/* * Unix SMB/CIFS implementation. * Virtual Windows Registry Layer * Copyright (C) Volker Lendecke 2006 * Copyright (C) Michael Adam 2007-2010 * * 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 . */ /* Attempt to wrap the existing API in a more winreg.idl-like way */ /* * Here is a list of winreg.idl functions and corresponding implementations * provided here: * * 0x00 winreg_OpenHKCR * 0x01 winreg_OpenHKCU * 0x02 winreg_OpenHKLM * 0x03 winreg_OpenHKPD * 0x04 winreg_OpenHKU * 0x05 winreg_CloseKey * 0x06 winreg_CreateKey reg_createkey * 0x07 winreg_DeleteKey reg_deletekey * 0x08 winreg_DeleteValue reg_deletevalue * 0x09 winreg_EnumKey reg_enumkey * 0x0a winreg_EnumValue reg_enumvalue * 0x0b winreg_FlushKey * 0x0c winreg_GetKeySecurity reg_getkeysecurity * 0x0d winreg_LoadKey * 0x0e winreg_NotifyChangeKeyValue * 0x0f winreg_OpenKey reg_openkey * 0x10 winreg_QueryInfoKey reg_queryinfokey * 0x11 winreg_QueryValue reg_queryvalue * 0x12 winreg_ReplaceKey * 0x13 winreg_RestoreKey reg_restorekey * 0x14 winreg_SaveKey reg_savekey * 0x15 winreg_SetKeySecurity reg_setkeysecurity * 0x16 winreg_SetValue reg_setvalue * 0x17 winreg_UnLoadKey * 0x18 winreg_InitiateSystemShutdown * 0x19 winreg_AbortSystemShutdown * 0x1a winreg_GetVersion reg_getversion * 0x1b winreg_OpenHKCC * 0x1c winreg_OpenHKDD * 0x1d winreg_QueryMultipleValues reg_querymultiplevalues * 0x1e winreg_InitiateSystemShutdownEx * 0x1f winreg_SaveKeyEx * 0x20 winreg_OpenHKPT * 0x21 winreg_OpenHKPN * 0x22 winreg_QueryMultipleValues2 reg_querymultiplevalues * */ #include "includes.h" #include "registry.h" #include "reg_api.h" #include "reg_cachehook.h" #include "reg_backend_db.h" #include "reg_dispatcher.h" #include "reg_objects.h" #include "../librpc/gen_ndr/ndr_security.h" #include "reg_parse_internal.h" #undef DBGC_CLASS #define DBGC_CLASS DBGC_REGISTRY /********************************************************************** * Helper functions **********************************************************************/ static WERROR fill_value_cache(struct registry_key *key) { WERROR werr; if (key->values != NULL) { if (!reg_values_need_update(key->key, key->values)) { return WERR_OK; } } TALLOC_FREE(key->values); werr = regval_ctr_init(key, &(key->values)); W_ERROR_NOT_OK_RETURN(werr); if (fetch_reg_values(key->key, key->values) == -1) { TALLOC_FREE(key->values); return WERR_BADFILE; } return WERR_OK; } static WERROR fill_subkey_cache(struct registry_key *key) { WERROR werr; if (key->subkeys != NULL) { if (!reg_subkeys_need_update(key->key, key->subkeys)) { return WERR_OK; } } TALLOC_FREE(key->subkeys); werr = regsubkey_ctr_init(key, &(key->subkeys)); W_ERROR_NOT_OK_RETURN(werr); if (fetch_reg_keys(key->key, key->subkeys) == -1) { TALLOC_FREE(key->subkeys); return WERR_BADFILE; } return WERR_OK; } static int regkey_destructor(struct registry_key_handle *key) { return regdb_close(); } static WERROR regkey_open_onelevel(TALLOC_CTX *mem_ctx, struct registry_key *parent, const char *name, const struct security_token *token, uint32_t access_desired, struct registry_key **pregkey) { WERROR result = WERR_OK; struct registry_key *regkey; struct registry_key_handle *key; DEBUG(7,("regkey_open_onelevel: name = [%s]\n", name)); SMB_ASSERT(strchr(name, '\\') == NULL); if (!(regkey = talloc_zero(mem_ctx, struct registry_key)) || !(regkey->token = dup_nt_token(regkey, token)) || !(regkey->key = talloc_zero(regkey, struct registry_key_handle))) { result = WERR_NOMEM; goto done; } result = regdb_open(); if (!