry,
"cn", str, sizeof(str)-1)) {
DEBUG(2, ("Could not retrieve cn attribute\n"));
continue;
}
for (rid_index = 0; rid_index < num_rids; rid_index++) {
if (rid == rids[rid_index])
break;
}
if (rid_index == num_rids) {
DEBUG(2, ("Got a RID not asked for: %d\n", rid));
continue;
}
(*attrs)[rid_index] = SID_NAME_DOM_GRP;
(*names)[rid_index] = talloc_strdup(mem_ctx, str);
if ((*names)[rid_index] == NULL) return NT_STATUS_NO_MEMORY;
num_mapped += 1;
}
result = NT_STATUS_NONE_MAPPED;
if (num_mapped > 0)
result = (num_mapped == num_rids) ?
NT_STATUS_OK : STATUS_SOME_UNMAPPED;
done:
SAFE_FREE(allsids);
if (msg != NULL)
ldap_msgfree(msg);
return result;
}
char *get_ldap_filter(TALLOC_CTX *mem_ctx, const char *username)
{
char *filter = NULL;
char *escaped = NULL;
char *result = NULL;
asprintf(&filter, "(&%s(objectclass=sambaSamAccount))",
lp_ldap_filter());
if (filter == NULL) goto done;
escaped = escape_ldap_string_alloc(username);
if (escaped == NULL) goto done;
filter = realloc_string_sub(filter, "%u", username);
result = talloc_strdup(mem_ctx, filter);
done:
SAFE_FREE(filter);
SAFE_FREE(escaped);
return result;
}
const char **talloc_attrs(TALLOC_CTX *mem_ctx, ...)
{
int i, num = 0;
va_list ap;
const char **result;
va_start(ap, mem_ctx);
while (va_arg(ap, const char *) != NULL)
num += 1;
va_end(ap);
result = TALLOC_ARRAY(mem_ctx, const char *, num+1);
va_start(ap, mem_ctx);
for (i=0; i<num; i++)
result[i] = talloc_strdup(mem_ctx, va_arg(ap, const char*));
va_end(ap);
result[num] = NULL;
return result;
}
struct ldap_search_state {
struct smbldap_state *connection;
uint16 acct_flags;
const char *base;
int scope;
const char *filter;
const char **attrs;
int attrsonly;
void *pagedresults_cookie;
LDAPMessage *entries, *current_entry;
BOOL (*ldap2displayentry)(struct ldap_search_state *state,
TALLOC_CTX *mem_ctx,
LDAP *ld, LDAPMessage *entry,
struct samr_displayentry *result);
};
static BOOL ldapsam_search_firstpage(struct pdb_search *search)
{
struct ldap_search_state *state = search->private;
LDAP *ld = state->connection->ldap_struct;
int rc = LDAP_OPERATIONS_ERROR;
state->entries = NULL;
if (state->connection->paged_results) {
rc = smbldap_search_paged(state->connection, state->base,
state->scope, state->filter,
state->attrs, state->attrsonly,
lp_ldap_page_size(), &state->entries,
&state->pagedresults_cookie);
}
if ((rc != LDAP_SUCCESS) || (state->entries == NULL)) {
if (state->entries != NULL) {
/* Left over from unsuccessful paged attempt */
ldap_msgfree(state->entries);
state->entries = NULL;
}
rc = smbldap_search(state->connection, state->base,
state->scope, state->filter, state->attrs,
state->attrsonly, &state->entries);
if ((rc != LDAP_SUCCESS) || (state->entries == NULL))
return False;
/* Ok, the server was lying. It told us it could do paged
* searches when it could not. */
state->connection->paged_results = False;
}
if ( ld )
state->current_entry = ldap_first_entry(ld, state->entries);
if (state->current_entry == NULL) {
ldap_msgfree(state->entries);
state->entries = NULL;
}
return True;
}
static BOOL ldapsam_search_nextpage(struct pdb_search *search)
{
struct ldap_search_state *state = search->private;
LDAP *ld = state->connection->ldap_struct;
int rc;
if (!state->connection->paged_results) {
/* There is no next page when there are no paged results */
return False;
}
rc = smbldap_search_paged(state->connection, state->base,
state->scope, state->filter, state->attrs,
state->attrsonly, lp_ldap_page_size(),
&state->entries,
&state->pagedresults_cookie);
if ((rc != LDAP_SUCCESS) || (state->entries == NULL))
return False;
state->current_entry = ldap_first_entry(ld, state->entries);
if (state->current_entry == NULL) {
ldap_msgfree(state->entries);
