/*
* Unix SMB/CIFS implementation.
* Virtual Windows Registry Layer
* Copyright (C) Gerald Carter 2002-2005
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see .
*/
/* Implementation of internal registry database functions. */
#include "includes.h"
#undef DBGC_CLASS
#define DBGC_CLASS DBGC_REGISTRY
static struct db_context *regdb = NULL;
static int regdb_refcount;
static bool regdb_key_exists(const char *key);
static bool regdb_key_is_base_key(const char *key);
/* List the deepest path into the registry. All part components will be created.*/
/* If you want to have a part of the path controlled by the tdb and part by
a virtual registry db (e.g. printing), then you have to list the deepest path.
For example,"HKLM/SOFTWARE/Microsoft/Windows NT/CurrentVersion/Print"
allows the reg_db backend to handle everything up to
"HKLM/SOFTWARE/Microsoft/Windows NT/CurrentVersion" and then we'll hook
the reg_printing backend onto the last component of the path (see
KEY_PRINTING_2K in include/rpc_reg.h) --jerry */
static const char *builtin_registry_paths[] = {
KEY_PRINTING_2K,
KEY_PRINTING_PORTS,
KEY_PRINTING,
KEY_SHARES,
KEY_EVENTLOG,
KEY_SMBCONF,
KEY_PERFLIB,
KEY_PERFLIB_009,
KEY_GROUP_POLICY,
KEY_SAMBA_GROUP_POLICY,
KEY_GP_MACHINE_POLICY,
KEY_GP_MACHINE_WIN_POLICY,
KEY_HKCU,
KEY_GP_USER_POLICY,
KEY_GP_USER_WIN_POLICY,
KEY_WINLOGON_GPEXT_PATH,
"HKLM\\SYSTEM\\CurrentControlSet\\Control\\Print\\Monitors",
KEY_PROD_OPTIONS,
"HKLM\\SYSTEM\\CurrentControlSet\\Control\\Terminal Server\\DefaultUserConfiguration",
KEY_TCPIP_PARAMS,
KEY_NETLOGON_PARAMS,
KEY_HKU,
KEY_HKCR,
KEY_HKPD,
KEY_HKPT,
NULL };
struct builtin_regkey_value {
const char *path;
const char *valuename;
uint32 type;
union {
const char *string;
uint32 dw_value;
} data;
};
static struct builtin_regkey_value builtin_registry_values[] = {
{ KEY_PRINTING_PORTS,
SAMBA_PRINTER_PORT_NAME, REG_SZ, { "" } },
{ KEY_PRINTING_2K,
"DefaultSpoolDirectory", REG_SZ, { "C:\\Windows\\System32\\Spool\\Printers" } },
{ KEY_EVENTLOG,
"DisplayName", REG_SZ, { "Event Log" } },
{ KEY_EVENTLOG,
"ErrorControl", REG_DWORD, { (char*)0x00000001 } },
{ NULL, NULL, 0, { NULL } }
};
/**
* Initialize a key in the registry:
* create each component key of the specified path.
*/
static WERROR init_registry_key_internal(const char *add_path)
{
WERROR werr;
TALLOC_CTX *frame = talloc_stackframe();
char *path = NULL;
char *base = NULL;
char *remaining = NULL;
char *keyname;
char *subkeyname;
REGSUBKEY_CTR *subkeys;
const char *p, *p2;
DEBUG(6, ("init_registry_key: Adding [%s]\n", add_path));
path = talloc_strdup(frame, add_path);
base = talloc_strdup(frame, "");
if (!path || !base) {
werr = WERR_NOMEM;
goto fail;
}
p = path;
while (next_token_talloc(frame, &p, &keyname, "\\")) {
/* build up the registry path from the components */
if (*base) {
base = talloc_asprintf(frame, "%s\\", base);
if (!base) {
werr = WERR_NOMEM;
goto fail;
}
}
base = talloc_asprintf_append(base, "%s", keyname);
if (!base) {
werr = WERR_NOMEM;
goto fail;
}
/* get the immediate subkeyname (if we have one ) */
subkeyname = talloc_strdup(frame, "");
if (!subkeyname) {
werr = WERR_NOMEM;
goto fail;
}
if (*p) {
remaining = talloc_strdup(frame, p);
if (!remaining) {
werr = WERR_NOMEM;
goto fail;
}
p2 = remaining;
if (!next_token_talloc(frame, &p2,
&subkeyname, "\\"))
{
subkeyname = talloc_strdup(frame,p2);
if (!subkeyname) {
werr = WERR_NOMEM;
goto fail;
}
}
}
DEBUG(10,("init_registry_key: Storing key [%s] with "
"subkey [%s]\n", base,
*subkeyname ? subkeyname : "NULL"));
/* we don't really care if the lookup succeeds or not
* since we are about to update the record.