(W_ERROR_IS_OK(result))) { goto done; } key = regkey->key; talloc_set_destructor(key, regkey_destructor); /* initialization */ key->type = REG_KEY_GENERIC; if (name[0] == '\0') { /* * Open a copy of the parent key */ if (!parent) { result = WERR_BADFILE; goto done; } key->name = talloc_strdup(key, parent->key->name); } else { /* * Normal subkey open */ key->name = talloc_asprintf(key, "%s%s%s", parent ? parent->key->name : "", parent ? "\\": "", name); } if (key->name == NULL) { result = WERR_NOMEM; goto done; } /* Tag this as a Performance Counter Key */ if( strncasecmp_m(key->name, KEY_HKPD, strlen(KEY_HKPD)) == 0 ) key->type = REG_KEY_HKPD; /* Look up the table of registry I/O operations */ key->ops = reghook_cache_find( key->name ); if (key->ops == NULL) { DEBUG(0,("reg_open_onelevel: Failed to assign " "registry_ops to [%s]\n", key->name )); result = WERR_BADFILE; goto done; } /* FIXME: Existence is currently checked by fetching the subkeys */ result = fill_subkey_cache(regkey); if (!W_ERROR_IS_OK(result)) { goto done; } if ( !regkey_access_check( key, access_desired, &key->access_granted, token ) ) { result = WERR_ACCESS_DENIED; goto done; } *pregkey = regkey; result = WERR_OK; done: if ( !W_ERROR_IS_OK(result) ) { TALLOC_FREE(regkey); } return result; } WERROR reg_openhive(TALLOC_CTX *mem_ctx, const char *hive, uint32_t desired_access, const struct security_token *token, struct registry_key **pkey) { const struct hive_info *hi; SMB_ASSERT(hive != NULL); SMB_ASSERT(strchr(hive, '\\') == NULL); hi = hive_info(hive); if (hi == NULL) { return WERR_BADFILE; } return regkey_open_onelevel(mem_ctx, NULL, hi->short_name, token, desired_access, pkey); } /********************************************************************** * The API functions **********************************************************************/ WERROR reg_openkey(TALLOC_CTX *mem_ctx, struct registry_key *parent, const char *name, uint32_t desired_access, struct registry_key **pkey) { struct registry_key *direct_parent = parent; WERROR err; char *p, *path; size_t len; TALLOC_CTX *frame = talloc_stackframe(); path = talloc_strdup(frame, name); if (path == NULL) { err = WERR_NOMEM; goto error; } len = strlen(path); if ((len > 0) && (path[len-1] == '\\')) { path[len-1] = '\0'; } while ((p = strchr(path, '\\')) != NULL) { char *name_component; struct registry_key *tmp; name_component = talloc_strndup(frame, path, (p - path)); if (name_component == NULL) { err = WERR_NOMEM; goto error; } err = regkey_open_onelevel(frame, direct_parent, name_component, parent->token, KEY_ENUMERATE_SUB_KEYS, &tmp); if (!W_ERROR_IS_OK(err)) { goto error; } direct_parent = tmp; path = p+1; } err = regkey_open_onelevel(mem_ctx, direct_parent, path, parent->token, desired_access, pkey); error: talloc_free(frame); return err; } WERROR reg_enumkey(TALLOC_CTX *mem_ctx, struct registry_key *key, uint32_t idx, char **name, NTTIME *last_write_time) { WERROR err; if (!(key->key->access_granted & KEY_ENUMERATE_SUB_KEYS)) { return WERR_ACCESS_DENIED; } err = fill_subkey_cache(key); if (!W_ERROR_IS_OK(err)) { return err; } if (idx >= regsubkey_ctr_numkeys(key->subkeys)) { return WERR_NO_MORE_ITEMS; } if (!(*name = talloc_strdup(mem_ctx, regsubkey_ctr_specific_key(key->subkeys, idx)))) { return WERR_NOMEM; } if (last_write_time) { *last_write_time = 0; } return WERR_OK; } WERROR reg_enumvalue(TALLOC_CTX *mem_ctx, struct registry_key *key, uint32_t idx, char **pname, struct registry_value **pval) { struct registry_value *val; struct regval_blob *blob; WERROR err; if (!(key->key->access_granted & KEY_QUERY_VALUE)) { return WERR_ACCESS_DENIED; } err = fill_value_cache(key); if (!(W_ERROR_IS_OK(err))) { return err; } if (idx >= regval_ctr_numvals(key->values)) { return WERR_NO_MORE_ITEMS; } blob = regval_ctr_specific_value(key->values, idx); val = talloc_zero(mem_ctx, struct registry_value); if (val == NULL) { return WERR_NOMEM; } val->type = regval_type(blob); val->data = data_blob_talloc(mem_ctx, regval_data_p(blob), regval_size(blob)); if (pname && !