/* Unix SMB/CIFS implementation. endpoint server for the backupkey interface Copyright (C) Matthieu Patou 2010 Copyright (C) Andreas Schneider 2015 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 "rpc_server/dcerpc_server.h" #include "rpc_server/common/common.h" #include "librpc/gen_ndr/ndr_backupkey.h" #include "dsdb/common/util.h" #include "dsdb/samdb/samdb.h" #include "lib/ldb/include/ldb_errors.h" #include "../lib/util/util_ldb.h" #include "param/param.h" #include "auth/session.h" #include "system/network.h" #include "../lib/tsocket/tsocket.h" #include "../libcli/security/security.h" #include "librpc/gen_ndr/ndr_security.h" #include "libds/common/roles.h" #include #include #include #include #include "lib/crypto/gnutls_helpers.h" #undef strncasecmp #define DCESRV_INTERFACE_BACKUPKEY_BIND(context, iface) \ dcesrv_interface_backupkey_bind(context, iface) static NTSTATUS dcesrv_interface_backupkey_bind(struct dcesrv_connection_context *context, const struct dcesrv_interface *iface) { return dcesrv_interface_bind_require_privacy(context, iface); } static NTSTATUS set_lsa_secret(TALLOC_CTX *mem_ctx, struct ldb_context *ldb, const char *name, const DATA_BLOB *lsa_secret) { TALLOC_CTX *frame = talloc_stackframe(); struct ldb_message *msg; struct ldb_result *res; struct ldb_dn *system_dn = NULL; struct ldb_val val; int ret; char *name2; struct timeval now = timeval_current(); NTTIME nt_now = timeval_to_nttime(&now); const char *attrs[] = { NULL }; msg = ldb_msg_new(frame); if (msg == NULL) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } /* * This function is a lot like dcesrv_lsa_CreateSecret * in the rpc_server/lsa directory * The reason why we duplicate the effort here is that: * * we want to keep the former function static * * we want to avoid the burden of doing LSA calls * when we can just manipulate the secrets directly * * taillor the function to the particular needs of backup protocol */ system_dn = samdb_system_container_dn(ldb, frame); if (system_dn == NULL) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } name2 = talloc_asprintf(msg, "%s Secret", name); if (name2 == NULL) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } ret = ldb_search(ldb, frame, &res, system_dn, LDB_SCOPE_SUBTREE, attrs, "(&(cn=%s)(objectclass=secret))", ldb_binary_encode_string(frame, name2)); if (ret != LDB_SUCCESS || res->count != 0 ) { DEBUG(2, ("Secret %s already exists !\n", name2)); talloc_free(frame); return NT_STATUS_OBJECT_NAME_COLLISION; } /* * We don't care about previous value as we are * here only if the key didn't exists before */ msg->dn = ldb_dn_copy(frame, system_dn); if (msg->dn == NULL) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } if (!ldb_dn_add_child_fmt(msg->dn, "cn=%s", name2)) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } ret = ldb_msg_add_string(msg, "cn", name2); if (ret != LDB_SUCCESS) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } ret = ldb_msg_add_string(msg, "objectClass", "secret"); if (ret != LDB_SUCCESS) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } ret = samdb_msg_add_uint64(ldb, frame, msg, "priorSetTime", nt_now); if (ret != LDB_SUCCESS) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } val.data = lsa_secret->data; val.length = lsa_secret->length; ret = ldb_msg_add_value(msg, "currentValue", &val, NULL); if (ret != LDB_SUCCESS) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } ret = samdb_msg_add_uint64(ldb, frame, msg, "lastSetTime", nt_now); if (ret != LDB_SUCCESS) { talloc_free(frame); return NT_STATUS_NO_MEMORY; } /* * create the secret with DSDB_MODIFY_RELAX * otherwise dsdb/samdb/ldb_modules/objectclass.c forbid * the create of LSA secret object */ ret = dsdb_add(ldb, msg, DSDB_MODIFY_RELAX); if (ret != LDB_SUCCESS) { DEBUG(2,("Failed to create secret record %s: %s\n", ldb_dn_get_linearized(msg->dn), ldb_errstring(ldb))); talloc_free(frame); return NT_STATUS_ACCESS_DENIED; } talloc_free(frame); return NT_STATUS_OK; } /* This function is pretty much like dcesrv_lsa_QuerySecret */ static NTSTATUS get_lsa_secret(TALLOC_CTX *mem_ctx, struct ldb_context *ldb, const char *name, DATA_BLOB *lsa_secret) { TALLOC_CTX *tmp_mem; struct ldb_result *res; struct ldb_dn *system_dn = NULL; const struct ldb_val *val; uint8_t *data; const char *attrs[] = { "currentValue", NULL }; int ret; lsa_secret->data = NULL; lsa_secret->length = 0; tmp_mem = talloc_new(mem_ctx); if (tmp_mem == NULL) { return NT_STATUS_NO_MEMORY; } system_dn = samdb_system_container_dn(ldb, tmp_mem); if (system_dn == NULL) { talloc_free(tmp_mem); return NT_STATUS_NO_MEMORY; } ret = ldb_search(ldb, tmp_mem, &res, system_dn, LDB_SCOPE_SUBTREE, attrs, "(&(cn=%s Secret)(objectclass=secret))", ldb_binary_encode_string(tmp_mem, name)); if (ret != LDB_SUCCESS) { talloc_free(tmp_mem); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { talloc_free(tmp_mem); return NT_STATUS_RESOURCE_NAME_NOT_FOUND; } if (res->count > 1) { DEBUG(2, ("Secret %s collision\n", name)); talloc_free(tmp_mem); return NT_STATUS_INTERNAL_DB_CORRUPTION; } val = ldb_msg_find_ldb_val(res->msgs[0], "currentValue"); if (val == NULL) { /* * The secret object is here but we don't have the secret value * The most common case is a RODC */ *lsa_secret = data_blob_null; talloc_free(tmp_mem); return NT_STATUS_OK; } data = val->data; lsa_secret->data = talloc_move(mem_ctx, &data); lsa_secret->length = val->length; talloc_free(tmp_mem); return NT_STATUS_OK; } static int reverse_and_get_bignum(TALLOC_CTX *mem_ctx, DATA_BLOB blob, gnutls_datum_t *datum) { uint32_t i; datum->data = talloc_array(mem_ctx, uint8_t, blob.length); if (datum->data == NULL) { return -1; } for(i = 0; i < blob.length; i++) { datum->data[i] = blob.data[blob.length - i - 1]; } datum->size = blob.length; return 0; } static NTSTATUS get_pk_from_raw_keypair_params(TALLOC_CTX *ctx, struct bkrp_exported_RSA_key_pair *keypair, gnutls_privkey_t *pk) { gnutls_x509_privkey_t x509_privkey = NULL; gnutls_privkey_t privkey = NULL; gnutls_datum_t m, e, d, p, q, u, e1, e2; int rc; rc = reverse_and_get_bignum(ctx, keypair->modulus, &m); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->public_exponent, &e); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->private_exponent, &d); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->prime1, &p); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->prime2, &q); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->coefficient, &u); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->exponent1, &e1); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = reverse_and_get_bignum(ctx, keypair->exponent2, &e2); if (rc != 0) { return NT_STATUS_INVALID_PARAMETER; } rc = gnutls_x509_privkey_init(&x509_privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_init failed - %s\n", gnutls_strerror(rc)); return NT_STATUS_INTERNAL_ERROR; } rc = gnutls_x509_privkey_import_rsa_raw2(x509_privkey, &m, &e, &d, &p, &q, &u, &e1, &e2); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_import_rsa_raw2 failed - %s\n", gnutls_strerror(rc)); return NT_STATUS_INTERNAL_ERROR; } rc = gnutls_privkey_init(&privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_privkey_init failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_privkey); return NT_STATUS_INTERNAL_ERROR; } rc = gnutls_privkey_import_x509(privkey, x509_privkey, GNUTLS_PRIVKEY_IMPORT_AUTO_RELEASE); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_privkey_import_x509 failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_privkey); return NT_STATUS_INTERNAL_ERROR; } *pk = privkey; return NT_STATUS_OK; } static WERROR get_and_verify_access_check(TALLOC_CTX *sub_ctx, uint32_t version, uint8_t *key_and_iv, uint8_t *access_check, uint32_t access_check_len, struct auth_session_info *session_info) { struct bkrp_access_check_v2 uncrypted_accesscheckv2; struct bkrp_access_check_v3 uncrypted_accesscheckv3; gnutls_cipher_hd_t cipher_handle = { 0 }; gnutls_cipher_algorithm_t cipher_algo; DATA_BLOB blob_us; enum ndr_err_code ndr_err; gnutls_datum_t key; gnutls_datum_t iv; struct dom_sid *access_sid = NULL; struct dom_sid *caller_sid = NULL; int rc; switch (version) { case 2: cipher_algo = GNUTLS_CIPHER_3DES_CBC; break; case 3: cipher_algo = GNUTLS_CIPHER_AES_256_CBC; break; default: return WERR_INVALID_DATA; } key.data = key_and_iv; key.size = gnutls_cipher_get_key_size(cipher_algo); iv.data = key_and_iv + key.size; iv.size = gnutls_cipher_get_iv_size(cipher_algo); /* Allocate data structure for the plaintext */ blob_us = data_blob_talloc_zero(sub_ctx, access_check_len); if (blob_us.data == NULL) { return WERR_INVALID_DATA; } rc = gnutls_cipher_init(&cipher_handle, cipher_algo, &key, &iv); if (rc < 0) { DBG_ERR("gnutls_cipher_init failed: %s\n", gnutls_strerror(rc)); return WERR_INVALID_DATA; } rc = gnutls_cipher_decrypt2(cipher_handle, access_check, access_check_len, blob_us.data, blob_us.length); gnutls_cipher_deinit(cipher_handle); if (rc < 0) { DBG_ERR("gnutls_cipher_decrypt2 failed: %s\n", gnutls_strerror(rc)); return WERR_INVALID_DATA; } switch (version) { case 2: { uint32_t hash_size = 20; uint8_t hash[hash_size]; gnutls_hash_hd_t dig_ctx; ndr_err = ndr_pull_struct_blob(&blob_us, sub_ctx, &uncrypted_accesscheckv2, (ndr_pull_flags_fn_t)ndr_pull_bkrp_access_check_v2); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { /* Unable to unmarshall */ return WERR_INVALID_DATA; } if (uncrypted_accesscheckv2.magic != 0x1) { /* wrong magic */ return WERR_INVALID_DATA; } rc = gnutls_hash_init(&dig_ctx, GNUTLS_DIG_SHA1); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_hash(dig_ctx, blob_us.data, blob_us.length - hash_size); gnutls_hash_deinit(dig_ctx, hash); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* * We free it after the sha1 calculation because blob.data * points to the same area */ if (!mem_equal_const_time(hash, uncrypted_accesscheckv2.hash, hash_size)) { DEBUG(2, ("Wrong hash value in the access check in backup key remote protocol\n")); return WERR_INVALID_DATA; } access_sid = &(uncrypted_accesscheckv2.sid); break; } case 3: { uint32_t hash_size = 64; uint8_t hash[hash_size]; gnutls_hash_hd_t dig_ctx; ndr_err = ndr_pull_struct_blob(&blob_us, sub_ctx, &uncrypted_accesscheckv3, (ndr_pull_flags_fn_t)ndr_pull_bkrp_access_check_v3); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { /* Unable to unmarshall */ return WERR_INVALID_DATA; } if (uncrypted_accesscheckv3.magic != 0x1) { /* wrong magic */ return WERR_INVALID_DATA; } rc = gnutls_hash_init(&dig_ctx, GNUTLS_DIG_SHA512); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_hash(dig_ctx, blob_us.data, blob_us.length - hash_size); gnutls_hash_deinit(dig_ctx, hash); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* * We free it after the sha1 calculation because blob.data * points to the same area */ if (!mem_equal_const_time(hash, uncrypted_accesscheckv3.hash, hash_size)) { DEBUG(2, ("Wrong hash value in the access check in backup key remote protocol\n")); return WERR_INVALID_DATA; } access_sid = &(uncrypted_accesscheckv3.sid); break; } default: /* Never reached normally as we filtered at the switch / case level */ return WERR_INVALID_DATA; } caller_sid = &session_info->security_token->sids[PRIMARY_USER_SID_INDEX]; if (!dom_sid_equal(caller_sid, access_sid)) { return WERR_INVALID_ACCESS; } return WERR_OK; } /* * We have some data, such as saved website or IMAP passwords that the * client has in profile on-disk. This needs to be decrypted. This * version gives the server the data over the network (protected by * the X.509 certificate and public key encryption, and asks that it * be decrypted returned for short-term use, protected only by the * negotiated transport encryption. * * The data is NOT stored in the LSA, but a X.509 certificate, public * and private keys used to encrypt the data will be stored. There is * only one active encryption key pair and certificate per domain, it * is pointed at with G$BCKUPKEY_PREFERRED in the LSA secrets store. * * The potentially multiple valid decrypting key pairs are in turn * stored in the LSA secrets store as G$BCKUPKEY_keyGuidString. * */ static WERROR bkrp_client_wrap_decrypt_data(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r, struct ldb_context *ldb_ctx) { struct auth_session_info *session_info = dcesrv_call_session_info(dce_call); struct bkrp_client_side_wrapped uncrypt_request; DATA_BLOB blob; enum ndr_err_code ndr_err; char *guid_string; char *cert_secret_name; DATA_BLOB lsa_secret; DATA_BLOB *uncrypted_data = NULL; NTSTATUS status; uint32_t requested_version; blob.data = r->in.data_in; blob.length = r->in.data_in_len; if (r->in.data_in_len < 4 || r->in.data_in == NULL) { return WERR_INVALID_PARAMETER; } /* * We check for the version here, so we can actually print the * message as we are unlikely to parse it with NDR. */ requested_version = IVAL(r->in.data_in, 0); if ((requested_version != BACKUPKEY_CLIENT_WRAP_VERSION2) && (requested_version != BACKUPKEY_CLIENT_WRAP_VERSION3)) { DEBUG(1, ("Request for unknown BackupKey sub-protocol %d\n", requested_version)); return WERR_INVALID_PARAMETER; } ndr_err = ndr_pull_struct_blob(&blob, mem_ctx, &uncrypt_request, (ndr_pull_flags_fn_t)ndr_pull_bkrp_client_side_wrapped); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INVALID_PARAMETER; } if ((uncrypt_request.version != BACKUPKEY_CLIENT_WRAP_VERSION2) && (uncrypt_request.version != BACKUPKEY_CLIENT_WRAP_VERSION3)) { DEBUG(1, ("Request for unknown BackupKey sub-protocol %d\n", uncrypt_request.version)); return WERR_INVALID_PARAMETER; } guid_string = GUID_string(mem_ctx, &uncrypt_request.guid); if (guid_string == NULL) { return WERR_NOT_ENOUGH_MEMORY; } cert_secret_name = talloc_asprintf(mem_ctx, "BCKUPKEY_%s", guid_string); if (cert_secret_name == NULL) { return WERR_NOT_ENOUGH_MEMORY; } status = get_lsa_secret(mem_ctx, ldb_ctx, cert_secret_name, &lsa_secret); if (!NT_STATUS_IS_OK(status)) { DEBUG(10, ("Error while fetching secret %s\n", cert_secret_name)); return WERR_INVALID_DATA; } else if (lsa_secret.length == 0) { /* we do not have the real secret attribute, like if we are an RODC */ return WERR_INVALID_PARAMETER; } else { struct bkrp_exported_RSA_key_pair keypair; gnutls_privkey_t privkey = NULL; gnutls_datum_t reversed_secret; gnutls_datum_t uncrypted_secret; uint32_t i; DATA_BLOB blob_us; WERROR werr; int rc; ndr_err = ndr_pull_struct_blob(&lsa_secret, mem_ctx, &keypair, (ndr_pull_flags_fn_t)ndr_pull_bkrp_exported_RSA_key_pair); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { DEBUG(2, ("Unable to parse the ndr encoded cert in key %s\n", cert_secret_name)); return WERR_FILE_NOT_FOUND; } status = get_pk_from_raw_keypair_params(mem_ctx, &keypair, &privkey); if (!NT_STATUS_IS_OK(status)) { return WERR_INTERNAL_ERROR; } reversed_secret.data = talloc_array(mem_ctx, uint8_t, uncrypt_request.encrypted_secret_len); if (reversed_secret.data == NULL) { gnutls_privkey_deinit(privkey); return WERR_NOT_ENOUGH_MEMORY; } /* The secret has to be reversed ... */ for(i=0; i< uncrypt_request.encrypted_secret_len; i++) { uint8_t *reversed = (uint8_t *)reversed_secret.data; uint8_t *uncrypt = uncrypt_request.encrypted_secret; reversed[i] = uncrypt[uncrypt_request.encrypted_secret_len - 1 - i]; } reversed_secret.size = uncrypt_request.encrypted_secret_len; /* * Let's try to decrypt the secret now that * we have the private key ... */ rc = gnutls_privkey_decrypt_data(privkey, 0, &reversed_secret, &uncrypted_secret); gnutls_privkey_deinit(privkey); if (rc != GNUTLS_E_SUCCESS) { /* We are not able to decrypt the secret, looks like something is wrong */ return WERR_INVALID_PARAMETER; } blob_us.data = uncrypted_secret.data; blob_us.length = uncrypted_secret.size; if (uncrypt_request.version == 2) { struct bkrp_encrypted_secret_v2 uncrypted_secretv2; ndr_err = ndr_pull_struct_blob(&blob_us, mem_ctx, &uncrypted_secretv2, (ndr_pull_flags_fn_t)ndr_pull_bkrp_encrypted_secret_v2); gnutls_free(uncrypted_secret.data); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { /* Unable to unmarshall */ return WERR_INVALID_DATA; } if (uncrypted_secretv2.magic != 0x20) { /* wrong magic */ return WERR_INVALID_DATA; } werr = get_and_verify_access_check(mem_ctx, 2, uncrypted_secretv2.payload_key, uncrypt_request.access_check, uncrypt_request.access_check_len, session_info); if (!W_ERROR_IS_OK(werr)) { return werr; } uncrypted_data = talloc(mem_ctx, DATA_BLOB); if (uncrypted_data == NULL) { return WERR_INVALID_DATA; } uncrypted_data->data = uncrypted_secretv2.secret; uncrypted_data->length = uncrypted_secretv2.secret_len; } if (uncrypt_request.version == 3) { struct bkrp_encrypted_secret_v3 uncrypted_secretv3; ndr_err = ndr_pull_struct_blob(&blob_us, mem_ctx, &uncrypted_secretv3, (ndr_pull_flags_fn_t)ndr_pull_bkrp_encrypted_secret_v3); gnutls_free(uncrypted_secret.data); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { /* Unable to unmarshall */ return WERR_INVALID_DATA; } if (uncrypted_secretv3.magic1 != 0x30 || uncrypted_secretv3.magic2 != 0x6610 || uncrypted_secretv3.magic3 != 0x800e) { /* wrong magic */ return WERR_INVALID_DATA; } /* * Confirm that the caller is permitted to * read this particular data. Because one key * pair is used per domain, the caller could * have stolen the profile data on-disk and * would otherwise be able to read the * passwords. */ werr = get_and_verify_access_check(mem_ctx, 3, uncrypted_secretv3.payload_key, uncrypt_request.access_check, uncrypt_request.access_check_len, session_info); if (!W_ERROR_IS_OK(werr)) { return werr; } uncrypted_data = talloc(mem_ctx, DATA_BLOB); if (uncrypted_data == NULL) { return WERR_INVALID_DATA; } uncrypted_data->data = uncrypted_secretv3.secret; uncrypted_data->length = uncrypted_secretv3.secret_len; } /* * Yeah if we are here all looks pretty good: * - hash is ok * - user sid is the same as the one in access check * - we were able to decrypt the whole stuff */ } if (uncrypted_data->data == NULL) { return WERR_INVALID_DATA; } /* There is a magic value at the beginning of the data * we can use an ad hoc structure but as the * parent structure is just an array of bytes it is a lot of * work just prepending 4 bytes */ *(r->out.data_out) = talloc_zero_array(mem_ctx, uint8_t, uncrypted_data->length + 4); W_ERROR_HAVE_NO_MEMORY(*(r->out.data_out)); memcpy(4+*(r->out.data_out), uncrypted_data->data, uncrypted_data->length); *(r->out.data_out_len) = uncrypted_data->length + 4; return WERR_OK; } static DATA_BLOB *reverse_and_get_blob(TALLOC_CTX *mem_ctx, gnutls_datum_t *datum) { DATA_BLOB *blob; size_t i; blob = talloc(mem_ctx, DATA_BLOB); if (blob == NULL) { return NULL; } blob->length = datum->size; if (datum->data[0] == '\0') { /* The datum has a leading byte zero, skip it */ blob->length = datum->size - 1; } blob->data = talloc_zero_array(mem_ctx, uint8_t, blob->length); if (blob->data == NULL) { talloc_free(blob); return NULL; } for (i = 0; i < blob->length; i++) { blob->data[i] = datum->data[datum->size - i - 1]; } return blob; } static WERROR create_privkey_rsa(gnutls_privkey_t *pk) { int bits = 2048; gnutls_x509_privkey_t x509_privkey = NULL; gnutls_privkey_t privkey = NULL; int rc; rc = gnutls_x509_privkey_init(&x509_privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_init failed - %s\n", gnutls_strerror(rc)); return WERR_INTERNAL_ERROR; } rc = gnutls_x509_privkey_generate(x509_privkey, GNUTLS_PK_RSA, bits, 0); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_generate failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_privkey); return WERR_INTERNAL_ERROR; } rc = gnutls_privkey_init(&privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_privkey_init failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_privkey); return WERR_INTERNAL_ERROR; } rc = gnutls_privkey_import_x509(privkey, x509_privkey, GNUTLS_PRIVKEY_IMPORT_AUTO_RELEASE); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_privkey_import_x509 failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_privkey); return WERR_INTERNAL_ERROR; } *pk = privkey; return WERR_OK; } static WERROR self_sign_cert(TALLOC_CTX *mem_ctx, time_t lifetime, const char *dn, gnutls_privkey_t issuer_privkey, gnutls_x509_crt_t *certificate, DATA_BLOB *guidblob) { gnutls_datum_t unique_id; gnutls_datum_t serial_number; gnutls_x509_crt_t issuer_cert; gnutls_x509_privkey_t x509_issuer_privkey; time_t activation = time(NULL); time_t expiry = activation + lifetime; const char *error_string; uint8_t *reversed; size_t i; int rc; unique_id.size = guidblob->length; unique_id.data = talloc_memdup(mem_ctx, guidblob->data, guidblob->length); if (unique_id.data == NULL) { return WERR_NOT_ENOUGH_MEMORY; } reversed = talloc_array(mem_ctx, uint8_t, guidblob->length); if (reversed == NULL) { talloc_free(unique_id.data); return WERR_NOT_ENOUGH_MEMORY; } /* Native AD generates certificates with serialnumber in reversed notation */ for (i = 0; i < guidblob->length; i++) { uint8_t *uncrypt = guidblob->data; reversed[i] = uncrypt[guidblob->length - i - 1]; } serial_number.size = guidblob->length; serial_number.data = reversed; /* Create certificate to sign */ rc = gnutls_x509_crt_init(&issuer_cert); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_init failed - %s\n", gnutls_strerror(rc)); return WERR_NOT_ENOUGH_MEMORY; } rc = gnutls_x509_crt_set_dn(issuer_cert, dn, &error_string); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_dn failed - %s (%s)\n", gnutls_strerror(rc), error_string); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_issuer_dn(issuer_cert, dn, &error_string); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_issuer_dn failed - %s (%s)\n", gnutls_strerror(rc), error_string); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } /* Get x509 privkey for subjectPublicKeyInfo */ rc = gnutls_x509_privkey_init(&x509_issuer_privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_init failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_privkey_export_x509(issuer_privkey, &x509_issuer_privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_privkey_init failed - %s\n", gnutls_strerror(rc)); gnutls_x509_privkey_deinit(x509_issuer_privkey); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } /* Set subjectPublicKeyInfo */ rc = gnutls_x509_crt_set_key(issuer_cert, x509_issuer_privkey); gnutls_x509_privkey_deinit(x509_issuer_privkey); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_pubkey failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_activation_time(issuer_cert, activation); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_activation_time failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_expiration_time(issuer_cert, expiry); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_expiration_time failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_version(issuer_cert, 3); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_version failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_subject_unique_id(issuer_cert, unique_id.data, unique_id.size); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_subject_key_id failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_issuer_unique_id(issuer_cert, unique_id.data, unique_id.size); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_issuer_unique_id failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_set_serial(issuer_cert, serial_number.data, serial_number.size); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_set_serial failed - %s\n", gnutls_strerror(rc)); gnutls_x509_crt_deinit(issuer_cert); return WERR_INVALID_PARAMETER; } rc = gnutls_x509_crt_privkey_sign(issuer_cert, issuer_cert, issuer_privkey, GNUTLS_DIG_SHA1, 0); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_privkey_sign failed - %s\n", gnutls_strerror(rc)); return WERR_INVALID_PARAMETER; } *certificate = issuer_cert; return WERR_OK; } /* Return an error when we fail to generate a certificate */ static WERROR generate_bkrp_cert(TALLOC_CTX *mem_ctx, struct dcesrv_call_state *dce_call, struct ldb_context *ldb_ctx, const char *dn) { WERROR werr; gnutls_privkey_t issuer_privkey = NULL; gnutls_x509_crt_t cert = NULL; gnutls_datum_t cert_blob; gnutls_datum_t m, e, d, p, q, u, e1, e2; DATA_BLOB blob; DATA_BLOB blobkeypair; DATA_BLOB *tmp; bool ok = true; struct GUID guid = GUID_random(); NTSTATUS status; char *secret_name; struct bkrp_exported_RSA_key_pair keypair; enum ndr_err_code ndr_err; time_t nb_seconds_validity = 3600 * 24 * 365; int rc; DEBUG(6, ("Trying to generate a certificate\n")); werr = create_privkey_rsa(&issuer_privkey); if (!W_ERROR_IS_OK(werr)) { return werr; } status = GUID_to_ndr_blob(&guid, mem_ctx, &blob); if (!NT_STATUS_IS_OK(status)) { gnutls_privkey_deinit(issuer_privkey); return WERR_INVALID_DATA; } werr = self_sign_cert(mem_ctx, nb_seconds_validity, dn, issuer_privkey, &cert, &blob); if (!W_ERROR_IS_OK(werr)) { gnutls_privkey_deinit(issuer_privkey); return WERR_INVALID_DATA; } rc = gnutls_x509_crt_export2(cert, GNUTLS_X509_FMT_DER, &cert_blob); if (rc != GNUTLS_E_SUCCESS) { DBG_ERR("gnutls_x509_crt_export2 failed - %s\n", gnutls_strerror(rc)); gnutls_privkey_deinit(issuer_privkey); gnutls_x509_crt_deinit(cert); return WERR_INVALID_DATA; } keypair.cert.length = cert_blob.size; keypair.cert.data = talloc_memdup(mem_ctx, cert_blob.data, cert_blob.size); gnutls_x509_crt_deinit(cert); gnutls_free(cert_blob.data); if (keypair.cert.data == NULL) { gnutls_privkey_deinit(issuer_privkey); return WERR_NOT_ENOUGH_MEMORY; } rc = gnutls_privkey_export_rsa_raw(issuer_privkey, &m, &e, &d, &p, &q, &u, &e1, &e2); if (rc != GNUTLS_E_SUCCESS) { gnutls_privkey_deinit(issuer_privkey); return WERR_INVALID_DATA; } /* * Heimdal's bignum are big endian and the * structure expect it to be in little endian * so we reverse the buffer to make it work */ tmp = reverse_and_get_blob(mem_ctx, &e); if (tmp == NULL) { ok = false; } else { SMB_ASSERT(tmp->length <= 4); keypair.public_exponent = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &d); if (tmp == NULL) { ok = false; } else { keypair.private_exponent = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &m); if (tmp == NULL) { ok = false; } else { keypair.modulus = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &p); if (tmp == NULL) { ok = false; } else { keypair.prime1 = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &q); if (tmp == NULL) { ok = false; } else { keypair.prime2 = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &e1); if (tmp == NULL) { ok = false; } else { keypair.exponent1 = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &e2); if (tmp == NULL) { ok = false; } else { keypair.exponent2 = *tmp; } tmp = reverse_and_get_blob(mem_ctx, &u); if (tmp == NULL) { ok = false; } else { keypair.coefficient = *tmp; } /* One of the keypair allocation was wrong */ if (ok == false) { gnutls_privkey_deinit(issuer_privkey); return WERR_INVALID_DATA; } keypair.certificate_len = keypair.cert.length; ndr_err = ndr_push_struct_blob(&blobkeypair, mem_ctx, &keypair, (ndr_push_flags_fn_t)ndr_push_bkrp_exported_RSA_key_pair); gnutls_privkey_deinit(issuer_privkey); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INVALID_DATA; } secret_name = talloc_asprintf(mem_ctx, "BCKUPKEY_%s", GUID_string(mem_ctx, &guid)); if (secret_name == NULL) { return WERR_OUTOFMEMORY; } status = set_lsa_secret(mem_ctx, ldb_ctx, secret_name, &blobkeypair); if (!NT_STATUS_IS_OK(status)) { DEBUG(2, ("Failed to save the secret %s\n", secret_name)); } talloc_free(secret_name); GUID_to_ndr_blob(&guid, mem_ctx, &blob); status = set_lsa_secret(mem_ctx, ldb_ctx, "BCKUPKEY_PREFERRED", &blob); if (!NT_STATUS_IS_OK(status)) { DEBUG(2, ("Failed to save the secret BCKUPKEY_PREFERRED\n")); } return WERR_OK; } static WERROR bkrp_retrieve_client_wrap_key(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r, struct ldb_context *ldb_ctx) { struct GUID guid; char *guid_string; DATA_BLOB lsa_secret; enum ndr_err_code ndr_err; NTSTATUS status; /* * here we basically need to return our certificate * search for lsa secret BCKUPKEY_PREFERRED first */ status = get_lsa_secret(mem_ctx, ldb_ctx, "BCKUPKEY_PREFERRED", &lsa_secret); if (NT_STATUS_EQUAL(status, NT_STATUS_RESOURCE_NAME_NOT_FOUND)) { /* Ok we can be in this case if there was no certs */ struct loadparm_context *lp_ctx = dce_call->conn->dce_ctx->lp_ctx; char *dn = talloc_asprintf(mem_ctx, "CN=%s", lpcfg_realm(lp_ctx)); WERROR werr = generate_bkrp_cert(mem_ctx, dce_call, ldb_ctx, dn); if (!W_ERROR_IS_OK(werr)) { return WERR_INVALID_PARAMETER; } status = get_lsa_secret(mem_ctx, ldb_ctx, "BCKUPKEY_PREFERRED", &lsa_secret); if (!NT_STATUS_IS_OK(status)) { /* Ok we really don't manage to get this certs ...*/ DEBUG(2, ("Unable to locate BCKUPKEY_PREFERRED after cert generation\n")); return WERR_FILE_NOT_FOUND; } } else if (!NT_STATUS_IS_OK(status)) { return WERR_INTERNAL_ERROR; } if (lsa_secret.length == 0) { DEBUG(1, ("No secret in BCKUPKEY_PREFERRED, are we an undetected RODC?