* We just want any subkeys already present */
if (!(subkeys = TALLOC_ZERO_P(frame, REGSUBKEY_CTR))) {
DEBUG(0,("talloc() failure!\n"));
werr = WERR_NOMEM;
goto fail;
}
regdb_fetch_keys(base, subkeys);
if (*subkeyname) {
werr = regsubkey_ctr_addkey(subkeys, subkeyname);
if (!W_ERROR_IS_OK(werr)) {
goto fail;
}
}
if (!regdb_store_keys( base, subkeys)) {
werr = WERR_CAN_NOT_COMPLETE;
goto fail;
}
}
werr = WERR_OK;
fail:
TALLOC_FREE(frame);
return werr;
}
/**
* Initialize a key in the registry:
* create each component key of the specified path,
* wrapped in one db transaction.
*/
WERROR init_registry_key(const char *add_path)
{
WERROR werr;
if (regdb_key_exists(add_path)) {
return WERR_OK;
}
if (regdb->transaction_start(regdb) != 0) {
DEBUG(0, ("init_registry_key: transaction_start failed\n"));
return WERR_REG_IO_FAILURE;
}
werr = init_registry_key_internal(add_path);
if (!W_ERROR_IS_OK(werr)) {
goto fail;
}
if (regdb->transaction_commit(regdb) != 0) {
DEBUG(0, ("init_registry_key: Could not commit transaction\n"));
return WERR_REG_IO_FAILURE;
}
return WERR_OK;
fail:
if (regdb->transaction_cancel(regdb) != 0) {
smb_panic("init_registry_key: transaction_cancel failed\n");
}
return werr;
}
/***********************************************************************
Open the registry data in the tdb
***********************************************************************/
WERROR init_registry_data(void)
{
WERROR werr;
TALLOC_CTX *frame = talloc_stackframe();
REGVAL_CTR *values;
int i;
UNISTR2 data;
/*
* First, check for the existence of the needed keys and values.
* If all do already exist, we can save the writes.
*/
for (i=0; builtin_registry_paths[i] != NULL; i++) {
if (!regdb_key_exists(builtin_registry_paths[i])) {
goto do_init;
}
}
for (i=0; builtin_registry_values[i].path != NULL; i++) {
values = TALLOC_ZERO_P(frame, REGVAL_CTR);
if (values == NULL) {
werr = WERR_NOMEM;
goto done;
}
regdb_fetch_values(builtin_registry_values[i].path, values);
if (!regval_ctr_key_exists(values,
builtin_registry_values[i].valuename))
{
TALLOC_FREE(values);
goto do_init;
}
TALLOC_FREE(values);
}
werr = WERR_OK;
goto done;
do_init:
/*
* There are potentially quite a few store operations which are all
* indiviually wrapped in tdb transactions. Wrapping them in a single
* transaction gives just a single transaction_commit() to actually do
* its fsync()s. See tdb/common/transaction.c for info about nested
* transaction behaviour.
