/* Unix SMB/CIFS implementation. code to manipulate domain credentials Copyright (C) Andrew Tridgell 1997-2003 Copyright (C) Andrew Bartlett 2004 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 "system/time.h" #include "../lib/crypto/crypto.h" #include "libcli/auth/libcli_auth.h" #include "../libcli/security/dom_sid.h" static void netlogon_creds_step_crypt(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *in, struct netr_Credential *out) { if (creds->negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { AES_KEY key; uint8_t iv[AES_BLOCK_SIZE]; AES_set_encrypt_key(creds->session_key, 128, &key); ZERO_STRUCT(iv); aes_cfb8_encrypt(in->data, out->data, 8, &key, iv, AES_ENCRYPT); } else { des_crypt112(out->data, in->data, creds->session_key, 1); } } /* initialise the credentials state for old-style 64 bit session keys this call is made after the netr_ServerReqChallenge call */ static void netlogon_creds_init_64bit(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge, const struct samr_Password *machine_password) { uint32_t sum[2]; uint8_t sum2[8]; sum[0] = IVAL(client_challenge->data, 0) + IVAL(server_challenge->data, 0); sum[1] = IVAL(client_challenge->data, 4) + IVAL(server_challenge->data, 4); SIVAL(sum2,0,sum[0]); SIVAL(sum2,4,sum[1]); ZERO_STRUCT(creds->session_key); des_crypt128(creds->session_key, sum2, machine_password->hash); } /* initialise the credentials state for ADS-style 128 bit session keys this call is made after the netr_ServerReqChallenge call */ static void netlogon_creds_init_128bit(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge, const struct samr_Password *machine_password) { unsigned char zero[4], tmp[16]; HMACMD5Context ctx; MD5_CTX md5; ZERO_STRUCT(creds->session_key); memset(zero, 0, sizeof(zero)); hmac_md5_init_rfc2104(machine_password->hash, sizeof(machine_password->hash), &ctx); MD5Init(&md5); MD5Update(&md5, zero, sizeof(zero)); MD5Update(&md5, client_challenge->data, 8); MD5Update(&md5, server_challenge->data, 8); MD5Final(tmp, &md5); hmac_md5_update(tmp, sizeof(tmp), &ctx); hmac_md5_final(creds->session_key, &ctx); } /* initialise the credentials state for AES/HMAC-SHA256-style 128 bit session keys this call is made after the netr_ServerReqChallenge call */ static void netlogon_creds_init_hmac_sha256(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge, const struct samr_Password *machine_password) { struct HMACSHA256Context ctx; uint8_t digest[SHA256_DIGEST_LENGTH]; ZERO_STRUCT(creds->session_key); hmac_sha256_init(machine_password->hash, sizeof(machine_password->hash), &ctx); hmac_sha256_update(client_challenge->data, 8, &ctx); hmac_sha256_update(server_challenge->data, 8, &ctx); hmac_sha256_final(digest, &ctx); memcpy(creds->session_key, digest, sizeof(creds->session_key)); ZERO_STRUCT(digest); ZERO_STRUCT(ctx); } static void netlogon_creds_first_step(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge) { netlogon_creds_step_crypt(creds, client_challenge, &creds->client); netlogon_creds_step_crypt(creds, server_challenge, &creds->server); creds->seed = creds->client; } /* step the credentials to the next element in the chain, updating the current client and server credentials and the seed */ static void netlogon_creds_step(struct netlogon_creds_CredentialState *creds) { struct netr_Credential time_cred; DEBUG(5,("\tseed %08x:%08x\n", IVAL(creds->seed.data, 0), IVAL(creds->seed.data, 4))); SIVAL(time_cred.data, 0, IVAL(creds->seed.data, 0) + creds->sequence); SIVAL(time_cred.data, 4, IVAL(creds->seed.data, 4)); DEBUG(5,("\tseed+time %08x:%08x\n", IVAL(time_cred.data, 0), IVAL(time_cred.data, 4))); netlogon_creds_step_crypt(creds, &time_cred, &creds->client); DEBUG(5,("\tCLIENT %08x:%08x\n", IVAL(creds->client.data, 0), IVAL(creds->client.data, 4))); SIVAL(time_cred.data, 0, IVAL(creds->seed.data, 0) + creds->sequence + 1); SIVAL(time_cred.data, 4, IVAL(creds->seed.data, 4)); DEBUG(5,("\tseed+time+1 %08x:%08x\n", IVAL(time_cred.data, 0), IVAL(time_cred.data, 4))); netlogon_creds_step_crypt(creds, &time_cred, &creds->server); DEBUG(5,("\tSERVER %08x:%08x\n", IVAL(creds->server.data, 0), IVAL(creds->server.data, 4))); creds->seed = time_cred; } /* DES encrypt a 8 byte LMSessionKey buffer using the Netlogon session key */ void netlogon_creds_des_encrypt_LMKey(struct netlogon_creds_CredentialState *creds, struct netr_LMSessionKey *key) { struct netr_LMSessionKey tmp; des_crypt56(tmp.key, key->key, creds->session_key, 1); *key = tmp; } /* DES decrypt a 8 byte LMSessionKey buffer using the Netlogon session key */ void netlogon_creds_des_decrypt_LMKey(struct netlogon_creds_CredentialState *creds, struct netr_LMSessionKey *key) { struct netr_LMSessionKey tmp; des_crypt56(tmp.key, key->key, creds->session_key, 0); *key = tmp; } /* DES encrypt a 16 byte password buffer using the session key */ void netlogon_creds_des_encrypt(struct netlogon_creds_CredentialState *creds, struct samr_Password *pass) { struct samr_Password tmp; des_crypt112_16(tmp.hash, pass->hash, creds->session_key, 1); *pass = tmp; } /* DES decrypt a 16 byte password buffer using the session key */ void netlogon_creds_des_decrypt(struct netlogon_creds_CredentialState *creds, struct samr_Password *pass) { struct samr_Password tmp; des_crypt112_16(tmp.hash, pass->hash, creds->session_key, 0); *pass = tmp; } /* ARCFOUR encrypt/decrypt a password buffer using the session key */ void netlogon_creds_arcfour_crypt(struct netlogon_creds_CredentialState *creds, uint8_t *data, size_t len) { DATA_BLOB session_key = data_blob(creds->session_key, 16); arcfour_crypt_blob(data, len, &session_key); data_blob_free(&session_key); } /* AES encrypt a password buffer using the session key */ void netlogon_creds_aes_encrypt(struct netlogon_creds_CredentialState *creds, uint8_t *data, size_t len) { AES_KEY key; uint8_t iv[AES_BLOCK_SIZE]; AES_set_encrypt_key(creds->session_key, 128, &key); ZERO_STRUCT(iv); aes_cfb8_encrypt(data, data, len, &key, iv, AES_ENCRYPT); } /* AES decrypt a password buffer using the session key */ void netlogon_creds_aes_decrypt(struct netlogon_creds_CredentialState *creds, uint8_t *data, size_t len) { AES_KEY key; uint8_t iv[AES_BLOCK_SIZE]; AES_set_encrypt_key(creds->session_key, 128, &key); ZERO_STRUCT(iv); aes_cfb8_encrypt(data, data, len, &key, iv, AES_DECRYPT); } /***************************************************************** The above functions are common to the client and server interface next comes the client specific functions ******************************************************************/ /* initialise the credentials chain and return the first client credentials */ struct netlogon_creds_CredentialState *netlogon_creds_client_init(TALLOC_CTX *mem_ctx, const char *client_account, const char *client_computer_name, uint16_t secure_channel_type, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge, const struct samr_Password *machine_password, struct netr_Credential *initial_credential, uint32_t negotiate_flags) { struct netlogon_creds_CredentialState *creds = talloc_zero(mem_ctx, struct netlogon_creds_CredentialState); if (!creds) { return NULL; } creds->sequence = time(NULL); creds->negotiate_flags = negotiate_flags; creds->secure_channel_type = secure_channel_type; creds->computer_name = talloc_strdup(creds, client_computer_name); if (!creds->computer_name) { talloc_free(creds); return NULL; } creds->account_name = talloc_strdup(creds, client_account); if (!creds->account_name) { talloc_free(creds); return NULL; } dump_data_pw("Client chall", client_challenge->data, sizeof(client_challenge->data)); dump_data_pw("Server chall", server_challenge->data, sizeof(server_challenge->data)); dump_data_pw("Machine Pass", machine_password->hash, sizeof(machine_password->hash)); if (negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { netlogon_creds_init_hmac_sha256(creds, client_challenge, server_challenge, machine_password); } else if (negotiate_flags & NETLOGON_NEG_STRONG_KEYS) { netlogon_creds_init_128bit(creds, client_challenge, server_challenge, machine_password); } else { netlogon_creds_init_64bit(creds, client_challenge, server_challenge, machine_password); } netlogon_creds_first_step(creds, client_challenge, server_challenge); dump_data_pw("Session key", creds->session_key, 16); dump_data_pw("Credential ", creds->client.data, 8); *initial_credential = creds->client; return creds; } /* initialise the credentials structure with only a session key. The caller better know what they are doing! */ struct