\n")); return WERR_INTERNAL_ERROR; } else { char *cert_secret_name; status = GUID_from_ndr_blob(&lsa_secret, &guid); if (!NT_STATUS_IS_OK(status)) { return WERR_FILE_NOT_FOUND; } guid_string = GUID_string(mem_ctx, &guid); if (guid_string == NULL) { /* We return file not found because the client * expect this error */ return WERR_FILE_NOT_FOUND; } cert_secret_name = talloc_asprintf(mem_ctx, "BCKUPKEY_%s", guid_string); status = get_lsa_secret(mem_ctx, ldb_ctx, cert_secret_name, &lsa_secret); if (!NT_STATUS_IS_OK(status)) { return WERR_FILE_NOT_FOUND; } if (lsa_secret.length != 0) { struct bkrp_exported_RSA_key_pair keypair; ndr_err = ndr_pull_struct_blob(&lsa_secret, mem_ctx, &keypair, (ndr_pull_flags_fn_t)ndr_pull_bkrp_exported_RSA_key_pair); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_FILE_NOT_FOUND; } *(r->out.data_out_len) = keypair.cert.length; *(r->out.data_out) = talloc_memdup(mem_ctx, keypair.cert.data, keypair.cert.length); W_ERROR_HAVE_NO_MEMORY(*(r->out.data_out)); return WERR_OK; } else { DEBUG(1, ("No or broken secret called %s\n", cert_secret_name)); return WERR_INTERNAL_ERROR; } } return WERR_NOT_SUPPORTED; } static WERROR generate_bkrp_server_wrap_key(TALLOC_CTX *ctx, struct ldb_context *ldb_ctx) { struct GUID guid = GUID_random(); enum ndr_err_code ndr_err; DATA_BLOB blob_wrap_key, guid_blob; struct bkrp_dc_serverwrap_key wrap_key; NTSTATUS status; char *secret_name; TALLOC_CTX *frame = talloc_stackframe(); generate_random_buffer(wrap_key.key, sizeof(wrap_key.key)); ndr_err = ndr_push_struct_blob(&blob_wrap_key, ctx, &wrap_key, (ndr_push_flags_fn_t)ndr_push_bkrp_dc_serverwrap_key); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { TALLOC_FREE(frame); return WERR_INVALID_DATA; } secret_name = talloc_asprintf(frame, "BCKUPKEY_%s", GUID_string(ctx, &guid)); if (secret_name == NULL) { TALLOC_FREE(frame); return WERR_NOT_ENOUGH_MEMORY; } status = set_lsa_secret(frame, ldb_ctx, secret_name, &blob_wrap_key); if (!NT_STATUS_IS_OK(status)) { DEBUG(2, ("Failed to save the secret %s\n", secret_name)); TALLOC_FREE(frame); return WERR_INTERNAL_ERROR; } status = GUID_to_ndr_blob(&guid, frame, &guid_blob); if (!NT_STATUS_IS_OK(status)) { DEBUG(2, ("Failed to save the secret %s\n", secret_name)); TALLOC_FREE(frame); } status = set_lsa_secret(frame, ldb_ctx, "BCKUPKEY_P", &guid_blob); if (!NT_STATUS_IS_OK(status)) { DEBUG(2, ("Failed to save the secret %s\n", secret_name)); TALLOC_FREE(frame); return WERR_INTERNAL_ERROR; } TALLOC_FREE(frame); return WERR_OK; } /* * Find the specified decryption keys from the LSA secrets store as * G$BCKUPKEY_keyGuidString. */ static WERROR bkrp_do_retrieve_server_wrap_key(TALLOC_CTX *mem_ctx, struct ldb_context *ldb_ctx, struct bkrp_dc_serverwrap_key *server_key, struct GUID *guid) { NTSTATUS status; DATA_BLOB lsa_secret; char *secret_name; char *guid_string; enum ndr_err_code ndr_err; guid_string = GUID_string(mem_ctx, guid); if (guid_string == NULL) { /* We return file not found because the client * expect this error */ return WERR_FILE_NOT_FOUND; } secret_name = talloc_asprintf(mem_ctx, "BCKUPKEY_%s", guid_string); if (secret_name == NULL) { return WERR_NOT_ENOUGH_MEMORY; } status = get_lsa_secret(mem_ctx, ldb_ctx, secret_name, &lsa_secret); if (!NT_STATUS_IS_OK(status)) { DEBUG(10, ("Error while fetching secret %s\n", secret_name)); return WERR_INVALID_DATA; } if (lsa_secret.length == 0) { /* RODC case, we do not have secrets locally */ DEBUG(1, ("Unable to fetch value for secret %s, are we an undetected RODC?\n", secret_name)); return WERR_INTERNAL_ERROR; } ndr_err = ndr_pull_struct_blob(&lsa_secret, mem_ctx, server_key, (ndr_pull_flags_fn_t)ndr_pull_bkrp_dc_serverwrap_key); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { DEBUG(2, ("Unable to parse the ndr encoded server wrap key %s\n", secret_name)); return WERR_INVALID_DATA; } return WERR_OK; } /* * Find the current, preferred ServerWrap Key by looking at * G$BCKUPKEY_P in the LSA secrets store. * * Then find the current decryption keys from the LSA secrets store as * G$BCKUPKEY_keyGuidString. */ static WERROR bkrp_do_retrieve_default_server_wrap_key(TALLOC_CTX *mem_ctx, struct ldb_context *ldb_ctx, struct bkrp_dc_serverwrap_key *server_key, struct GUID *returned_guid) { NTSTATUS status; DATA_BLOB guid_binary; status = get_lsa_secret(mem_ctx, ldb_ctx, "BCKUPKEY_P", &guid_binary); if (!NT_STATUS_IS_OK(status)) { DEBUG(10, ("Error while fetching secret BCKUPKEY_P to find current GUID\n")); return WERR_FILE_NOT_FOUND; } else if (guid_binary.length == 0) { /* RODC case, we do not have secrets locally */ DEBUG(1, ("Unable to fetch value for secret BCKUPKEY_P, are we an undetected RODC?\n")); return WERR_INTERNAL_ERROR; } status = GUID_from_ndr_blob(&guid_binary, returned_guid); if (!NT_STATUS_IS_OK(status)) { return WERR_FILE_NOT_FOUND; } return bkrp_do_retrieve_server_wrap_key(mem_ctx, ldb_ctx, server_key, returned_guid); } static WERROR bkrp_server_wrap_decrypt_data(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r ,struct ldb_context *ldb_ctx) { struct auth_session_info *session_info = dcesrv_call_session_info(dce_call); WERROR werr; struct bkrp_server_side_wrapped decrypt_request; DATA_BLOB sid_blob, encrypted_blob; DATA_BLOB blob; enum ndr_err_code ndr_err; struct bkrp_dc_serverwrap_key server_key; struct bkrp_rc4encryptedpayload rc4payload; struct dom_sid *caller_sid; uint8_t symkey[20]; /* SHA-1 hash len */ uint8_t mackey[20]; /* SHA-1 hash len */ uint8_t mac[20]; /* SHA-1 hash len */ gnutls_hmac_hd_t hmac_hnd; gnutls_cipher_hd_t cipher_hnd; gnutls_datum_t cipher_key; int rc; blob.data = r->in.data_in; blob.length = r->in.data_in_len; if (r->in.data_in_len == 0 || r->in.data_in == NULL) { return WERR_INVALID_PARAMETER; } ndr_err = ndr_pull_struct_blob_all(&blob, mem_ctx, &decrypt_request, (ndr_pull_flags_fn_t)ndr_pull_bkrp_server_side_wrapped); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INVALID_PARAMETER; } if (decrypt_request.magic != BACKUPKEY_SERVER_WRAP_VERSION) { return WERR_INVALID_PARAMETER; } werr = bkrp_do_retrieve_server_wrap_key(mem_ctx, ldb_ctx, &server_key, &decrypt_request.guid); if (!W_ERROR_IS_OK(werr)) { return werr; } dump_data_pw("server_key: \n", server_key.key, sizeof(server_key.key)); dump_data_pw("r2: \n", decrypt_request.r2, sizeof(decrypt_request.r2)); /* * This is *not* the leading 64 bytes, as indicated in MS-BKRP 3.1.4.1.1 * BACKUPKEY_BACKUP_GUID, it