*/
if (regdb->transaction_start(regdb) != 0) {
DEBUG(0, ("init_registry_data: tdb_transaction_start "
"failed\n"));
werr = WERR_REG_IO_FAILURE;
goto done;
}
/* loop over all of the predefined paths and add each component */
for (i=0; builtin_registry_paths[i] != NULL; i++) {
if (regdb_key_exists(builtin_registry_paths[i])) {
continue;
}
werr = init_registry_key_internal(builtin_registry_paths[i]);
if (!W_ERROR_IS_OK(werr)) {
goto fail;
}
}
/* loop over all of the predefined values and add each component */
for (i=0; builtin_registry_values[i].path != NULL; i++) {
values = TALLOC_ZERO_P(frame, REGVAL_CTR);
if (values == NULL) {
werr = WERR_NOMEM;
goto fail;
}
regdb_fetch_values(builtin_registry_values[i].path, values);
/* preserve existing values across restarts. Only add new ones */
if (!regval_ctr_key_exists(values,
builtin_registry_values[i].valuename))
{
switch(builtin_registry_values[i].type) {
case REG_DWORD:
regval_ctr_addvalue(values,
builtin_registry_values[i].valuename,
REG_DWORD,
(char*)&builtin_registry_values[i].data.dw_value,
sizeof(uint32));
break;
case REG_SZ:
init_unistr2(&data,
builtin_registry_values[i].data.string,
UNI_STR_TERMINATE);
regval_ctr_addvalue(values,
builtin_registry_values[i].valuename,
REG_SZ,
(char*)data.buffer,
data.uni_str_len*sizeof(uint16));
break;
default:
DEBUG(0, ("init_registry_data: invalid value "
"type in builtin_registry_values "
"[%d]\n",
builtin_registry_values[i].type));
}
regdb_store_values(builtin_registry_values[i].path,
values);
}
TALLOC_FREE(values);
}
if (regdb->transaction_commit(regdb) != 0) {
DEBUG(0, ("init_registry_data: Could not commit "
"transaction\n"));
werr = WERR_REG_IO_FAILURE;
} else {
werr = WERR_OK;
}
goto done;
fail:
if (regdb->transaction_cancel(regdb) != 0) {
smb_panic("init_registry_data: tdb_transaction_cancel "
"failed\n");
}
done:
TALLOC_FREE(frame);
return werr;
}
/***********************************************************************
Open the registry database
***********************************************************************/
WERROR regdb_init(void)
{
const char *vstring = "INFO/version";
uint32 vers_id;
WERROR werr;
if (regdb) {
DEBUG(10, ("regdb_init: incrementing refcount (%d)\n",
regdb_refcount));
regdb_refcount++;
return WERR_OK;
}
regdb = db_open(NULL, state_path("registry.tdb"), 0,
REG_TDB_FLAGS, O_RDWR, 0600);
if (!regdb) {
regdb = db_open(NULL, state_path("registry.tdb"), 0,
REG_TDB_FLAGS, O_RDWR|O_CREAT, 0600);
if (!regdb) {
werr = ntstatus_to_werror(map_nt_error_from_unix(errno));
DEBUG(1,("regdb_init: Failed to open registry %s (%s)\n",
state_path("registry.tdb"), strerror(errno) ));
return werr;
}
DEBUG(10,("regdb_init: Successfully created registry tdb\n"));
}
regdb_refcount = 1;
vers_id = dbwrap_fetch_int32(regdb, vstring);
if ( vers_id != REGVER_V1 ) {
NTSTATUS status;
/* any upgrade code here if needed */
DEBUG(10, ("regdb_init: got %s = %d != %d\n", vstring,
vers_id, REGVER_V1));
status = dbwrap_trans_store_int32(regdb, vstring, REGVER_V1);
if (!NT_STATUS_IS_OK(status)) {
DEBUG(1, ("regdb_init: error storing %s = %d: %s\n",
vstring, REGVER_V1, nt_errstr(status)));
return ntstatus_to_werror(status);
} else {
DEBUG(10, ("regdb_init: stored %s = %d\n",
vstring, REGVER_V1));
}
}
return WERR_OK;
}
/***********************************************************************
Open the registry. Must already have been initialized by regdb_init()
***********************************************************************/
WERROR regdb_open( void )
{
WERROR result = WERR_OK;
if ( regdb ) {
DEBUG(10,("regdb_open: incrementing refcount (%d)\n", regdb_refcount));
regdb_refcount++;
return WERR_OK;
}
become_root();
regdb = db_open(NULL, state_path("registry.tdb"), 0,
REG_TDB_FLAGS, O_RDWR, 0600);
if ( !regdb ) {
result = ntstatus_to_werror( map_nt_error_from_unix( errno ) );
DEBUG(0,("regdb_open: Failed to open %s! (%s)\n",
state_path("registry.tdb"), strerror(errno) ));
}
unbecome_root();
regdb_refcount = 1;
DEBUG(10,("regdb_open: refcount reset (%d)\n", regdb_refcount));
return result;
}
/***********************************************************************
***********************************************************************/
int regdb_close( void )
{
if (regdb_refcount == 0) {
return 0;
}
regdb_refcount--;
DEBUG(10,("regdb_close: decrementing refcount (%d)\n", regdb_refcount));
if ( regdb_refcount > 0 )
return 0;
SMB_ASSERT( regdb_refcount >= 0 );
TALLOC_FREE(regdb);
return 0;
}
WERROR regdb_transaction_start(void)
{
return (regdb->transaction_start(regdb) == 0) ?
WERR_OK : WERR_REG_IO_FAILURE;
}
WERROR regdb_transaction_commit(void)
{
return (regdb->transaction_commit(regdb) == 0) ?
