/* Unix SMB/CIFS implementation. test suite for winreg rpc operations Copyright (C) Tim Potter 2003 Copyright (C) Jelmer Vernooij 2004-2007 Copyright (C) Günther Deschner 2007 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "includes.h" #include "torture/torture.h" #include "librpc/gen_ndr/ndr_winreg_c.h" #include "librpc/gen_ndr/ndr_security.h" #include "libcli/security/security.h" #include "torture/rpc/rpc.h" #define TEST_KEY_BASE "smbtorture test" #define TEST_KEY1 TEST_KEY_BASE "\\spottyfoot" #define TEST_KEY2 TEST_KEY_BASE "\\with a SD (#1)" #define TEST_KEY3 TEST_KEY_BASE "\\with a subkey" #define TEST_KEY4 TEST_KEY_BASE "\\sd_tests" #define TEST_SUBKEY TEST_KEY3 "\\subkey" #define TEST_SUBKEY_SD TEST_KEY4 "\\subkey_sd" #define TEST_SUBSUBKEY_SD TEST_KEY4 "\\subkey_sd\\subsubkey_sd" #define TEST_SID "S-1-5-21-1234567890-1234567890-1234567890-500" static void init_initshutdown_String(TALLOC_CTX *mem_ctx, struct initshutdown_String *name, const char *s) { name->name = talloc(mem_ctx, struct initshutdown_String_sub); name->name->name = s; } static void init_winreg_String(struct winreg_String *name, const char *s) { name->name = s; if (s) { name->name_len = 2 * (strlen_m(s) + 1); name->name_size = name->name_len; } else { name->name_len = 0; name->name_size = 0; } } static bool test_GetVersion(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle) { struct winreg_GetVersion r; uint32_t v; ZERO_STRUCT(r); r.in.handle = handle; r.out.version = &v; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_GetVersion(p, tctx, &r), "GetVersion failed"); torture_assert_werr_ok(tctx, r.out.result, "GetVersion failed"); return true; } static bool test_NotifyChangeKeyValue(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle) { struct winreg_NotifyChangeKeyValue r; r.in.handle = handle; r.in.watch_subtree = true; r.in.notify_filter = 0; r.in.unknown = r.in.unknown2 = 0; init_winreg_String(&r.in.string1, NULL); init_winreg_String(&r.in.string2, NULL); torture_assert_ntstatus_ok(tctx, dcerpc_winreg_NotifyChangeKeyValue(p, tctx, &r), "NotifyChangeKeyValue failed"); if (!W_ERROR_IS_OK(r.out.result)) { torture_comment(tctx, "NotifyChangeKeyValue failed - %s - not considering\n", win_errstr(r.out.result)); return true; } return true; } static bool test_CreateKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *name, const char *class) { struct winreg_CreateKey r; struct policy_handle newhandle; enum winreg_CreateAction action_taken = 0; r.in.handle = handle; r.out.new_handle = &newhandle; init_winreg_String(&r.in.name, name); init_winreg_String(&r.in.keyclass, class); r.in.options = 0x0; r.in.access_mask = SEC_FLAG_MAXIMUM_ALLOWED; r.in.action_taken = r.out.action_taken = &action_taken; r.in.secdesc = NULL; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_CreateKey(p, tctx, &r), "CreateKey failed"); torture_assert_werr_ok(tctx, r.out.result, "CreateKey failed"); return true; } /* createkey testing with a SD */ static bool test_CreateKey_sd(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *name, const char *class, struct policy_handle *newhandle) { struct winreg_CreateKey r; enum winreg_CreateAction action_taken = 0; struct security_descriptor *sd; DATA_BLOB sdblob; struct winreg_SecBuf secbuf; sd = security_descriptor_dacl_create(tctx, 0, NULL, NULL, SID_NT_AUTHENTICATED_USERS, SEC_ACE_TYPE_ACCESS_ALLOWED, SEC_GENERIC_ALL, SEC_ACE_FLAG_OBJECT_INHERIT | SEC_ACE_FLAG_CONTAINER_INHERIT, NULL); torture_assert_ndr_success(tctx, ndr_push_struct_blob(&sdblob, tctx, NULL, sd, (ndr_push_flags_fn_t)ndr_push_security_descriptor), "Failed to push security_descriptor ?!\n"); secbuf.sd.data = sdblob.data; secbuf.sd.len = sdblob.length; secbuf.sd.size = sdblob.length; secbuf.length = sdblob.length-10; secbuf.inherit = 0; r.in.handle = handle; r.out.new_handle = newhandle; init_winreg_String(&r.in.name, name); init_winreg_String(&r.in.keyclass, class); r.in.options = 0x0; r.in.access_mask = SEC_FLAG_MAXIMUM_ALLOWED; r.in.action_taken = r.out.action_taken = &action_taken; r.in.secdesc = &secbuf; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_CreateKey(p, tctx, &r), "CreateKey with sd failed"); torture_assert_werr_ok(tctx, r.out.result, "CreateKey with sd failed"); return true; } static bool _test_GetKeySecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, uint32_t *sec_info_ptr, WERROR get_werr, struct security_descriptor **sd_out) { struct winreg_GetKeySecurity r; struct security_descriptor *sd = NULL; uint32_t sec_info; DATA_BLOB sdblob; if (sec_info_ptr) { sec_info = *sec_info_ptr; } else { sec_info = SECINFO_OWNER | SECINFO_GROUP | SECINFO_DACL; } ZERO_STRUCT(r); r.in.handle = handle; r.in.sec_info = sec_info; r.in.sd = r.out.sd = talloc_zero(tctx, struct KeySecurityData); r.in.sd->size = 0x1000; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_GetKeySecurity(p, tctx, &r), "GetKeySecurity failed"); torture_assert_werr_equal(tctx, r.out.result, get_werr, "GetKeySecurity failed"); sdblob.data = r.out.sd->data; sdblob.length = r.out.sd->len; sd = talloc_zero(tctx, struct security_descriptor); torture_assert_ndr_success(tctx, ndr_pull_struct_blob(&sdblob, tctx, sd, (ndr_pull_flags_fn_t)ndr_pull_security_descriptor), "pull_security_descriptor failed"); if (p->conn->flags & DCERPC_DEBUG_PRINT_OUT) { NDR_PRINT_DEBUG(security_descriptor, sd); } if (sd_out) { *sd_out = sd; } else { talloc_free(sd); } return true; } static bool test_GetKeySecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, struct security_descriptor **sd_out) { return _test_GetKeySecurity(p, tctx, handle, NULL, WERR_OK, sd_out); } static bool _test_SetKeySecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, uint32_t *sec_info_ptr, struct security_descriptor *sd, WERROR werr) { struct winreg_SetKeySecurity r; struct KeySecurityData *sdata = NULL; DATA_BLOB sdblob; uint32_t sec_info; ZERO_STRUCT(r); if (sd && (p->conn->flags & DCERPC_DEBUG_PRINT_OUT)) { NDR_PRINT_DEBUG(security_descriptor, sd); } torture_assert_ndr_success(tctx, ndr_push_struct_blob(&sdblob, tctx, NULL, sd, (ndr_push_flags_fn_t)ndr_push_security_descriptor), "push_security_descriptor failed"); sdata = talloc_zero(tctx, struct KeySecurityData); sdata->data = sdblob.data; sdata->size = sdblob.length; sdata->len = sdblob.length; if (sec_info_ptr) { sec_info = *sec_info_ptr; } else { sec_info = SECINFO_UNPROTECTED_SACL | SECINFO_UNPROTECTED_DACL; if (sd->owner_sid) { sec_info |= SECINFO_OWNER; } if (sd->group_sid) { sec_info |= SECINFO_GROUP; } if (sd->sacl) { sec_info |= SECINFO_SACL; } if (sd->dacl) { sec_info |= SECINFO_DACL; } } r.in.handle = handle; r.in.sec_info = sec_info; r.in.sd = sdata; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_SetKeySecurity(p, tctx, &r), "SetKeySecurity failed"); torture_assert_werr_equal(tctx, r.out.result, werr, "SetKeySecurity failed"); return true; } static bool test_SetKeySecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, struct security_descriptor *sd) { return _test_SetKeySecurity(p, tctx, handle, NULL, sd, WERR_OK); } static bool test_CloseKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle) { struct winreg_CloseKey r; r.in.handle = r.out.handle = handle; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_CloseKey(p, tctx, &r), "CloseKey failed"); torture_assert_werr_ok(tctx, r.out.result, "CloseKey failed"); return true; } static bool test_FlushKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle) { struct winreg_FlushKey r; r.in.handle = handle; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_FlushKey(p, tctx, &r), "FlushKey failed"); torture_assert_werr_ok(tctx, r.out.result, "FlushKey failed"); return true; } static bool _test_OpenKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *hive_handle, const char *keyname, uint32_t access_mask, struct policy_handle *key_handle, WERROR open_werr, bool *success) { struct winreg_OpenKey r; r.in.parent_handle = hive_handle; init_winreg_String(&r.in.keyname, keyname); r.in.unknown = 0x00000000; r.in.access_mask = access_mask; r.out.handle = key_handle; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_OpenKey(p, tctx, &r), "OpenKey failed"); torture_assert_werr_equal(tctx, r.out.result, open_werr, "OpenKey failed"); if (success && W_ERROR_EQUAL(r.out.result, WERR_OK)) { *success = true; } return true; } static bool test_OpenKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *hive_handle, const char *keyname, struct policy_handle *key_handle) { return _test_OpenKey(p, tctx, hive_handle, keyname, SEC_FLAG_MAXIMUM_ALLOWED, key_handle, WERR_OK, NULL); } static bool test_Cleanup(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { struct winreg_DeleteKey r; r.in.handle = handle; init_winreg_String(&r.in.key, key); dcerpc_winreg_DeleteKey(p, tctx, &r); return true; } static bool _test_GetSetSecurityDescriptor(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, WERROR get_werr, WERROR set_werr) { struct security_descriptor *sd = NULL; if (!_test_GetKeySecurity(p, tctx, handle, NULL, get_werr, &sd)) { return false; } if (!_test_SetKeySecurity(p, tctx, handle, NULL, sd, set_werr)) { return false; } return true; } static bool test_SecurityDescriptor(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { struct policy_handle new_handle; bool ret = true; torture_comment(tctx, "SecurityDescriptor get & set\n"); if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } if (!_test_GetSetSecurityDescriptor(p, tctx, &new_handle, WERR_OK, WERR_OK)) { ret = false; } if (!test_CloseKey(p, tctx, &new_handle)) { return false; } return ret; } static bool _test_SecurityDescriptor(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, uint32_t access_mask, const char *key, WERROR open_werr, WERROR get_werr, WERROR set_werr) { struct policy_handle new_handle; bool ret = true; bool got_key = false; if (!_test_OpenKey(p, tctx, handle, key, access_mask, &new_handle, open_werr, &got_key)) { return false; } if (!got_key) { return true; } if (!