state->entries = NULL;
}
return True;
}
static BOOL ldapsam_search_next_entry(struct pdb_search *search,
struct samr_displayentry *entry)
{
struct ldap_search_state *state = search->private;
LDAP *ld = state->connection->ldap_struct;
BOOL result;
retry:
if ((state->entries == NULL) && (state->pagedresults_cookie == NULL))
return False;
if ((state->entries == NULL) &&
!ldapsam_search_nextpage(search))
return False;
result = state->ldap2displayentry(state, search->mem_ctx, ld,
state->current_entry, entry);
if (!result) {
char *dn;
dn = ldap_get_dn(ld, state->current_entry);
DEBUG(5, ("Skipping entry %s\n", dn != NULL ? dn : "<NULL>"));
if (dn != NULL) ldap_memfree(dn);
}
state->current_entry = ldap_next_entry(ld, state->current_entry);
if (state->current_entry == NULL) {
ldap_msgfree(state->entries);
state->entries = NULL;
}
if (!result) goto retry;
return True;
}
static void ldapsam_search_end(struct pdb_search *search)
{
struct ldap_search_state *state = search->private;
int rc;
if (state->pagedresults_cookie == NULL)
return;
if (state->entries != NULL)
ldap_msgfree(state->entries);
state->entries = NULL;
state->current_entry = NULL;
if (!state->connection->paged_results)
return;
/* Tell the LDAP server we're not interested in the rest anymore. */
rc = smbldap_search_paged(state->connection, state->base, state->scope,
state->filter, state->attrs,
state->attrsonly, 0, &state->entries,
&state->pagedresults_cookie);
if (rc != LDAP_SUCCESS)
DEBUG(5, ("Could not end search properly\n"));
return;
}
static BOOL ldapuser2displayentry(struct ldap_search_state *state,
TALLOC_CTX *mem_ctx,
LDAP *ld, LDAPMessage *entry,
struct samr_displayentry *result)
{
char **vals;
DOM_SID sid;
uint16 acct_flags;
vals = ldap_get_values(ld, entry, "sambaAcctFlags");
if ((vals == NULL) || (vals[0] == NULL)) {
DEBUG(5, ("\"sambaAcctFlags\" not found\n"));
return False;
}
acct_flags = pdb_decode_acct_ctrl(vals[0]);
ldap_value_free(vals);
if ((state->acct_flags != 0) &&
((state->acct_flags & acct_flags) == 0))
return False;
result->acct_flags = acct_flags;
result->account_name = "";
result->fullname = "";
result->description = "";
vals = ldap_get_values(ld, entry, "uid");
if ((vals == NULL) || (vals[0] == NULL)) {
DEBUG(5, ("\"uid\" not found\n"));
return False;
}
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->account_name),
vals[0]);
ldap_value_free(vals);
vals = ldap_get_values(ld, entry, "displayName");
if ((vals == NULL) || (vals[0] == NULL))
DEBUG(8, ("\"displayName\" not found\n"));
else
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->fullname),
vals[0]);
ldap_value_free(vals);
vals = ldap_get_values(ld, entry, "description");
if ((vals == NULL) || (vals[0] == NULL))
DEBUG(8, ("\"description\" not found\n"));
else
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->description),
vals[0]);
ldap_value_free(vals);
if ((result->account_name == NULL) ||
(result->fullname == NULL) ||
(result->description == NULL)) {
DEBUG(0, ("talloc failed\n"));
return False;
}
vals = ldap_get_values(ld, entry, "sambaSid");
if ((vals == NULL) || (vals[0] == NULL)) {
DEBUG(0, ("\"objectSid\" not found\n"));
return False;
}
if (!string_to_sid(&sid, vals[0])) {
DEBUG(0, ("Could not convert %s to SID\n", vals[0]));
ldap_value_free(vals);
return False;
}
ldap_value_free(vals);
if (!sid_peek_check_rid(get_global_sam_sid(), &sid, &result->rid)) {
DEBUG(0, ("%s is not our domain\n", vals[0]));
return False;
}
return True;
}
static BOOL ldapsam_search_users(struct pdb_methods *methods,
struct pdb_search *search,
uint16 acct_flags)
{
struct ldapsam_privates *ldap_state = methods->private_data;
struct ldap_search_state *state;
state = TALLOC_P(search->mem_ctx, struct ldap_search_state);