WERR_OK : WERR_REG_IO_FAILURE;
}
WERROR regdb_transaction_cancel(void)
{
return (regdb->transaction_cancel(regdb) == 0) ?
WERR_OK : WERR_REG_IO_FAILURE;
}
/***********************************************************************
return the tdb sequence number of the registry tdb.
this is an indicator for the content of the registry
having changed. it will change upon regdb_init, too, though.
***********************************************************************/
int regdb_get_seqnum(void)
{
return regdb->get_seqnum(regdb);
}
/***********************************************************************
Add subkey strings to the registry tdb under a defined key
fmt is the same format as tdb_pack except this function only supports
fstrings
***********************************************************************/
static bool regdb_store_keys_internal(const char *key, REGSUBKEY_CTR *ctr)
{
TDB_DATA dbuf;
uint8 *buffer = NULL;
int i = 0;
uint32 len, buflen;
bool ret = true;
uint32 num_subkeys = regsubkey_ctr_numkeys(ctr);
char *keyname = NULL;
TALLOC_CTX *ctx = talloc_stackframe();
NTSTATUS status;
if (!key) {
return false;
}
keyname = talloc_strdup(ctx, key);
if (!keyname) {
return false;
}
keyname = normalize_reg_path(ctx, keyname);
/* allocate some initial memory */
buffer = (uint8 *)SMB_MALLOC(1024);
if (buffer == NULL) {
return false;
}
buflen = 1024;
len = 0;
/* store the number of subkeys */
len += tdb_pack(buffer+len, buflen-len, "d", num_subkeys);
/* pack all the strings */
for (i=0; i buflen) {
size_t thistime2;
/*
* tdb_pack hasn't done anything because of the short
* buffer, allocate extra space.
*/
buffer = SMB_REALLOC_ARRAY(buffer, uint8_t,
(len+thistime)*2);
if(buffer == NULL) {
DEBUG(0, ("regdb_store_keys: Failed to realloc "
"memory of size [%u]\n",
(unsigned int)(len+thistime)*2));
ret = false;
goto done;
}
buflen = (len+thistime)*2;
thistime2 = tdb_pack(
buffer+len, buflen-len, "f",
regsubkey_ctr_specific_key(ctr, i));
if (thistime2 != thistime) {
DEBUG(0, ("tdb_pack failed\n"));
ret = false;
goto done;
}
}
len += thistime;
}
/* finally write out the data */
dbuf.dptr = buffer;
dbuf.dsize = len;
status = dbwrap_store_bystring(regdb, keyname, dbuf, TDB_REPLACE);
if (!NT_STATUS_IS_OK(status)) {
ret = false;
goto done;
}
/*
* Delete a sorted subkey cache for regdb_key_exists, will be
* recreated automatically
*/
keyname = talloc_asprintf(ctx, "%s/%s", REG_SORTED_SUBKEYS_PREFIX,
keyname);
if (keyname != NULL) {
dbwrap_delete_bystring(regdb, keyname);
}
done:
TALLOC_FREE(ctx);
SAFE_FREE(buffer);
return ret;
}
/***********************************************************************
Store the new subkey record and create any child key records that
do not currently exist
***********************************************************************/
bool regdb_store_keys(const char *key, REGSUBKEY_CTR *ctr)
{
int num_subkeys, i;
char *path = NULL;
REGSUBKEY_CTR *subkeys = NULL, *old_subkeys = NULL;
char *oldkeyname = NULL;
TALLOC_CTX *ctx = talloc_stackframe();
NTSTATUS status;
if (!regdb_key_is_base_key(key) && !regdb_key_exists(key)) {
goto fail;
}
/*
* fetch a list of the old subkeys so we can determine if anything has
* changed
*/
if (!(old_subkeys = TALLOC_ZERO_P(ctx, REGSUBKEY_CTR))) {
DEBUG(0,("regdb_store_keys: talloc() failure!\n"));
return false;
}
regdb_fetch_keys(key, old_subkeys);
if ((ctr->num_subkeys && old_subkeys->num_subkeys) &&
(ctr->num_subkeys == old_subkeys->num_subkeys)) {
for (i = 0; inum_subkeys; i++) {
if (strcmp(ctr->subkeys[i],
old_subkeys->subkeys[i]) != 0) {
break;
}
}
if (i == ctr->num_subkeys) {
/*
* Nothing changed, no point to even start a tdb
* transaction
*/
TALLOC_FREE(old_subkeys);
return true;
}
}
TALLOC_FREE(old_subkeys);
if (regdb->transaction_start(regdb) != 0) {
DEBUG(0, ("regdb_store_keys: transaction_start failed\n"));
goto fail;
}
/*
* Re-fetch the old keys inside the transaction
*/
if (!(old_subkeys = TALLOC_ZERO_P(ctx, REGSUBKEY_CTR))) {
DEBUG(0,("regdb_store_keys: talloc() failure!\n"));
goto cancel;
}
regdb_fetch_keys(key, old_subkeys);
/*
* Make the store operation as safe as possible without transactions:
*
* (1) For each subkey removed from ctr compared with old_subkeys:
*
* (a) First delete the value db entry.