_test_GetSetSecurityDescriptor(p, tctx, &new_handle, get_werr, set_werr)) { ret = false; } if (!test_CloseKey(p, tctx, &new_handle)) { return false; } return ret; } static bool test_dacl_trustee_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct dom_sid *sid) { struct security_descriptor *sd = NULL; int i; if (!test_GetKeySecurity(p, tctx, handle, &sd)) { return false; } if (!sd || !sd->dacl) { return false; } for (i = 0; i < sd->dacl->num_aces; i++) { if (dom_sid_equal(&sd->dacl->aces[i].trustee, sid)) { return true; } } return false; } static bool _test_dacl_trustee_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, const struct dom_sid *sid) { struct policy_handle new_handle; bool ret = true; if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } ret = test_dacl_trustee_present(p, tctx, &new_handle, sid); test_CloseKey(p, tctx, &new_handle); return ret; } static bool test_sacl_trustee_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct dom_sid *sid) { struct security_descriptor *sd = NULL; int i; uint32_t sec_info = SECINFO_SACL; if (!_test_GetKeySecurity(p, tctx, handle, &sec_info, WERR_OK, &sd)) { return false; } if (!sd || !sd->sacl) { return false; } for (i = 0; i < sd->sacl->num_aces; i++) { if (dom_sid_equal(&sd->sacl->aces[i].trustee, sid)) { return true; } } return false; } static bool _test_sacl_trustee_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, const struct dom_sid *sid) { struct policy_handle new_handle; bool ret = true; if (!_test_OpenKey(p, tctx, handle, key, SEC_FLAG_SYSTEM_SECURITY, &new_handle, WERR_OK, NULL)) { return false; } ret = test_sacl_trustee_present(p, tctx, &new_handle, sid); test_CloseKey(p, tctx, &new_handle); return ret; } static bool test_owner_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct dom_sid *sid) { struct security_descriptor *sd = NULL; uint32_t sec_info = SECINFO_OWNER; if (!_test_GetKeySecurity(p, tctx, handle, &sec_info, WERR_OK, &sd)) { return false; } if (!sd || !sd->owner_sid) { return false; } return dom_sid_equal(sd->owner_sid, sid); } static bool _test_owner_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, const struct dom_sid *sid) { struct policy_handle new_handle; bool ret = true; if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } ret = test_owner_present(p, tctx, &new_handle, sid); test_CloseKey(p, tctx, &new_handle); return ret; } static bool test_group_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct dom_sid *sid) { struct security_descriptor *sd = NULL; uint32_t sec_info = SECINFO_GROUP; if (!_test_GetKeySecurity(p, tctx, handle, &sec_info, WERR_OK, &sd)) { return false; } if (!sd || !sd->group_sid) { return false; } return dom_sid_equal(sd->group_sid, sid); } static bool _test_group_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, const struct dom_sid *sid) { struct policy_handle new_handle; bool ret = true; if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } ret = test_group_present(p, tctx, &new_handle, sid); test_CloseKey(p, tctx, &new_handle); return ret; } static bool test_dacl_trustee_flags_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct dom_sid *sid, uint8_t flags) { struct security_descriptor *sd = NULL; int i; if (!test_GetKeySecurity(p, tctx, handle, &sd)) { return false; } if (!sd || !sd->dacl) { return false; } for (i = 0; i < sd->dacl->num_aces; i++) { if ((dom_sid_equal(&sd->dacl->aces[i].trustee, sid)) && (sd->dacl->aces[i].flags == flags)) { return true; } } return false; } static bool test_dacl_ace_present(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const struct security_ace *ace) { struct security_descriptor *sd = NULL; int i; if (!test_GetKeySecurity(p, tctx, handle, &sd)) { return false; } if (!sd || !sd->dacl) { return false; } for (i = 0; i < sd->dacl->num_aces; i++) { if (security_ace_equal(&sd->dacl->aces[i], ace)) { return true; } } return false; } static bool test_RestoreSecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, struct security_descriptor *sd) { struct policy_handle new_handle; bool ret = true; if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } if (!test_SetKeySecurity(p, tctx, &new_handle, sd)) { ret = false; } if (!test_CloseKey(p, tctx, &new_handle)) { ret = false; } return ret; } static bool test_BackupSecurity(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, struct security_descriptor **sd) { struct policy_handle new_handle; bool ret = true; if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } if (!test_GetKeySecurity(p, tctx, &new_handle, sd)) { ret = false; } if (!test_CloseKey(p, tctx, &new_handle)) { ret = false; } return ret; } static bool test_SecurityDescriptorInheritance(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { /* get sd add ace SEC_ACE_FLAG_CONTAINER_INHERIT set sd get sd check ace add subkey get sd check ace add subsubkey get sd check ace del subsubkey del subkey reset sd */ struct security_descriptor *sd = NULL; struct security_descriptor *sd_orig = NULL; struct security_ace *ace = NULL; struct policy_handle new_handle; NTSTATUS status; bool ret = true; torture_comment(tctx, "SecurityDescriptor inheritance\n"); if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } if (!