netlogon_creds_CredentialState *netlogon_creds_client_init_session_key(TALLOC_CTX *mem_ctx, const uint8_t session_key[16]) { struct netlogon_creds_CredentialState *creds; creds = talloc_zero(mem_ctx, struct netlogon_creds_CredentialState); if (!creds) { return NULL; } memcpy(creds->session_key, session_key, 16); return creds; } /* step the credentials to the next element in the chain, updating the current client and server credentials and the seed produce the next authenticator in the sequence ready to send to the server */ void netlogon_creds_client_authenticator(struct netlogon_creds_CredentialState *creds, struct netr_Authenticator *next) { creds->sequence += 2; netlogon_creds_step(creds); next->cred = creds->client; next->timestamp = creds->sequence; } /* check that a credentials reply from a server is correct */ bool netlogon_creds_client_check(struct netlogon_creds_CredentialState *creds, const struct netr_Credential *received_credentials) { if (!received_credentials || memcmp(received_credentials->data, creds->server.data, 8) != 0) { DEBUG(2,("credentials check failed\n")); return false; } return true; } /***************************************************************** The above functions are common to the client and server interface next comes the server specific functions ******************************************************************/ /* check that a credentials reply from a server is correct */ static bool netlogon_creds_server_check_internal(const struct netlogon_creds_CredentialState *creds, const struct netr_Credential *received_credentials) { if (memcmp(received_credentials->data, creds->client.data, 8) != 0) { DEBUG(2,("credentials check failed\n")); dump_data_pw("client creds", creds->client.data, 8); dump_data_pw("calc creds", received_credentials->data, 8); return false; } return true; } /* initialise the credentials chain and return the first server credentials */ struct netlogon_creds_CredentialState *netlogon_creds_server_init(TALLOC_CTX *mem_ctx, const char *client_account, const char *client_computer_name, uint16_t secure_channel_type, const struct netr_Credential *client_challenge, const struct netr_Credential *server_challenge, const struct samr_Password *machine_password, struct netr_Credential *credentials_in, struct netr_Credential *credentials_out, uint32_t negotiate_flags) { struct netlogon_creds_CredentialState *creds = talloc_zero(mem_ctx, struct netlogon_creds_CredentialState); if (!creds) { return NULL; } creds->negotiate_flags = negotiate_flags; creds->secure_channel_type = secure_channel_type; dump_data_pw("Client chall", client_challenge->data, sizeof(client_challenge->data)); dump_data_pw("Server chall", server_challenge->data, sizeof(server_challenge->data)); dump_data_pw("Machine Pass", machine_password->hash, sizeof(machine_password->hash)); creds->computer_name = talloc_strdup(creds, client_computer_name); if (!creds->computer_name) { talloc_free(creds); return NULL; } creds->account_name = talloc_strdup(creds, client_account); if (!creds->account_name) { talloc_free(creds); return NULL; } if (negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { netlogon_creds_init_hmac_sha256(creds, client_challenge, server_challenge, machine_password); } else if (negotiate_flags & NETLOGON_NEG_STRONG_KEYS) { netlogon_creds_init_128bit(creds, client_challenge, server_challenge, machine_password); } else { netlogon_creds_init_64bit(creds, client_challenge, server_challenge, machine_password); } netlogon_creds_first_step(creds, client_challenge, server_challenge); dump_data_pw("Session key", creds->session_key, 16); dump_data_pw("Client Credential ", creds->client.data, 8); dump_data_pw("Server Credential ", creds->server.data, 8); dump_data_pw("Credentials in", credentials_in->data, sizeof(credentials_in->data)); /* And before we leak information about the machine account * password, check that they got the first go right */ if (!netlogon_creds_server_check_internal(creds, credentials_in)) { talloc_free(creds); return NULL; } *credentials_out = creds->server; dump_data_pw("Credentials out", credentials_out->data, sizeof(credentials_out->data)); return creds; } NTSTATUS netlogon_creds_server_step_check(struct netlogon_creds_CredentialState *creds, struct