*
* (b) Next delete the secdesc db record.
*
* (c) Then delete the subkey list entry.
*
* (2) Now write the list of subkeys of the parent key,
* deleting removed entries and adding new ones.
*
* (3) Finally create the subkey list entries for the added keys.
*
* This way if we crash half-way in between deleting the subkeys
* and storing the parent's list of subkeys, no old data can pop up
* out of the blue when re-adding keys later on.
*/
/* (1) delete removed keys' lists (values/secdesc/subkeys) */
num_subkeys = regsubkey_ctr_numkeys(old_subkeys);
for (i=0; itransaction_commit(regdb) != 0) {
DEBUG(0, ("regdb_store_keys: Could not commit transaction\n"));
goto fail;
}
TALLOC_FREE(ctx);
return true;
cancel:
if (regdb->transaction_cancel(regdb) != 0) {
smb_panic("regdb_store_keys: transaction_cancel failed\n");
}
fail:
TALLOC_FREE(ctx);
return false;
}
static TDB_DATA regdb_fetch_key_internal(TALLOC_CTX *mem_ctx, const char *key)
{
char *path = NULL;
TDB_DATA data;
path = normalize_reg_path(mem_ctx, key);
if (!path) {
return make_tdb_data(NULL, 0);
}
data = dbwrap_fetch_bystring(regdb, mem_ctx, path);
TALLOC_FREE(path);
return data;
}
/**
* check whether a given key name represents a base key,
* i.e one without a subkey separator ('/' or '\').
*/
static bool regdb_key_is_base_key(const char *key)
{
TALLOC_CTX *mem_ctx = talloc_stackframe();
bool ret = false;
char *path;
if (key == NULL) {
goto done;
}
path = normalize_reg_path(mem_ctx, key);
if (path == NULL) {
DEBUG(0, ("out of memory! (talloc failed)\n"));
goto done;
}
if (*path == '\0') {
goto done;
}
ret = (strrchr(path, '/') == NULL);
done:
TALLOC_FREE(mem_ctx);
return ret;
}
/*
* regdb_key_exists() is a very frequent operation. It can be quite
* time-consuming to fully fetch the parent's subkey list, talloc_strdup all
* subkeys and then compare the keyname linearly to all the parent's subkeys.
*
* The following code tries to make this operation as efficient as possible:
* Per registry key we create a list of subkeys that is very efficient to
* search for existence of a subkey. Its format is:
*
* 4 bytes num_subkeys
* 4*num_subkey bytes offset into the string array
* then follows a sorted list of subkeys in uppercase
*
* This record is created by create_sorted_subkeys() on demand if it does not
* exist. scan_parent_subkeys() uses regdb->parse_record to search the sorted
* list, the parsing code and the binary search can be found in
* parent_subkey_scanner. The code uses parse_record() to avoid a memcpy of
* the potentially large subkey record.
*
* The sorted subkey record is deleted in regdb_store_keys_internal and
* recreated on demand.