_test_GetKeySecurity(p, tctx, &new_handle, NULL, WERR_OK, &sd)) { return false; } sd_orig = security_descriptor_copy(tctx, sd); if (sd_orig == NULL) { return false; } ace = security_ace_create(tctx, TEST_SID, SEC_ACE_TYPE_ACCESS_ALLOWED, SEC_STD_REQUIRED, SEC_ACE_FLAG_CONTAINER_INHERIT); status = security_descriptor_dacl_add(sd, ace); if (!NT_STATUS_IS_OK(status)) { printf("failed to add ace: %s\n", nt_errstr(status)); return false; } /* FIXME: add further tests for these flags */ sd->type |= SEC_DESC_DACL_AUTO_INHERIT_REQ | SEC_DESC_SACL_AUTO_INHERITED; if (!test_SetKeySecurity(p, tctx, &new_handle, sd)) { return false; } if (!test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("new ACE not present!\n"); return false; } if (!test_CloseKey(p, tctx, &new_handle)) { return false; } if (!test_CreateKey(p, tctx, handle, TEST_SUBKEY_SD, NULL)) { ret = false; goto out; } if (!test_OpenKey(p, tctx, handle, TEST_SUBKEY_SD, &new_handle)) { ret = false; goto out; } if (!test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("inherited ACE not present!\n"); ret = false; goto out; } test_CloseKey(p, tctx, &new_handle); if (!test_CreateKey(p, tctx, handle, TEST_SUBSUBKEY_SD, NULL)) { ret = false; goto out; } if (!test_OpenKey(p, tctx, handle, TEST_SUBSUBKEY_SD, &new_handle)) { ret = false; goto out; } if (!test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("inherited ACE not present!\n"); ret = false; goto out; } out: test_CloseKey(p, tctx, &new_handle); test_Cleanup(p, tctx, handle, TEST_SUBSUBKEY_SD); test_Cleanup(p, tctx, handle, TEST_SUBKEY_SD); test_RestoreSecurity(p, tctx, handle, key, sd_orig); return true; } static bool test_SecurityDescriptorBlockInheritance(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { /* get sd add ace SEC_ACE_FLAG_NO_PROPAGATE_INHERIT set sd add subkey/subkey get sd check ace get sd from subkey check ace del subkey/subkey del subkey reset sd */ struct security_descriptor *sd = NULL; struct security_descriptor *sd_orig = NULL; struct security_ace *ace = NULL; struct policy_handle new_handle; struct dom_sid *sid = NULL; NTSTATUS status; bool ret = true; uint8_t ace_flags = 0x0; torture_comment(tctx, "SecurityDescriptor inheritance block\n"); if (!test_OpenKey(p, tctx, handle, key, &new_handle)) { return false; } if (!_test_GetKeySecurity(p, tctx, &new_handle, NULL, WERR_OK, &sd)) { return false; } sd_orig = security_descriptor_copy(tctx, sd); if (sd_orig == NULL) { return false; } ace = security_ace_create(tctx, TEST_SID, SEC_ACE_TYPE_ACCESS_ALLOWED, SEC_STD_REQUIRED, SEC_ACE_FLAG_CONTAINER_INHERIT | SEC_ACE_FLAG_NO_PROPAGATE_INHERIT); status = security_descriptor_dacl_add(sd, ace); if (!NT_STATUS_IS_OK(status)) { printf("failed to add ace: %s\n", nt_errstr(status)); return false; } if (!_test_SetKeySecurity(p, tctx, &new_handle, NULL, sd, WERR_OK)) { return false; } if (!test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("new ACE not present!\n"); return false; } if (!test_CloseKey(p, tctx, &new_handle)) { return false; } if (!test_CreateKey(p, tctx, handle, TEST_SUBSUBKEY_SD, NULL)) { return false; } if (!test_OpenKey(p, tctx, handle, TEST_SUBSUBKEY_SD, &new_handle)) { ret = false; goto out; } if (test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("inherited ACE present but should not!\n"); ret = false; goto out; } sid = dom_sid_parse_talloc(tctx, TEST_SID); if (sid == NULL) { return false; } if (test_dacl_trustee_present(p, tctx, &new_handle, sid)) { printf("inherited trustee SID present but should not!\n"); ret = false; goto out; } test_CloseKey(p, tctx, &new_handle); if (!test_OpenKey(p, tctx, handle, TEST_SUBKEY_SD, &new_handle)) { ret = false; goto out; } if (test_dacl_ace_present(p, tctx, &new_handle, ace)) { printf("inherited ACE present but should not!\n"); ret = false; goto out; } if (!test_dacl_trustee_flags_present(p, tctx, &new_handle, sid, ace_flags)) { printf("inherited trustee SID with flags 0x%02x not present!\n", ace_flags); ret = false; goto out; } out: test_CloseKey(p, tctx, &new_handle); test_Cleanup(p, tctx, handle, TEST_SUBSUBKEY_SD); test_Cleanup(p, tctx, handle, TEST_SUBKEY_SD); test_RestoreSecurity(p, tctx, handle, key, sd_orig); return ret; } static bool test_SecurityDescriptorsMasks(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { bool ret = true; int i; struct winreg_mask_result_table { uint32_t access_mask; WERROR open_werr; WERROR get_werr; WERROR set_werr; } sd_mask_tests[] = { { 0, WERR_ACCESS_DENIED, WERR_BADFILE, WERR_FOOBAR }, { SEC_FLAG_MAXIMUM_ALLOWED, WERR_OK, WERR_OK, WERR_OK }, { SEC_STD_WRITE_DAC, WERR_OK, WERR_ACCESS_DENIED, WERR_FOOBAR }, { SEC_FLAG_SYSTEM_SECURITY, WERR_OK, WERR_ACCESS_DENIED, WERR_FOOBAR } }; /* FIXME: before this test can ever run successfully we need a way to * correctly read a NULL security_descritpor in ndr, get the required * length, requery, etc. */ return true; for (i=0; i < ARRAY_SIZE(sd_mask_tests); i++) { torture_comment(tctx, "SecurityDescriptor get & set with access_mask: 0x%08x\n", sd_mask_tests[i].access_mask); torture_comment(tctx, "expecting: open %s, get: %s, set: %s\n", win_errstr(sd_mask_tests[i].open_werr), win_errstr(sd_mask_tests[i].get_werr), win_errstr(sd_mask_tests[i].set_werr)); if (_test_SecurityDescriptor(p, tctx, handle, sd_mask_tests[i].access_mask, key, sd_mask_tests[i].open_werr, sd_mask_tests[i].get_werr, sd_mask_tests[i].set_werr)) { ret = false; } } return ret; } typedef bool (*secinfo_verify_fn)(struct dcerpc_pipe *, struct torture_context *, struct policy_handle *, const char *, const struct dom_sid *); static bool test_SetSecurityDescriptor_SecInfo(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key, const char *test, uint32_t access_mask, uint32_t sec_info, struct security_descriptor *sd, WERROR set_werr, bool expect_present, bool (*fn) (struct dcerpc_pipe *, struct torture_context *, struct policy_handle *, const char *, const struct dom_sid *), const struct dom_sid *sid) { struct policy_handle new_handle; bool open_success = false; torture_comment(tctx, "SecurityDescriptor (%s) sets for secinfo: " "0x%08x, access_mask: 0x%08x\n", test, sec_info, access_mask); if (!_test_OpenKey(p, tctx, handle, key, access_mask, &new_handle, WERR_OK, &open_success)) { return false; } if (!open_success) { printf("key did not open\n"); test_CloseKey(p, tctx, &new_handle); return false; } if (!_test_SetKeySecurity(p, tctx, &new_handle, &sec_info, sd, set_werr)) { torture_warning(tctx, "SetKeySecurity with secinfo: 0x%08x has failed\n", sec_info); smb_panic(""); test_CloseKey(p, tctx, &new_handle); return false; } test_CloseKey(p, tctx, &new_handle); if (W_ERROR_IS_OK(set_werr)) { bool present; present = fn(p, tctx, handle, key, sid); if ((expect_present) && (!present)) { torture_warning(tctx, "%s sid is not present!\n", test); return false; } if ((!expect_present) && (present)) { torture_warning(tctx, "%s sid is present but not expected!\n", test); return false; } } return true; } static bool test_SecurityDescriptorsSecInfo(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { struct security_descriptor *sd_orig = NULL; struct dom_sid *sid = NULL; bool ret = true; int i, a; struct security_descriptor *sd_owner = security_descriptor_dacl_create(tctx, 0, TEST_SID, NULL, NULL); struct security_descriptor *sd_group = security_descriptor_dacl_create(tctx, 0, NULL, TEST_SID, NULL); struct security_descriptor *sd_dacl = security_descriptor_dacl_create(tctx, 0, NULL, NULL, TEST_SID, SEC_ACE_TYPE_ACCESS_ALLOWED, SEC_GENERIC_ALL, 0, SID_NT_AUTHENTICATED_USERS, SEC_ACE_TYPE_ACCESS_ALLOWED, SEC_GENERIC_ALL, 0, NULL); struct security_descriptor *sd_sacl = security_descriptor_sacl_create(tctx, 0, NULL, NULL, TEST_SID, SEC_ACE_TYPE_SYSTEM_AUDIT, SEC_GENERIC_ALL, SEC_ACE_FLAG_SUCCESSFUL_ACCESS, NULL); struct winreg_secinfo_table { struct security_descriptor *sd; uint32_t sec_info; WERROR set_werr; bool sid_present; secinfo_verify_fn fn; }; struct winreg_secinfo_table sec_info_owner_tests[] = { { sd_owner, 0, WERR_OK, false, (secinfo_verify_fn)_test_owner_present }, { sd_owner, SECINFO_OWNER, WERR_OK, true, (secinfo_verify_fn)_test_owner_present }, { sd_owner, SECINFO_GROUP, WERR_INVALID_PARAM }, { sd_owner, SECINFO_DACL, WERR_OK, true, (secinfo_verify_fn)_test_owner_present }, { sd_owner, SECINFO_SACL, WERR_ACCESS_DENIED }, }; uint32_t sd_owner_good_access_masks[] = { SEC_FLAG_MAXIMUM_ALLOWED, /* SEC_STD_WRITE_OWNER, */ }; struct winreg_secinfo_table sec_info_group_tests[] = { { sd_group, 0, WERR_OK, false, (secinfo_verify_fn)_test_group_present }, { sd_group, SECINFO_OWNER, WERR_INVALID_PARAM }, { sd_group, SECINFO_GROUP, WERR_OK, true, (secinfo_verify_fn)_test_group_present }, { sd_group, SECINFO_DACL, WERR_OK, true, (secinfo_verify_fn)_test_group_present }, { sd_group, SECINFO_SACL, WERR_ACCESS_DENIED }, }; uint32_t sd_group_good_access_masks[] = { SEC_FLAG_MAXIMUM_ALLOWED, }; struct winreg_secinfo_table sec_info_dacl_tests[] = { { sd_dacl, 0, WERR_OK, false, (secinfo_verify_fn)_test_dacl_trustee_present }, { sd_dacl, SECINFO_OWNER, WERR_INVALID_PARAM }, { sd_dacl, SECINFO_GROUP, WERR_INVALID_PARAM }, { sd_dacl, SECINFO_DACL, WERR_OK, true, (secinfo_verify_fn)_test_dacl_trustee_present }, { sd_dacl, SECINFO_SACL, WERR_ACCESS_DENIED }, }; uint32_t sd_dacl_good_access_masks[] = { SEC_FLAG_MAXIMUM_ALLOWED, SEC_STD_WRITE_DAC, }; struct winreg_secinfo_table sec_info_sacl_tests[] = { { sd_sacl, 0, WERR_OK, false, (secinfo_verify_fn)_test_sacl_trustee_present }, { sd_sacl, SECINFO_OWNER, WERR_INVALID_PARAM }, { sd_sacl, SECINFO_GROUP, WERR_INVALID_PARAM }, { sd_sacl, SECINFO_DACL, WERR_OK, false, (secinfo_verify_fn)_test_sacl_trustee_present }, { sd_sacl, SECINFO_SACL, WERR_OK, true, (secinfo_verify_fn)_test_sacl_trustee_present }, }; uint32_t sd_sacl_good_access_masks[] = { SEC_FLAG_MAXIMUM_ALLOWED | SEC_FLAG_SYSTEM_SECURITY, /* SEC_FLAG_SYSTEM_SECURITY, */ }; sid = dom_sid_parse_talloc(tctx, TEST_SID); if (sid == NULL) { return false; } if (!test_BackupSecurity(p, tctx, handle, key, &sd_orig)) { return false; } /* OWNER */ for (i=0; i < ARRAY_SIZE(sec_info_owner_tests); i++) { for (a=0; a < ARRAY_SIZE(sd_owner_good_access_masks); a++) { if (!test_SetSecurityDescriptor_SecInfo(p, tctx, handle, key, "OWNER", sd_owner_good_access_masks[a], sec_info_owner_tests[i].sec_info, sec_info_owner_tests[i].sd, sec_info_owner_tests[i].set_werr, sec_info_owner_tests[i].sid_present, sec_info_owner_tests[i].fn, sid)) { printf("test_SetSecurityDescriptor_SecInfo failed for OWNER\n"); ret = false; goto out; } } } /* GROUP */ for (i=0; i < ARRAY_SIZE(sec_info_group_tests); i++) { for (a=0; a < ARRAY_SIZE(sd_group_good_access_masks); a++) { if (!test_SetSecurityDescriptor_SecInfo(p, tctx, handle, key, "GROUP", sd_group_good_access_masks[a], sec_info_group_tests[i].sec_info, sec_info_group_tests[i].sd, sec_info_group_tests[i].set_werr, sec_info_group_tests[i].sid_present, sec_info_group_tests[i].fn, sid)) { printf("test_SetSecurityDescriptor_SecInfo failed for GROUP\n"); ret = false; goto out; } } } /* DACL */ for (i=0; i < ARRAY_SIZE(sec_info_dacl_tests); i++) { for (a=0; a < ARRAY_SIZE(sd_dacl_good_access_masks); a++) { if (!test_SetSecurityDescriptor_SecInfo(p, tctx, handle, key, "DACL", sd_dacl_good_access_masks[a], sec_info_dacl_tests[i].sec_info, sec_info_dacl_tests[i].sd, sec_info_dacl_tests[i].set_werr, sec_info_dacl_tests[i].sid_present, sec_info_dacl_tests[i].fn, sid)) { printf("test_SetSecurityDescriptor_SecInfo failed for DACL\n"); ret = false; goto out; } } } /* SACL */ for (i=0; i < ARRAY_SIZE(sec_info_sacl_tests); i++) { for (a=0; a < ARRAY_SIZE(sd_sacl_good_access_masks); a++) { if (!test_SetSecurityDescriptor_SecInfo(p, tctx, handle, key, "SACL", sd_sacl_good_access_masks[a], sec_info_sacl_tests[i].sec_info, sec_info_sacl_tests[i].sd, sec_info_sacl_tests[i].set_werr, sec_info_sacl_tests[i].sid_present, sec_info_sacl_tests[i].fn, sid)) { printf("test_SetSecurityDescriptor_SecInfo failed for SACL\n"); ret = false; goto out; } } } out: test_RestoreSecurity(p, tctx, handle, key, sd_orig); return ret; } static bool test_SecurityDescriptors(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { bool ret = true; if (!test_SecurityDescriptor(p, tctx, handle, key)) { printf("test_SecurityDescriptor failed\n"); ret = false; } if (!test_SecurityDescriptorInheritance(p, tctx, handle, key)) { printf("test_SecurityDescriptorInheritance failed\n"); ret = false; } if (!test_SecurityDescriptorBlockInheritance(p, tctx, handle, key)) { printf("test_SecurityDescriptorBlockInheritance failed\n"); ret = false; } if (!test_SecurityDescriptorsSecInfo(p, tctx, handle, key)) { printf("test_SecurityDescriptorsSecInfo failed\n"); ret = false; } if (!test_SecurityDescriptorsMasks(p, tctx, handle, key)) { printf("test_SecurityDescriptorsMasks failed\n"); ret = false; } return ret; } static bool test_DeleteKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { NTSTATUS status; struct winreg_DeleteKey r; r.in.handle = handle; init_winreg_String(&r.in.key, key); status = dcerpc_winreg_DeleteKey(p, tctx, &r); torture_assert_ntstatus_ok(tctx, status, "DeleteKey failed"); torture_assert_werr_ok(tctx, r.out.result, "DeleteKey failed"); return true; } /* DeleteKey on a key with subkey(s) should * return WERR_ACCESS_DENIED. */ static bool test_DeleteKeyWithSubkey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *key) { struct winreg_DeleteKey r; r.in.handle = handle; init_winreg_String(&r.in.key, key); torture_assert_ntstatus_ok(tctx, dcerpc_winreg_DeleteKey(p, tctx, &r), "DeleteKeyWithSubkey failed"); torture_assert_werr_equal(tctx, r.out.result, WERR_ACCESS_DENIED, "DeleteKeyWithSubkey failed"); return true; } static bool test_QueryInfoKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, char *class) { struct winreg_QueryInfoKey r; uint32_t num_subkeys, max_subkeylen, max_subkeysize, num_values, max_valnamelen, max_valbufsize, secdescsize; NTTIME last_changed_time; ZERO_STRUCT(r); r.in.handle = handle; r.out.num_subkeys = &num_subkeys; r.out.max_subkeylen = &max_subkeylen; r.out.max_subkeysize = &max_subkeysize; r.out.num_values = &num_values; r.out.max_valnamelen = &max_valnamelen; r.out.max_valbufsize = &max_valbufsize; r.out.secdescsize = &secdescsize; r.out.last_changed_time = &last_changed_time; r.out.classname = talloc(tctx, struct winreg_String); r.in.classname = talloc(tctx, struct winreg_String); init_winreg_String(r.in.classname, class); torture_assert_ntstatus_ok(tctx, dcerpc_winreg_QueryInfoKey(p, tctx, &r), "QueryInfoKey failed"); torture_assert_werr_ok(tctx, r.out.result, "QueryInfoKey failed"); return true; } static bool test_key(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, int depth); static bool test_EnumKey(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, int depth) { struct winreg_EnumKey r; struct winreg_StringBuf class, name; NTSTATUS