if (state == NULL) {
DEBUG(0, ("talloc failed\n"));
return False;
}
state->connection = ldap_state->smbldap_state;
if ((acct_flags != 0) && ((acct_flags & ACB_NORMAL) != 0))
state->base = lp_ldap_user_suffix();
else if ((acct_flags != 0) &&
((acct_flags & (ACB_WSTRUST|ACB_SVRTRUST)) != 0))
state->base = lp_ldap_machine_suffix();
else
state->base = lp_ldap_suffix();
state->acct_flags = acct_flags;
state->base = talloc_strdup(search->mem_ctx, state->base);
state->scope = LDAP_SCOPE_SUBTREE;
state->filter = get_ldap_filter(search->mem_ctx, "*");
state->attrs = talloc_attrs(search->mem_ctx, "uid", "sambaSid",
"displayName", "description",
"sambaAcctFlags", NULL);
state->attrsonly = 0;
state->pagedresults_cookie = NULL;
state->entries = NULL;
state->ldap2displayentry = ldapuser2displayentry;
if ((state->filter == NULL) || (state->attrs == NULL)) {
DEBUG(0, ("talloc failed\n"));
return False;
}
search->private = state;
search->next_entry = ldapsam_search_next_entry;
search->search_end = ldapsam_search_end;
return ldapsam_search_firstpage(search);
}
static BOOL ldapgroup2displayentry(struct ldap_search_state *state,
TALLOC_CTX *mem_ctx,
LDAP *ld, LDAPMessage *entry,
struct samr_displayentry *result)
{
char **vals;
DOM_SID sid;
result->account_name = "";
result->fullname = "";
result->description = "";
vals = ldap_get_values(ld, entry, "cn");
if ((vals == NULL) || (vals[0] == NULL)) {
DEBUG(5, ("\"cn\" not found\n"));
return False;
}
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->account_name),
vals[0]);
ldap_value_free(vals);
vals = ldap_get_values(ld, entry, "displayName");
if ((vals == NULL) || (vals[0] == NULL))
DEBUG(8, ("\"displayName\" not found\n"));
else
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->fullname),
vals[0]);
ldap_value_free(vals);
vals = ldap_get_values(ld, entry, "description");
if ((vals == NULL) || (vals[0] == NULL))
DEBUG(8, ("\"description\" not found\n"));
else
pull_utf8_talloc(mem_ctx,
CONST_DISCARD(char **, &result->description),
vals[0]);
ldap_value_free(vals);
if ((result->account_name == NULL) ||
(result->fullname == NULL) ||
(result->description == NULL)) {
DEBUG(0, ("talloc failed\n"));
return False;
}
vals = ldap_get_values(ld, entry, "sambaSid");
if ((vals == NULL) || (vals[0] == NULL)) {
DEBUG(0, ("\"objectSid\" not found\n"));
return False;
}
if (!string_to_sid(&sid, vals[0])) {
DEBUG(0, ("Could not convert %s to SID\n", vals[0]));
return False;
}
if (!sid_peek_check_rid(get_global_sam_sid(), &sid, &result->rid)) {
DEBUG(0, ("%s is not our domain\n", vals[0]));
return False;
}
ldap_value_free(vals);
return True;
}
static BOOL ldapsam_search_grouptype(struct pdb_methods *methods,
struct pdb_search *search,
enum SID_NAME_USE type)
{
struct ldapsam_privates *ldap_state = methods->private_data;
struct ldap_search_state *state;
state = TALLOC_P(search->mem_ctx, struct ldap_search_state);
if (state == NULL) {
DEBUG(0, ("talloc failed\n"));
return False;
}
state->connection = ldap_state->smbldap_state;
state->base = talloc_strdup(search->mem_ctx, lp_ldap_group_suffix());
state->connection = ldap_state->smbldap_state;
state->scope = LDAP_SCOPE_SUBTREE;
state->filter = talloc_asprintf(search->mem_ctx,
"(&(objectclass=sambaGroupMapping)"
"(sambaGroupType=%d))", type);
state->attrs = talloc_attrs(search->mem_ctx, "cn", "sambaSid",
"displayName", "description", NULL);
state->attrsonly = 0;
state->pagedresults_cookie = NULL;
state->entries = NULL;
state->ldap2displayentry = ldapgroup2displayentry;
if ((state->filter == NULL) || (state->attrs == NULL)) {
DEBUG(0, ("talloc failed\n"));
return False;
}
search->private = state;
search->next_entry = ldapsam_search_next_entry;