*/
static int cmp_keynames(const void *p1, const void *p2)
{
return StrCaseCmp(*((char **)p1), *((char **)p2));
}
static bool create_sorted_subkeys(const char *key, const char *sorted_keyname)
{
char **sorted_subkeys;
REGSUBKEY_CTR *ctr;
bool result = false;
NTSTATUS status;
char *buf;
char *p;
int i, res;
size_t len;
if (regdb->transaction_start(regdb) != 0) {
DEBUG(0, ("create_sorted_subkeys: transaction_start "
"failed\n"));
return false;
}
ctr = talloc(talloc_tos(), REGSUBKEY_CTR);
if (ctr == NULL) {
goto fail;
}
res = regdb_fetch_keys(key, ctr);
if (res == -1) {
goto fail;
}
sorted_subkeys = talloc_array(ctr, char *, ctr->num_subkeys);
if (sorted_subkeys == NULL) {
goto fail;
}
len = 4 + 4*ctr->num_subkeys;
for (i = 0; inum_subkeys; i++) {
sorted_subkeys[i] = talloc_strdup_upper(sorted_subkeys,
ctr->subkeys[i]);
if (sorted_subkeys[i] == NULL) {
goto fail;
}
len += strlen(sorted_subkeys[i])+1;
}
qsort(sorted_subkeys, ctr->num_subkeys, sizeof(char *), cmp_keynames);
buf = talloc_array(ctr, char, len);
if (buf == NULL) {
goto fail;
}
p = buf + 4 + 4*ctr->num_subkeys;
SIVAL(buf, 0, ctr->num_subkeys);
for (i=0; inum_subkeys; i++) {
ptrdiff_t offset = p - buf;
SIVAL(buf, 4 + 4*i, offset);
strlcpy(p, sorted_subkeys[i], len-offset);
p += strlen(sorted_subkeys[i]) + 1;
}
status = dbwrap_store_bystring(
regdb, sorted_keyname, make_tdb_data((uint8_t *)buf, len),
TDB_REPLACE);
if (!NT_STATUS_IS_OK(status)) {
/*
* Don't use a "goto fail;" here, this would commit the broken
* transaction. See below for an explanation.
*/
if (regdb->transaction_cancel(regdb) == -1) {
DEBUG(0, ("create_sorted_subkeys: transaction_cancel "
"failed\n"));
}
TALLOC_FREE(ctr);
return false;
}
result = true;
fail:
/*
* We only get here via the "goto fail" when we did not write anything
* yet. Using transaction_commit even in a failure case is necessary
* because this (disposable) call might be nested in other
* transactions. Doing a cancel here would destroy the possibility of
* a transaction_commit for transactions that we might be wrapped in.
*/
if (regdb->transaction_commit(regdb) == -1) {
DEBUG(0, ("create_sorted_subkeys: transaction_start "
"failed\n"));
goto fail;
}
TALLOC_FREE(ctr);
return result;
}
struct scan_subkey_state {
char *name;
bool scanned;
bool found;
};
static int parent_subkey_scanner(TDB_DATA key, TDB_DATA data,
void *private_data)
{
struct scan_subkey_state *state =
(struct scan_subkey_state *)private_data;
uint32_t num_subkeys;
uint32_t l, u;
if (data.dsize < sizeof(uint32_t)) {
return -1;
}
state->scanned = true;
state->found = false;
tdb_unpack(data.dptr, data.dsize, "d", &num_subkeys);
l = 0;
u = num_subkeys;
while (l < u) {
uint32_t idx = (l+u)/2;
char *s = (char *)data.dptr + IVAL(data.dptr, 4 + 4*idx);
int comparison = strcmp(state->name, s);
if (comparison < 0) {
u = idx;
} else if (comparison > 0) {
l = idx + 1;
} else {
state->found = true;
return 0;
}
}
return 0;
}
static bool scan_parent_subkeys(const char *parent, const char *name)
{
char *path = NULL;
char *key = NULL;
struct scan_subkey_state state = { 0, };
bool result = false;
int res;
state.name = NULL;
path = normalize_reg_path(talloc_tos(), parent);
if (path == NULL) {
goto fail;
}
key = talloc_asprintf(talloc_tos(), "%s/%s",
REG_SORTED_SUBKEYS_PREFIX, path);
if (key == NULL) {
goto fail;
}
state.name = talloc_strdup_upper(talloc_tos(), name);
if (state.name == NULL) {
goto fail;
}
state.scanned = false;
res = regdb->parse_record(regdb, string_term_tdb_data(key),
parent_subkey_scanner, &state);
if (state.scanned) {
result = state.found;
} else {
if (!create_sorted_subkeys(path, key)) {
goto fail;
}
res = regdb->parse_record(regdb, string_term_tdb_data(key),
parent_subkey_scanner, &state);
if ((res == 0) && (state.scanned)) {
result = state.found;
}
}
fail:
TALLOC_FREE(path);
TALLOC_FREE(state.name);
return result;
}
/**
* Check for the existence of a key.
*
* Existence of a key is authoritatively defined by its
* existence in the list of subkeys of its parent key.
* The exeption of this are keys without a parent key,
* i.e. the "base" keys (HKLM, HKCU, ...).