(*pname = talloc_strdup( mem_ctx, regval_name(blob)))) { TALLOC_FREE(val); return WERR_NOMEM; } *pval = val; return WERR_OK; } static WERROR reg_enumvalue_nocachefill(TALLOC_CTX *mem_ctx, struct registry_key *key, uint32_t idx, char **pname, struct registry_value **pval) { struct registry_value *val; struct regval_blob *blob; if (!(key->key->access_granted & KEY_QUERY_VALUE)) { return WERR_ACCESS_DENIED; } if (idx >= regval_ctr_numvals(key->values)) { return WERR_NO_MORE_ITEMS; } blob = regval_ctr_specific_value(key->values, idx); val = talloc_zero(mem_ctx, struct registry_value); if (val == NULL) { return WERR_NOMEM; } val->type = regval_type(blob); val->data = data_blob_talloc(mem_ctx, regval_data_p(blob), regval_size(blob)); if (pname && !(*pname = talloc_strdup( mem_ctx, regval_name(blob)))) { TALLOC_FREE(val); return WERR_NOMEM; } *pval = val; return WERR_OK; } WERROR reg_queryvalue(TALLOC_CTX *mem_ctx, struct registry_key *key, const char *name, struct registry_value **pval) { WERROR err; uint32_t i; if (!(key->key->access_granted & KEY_QUERY_VALUE)) { return WERR_ACCESS_DENIED; } if (!(W_ERROR_IS_OK(err = fill_value_cache(key)))) { return err; } for (i=0; i < regval_ctr_numvals(key->values); i++) { struct regval_blob *blob; blob = regval_ctr_specific_value(key->values, i); if (strequal(regval_name(blob), name)) { /* * don't use reg_enumvalue here: * re-reading the values from the disk * would change the indexing and break * this function. */ return reg_enumvalue_nocachefill(mem_ctx, key, i, NULL, pval); } } return WERR_BADFILE; } WERROR reg_querymultiplevalues(TALLOC_CTX *mem_ctx, struct registry_key *key, uint32_t num_names, const char **names, uint32_t *pnum_vals, struct registry_value **pvals) { WERROR err; uint32_t i, n, found = 0; struct registry_value *vals; if (num_names == 0) { return WERR_OK; } if (!(key->key->access_granted & KEY_QUERY_VALUE)) { return WERR_ACCESS_DENIED; } if (!(W_ERROR_IS_OK(err = fill_value_cache(key)))) { return err; } vals = talloc_zero_array(mem_ctx, struct registry_value, num_names); if (vals == NULL) { return WERR_NOMEM; } for (n=0; n < num_names; n++) { for (i=0; i < regval_ctr_numvals(key->values); i++) { struct regval_blob *blob; blob = regval_ctr_specific_value(key->values, i); if (strequal(regval_name(blob), names[n])) { struct registry_value *v; err = reg_enumvalue(mem_ctx, key, i, NULL, &v); if (!W_ERROR_IS_OK(err)) { return err; } vals[n] = *v; found++; } } } *pvals = vals; *pnum_vals = found; return WERR_OK; } WERROR reg_queryinfokey(struct registry_key *key, uint32_t *num_subkeys, uint32_t *max_subkeylen, uint32_t *max_subkeysize, uint32_t *num_values, uint32_t *max_valnamelen, uint32_t *max_valbufsize, uint32_t *secdescsize, NTTIME *last_changed_time) { uint32_t i, max_size; size_t max_len; TALLOC_CTX *mem_ctx; WERROR err; struct security_descriptor *secdesc; if (!(key->key->access_granted & KEY_QUERY_VALUE)) { return WERR_ACCESS_DENIED; } if (!W_ERROR_IS_OK(fill_subkey_cache(key)) || !W_ERROR_IS_OK(fill_value_cache(key))) { return WERR_BADFILE; } max_len = 0; for (i=0; i< regsubkey_ctr_numkeys(key->subkeys); i++) { max_len = MAX(max_len, strlen(regsubkey_ctr_specific_key(key->subkeys, i))); } *num_subkeys = regsubkey_ctr_numkeys(key->subkeys); *max_subkeylen = max_len; *max_subkeysize = 0; /* Class length? */ max_len = 0; max_size = 0; for (i=0; i < regval_ctr_numvals(key->values); i++) { struct regval_blob *blob; blob = regval_ctr_specific_value(key->values, i); max_len = MAX(max_len, strlen(regval_name(blob))); max_size = MAX(max_size, regval_size(blob)); } *num_values = regval_ctr_numvals(key->values); *max_valnamelen = max_len; *max_valbufsize = max_size; if (!