search->search_end = ldapsam_search_end;
return ldapsam_search_firstpage(search);
}
static BOOL ldapsam_search_groups(struct pdb_methods *methods,
struct pdb_search *search)
{
return ldapsam_search_grouptype(methods, search, SID_NAME_DOM_GRP);
}
static BOOL ldapsam_search_aliases(struct pdb_methods *methods,
struct pdb_search *search,
const DOM_SID *sid)
{
if (sid_check_is_domain(sid))
return ldapsam_search_grouptype(methods, search,
SID_NAME_ALIAS);
if (sid_check_is_builtin(sid))
return ldapsam_search_grouptype(methods, search,
SID_NAME_WKN_GRP);
DEBUG(5, ("Don't know SID %s\n", sid_string_static(sid)));
return False;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
/**********************************************************************
Housekeeping
*********************************************************************/
static void free_private_data(void **vp)
{
struct ldapsam_privates **ldap_state = (struct ldapsam_privates **)vp;
smbldap_free_struct(&(*ldap_state)->smbldap_state);
if ((*ldap_state)->result != NULL) {
ldap_msgfree((*ldap_state)->result);
(*ldap_state)->result = NULL;
}
if ((*ldap_state)->domain_dn != NULL) {
SAFE_FREE((*ldap_state)->domain_dn);
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
*ldap_state = NULL;
/* No need to free any further, as it is talloc()ed */
}
/**********************************************************************
Intitalise the parts of the pdb_context that are common to all pdb_ldap modes
*********************************************************************/
static NTSTATUS pdb_init_ldapsam_common(PDB_CONTEXT *pdb_context, PDB_METHODS **pdb_method,
const char *location)
{
NTSTATUS nt_status;
struct ldapsam_privates *ldap_state;
if (!NT_STATUS_IS_OK(nt_status = make_pdb_methods(pdb_context->mem_ctx, pdb_method))) {
return nt_status;
}
(*pdb_method)->name = "ldapsam";
(*pdb_method)->setsampwent = ldapsam_setsampwent;
(*pdb_method)->endsampwent = ldapsam_endsampwent;
(*pdb_method)->getsampwent = ldapsam_getsampwent;
(*pdb_method)->getsampwnam = ldapsam_getsampwnam;
(*pdb_method)->getsampwsid = ldapsam_getsampwsid;
(*pdb_method)->add_sam_account = ldapsam_add_sam_account;
(*pdb_method)->update_sam_account = ldapsam_update_sam_account;
(*pdb_method)->delete_sam_account = ldapsam_delete_sam_account;
(*pdb_method)->getgrsid = ldapsam_getgrsid;
(*pdb_method)->getgrgid = ldapsam_getgrgid;
(*pdb_method)->getgrnam = ldapsam_getgrnam;
(*pdb_method)->add_group_mapping_entry = ldapsam_add_group_mapping_entry;
(*pdb_method)->update_group_mapping_entry = ldapsam_update_group_mapping_entry;
(*pdb_method)->delete_group_mapping_entry = ldapsam_delete_group_mapping_entry;
(*pdb_method)->enum_group_mapping = ldapsam_enum_group_mapping;
(*pdb_method)->enum_group_members = ldapsam_enum_group_members;
(*pdb_method)->enum_group_memberships = ldapsam_enum_group_memberships;
(*pdb_method)->lookup_rids = ldapsam_lookup_rids;
/* TODO: Setup private data and free */
ldap_state = TALLOC_ZERO_P(pdb_context->mem_ctx, struct ldapsam_privates);
if (!ldap_state) {
DEBUG(0, ("pdb_init_ldapsam_common: talloc() failed for ldapsam private_data!\n"));
return NT_STATUS_NO_MEMORY;
}
if (!NT_STATUS_IS_OK(nt_status =
smbldap_init(pdb_context->mem_ctx, location,
&ldap_state->smbldap_state)));
ldap_state->domain_name = talloc_strdup(pdb_context->mem_ctx, get_global_sam_name());
if (!ldap_state->domain_name) {
return NT_STATUS_NO_MEMORY;
}
(*pdb_method)->private_data = ldap_state;
(*pdb_method)->free_private_data = free_private_data;
return NT_STATUS_OK;
}
/**********************************************************************
Initialise the 'compat' mode for pdb_ldap