netr_Authenticator *received_authenticator, struct netr_Authenticator *return_authenticator) { if (!received_authenticator || !return_authenticator) { return NT_STATUS_INVALID_PARAMETER; } if (!creds) { return NT_STATUS_ACCESS_DENIED; } /* TODO: this may allow the a replay attack on a non-signed connection. Should we check that this is increasing? */ creds->sequence = received_authenticator->timestamp; netlogon_creds_step(creds); if (netlogon_creds_server_check_internal(creds, &received_authenticator->cred)) { return_authenticator->cred = creds->server; return_authenticator->timestamp = creds->sequence; return NT_STATUS_OK; } else { ZERO_STRUCTP(return_authenticator); return NT_STATUS_ACCESS_DENIED; } } static void netlogon_creds_crypt_samlogon_validation(struct netlogon_creds_CredentialState *creds, uint16_t validation_level, union netr_Validation *validation, bool do_encrypt) { static const char zeros[16]; struct netr_SamBaseInfo *base = NULL; if (validation == NULL) { return; } switch (validation_level) { case 2: if (validation->sam2) { base = &validation->sam2->base; } break; case 3: if (validation->sam3) { base = &validation->sam3->base; } break; case 6: if (validation->sam6) { base = &validation->sam6->base; } break; default: /* If we can't find it, we can't very well decrypt it */ return; } if (!base) { return; } /* find and decyrpt the session keys, return in parameters above */ if (validation_level == 6) { /* they aren't encrypted! */ } else if (creds->negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { /* Don't crypt an all-zero key, it would give away the NETLOGON pipe session key */ if (memcmp(base->key.key, zeros, sizeof(base->key.key)) != 0) { if (do_encrypt) { netlogon_creds_aes_encrypt(creds, base->key.key, sizeof(base->key.key)); } else { netlogon_creds_aes_decrypt(creds, base->key.key, sizeof(base->key.key)); } } if (memcmp(base->LMSessKey.key, zeros, sizeof(base->LMSessKey.key)) != 0) { if (do_encrypt) { netlogon_creds_aes_encrypt(creds, base->LMSessKey.key, sizeof(base->LMSessKey.key)); } else { netlogon_creds_aes_decrypt(creds, base->LMSessKey.key, sizeof(base->LMSessKey.key)); } } } else if (creds->negotiate_flags & NETLOGON_NEG_ARCFOUR) { /* Don't crypt an all-zero key, it would give away the NETLOGON pipe session key */ if (memcmp(base->key.key, zeros, sizeof(base->key.key)) != 0) { netlogon_creds_arcfour_crypt(creds, base->key.key, sizeof(base->key.key)); } if (memcmp(base->LMSessKey.key, zeros, sizeof(base->LMSessKey.key)) != 0) { netlogon_creds_arcfour_crypt(creds, base->LMSessKey.key, sizeof(base->LMSessKey.key)); } } else { /* Don't crypt an all-zero key, it would give away the NETLOGON pipe session key */ if (memcmp(base->LMSessKey.key, zeros, sizeof(base->LMSessKey.key)) != 0) { if (do_encrypt) { netlogon_creds_des_encrypt_LMKey(creds, &base->LMSessKey); } else { netlogon_creds_des_decrypt_LMKey(creds, &base->LMSessKey); } } } } void netlogon_creds_decrypt_samlogon_validation(struct netlogon_creds_CredentialState *creds, uint16_t validation_level, union netr_Validation *validation) { netlogon_creds_crypt_samlogon_validation(creds, validation_level, validation, false); } void netlogon_creds_encrypt_samlogon_validation(struct netlogon_creds_CredentialState *creds, uint16_t validation_level, union netr_Validation *validation) { netlogon_creds_crypt_samlogon_validation(creds, validation_level, validation, true); } static void netlogon_creds_crypt_samlogon_logon(struct netlogon_creds_CredentialState *creds, enum netr_LogonInfoClass level, union netr_LogonLevel *logon, bool encrypt) { static const char zeros[16]; if (logon == NULL) { return; } switch (level) { case NetlogonInteractiveInformation: case NetlogonInteractiveTransitiveInformation: case NetlogonServiceInformation: case NetlogonServiceTransitiveInformation: if (logon->password == NULL) { return; } if (creds->negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { uint8_t *h; h = logon->password->lmpassword.hash; if (memcmp(h, zeros, 16) != 0) { if (encrypt) { netlogon_creds_aes_encrypt(creds, h, 16); } else { netlogon_creds_aes_decrypt(creds, h, 16); } } h = logon->password->ntpassword.hash; if (memcmp(h, zeros, 16) != 0) { if (encrypt) { netlogon_creds_aes_encrypt(creds, h, 16); } else { netlogon_creds_aes_decrypt(creds, h, 16); } } } else if (creds->negotiate_flags & NETLOGON_NEG_ARCFOUR) { uint8_t *h; h = logon->password->lmpassword.hash; if (memcmp(h, zeros, 16) != 0) { netlogon_creds_arcfour_crypt(creds, h, 16); } h = logon->password->ntpassword.hash; if (memcmp(h, zeros, 16) != 0) { netlogon_creds_arcfour_crypt(creds, h, 16); } } else { struct samr_Password *p; p = &logon->password->lmpassword; if (memcmp(p->hash, zeros, 16) != 0) { if (encrypt) { netlogon_creds_des_encrypt(creds, p); } else { netlogon_creds_des_decrypt(creds, p); } } p = &logon->password->ntpassword; if (memcmp(p->hash, zeros, 16) != 0) { if (encrypt) { netlogon_creds_des_encrypt(creds, p); } else { netlogon_creds_des_decrypt(creds, p); } } } break; case NetlogonNetworkInformation: case NetlogonNetworkTransitiveInformation: break; case NetlogonGenericInformation: if (logon->generic == NULL) { return; } if (creds->negotiate_flags & NETLOGON_NEG_SUPPORTS_AES) { if (encrypt) { netlogon_creds_aes_encrypt(creds, logon->generic->data, logon->generic->length); } else { netlogon_creds_aes_decrypt(creds, logon->generic->data, logon->generic->length); } } else if (creds->negotiate_flags & NETLOGON_NEG_ARCFOUR) { netlogon_creds_arcfour_crypt(creds, logon->generic->data, logon->generic->length); } else { /* Using DES to verify kerberos tickets makes no sense */ } break; } } void netlogon_creds_decrypt_samlogon_logon(struct netlogon_creds_CredentialState *creds, enum netr_LogonInfoClass level, union netr_LogonLevel *logon) { netlogon_creds_crypt_samlogon_logon(creds, level, logon, false); } void netlogon_creds_encrypt_samlogon_logon(struct netlogon_creds_CredentialState *creds, enum netr_LogonInfoClass level, union netr_LogonLevel *logon) { netlogon_creds_crypt_samlogon_logon(creds, level, logon, true); } union netr_LogonLevel *netlogon_creds_shallow_copy_logon(TALLOC_CTX *mem_ctx, enum netr_LogonInfoClass level, const union netr_LogonLevel *in) { union netr_LogonLevel *out; if (in == NULL) { return NULL; } out = talloc(mem_ctx, union netr_LogonLevel); if (out == NULL) { return NULL; } *out = *in; switch (level) { case NetlogonInteractiveInformation: case NetlogonInteractiveTransitiveInformation: case NetlogonServiceInformation: case NetlogonServiceTransitiveInformation: if (in->password == NULL) { return out; } out->password = talloc(out, struct netr_PasswordInfo); if (out->password == NULL) { talloc_free(out); return NULL; } *out->password = *in->password; return out; case NetlogonNetworkInformation: case NetlogonNetworkTransitiveInformation: break; case NetlogonGenericInformation: if (in->generic == NULL) { return out; } out->generic = talloc(out, struct netr_GenericInfo); if (out->generic == NULL) { talloc_free(out); return NULL; } *out->generic = *in->generic; if (in->generic->data == NULL) { return out; } if (in->generic->length == 0) { return out; } out->generic->data = talloc_memdup(out->generic, in->generic->data, in->generic->length); if (out->generic->data == NULL) { talloc_free(out); return NULL; } return out; } return out; } /* copy a netlogon_creds_CredentialState struct */ struct netlogon_creds_CredentialState *netlogon_creds_copy(TALLOC_CTX *mem_ctx, struct netlogon_creds_CredentialState *creds_in) { struct netlogon_creds_CredentialState *creds = talloc_zero(mem_ctx, struct netlogon_creds_CredentialState); if (!creds) { return NULL; } creds->sequence = creds_in->sequence; creds->negotiate_flags = creds_in->negotiate_flags; creds->secure_channel_type = creds_in->secure_channel_type; creds->computer_name = talloc_strdup(creds, creds_in->computer_name); if (!creds->computer_name) { talloc_free(creds); return NULL; } creds->account_name = talloc_strdup(creds, creds_in->account_name); if (!creds->account_name) { talloc_free(creds); return NULL; } if (creds_in->sid) { creds->sid = dom_sid_dup(creds, creds_in->sid); if (!creds->sid) { talloc_free(creds); return NULL; } } memcpy(creds->session_key, creds_in->session_key, sizeof(creds->session_key)); memcpy(creds->seed.data, creds_in->seed.data, sizeof(creds->seed.data)); memcpy(creds->client.data, creds_in->client.data, sizeof(creds->client.data)); memcpy(creds->server.data, creds_in->server.data, sizeof(creds->server.data)); return creds; }