(mem_ctx = talloc_new(key))) { return WERR_NOMEM; } err = regkey_get_secdesc(mem_ctx, key->key, &secdesc); if (!W_ERROR_IS_OK(err)) { TALLOC_FREE(mem_ctx); return err; } *secdescsize = ndr_size_security_descriptor(secdesc, 0); TALLOC_FREE(mem_ctx); *last_changed_time = 0; return WERR_OK; } WERROR reg_createkey(TALLOC_CTX *ctx, struct registry_key *parent, const char *subkeypath, uint32_t desired_access, struct registry_key **pkey, enum winreg_CreateAction *paction) { struct registry_key *key = parent; TALLOC_CTX *mem_ctx; char *path, *end; WERROR err; uint32_t access_granted; mem_ctx = talloc_new(ctx); if (mem_ctx == NULL) { return WERR_NOMEM; } path = talloc_strdup(mem_ctx, subkeypath); if (path == NULL) { err = WERR_NOMEM; goto done; } err = regdb_transaction_start(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_createkey: failed to start transaction: %s\n", win_errstr(err))); goto done; } while ((end = strchr(path, '\\')) != NULL) { struct registry_key *tmp; enum winreg_CreateAction action; *end = '\0'; err = reg_createkey(mem_ctx, key, path, KEY_ENUMERATE_SUB_KEYS, &tmp, &action); if (!W_ERROR_IS_OK(err)) { goto trans_done; } if (key != parent) { TALLOC_FREE(key); } key = tmp; path = end+1; } /* * At this point, "path" contains the one-element subkey of "key". We * can try to open it. */ err = reg_openkey(ctx, key, path, desired_access, pkey); if (W_ERROR_IS_OK(err)) { if (paction != NULL) { *paction = REG_OPENED_EXISTING_KEY; } goto trans_done; } if (!W_ERROR_EQUAL(err, WERR_BADFILE)) { /* * Something but "notfound" has happened, so bail out */ goto trans_done; } /* * We may (e.g. in the iteration) have opened the key with ENUM_SUBKEY. * Instead of re-opening the key with CREATE_SUB_KEY, we simply * duplicate the access check here and skip the expensive full open. */ if (!regkey_access_check(key->key, KEY_CREATE_SUB_KEY, &access_granted, key->token)) { err = WERR_ACCESS_DENIED; goto trans_done; } /* * Actually create the subkey */ err = create_reg_subkey(key->key, path); if (!W_ERROR_IS_OK(err)) { goto trans_done; } /* * Now open the newly created key */ err = reg_openkey(ctx, key, path, desired_access, pkey); if (W_ERROR_IS_OK(err) && (paction != NULL)) { *paction = REG_CREATED_NEW_KEY; } trans_done: if (W_ERROR_IS_OK(err)) { err = regdb_transaction_commit(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_createkey: Error committing transaction: %s\n", win_errstr(err))); } } else { WERROR err1 = regdb_transaction_cancel(); if (!W_ERROR_IS_OK(err1)) { DEBUG(0, ("reg_createkey: Error cancelling transaction: %s\n", win_errstr(err1))); } } done: TALLOC_FREE(mem_ctx); return err; } static WERROR reg_deletekey_internal(TALLOC_CTX *mem_ctx, struct registry_key *parent, const char *path, bool lazy) { WERROR err; char *name, *end; struct registry_key *key; name = talloc_strdup(mem_ctx, path); if (name == NULL) { err = WERR_NOMEM; goto done; } /* no subkeys - proceed with delete */ end = strrchr(name, '\\'); if (end != NULL) { *end = '\0'; err = reg_openkey(mem_ctx, parent, name, KEY_CREATE_SUB_KEY, &key); W_ERROR_NOT_OK_GOTO_DONE(err); parent = key; name = end+1; } if (name[0] == '\0') { err = WERR_INVALID_PARAM; goto done; } err = delete_reg_subkey(parent->key, name, lazy); done: return err; } WERROR reg_deletekey(struct registry_key *parent, const char *path) { WERROR err; struct registry_key *key; TALLOC_CTX *mem_ctx = talloc_stackframe(); /* check if the key has subkeys */ err = reg_openkey(mem_ctx, parent, path, REG_KEY_READ, &key); W_ERROR_NOT_OK_GOTO_DONE(err); err = regdb_transaction_start(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_deletekey: Error starting transaction: %s\n", win_errstr(err))); goto done; } err = fill_subkey_cache(key); if (!W_ERROR_IS_OK(err)) { goto