*/
static bool regdb_key_exists(const char *key)
{
TALLOC_CTX *mem_ctx = talloc_stackframe();
TDB_DATA value;
bool ret = false;
char *path, *p;
if (key == NULL) {
goto done;
}
path = normalize_reg_path(mem_ctx, key);
if (path == NULL) {
DEBUG(0, ("out of memory! (talloc failed)\n"));
goto done;
}
if (*path == '\0') {
goto done;
}
p = strrchr(path, '/');
if (p == NULL) {
/* this is a base key */
value = regdb_fetch_key_internal(mem_ctx, path);
ret = (value.dptr != NULL);
} else {
*p = '\0';
ret = scan_parent_subkeys(path, p+1);
}
done:
TALLOC_FREE(mem_ctx);
return ret;
}
/***********************************************************************
Retrieve an array of strings containing subkeys. Memory should be
released by the caller.
***********************************************************************/
int regdb_fetch_keys(const char *key, REGSUBKEY_CTR *ctr)
{
uint32 num_items;
uint8 *buf;
uint32 buflen, len;
int i;
fstring subkeyname;
int ret = -1;
TALLOC_CTX *frame = talloc_stackframe();
TDB_DATA value;
DEBUG(11,("regdb_fetch_keys: Enter key => [%s]\n", key ? key : "NULL"));
if (!regdb_key_exists(key)) {
goto done;
}
ctr->seqnum = regdb_get_seqnum();
value = regdb_fetch_key_internal(frame, key);
if (value.dptr == NULL) {
DEBUG(10, ("regdb_fetch_keys: no subkeys found for key [%s]\n",
key));
ret = 0;
goto done;
}
buf = value.dptr;
buflen = value.dsize;
len = tdb_unpack( buf, buflen, "d", &num_items);
/*
* The following code breaks the abstraction that reg_objects.c sets
* up with regsubkey_ctr_addkey(). But if we use that with the current
* data structure of ctr->subkeys being an unsorted array, we end up
* with an O(n^2) algorithm for retrieving keys from the tdb
* file. This is pretty pointless, as we have to trust the data
* structure on disk not to have duplicates anyway. The alternative to
* breaking this abstraction would be to set up a more sophisticated
* data structure in REGSUBKEY_CTR.
*
* This makes "net conf list" for a registry with >1000 shares
* actually usable :-)
*/
ctr->subkeys = talloc_array(ctr, char *, num_items);
if (ctr->subkeys == NULL) {
DEBUG(5, ("regdb_fetch_keys: could not allocate subkeys\n"));
goto done;
}
ctr->num_subkeys = num_items;
for (i=0; isubkeys[i] = talloc_strdup(ctr->subkeys, subkeyname);
if (ctr->subkeys[i] == NULL) {
DEBUG(5, ("regdb_fetch_keys: could not allocate "
"subkeyname\n"));
TALLOC_FREE(ctr->subkeys);
ctr->num_subkeys = 0;
goto done;
}
}
DEBUG(11,("regdb_fetch_keys: Exit [%d] items\n", num_items));
ret = num_items;
done:
TALLOC_FREE(frame);
return ret;
}
/****************************************************************************
Unpack a list of registry values frem the TDB
***************************************************************************/
static int regdb_unpack_values(REGVAL_CTR *values, uint8 *buf, int buflen)
{
int len = 0;
uint32 type;
fstring valuename;
uint32 size;
uint8 *data_p;
uint32 num_values = 0;
int i;
/* loop and unpack the rest of the registry values */
len += tdb_unpack(buf+len, buflen-len, "d", &num_values);
for ( i=0; iseqnum = regdb_get_seqnum();
value = regdb_fetch_key_internal(ctx, keystr);
if (!value.dptr) {
/* all keys have zero values by default */
goto done;
}
regdb_unpack_values(values, value.dptr, value.dsize);
ret = regval_ctr_numvals(values);
done:
TALLOC_FREE(ctx);
return ret;
}
bool regdb_store_values( const char *key, REGVAL_CTR *values )
{
TDB_DATA old_data, data;
char *keystr = NULL;