really is the whole key */ rc = gnutls_hmac_init(&hmac_hnd, GNUTLS_MAC_SHA1, server_key.key, sizeof(server_key.key)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_hmac(hmac_hnd, decrypt_request.r2, sizeof(decrypt_request.r2)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_output(hmac_hnd, symkey); dump_data_pw("symkey: \n", symkey, sizeof(symkey)); /* rc4 decrypt sid and secret using sym key */ cipher_key.data = symkey; cipher_key.size = sizeof(symkey); encrypted_blob = data_blob_const(decrypt_request.rc4encryptedpayload, decrypt_request.ciphertext_length); rc = gnutls_cipher_init(&cipher_hnd, GNUTLS_CIPHER_ARCFOUR_128, &cipher_key, NULL); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_cipher_encrypt2(cipher_hnd, encrypted_blob.data, encrypted_blob.length, encrypted_blob.data, encrypted_blob.length); gnutls_cipher_deinit(cipher_hnd); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } ndr_err = ndr_pull_struct_blob_all(&encrypted_blob, mem_ctx, &rc4payload, (ndr_pull_flags_fn_t)ndr_pull_bkrp_rc4encryptedpayload); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INVALID_PARAMETER; } if (decrypt_request.payload_length != rc4payload.secret_data.length) { return WERR_INVALID_PARAMETER; } dump_data_pw("r3: \n", rc4payload.r3, sizeof(rc4payload.r3)); /* * This is *not* the leading 64 bytes, as indicated in MS-BKRP 3.1.4.1.1 * BACKUPKEY_BACKUP_GUID, it really is the whole key */ rc = gnutls_hmac(hmac_hnd, rc4payload.r3, sizeof(rc4payload.r3)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_deinit(hmac_hnd, mackey); dump_data_pw("mackey: \n", mackey, sizeof(mackey)); ndr_err = ndr_push_struct_blob(&sid_blob, mem_ctx, &rc4payload.sid, (ndr_push_flags_fn_t)ndr_push_dom_sid); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INTERNAL_ERROR; } rc = gnutls_hmac_init(&hmac_hnd, GNUTLS_MAC_SHA1, mackey, sizeof(mackey)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* SID field */ rc = gnutls_hmac(hmac_hnd, sid_blob.data, sid_blob.length); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* Secret field */ rc = gnutls_hmac(hmac_hnd, rc4payload.secret_data.data, rc4payload.secret_data.length); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_deinit(hmac_hnd, mac); dump_data_pw("mac: \n", mac, sizeof(mac)); dump_data_pw("rc4payload.mac: \n", rc4payload.mac, sizeof(rc4payload.mac)); if (!mem_equal_const_time(mac, rc4payload.mac, sizeof(mac))) { return WERR_INVALID_ACCESS; } caller_sid = &session_info->security_token->sids[PRIMARY_USER_SID_INDEX]; if (!dom_sid_equal(&rc4payload.sid, caller_sid)) { return WERR_INVALID_ACCESS; } *(r->out.data_out) = rc4payload.secret_data.data; *(r->out.data_out_len) = rc4payload.secret_data.length; return WERR_OK; } /* * For BACKUPKEY_RESTORE_GUID we need to check the first 4 bytes to * determine what type of restore is wanted. * * See MS-BKRP 3.1.4.1.4 BACKUPKEY_RESTORE_GUID point 1. */ static WERROR bkrp_generic_decrypt_data(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r, struct ldb_context *ldb_ctx) { if (r->in.data_in_len < 4 || r->in.data_in == NULL) { return WERR_INVALID_PARAMETER; } if (IVAL(r->in.data_in, 0) == BACKUPKEY_SERVER_WRAP_VERSION) { return bkrp_server_wrap_decrypt_data(dce_call, mem_ctx, r, ldb_ctx); } return bkrp_client_wrap_decrypt_data(dce_call, mem_ctx, r, ldb_ctx); } /* * We have some data, such as saved website or IMAP passwords that the * client would like to put into the profile on-disk. This needs to * be encrypted. This version gives the server the data over the * network (protected only by the negotiated transport encryption), * and asks that it be encrypted and returned for long-term storage. * * The data is NOT stored in the LSA, but a key to encrypt the data * will be stored. There is only one active encryption key per domain, * it is pointed at with G$BCKUPKEY_P in the LSA secrets store. * * The potentially multiple valid decryption keys (and the encryption * key) are in turn stored in the LSA secrets store as * G$BCKUPKEY_keyGuidString. * */ static WERROR bkrp_server_wrap_encrypt_data(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r ,struct ldb_context *ldb_ctx) { struct auth_session_info *session_info = dcesrv_call_session_info(dce_call); DATA_BLOB sid_blob, encrypted_blob, server_wrapped_blob; WERROR werr; struct dom_sid *caller_sid; uint8_t symkey[20]; /* SHA-1 hash len */ uint8_t mackey[20]; /* SHA-1 hash len */ struct bkrp_rc4encryptedpayload rc4payload; gnutls_hmac_hd_t hmac_hnd; struct bkrp_dc_serverwrap_key server_key; enum ndr_err_code ndr_err; struct bkrp_server_side_wrapped server_side_wrapped; struct GUID guid; gnutls_cipher_hd_t cipher_hnd; gnutls_datum_t cipher_key; int rc; if (r->in.data_in_len == 0 || r->in.data_in == NULL) { return WERR_INVALID_PARAMETER; } werr = bkrp_do_retrieve_default_server_wrap_key(mem_ctx, ldb_ctx, &server_key, &guid); if (!W_ERROR_IS_OK(werr)) { if (W_ERROR_EQUAL(werr, WERR_FILE_NOT_FOUND)) { /* Generate the server wrap key since one wasn't found */ werr = generate_bkrp_server_wrap_key(mem_ctx, ldb_ctx); if (!W_ERROR_IS_OK(werr)) { return WERR_INVALID_PARAMETER; } werr = bkrp_do_retrieve_default_server_wrap_key(mem_ctx, ldb_ctx, &server_key, &guid); if (W_ERROR_EQUAL(werr, WERR_FILE_NOT_FOUND)) { /* Ok we really don't manage to get this secret ...