status; NTTIME t = 0; class.name = ""; class.size = 1024; r.in.handle = handle; r.in.enum_index = 0; r.in.name = &name; r.in.keyclass = &class; r.out.name = &name; r.in.last_changed_time = &t; do { name.name = NULL; name.size = 1024; status = dcerpc_winreg_EnumKey(p, tctx, &r); if (NT_STATUS_IS_OK(status) && W_ERROR_IS_OK(r.out.result)) { struct policy_handle key_handle; torture_comment(tctx, "EnumKey: %d: %s\n", r.in.enum_index, r.out.name->name); if (!test_OpenKey(p, tctx, handle, r.out.name->name, &key_handle)) { } else { test_key(p, tctx, &key_handle, depth + 1); } } r.in.enum_index++; } while (NT_STATUS_IS_OK(status) && W_ERROR_IS_OK(r.out.result)); torture_assert_ntstatus_ok(tctx, status, "EnumKey failed"); if (!W_ERROR_IS_OK(r.out.result) && !W_ERROR_EQUAL(r.out.result, WERR_NO_MORE_ITEMS)) { torture_fail(tctx, "EnumKey failed"); } return true; } static bool test_QueryMultipleValues(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *valuename) { struct winreg_QueryMultipleValues r; NTSTATUS status; uint32_t bufsize=0; r.in.key_handle = handle; r.in.values = r.out.values = talloc_array(tctx, struct QueryMultipleValue, 1); r.in.values[0].name = talloc(tctx, struct winreg_String); r.in.values[0].name->name = valuename; r.in.values[0].offset = 0; r.in.values[0].length = 0; r.in.values[0].type = 0; r.in.num_values = 1; r.in.buffer_size = r.out.buffer_size = talloc(tctx, uint32_t); *r.in.buffer_size = bufsize; do { *r.in.buffer_size = bufsize; r.in.buffer = r.out.buffer = talloc_zero_array(tctx, uint8_t, *r.in.buffer_size); status = dcerpc_winreg_QueryMultipleValues(p, tctx, &r); if(NT_STATUS_IS_ERR(status)) torture_fail(tctx, "QueryMultipleValues failed"); talloc_free(r.in.buffer); bufsize += 0x20; } while (W_ERROR_EQUAL(r.out.result, WERR_MORE_DATA)); torture_assert_werr_ok(tctx, r.out.result, "QueryMultipleValues failed"); return true; } static bool test_QueryValue(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, const char *valuename) { struct winreg_QueryValue r; NTSTATUS status; enum winreg_Type zero_type = 0; uint32_t offered = 0xfff; uint32_t zero = 0; r.in.handle = handle; r.in.data = NULL; r.in.value_name.name = valuename; r.in.type = &zero_type; r.in.size = &offered; r.in.length = &zero; status = dcerpc_winreg_QueryValue(p, tctx, &r); if (NT_STATUS_IS_ERR(status)) { torture_fail(tctx, "QueryValue failed"); } torture_assert_werr_ok(tctx, r.out.result, "QueryValue failed"); return true; } static bool test_EnumValue(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, int max_valnamelen, int max_valbufsize) { struct winreg_EnumValue r; enum winreg_Type type = 0; uint32_t size = max_valbufsize, zero = 0; bool ret = true; uint8_t buf8; struct winreg_StringBuf name; name.name = ""; name.size = 1024; r.in.handle = handle; r.in.enum_index = 0; r.in.name = &name; r.out.name = &name; r.in.type = &type; r.in.value = &buf8; r.in.length = &zero; r.in.size = &size; do { torture_assert_ntstatus_ok(tctx, dcerpc_winreg_EnumValue(p, tctx, &r), "EnumValue failed"); if (W_ERROR_IS_OK(r.out.result)) { ret &= test_QueryValue(p, tctx, handle, r.out.name->name); ret &= test_QueryMultipleValues(p, tctx, handle, r.out.name->name); } r.in.enum_index++; } while (W_ERROR_IS_OK(r.out.result)); torture_assert_werr_equal(tctx, r.out.result, WERR_NO_MORE_ITEMS, "EnumValue failed"); return ret; } static bool test_AbortSystemShutdown(struct dcerpc_pipe *p, struct torture_context *tctx) { struct winreg_AbortSystemShutdown r; uint16_t server = 0x0; r.in.server = &server; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_AbortSystemShutdown(p, tctx, &r), "AbortSystemShutdown failed"); torture_assert_werr_ok(tctx, r.out.result, "AbortSystemShutdown failed"); return true; } static bool test_InitiateSystemShutdown(struct torture_context *tctx, struct dcerpc_pipe *p) { struct winreg_InitiateSystemShutdown r; uint16_t hostname = 0x0; r.in.hostname = &hostname; r.in.message = talloc(tctx, struct initshutdown_String); init_initshutdown_String(tctx, r.in.message, "spottyfood"); r.in.force_apps = 1; r.in.timeout = 30; r.in.reboot = 1; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_InitiateSystemShutdown(p, tctx, &r), "InitiateSystemShutdown failed"); torture_assert_werr_ok(tctx, r.out.result, "InitiateSystemShutdown failed"); return test_AbortSystemShutdown(p, tctx); } static bool test_InitiateSystemShutdownEx(struct torture_context *tctx, struct dcerpc_pipe *p) { struct winreg_InitiateSystemShutdownEx r; uint16_t hostname = 0x0; r.in.hostname = &hostname; r.in.message = talloc(tctx, struct initshutdown_String); init_initshutdown_String(tctx, r.in.message, "spottyfood"); r.in.force_apps = 1; r.in.timeout = 30; r.in.reboot = 1; r.in.reason = 0; torture_assert_ntstatus_ok(tctx, dcerpc_winreg_InitiateSystemShutdownEx(p, tctx, &r), "InitiateSystemShutdownEx failed"); torture_assert_werr_ok(tctx, r.out.result, "InitiateSystemShutdownEx failed"); return test_AbortSystemShutdown(p, tctx); } #define MAX_DEPTH 2 /* Only go this