TALLOC_CTX *ctx = talloc_stackframe();
int len;
NTSTATUS status;
bool result = false;
DEBUG(10,("regdb_store_values: Looking for value of key [%s] \n", key));
if (!regdb_key_exists(key)) {
goto done;
}
ZERO_STRUCT(data);
len = regdb_pack_values(values, data.dptr, data.dsize);
if (len <= 0) {
DEBUG(0,("regdb_store_values: unable to pack values. len <= 0\n"));
goto done;
}
data.dptr = TALLOC_ARRAY(ctx, uint8, len);
data.dsize = len;
len = regdb_pack_values(values, data.dptr, data.dsize);
SMB_ASSERT( len == data.dsize );
keystr = talloc_asprintf(ctx, "%s/%s", REG_VALUE_PREFIX, key );
if (!keystr) {
goto done;
}
keystr = normalize_reg_path(ctx, keystr);
if (!keystr) {
goto done;
}
old_data = dbwrap_fetch_bystring(regdb, ctx, keystr);
if ((old_data.dptr != NULL)
&& (old_data.dsize == data.dsize)
&& (memcmp(old_data.dptr, data.dptr, data.dsize) == 0))
{
result = true;
goto done;
}
status = dbwrap_trans_store_bystring(regdb, keystr, data, TDB_REPLACE);
result = NT_STATUS_IS_OK(status);
done:
TALLOC_FREE(ctx);
return result;
}
static WERROR regdb_get_secdesc(TALLOC_CTX *mem_ctx, const char *key,
struct security_descriptor **psecdesc)
{
char *tdbkey;
TDB_DATA data;
NTSTATUS status;
TALLOC_CTX *tmp_ctx = talloc_stackframe();
WERROR err = WERR_OK;
DEBUG(10, ("regdb_get_secdesc: Getting secdesc of key [%s]\n", key));
if (!regdb_key_exists(key)) {
err = WERR_BADFILE;
goto done;
}
tdbkey = talloc_asprintf(tmp_ctx, "%s/%s", REG_SECDESC_PREFIX, key);
if (tdbkey == NULL) {
err = WERR_NOMEM;
goto done;
}
normalize_dbkey(tdbkey);
data = dbwrap_fetch_bystring(regdb, tmp_ctx, tdbkey);
if (data.dptr == NULL) {
err = WERR_BADFILE;
goto done;
}
status = unmarshall_sec_desc(mem_ctx, (uint8 *)data.dptr, data.dsize,
psecdesc);
if (NT_STATUS_EQUAL(status, NT_STATUS_NO_MEMORY)) {
err = WERR_NOMEM;
} else if (!NT_STATUS_IS_OK(status)) {
err = WERR_REG_CORRUPT;
}
done:
TALLOC_FREE(tmp_ctx);
return err;
}
static WERROR regdb_set_secdesc(const char *key,
struct security_descriptor *secdesc)
{
TALLOC_CTX *mem_ctx = talloc_stackframe();
char *tdbkey;
NTSTATUS status;
WERROR err = WERR_NOMEM;
TDB_DATA tdbdata;
if (!regdb_key_exists(key)) {
err = WERR_BADFILE;
goto done;
}
tdbkey = talloc_asprintf(mem_ctx, "%s/%s", REG_SECDESC_PREFIX, key);
if (tdbkey == NULL) {
goto done;
}
normalize_dbkey(tdbkey);
if (secdesc == NULL) {
/* assuming a delete */
status = dbwrap_trans_delete_bystring(regdb, tdbkey);
if (NT_STATUS_IS_OK(status)) {
err = WERR_OK;
} else {
err = ntstatus_to_werror(status);
}
goto done;
}
err = ntstatus_to_werror(marshall_sec_desc(mem_ctx, secdesc,
&tdbdata.dptr,
&tdbdata.dsize));
if (!W_ERROR_IS_OK(err)) {
goto done;
}
status = dbwrap_trans_store_bystring(regdb, tdbkey, tdbdata, 0);
if (!NT_STATUS_IS_OK(status)) {
err = ntstatus_to_werror(status);
goto done;
}
done:
TALLOC_FREE(mem_ctx);
return err;
}
bool regdb_subkeys_need_update(REGSUBKEY_CTR *subkeys)
{
return (regdb_get_seqnum() != subkeys->seqnum);
}
bool regdb_values_need_update(REGVAL_CTR *values)
{
return (regdb_get_seqnum() != values->seqnum);
}
/*
* Table of function pointers for default access
*/
REGISTRY_OPS regdb_ops = {
.fetch_subkeys = regdb_fetch_keys,
.fetch_values = regdb_fetch_values,
.store_subkeys = regdb_store_keys,
.store_values = regdb_store_values,
.get_secdesc = regdb_get_secdesc,
.set_secdesc = regdb_set_secdesc,
.subkeys_need_update = regdb_subkeys_need_update,
.values_need_update = regdb_values_need_update
};