*/ return WERR_FILE_NOT_FOUND; } } else { /* In theory we should NEVER reach this point as it should only appear in a rodc server */ /* we do not have the real secret attribute */ return WERR_INVALID_PARAMETER; } } caller_sid = &session_info->security_token->sids[PRIMARY_USER_SID_INDEX]; dump_data_pw("server_key: \n", server_key.key, sizeof(server_key.key)); /* * This is the key derivation step, so that the HMAC and RC4 * operations over the user-supplied data are not able to * disclose the master key. By using random data, the symkey * and mackey values are unique for this operation, and * discovering these (by reversing the RC4 over the * attacker-controlled data) does not return something able to * be used to decrypt the encrypted data of other users */ generate_random_buffer(server_side_wrapped.r2, sizeof(server_side_wrapped.r2)); dump_data_pw("r2: \n", server_side_wrapped.r2, sizeof(server_side_wrapped.r2)); generate_random_buffer(rc4payload.r3, sizeof(rc4payload.r3)); dump_data_pw("r3: \n", rc4payload.r3, sizeof(rc4payload.r3)); /* * This is *not* the leading 64 bytes, as indicated in MS-BKRP 3.1.4.1.1 * BACKUPKEY_BACKUP_GUID, it really is the whole key */ rc = gnutls_hmac_init(&hmac_hnd, GNUTLS_MAC_SHA1, server_key.key, sizeof(server_key.key)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_hmac(hmac_hnd, server_side_wrapped.r2, sizeof(server_side_wrapped.r2)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_output(hmac_hnd, symkey); dump_data_pw("symkey: \n", symkey, sizeof(symkey)); /* * This is *not* the leading 64 bytes, as indicated in MS-BKRP 3.1.4.1.1 * BACKUPKEY_BACKUP_GUID, it really is the whole key */ rc = gnutls_hmac(hmac_hnd, rc4payload.r3, sizeof(rc4payload.r3)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_deinit(hmac_hnd, mackey); dump_data_pw("mackey: \n", mackey, sizeof(mackey)); ndr_err = ndr_push_struct_blob(&sid_blob, mem_ctx, caller_sid, (ndr_push_flags_fn_t)ndr_push_dom_sid); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INTERNAL_ERROR; } rc4payload.secret_data.data = r->in.data_in; rc4payload.secret_data.length = r->in.data_in_len; rc = gnutls_hmac_init(&hmac_hnd, GNUTLS_MAC_SHA1, mackey, sizeof(mackey)); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* SID field */ rc = gnutls_hmac(hmac_hnd, sid_blob.data, sid_blob.length); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* Secret field */ rc = gnutls_hmac(hmac_hnd, rc4payload.secret_data.data, rc4payload.secret_data.length); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } gnutls_hmac_deinit(hmac_hnd, rc4payload.mac); dump_data_pw("rc4payload.mac: \n", rc4payload.mac, sizeof(rc4payload.mac)); rc4payload.sid = *caller_sid; ndr_err = ndr_push_struct_blob(&encrypted_blob, mem_ctx, &rc4payload, (ndr_push_flags_fn_t)ndr_push_bkrp_rc4encryptedpayload); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INTERNAL_ERROR; } /* rc4 encrypt sid and secret using sym key */ cipher_key.data = symkey; cipher_key.size = sizeof(symkey); rc = gnutls_cipher_init(&cipher_hnd, GNUTLS_CIPHER_ARCFOUR_128, &cipher_key, NULL); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } rc = gnutls_cipher_encrypt2(cipher_hnd, encrypted_blob.data, encrypted_blob.length, encrypted_blob.data, encrypted_blob.length); gnutls_cipher_deinit(cipher_hnd); if (rc != GNUTLS_E_SUCCESS) { return gnutls_error_to_werror(rc, WERR_INTERNAL_ERROR); } /* create server wrap structure */ server_side_wrapped.payload_length = rc4payload.secret_data.length; server_side_wrapped.ciphertext_length = encrypted_blob.length; server_side_wrapped.guid = guid; server_side_wrapped.rc4encryptedpayload = encrypted_blob.data; ndr_err = ndr_push_struct_blob(&server_wrapped_blob, mem_ctx, &server_side_wrapped, (ndr_push_flags_fn_t)ndr_push_bkrp_server_side_wrapped); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { return WERR_INTERNAL_ERROR; } *(r->out.data_out) = server_wrapped_blob.data; *(r->out.data_out_len) = server_wrapped_blob.length; return WERR_OK; } static WERROR dcesrv_bkrp_BackupKey(struct dcesrv_call_state *dce_call, TALLOC_CTX *mem_ctx, struct bkrp_BackupKey *r) { WERROR error = WERR_INVALID_PARAMETER; struct ldb_context *ldb_ctx; bool is_rodc; const char *addr = "unknown"; /* At which level we start to add more debug of what is done in the protocol */ const int debuglevel = 4; if (DEBUGLVL(debuglevel)) { const struct tsocket_address *remote_address; remote_address = dcesrv_connection_get_remote_address(dce_call->conn); if (tsocket_address_is_inet(remote_address, "ip")) { addr = tsocket_address_inet_addr_string(remote_address, mem_ctx); W_ERROR_HAVE_NO_MEMORY(addr); } } if (lpcfg_server_role(dce_call->conn->dce_ctx->lp_ctx) != ROLE_ACTIVE_DIRECTORY_DC) { return WERR_NOT_SUPPORTED; } /* * Save the current remote session details so they can used by the * audit logging module. This allows the audit logging to report the * remote users details, rather than the system users details. */ ldb_ctx = dcesrv_samdb_connect_as_system(mem_ctx, dce_call); if (samdb_rodc(ldb_ctx, &is_rodc) != LDB_SUCCESS) { talloc_unlink(mem_ctx, ldb_ctx); return WERR_INVALID_PARAMETER; } if (!is_rodc) { if(strncasecmp(GUID_string(mem_ctx, r->in.guidActionAgent), BACKUPKEY_RESTORE_GUID, strlen(BACKUPKEY_RESTORE_GUID)) == 0) { DEBUG(debuglevel, ("Client %s requested to decrypt a wrapped secret\n", addr)); error = bkrp_generic_decrypt_data(dce_call, mem_ctx, r, ldb_ctx); } if (strncasecmp(GUID_string(mem_ctx, r->in.guidActionAgent), BACKUPKEY_RETRIEVE_BACKUP_KEY_GUID, strlen(BACKUPKEY_RETRIEVE_BACKUP_KEY_GUID)) == 0) { DEBUG(debuglevel, ("Client %s requested certificate for client wrapped secret\n", addr)); error = bkrp_retrieve_client_wrap_key(dce_call, mem_ctx, r, ldb_ctx); } if (strncasecmp(GUID_string(mem_ctx, r->in.guidActionAgent), BACKUPKEY_RESTORE_GUID_WIN2K, strlen(BACKUPKEY_RESTORE_GUID_WIN2K)) == 0) { DEBUG(debuglevel, ("Client %s requested to decrypt a server side wrapped secret\n", addr)); error = bkrp_server_wrap_decrypt_data(dce_call, mem_ctx, r, ldb_ctx); } if (strncasecmp(GUID_string(mem_ctx, r->in.guidActionAgent), BACKUPKEY_BACKUP_GUID, strlen(BACKUPKEY_BACKUP_GUID)) == 0) { DEBUG(debuglevel, ("Client %s requested a server wrapped secret\n", addr)); error = bkrp_server_wrap_encrypt_data(dce_call, mem_ctx, r, ldb_ctx); } } /*else: I am a RODC so I don't handle backup key protocol */ talloc_unlink(mem_ctx, ldb_ctx); return error; } /* include the generated boilerplate */ #include "librpc/gen_ndr/ndr_backupkey_s.c"