trans_done; } if (regsubkey_ctr_numkeys(key->subkeys) > 0) { err = WERR_ACCESS_DENIED; goto trans_done; } err = reg_deletekey_internal(mem_ctx, parent, path, false); trans_done: if (W_ERROR_IS_OK(err)) { err = regdb_transaction_commit(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_deletekey: Error committing transaction: %s\n", win_errstr(err))); } } else { WERROR err1 = regdb_transaction_cancel(); if (!W_ERROR_IS_OK(err1)) { DEBUG(0, ("reg_deletekey: Error cancelling transaction: %s\n", win_errstr(err1))); } } done: TALLOC_FREE(mem_ctx); return err; } WERROR reg_setvalue(struct registry_key *key, const char *name, const struct registry_value *val) { struct regval_blob *existing; WERROR err; int res; if (!(key->key->access_granted & KEY_SET_VALUE)) { return WERR_ACCESS_DENIED; } err = regdb_transaction_start(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_setvalue: Failed to start transaction: %s\n", win_errstr(err))); return err; } err = fill_value_cache(key); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_setvalue: Error filling value cache: %s\n", win_errstr(err))); goto done; } existing = regval_ctr_getvalue(key->values, name); if ((existing != NULL) && (regval_size(existing) == val->data.length) && (memcmp(regval_data_p(existing), val->data.data, val->data.length) == 0)) { err = WERR_OK; goto done; } res = regval_ctr_addvalue(key->values, name, val->type, val->data.data, val->data.length); if (res == 0) { TALLOC_FREE(key->values); err = WERR_NOMEM; goto done; } if (!store_reg_values(key->key, key->values)) { TALLOC_FREE(key->values); DEBUG(0, ("reg_setvalue: store_reg_values failed\n")); err = WERR_REG_IO_FAILURE; goto done; } err = WERR_OK; done: if (W_ERROR_IS_OK(err)) { err = regdb_transaction_commit(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_setvalue: Error committing transaction: %s\n", win_errstr(err))); } } else { WERROR err1 = regdb_transaction_cancel(); if (!W_ERROR_IS_OK(err1)) { DEBUG(0, ("reg_setvalue: Error cancelling transaction: %s\n", win_errstr(err1))); } } return err; } static WERROR reg_value_exists(struct registry_key *key, const char *name) { struct regval_blob *blob; blob = regval_ctr_getvalue(key->values, name); if (blob == NULL) { return WERR_BADFILE; } else { return WERR_OK; } } WERROR reg_deletevalue(struct registry_key *key, const char *name) { WERROR err; if (!(key->key->access_granted & KEY_SET_VALUE)) { return WERR_ACCESS_DENIED; } err = regdb_transaction_start(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_deletevalue: Failed to start transaction: %s\n", win_errstr(err))); return err; } err = fill_value_cache(key); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_deletevalue; Error filling value cache: %s\n", win_errstr(err))); goto done; } err = reg_value_exists(key, name); if (!W_ERROR_IS_OK(err)) { goto done; } regval_ctr_delvalue(key->values, name); if (!store_reg_values(key->key, key->values)) { TALLOC_FREE(key->values); err = WERR_REG_IO_FAILURE; DEBUG(0, ("reg_deletevalue: store_reg_values failed\n")); goto done; } err = WERR_OK; done: if (W_ERROR_IS_OK(err)) { err = regdb_transaction_commit(); if (!W_ERROR_IS_OK(err)) { DEBUG(0, ("reg_deletevalue: Error committing transaction: %s\n", win_errstr(err))); } } else { WERROR err1 = regdb_transaction_cancel(); if (!W_ERROR_IS_OK(err1)) { DEBUG(0, ("reg_deletevalue: Error cancelling transaction: %s\n", win_errstr(err1))); } } return err; } WERROR reg_getkeysecurity(TALLOC_CTX *mem_ctx, struct registry_key *key, struct security_descriptor **psecdesc) { return regkey_get_secdesc(mem_ctx, key->key, psecdesc); } WERROR reg_setkeysecurity(struct registry_key *key, struct security_descriptor *psecdesc) { return regkey_set_secdesc(key->key, psecdesc); } WERROR reg_getversion(uint32_t *version) { if (version == NULL) { return WERR_INVALID_PARAM; } *version = 0x00000005; /* Windows 2000 registry API version */ return WERR_OK; } /********************************************************************** * Higher level utility functions **********************************************************************/ WERROR reg_deleteallvalues(struct registry_key *key) { WERROR err; int i; if (!