*********************************************************************/
NTSTATUS pdb_init_ldapsam_compat(PDB_CONTEXT *pdb_context, PDB_METHODS **pdb_method, const char *location)
{
NTSTATUS nt_status;
struct ldapsam_privates *ldap_state;
#ifdef WITH_LDAP_SAMCONFIG
if (!location) {
int ldap_port = lp_ldap_port();
/* remap default port if not using SSL (ie clear or TLS) */
if ( (lp_ldap_ssl() != LDAP_SSL_ON) && (ldap_port == 636) ) {
ldap_port = 389;
}
location = talloc_asprintf(pdb_context->mem_ctx, "%s://%s:%d", lp_ldap_ssl() == LDAP_SSL_ON ? "ldaps" : "ldap", lp_ldap_server(), ldap_port);
if (!location) {
return NT_STATUS_NO_MEMORY;
}
}
#endif
if (!NT_STATUS_IS_OK(nt_status = pdb_init_ldapsam_common(pdb_context, pdb_method, location))) {
return nt_status;
}
(*pdb_method)->name = "ldapsam_compat";
ldap_state = (*pdb_method)->private_data;
ldap_state->schema_ver = SCHEMAVER_SAMBAACCOUNT;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
sid_copy(&ldap_state->domain_sid, get_global_sam_sid());
return NT_STATUS_OK;
}
/**********************************************************************
Initialise the normal mode for pdb_ldap
*********************************************************************/
NTSTATUS pdb_init_ldapsam(PDB_CONTEXT *pdb_context, PDB_METHODS **pdb_method, const char *location)
{
NTSTATUS nt_status;
struct ldapsam_privates *ldap_state;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
uint32 alg_rid_base;
pstring alg_rid_base_string;
LDAPMessage *result = NULL;
LDAPMessage *entry = NULL;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
DOM_SID ldap_domain_sid;
DOM_SID secrets_domain_sid;
pstring domain_sid_string;
char *dn;
if (!NT_STATUS_IS_OK(nt_status = pdb_init_ldapsam_common(pdb_context, pdb_method, location))) {
return nt_status;
}
(*pdb_method)->name = "ldapsam";
(*pdb_method)->add_aliasmem = ldapsam_add_aliasmem;
(*pdb_method)->del_aliasmem = ldapsam_del_aliasmem;
(*pdb_method)->enum_aliasmem = ldapsam_enum_aliasmem;
(*pdb_method)->enum_alias_memberships = ldapsam_alias_memberships;
(*pdb_method)->search_users = ldapsam_search_users;
(*pdb_method)->search_groups = ldapsam_search_groups;
(*pdb_method)->search_aliases = ldapsam_search_aliases;
ldap_state = (*pdb_method)->private_data;
ldap_state->schema_ver = SCHEMAVER_SAMBASAMACCOUNT;
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
/* Try to setup the Domain Name, Domain SID, algorithmic rid base */
nt_status = smbldap_search_domain_info(ldap_state->smbldap_state, &result,
ldap_state->domain_name, True);
if ( !NT_STATUS_IS_OK(nt_status) ) {
DEBUG(2, ("pdb_init_ldapsam: WARNING: Could not get domain info, nor add one to the domain\n"));
DEBUGADD(2, ("pdb_init_ldapsam: Continuing on regardless, will be unable to allocate new users/groups, \
and will risk BDCs having inconsistant SIDs\n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
sid_copy(&ldap_state->domain_sid, get_global_sam_sid());
return NT_STATUS_OK;
}
/* Given that the above might fail, everything below this must be optional */
entry = ldap_first_entry(ldap_state->smbldap_state->ldap_struct, result);
if (!entry) {
DEBUG(0, ("pdb_init_ldapsam: Could not get domain info entry\n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
dn = smbldap_get_dn(ldap_state->smbldap_state->ldap_struct, entry);
if (!dn) {
return NT_STATUS_UNSUCCESSFUL;
}
ldap_state->domain_dn = smb_xstrdup(dn);
ldap_memfree(dn);
if (smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
get_userattr_key2string(ldap_state->schema_ver, LDAP_ATTR_USER_SID),
domain_sid_string)) {
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
BOOL found_sid;
if (!string_to_sid(&ldap_domain_sid, domain_sid_string)) {
DEBUG(1, ("pdb_init_ldapsam: SID [%s] could not be read as a valid SID\n", domain_sid_string));