far down the tree */ static bool test_key(struct dcerpc_pipe *p, struct torture_context *tctx, struct policy_handle *handle, int depth) { if (depth == MAX_DEPTH) return true; if (!test_QueryInfoKey(p, tctx, handle, NULL)) { } if (!test_NotifyChangeKeyValue(p, tctx, handle)) { } if (!test_GetKeySecurity(p, tctx, handle, NULL)) { } if (!test_EnumKey(p, tctx, handle, depth)) { } if (!test_EnumValue(p, tctx, handle, 0xFF, 0xFFFF)) { } test_CloseKey(p, tctx, handle); return true; } typedef NTSTATUS (*winreg_open_fn)(struct dcerpc_pipe *, TALLOC_CTX *, void *); static bool test_Open(struct torture_context *tctx, struct dcerpc_pipe *p, void *userdata) { struct policy_handle handle, newhandle; bool ret = true, created = false, created2 = false, deleted = false; bool created3 = false, created_subkey = false; bool created4 = false; struct winreg_OpenHKLM r; winreg_open_fn open_fn = userdata; r.in.system_name = 0; r.in.access_mask = SEC_FLAG_MAXIMUM_ALLOWED; r.out.handle = &handle; torture_assert_ntstatus_ok(tctx, open_fn(p, tctx, &r), "open"); test_Cleanup(p, tctx, &handle, TEST_KEY1); test_Cleanup(p, tctx, &handle, TEST_SUBSUBKEY_SD); test_Cleanup(p, tctx, &handle, TEST_SUBKEY_SD); test_Cleanup(p, tctx, &handle, TEST_KEY4); test_Cleanup(p, tctx, &handle, TEST_KEY2); test_Cleanup(p, tctx, &handle, TEST_SUBKEY); test_Cleanup(p, tctx, &handle, TEST_KEY3); test_Cleanup(p, tctx, &handle, TEST_KEY_BASE); if (!test_CreateKey(p, tctx, &handle, TEST_KEY1, NULL)) { torture_comment(tctx, "CreateKey failed - not considering a failure\n"); } else { created = true; } if (created && !test_FlushKey(p, tctx, &handle)) { torture_comment(tctx, "FlushKey failed\n"); ret = false; } if (created && !test_OpenKey(p, tctx, &handle, TEST_KEY1, &newhandle)) torture_fail(tctx, "CreateKey failed (OpenKey after Create didn't work)\n"); if (created && !test_CloseKey(p, tctx, &newhandle)) torture_fail(tctx, "CreateKey failed (CloseKey after Open didn't work)\n"); if (created && !test_DeleteKey(p, tctx, &handle, TEST_KEY1)) { torture_comment(tctx, "DeleteKey failed\n"); ret = false; } else { deleted = true; } if (created && !test_FlushKey(p, tctx, &handle)) { torture_comment(tctx, "FlushKey failed\n"); ret = false; } if (created && deleted && test_OpenKey(p, tctx, &handle, TEST_KEY1, &newhandle)) { torture_comment(tctx, "DeleteKey failed (OpenKey after Delete worked)\n"); ret = false; } if (!test_GetVersion(p, tctx, &handle)) { torture_comment(tctx, "GetVersion failed\n"); ret = false; } if (created && test_CreateKey_sd(p, tctx, &handle, TEST_KEY2, NULL, &newhandle)) { created2 = true; } if (created2 && !test_CloseKey(p, tctx, &newhandle)) { printf("CloseKey failed\n"); ret = false; } if (test_CreateKey_sd(p, tctx, &handle, TEST_KEY4, NULL, &newhandle)) { created4 = true; } if (!created4 && !test_CloseKey(p, tctx, &newhandle)) { printf("CloseKey failed\n"); ret = false; } if (created4 && !test_SecurityDescriptors(p, tctx, &handle, TEST_KEY4)) { ret = false; } if (created4 && !test_DeleteKey(p, tctx, &handle, TEST_KEY4)) { printf("DeleteKey failed\n"); ret = false; } if (created && !test_DeleteKey(p, tctx, &handle, TEST_KEY2)) { printf("DeleteKey failed\n"); ret = false; } if (created && test_CreateKey(p, tctx, &handle, TEST_KEY3, NULL)) { created3 = true; } if (created3 && test_CreateKey(p, tctx, &handle, TEST_SUBKEY, NULL)) { created_subkey = true; } if (created_subkey && !test_DeleteKeyWithSubkey(p, tctx, &handle, TEST_KEY3)) { printf("DeleteKeyWithSubkey failed " "(DeleteKey didn't return ACCESS_DENIED)\n"); ret = false; } if (created_subkey && !test_DeleteKey(p, tctx, &handle, TEST_SUBKEY)) { printf("DeleteKey failed\n"); ret = false; } if (created3 && !test_DeleteKey(p, tctx, &handle, TEST_KEY3)) { printf("DeleteKey failed\n"); ret = false; } /* The HKCR hive has a very large fanout */ if (open_fn == (void *)dcerpc_winreg_OpenHKCR) { if(!test_key(p, tctx, &handle, MAX_DEPTH - 1)) { ret = false; } } if (!test_key(p, tctx, &handle, 0)) { ret = false; } test_Cleanup(p, tctx, &handle, TEST_KEY_BASE); return ret; } struct torture_suite *torture_rpc_winreg(TALLOC_CTX *mem_ctx) { struct { const char *name; winreg_open_fn fn; } open_fns[] = {{"OpenHKLM", (winreg_open_fn)dcerpc_winreg_OpenHKLM }, {"OpenHKU", (winreg_open_fn)dcerpc_winreg_OpenHKU }, {"OpenHKCR", (winreg_open_fn)dcerpc_winreg_OpenHKCR }, {"OpenHKCU", (winreg_open_fn)dcerpc_winreg_OpenHKCU }}; int i; struct torture_rpc_tcase *tcase; struct torture_suite *suite = torture_suite_create(mem_ctx, "WINREG"); struct torture_test *test; tcase = torture_suite_add_rpc_iface_tcase(suite, "winreg", &ndr_table_winreg); test = torture_rpc_tcase_add_test(tcase, "InitiateSystemShutdown", test_InitiateSystemShutdown); test->dangerous = true; test = torture_rpc_tcase_add_test(tcase, "InitiateSystemShutdownEx", test_InitiateSystemShutdownEx); test->dangerous = true; for (i = 0; i < ARRAY_SIZE(open_fns); i++) { torture_rpc_tcase_add_test_ex(tcase, open_fns[i].name, test_Open, open_fns[i].fn); } return suite; }