(key->key->access_granted & KEY_SET_VALUE)) { return WERR_ACCESS_DENIED; } if (!W_ERROR_IS_OK(err = fill_value_cache(key))) { return err; } for (i=0; i < regval_ctr_numvals(key->values); i++) { struct regval_blob *blob; blob = regval_ctr_specific_value(key->values, i); regval_ctr_delvalue(key->values, regval_name(blob)); } if (!store_reg_values(key->key, key->values)) { TALLOC_FREE(key->values); return WERR_REG_IO_FAILURE; } return WERR_OK; } /* * Utility function to delete a registry key with all its subkeys. * Note that reg_deletekey returns ACCESS_DENIED when called on a * key that has subkeys. */ static WERROR reg_deletekey_recursive_internal(struct registry_key *parent, const char *path, bool del_key, bool lazy) { WERROR werr = WERR_OK; struct registry_key *key; char *subkey_name = NULL; uint32_t i; TALLOC_CTX *mem_ctx = talloc_stackframe(); DEBUG(5, ("reg_deletekey_recursive_internal: deleting '%s' from '%s'\n", path, parent->key->name)); /* recurse through subkeys first */ werr = reg_openkey(mem_ctx, parent, path, REG_KEY_ALL, &key); if (!W_ERROR_IS_OK(werr)) { DEBUG(3, ("reg_deletekey_recursive_internal: error opening " "subkey '%s' of '%s': '%s'\n", path, parent->key->name, win_errstr(werr))); goto done; } werr = fill_subkey_cache(key); W_ERROR_NOT_OK_GOTO_DONE(werr); /* * loop from top to bottom for perfomance: * this way, we need to rehash the regsubkey containers less */ for (i = regsubkey_ctr_numkeys(key->subkeys) ; i > 0; i--) { subkey_name = regsubkey_ctr_specific_key(key->subkeys, i-1); werr = reg_deletekey_recursive_internal(key, subkey_name, true, del_key); W_ERROR_NOT_OK_GOTO_DONE(werr); } if (del_key) { /* now delete the actual key */ werr = reg_deletekey_internal(mem_ctx, parent, path, lazy); } done: DEBUG(5, ("reg_deletekey_recursive_internal: done deleting '%s' from " "'%s': %s\n", path, parent->key->name, win_errstr(werr))); TALLOC_FREE(mem_ctx); return werr; } static WERROR reg_deletekey_recursive_trans(struct registry_key *parent, const char *path, bool del_key) { WERROR werr; werr = regdb_transaction_start(); if (!W_ERROR_IS_OK(werr)) { DEBUG(0, ("reg_deletekey_recursive_trans: " "error starting transaction: %s\n", win_errstr(werr))); return werr; } werr = reg_deletekey_recursive_internal(parent, path, del_key, false); if (!W_ERROR_IS_OK(werr)) { WERROR werr2; DEBUG(W_ERROR_EQUAL(werr, WERR_BADFILE) ? 5 : 1, (__location__ ": failed to delete key '%s' from key " "'%s': %s\n", path, parent->key->name, win_errstr(werr))); werr2 = regdb_transaction_cancel(); if (!W_ERROR_IS_OK(werr2)) { DEBUG(0, ("reg_deletekey_recursive_trans: " "error cancelling transaction: %s\n", win_errstr(werr2))); /* * return the original werr or the * error from cancelling the transaction? */ } } else { werr = regdb_transaction_commit(); if (!W_ERROR_IS_OK(werr)) { DEBUG(0, ("reg_deletekey_recursive_trans: " "error committing transaction: %s\n", win_errstr(werr))); } else { DEBUG(5, ("reg_deletekey_recursive_trans: deleted key '%s' from '%s'\n", path, parent->key->name)); } } return werr; } WERROR reg_deletekey_recursive(struct registry_key *parent, const char *path) { return reg_deletekey_recursive_trans(parent, path, true); } WERROR reg_deletesubkeys_recursive(struct registry_key *parent, const char *path) { return reg_deletekey_recursive_trans(parent, path, false); }