return NT_STATUS_INVALID_PARAMETER;
}
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
found_sid = secrets_fetch_domain_sid(ldap_state->domain_name, &secrets_domain_sid);
if (!found_sid || !sid_equal(&secrets_domain_sid, &ldap_domain_sid)) {
fstring new_sid_str, old_sid_str;
DEBUG(1, ("pdb_init_ldapsam: Resetting SID for domain %s based on pdb_ldap results %s -> %s\n",
ldap_state->domain_name,
sid_to_string(old_sid_str, &secrets_domain_sid),
sid_to_string(new_sid_str, &ldap_domain_sid)));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
/* reset secrets.tdb sid */
secrets_store_domain_sid(ldap_state->domain_name, &ldap_domain_sid);
DEBUG(1, ("New global sam SID: %s\n", sid_to_string(new_sid_str, get_global_sam_sid())));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
}
sid_copy(&ldap_state->domain_sid, &ldap_domain_sid);
}
if (smbldap_get_single_pstring(ldap_state->smbldap_state->ldap_struct, entry,
get_attr_key2string( dominfo_attr_list, LDAP_ATTR_ALGORITHMIC_RID_BASE ),
alg_rid_base_string)) {
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
alg_rid_base = (uint32)atol(alg_rid_base_string);
if (alg_rid_base != algorithmic_rid_base()) {
DEBUG(0, ("The value of 'algorithmic RID base' has changed since the LDAP\n"
"database was initialised. Aborting. \n"));
This patch cleans up some of our ldap code, for better behaviour: We now always read the Domain SID out of LDAP. If the local secrets.tdb is ever different to LDAP, it is overwritten out of LDAP. We also store the 'algorithmic rid base' into LDAP, and assert if it changes. (This ensures cross-host synchronisation, and allows for possible integration with idmap). If we fail to read/add the domain entry, we just fallback to the old behaviour. We always use an existing DN when adding IDMAP entries to LDAP, unless no suitable entry is available. This means that a user's posixAccount will have a SID added to it, or a user's sambaSamAccount will have a UID added. Where we cannot us an existing DN, we use 'sambaSid=S-x-y-z,....' as the DN. The code now allows modifications to the ID mapping in many cases. Likewise, we now check more carefully when adding new user entires to LDAP, to not duplicate SIDs (for users, at this stage), and to add the sambaSamAccount onto the idmap entry for that user, if it is already established (ensuring we do not duplicate sambaSid entries in the directory). The allocated UID code has been expanded to take into account the space between '1000 - algorithmic rid base'. This much better fits into what an NT4 does - allocating in the bottom part of the RID range. On the code cleanup side of things, we now share as much code as possible between idmap_ldap and pdb_ldap. We also no longer use the race-prone 'enumerate all users' method for finding the next RID to allocate. Instead, we just start at the bottom of the range, and increment again if the user already exists. The first time this is run, it may well take a long time, but next time will just be able to use the next Rid. Thanks to metze and AB for double-checking parts of this. Andrew Bartlett (This used to be commit 9c595c8c2327b92a86901d84c3f2c284dabd597e)
2003-07-04 17:29:42 +04:00
ldap_msgfree(result);
return NT_STATUS_UNSUCCESSFUL;
}
}
ldap_msgfree(result);
return NT_STATUS_OK;
}
NTSTATUS pdb_ldap_init(void)
{
NTSTATUS nt_status;
if (!NT_STATUS_IS_OK(nt_status = smb_register_passdb(PASSDB_INTERFACE_VERSION, "ldapsam", pdb_init_ldapsam)))
return nt_status;
if (!NT_STATUS_IS_OK(nt_status = smb_register_passdb(PASSDB_INTERFACE_VERSION, "ldapsam_compat", pdb_init_ldapsam_compat)))
return nt_status;
/* Let pdb_nds register backends */
pdb_nds_init();
return NT_STATUS_OK;
}