#include "sgx_eid.h" #define __STDC_FORMAT_MACROS #include #include "ProtobufLAMessages.h" #include #include "sgx_trts.h" #include "sgx_utils.h" #include "error_codes.h" #include "sgx_ecp_types.h" #include "sgx_thread.h" #include #include "sgx_dh.h" #include "dh_session_protocol.h" #include "sgx_tcrypto.h" #include "datatypes.h" #include "SgxProtobufLAInitiator_Transforms.h" #define MAX_SESSION_COUNT 16 #define SGX_CAST(type, item) ((type)(item)) #include #include "crypto.h" #include "stdio.h" dh_session_t global_session_info; sgx_dh_session_t sgx_dh_session; // sgx_key_128bit_t dh_aek; // Session Key uint32_t verify_peer_enclave_trust(sgx_dh_session_enclave_identity_t* peer_enclave_identity, uint8_t* expected_mr_enclave, uint8_t* expected_mr_signer); uint32_t process_protobuf_dh_msg1_generate_protobuf_dh_msg2(protobuf_sgx_dh_msg1_t& protobuf_msg1, protobuf_sgx_dh_msg2_t& protobuf_msg2, uint32_t* session_id) { sgx_dh_msg1_t dh_msg1; //Diffie-Hellman Message 1 sgx_dh_msg2_t dh_msg2; memset(&dh_msg1, 0, sizeof(sgx_dh_msg1_t)); uint32_t ret_status; if(decode_msg1_from_protobuf(protobuf_msg1, &dh_msg1)!=0) return -1; //Intialize the session as a session initiator ret_status = sgx_dh_init_session(SGX_DH_SESSION_INITIATOR, &sgx_dh_session); if(ret_status != SGX_SUCCESS) return ret_status; //Process the message 1 obtained from desination enclave and generate message 2 ret_status = sgx_dh_initiator_proc_msg1(&dh_msg1, &dh_msg2, &sgx_dh_session); if(SGX_SUCCESS != ret_status) return ret_status; encode_msg2_to_protobuf(protobuf_msg2, &dh_msg2); return 0; } uint32_t process_protobuf_dh_msg3(protobuf_sgx_dh_msg3_t& protobuf_msg3, uint32_t* session_id) { uint32_t ret_status; sgx_dh_msg3_t dh_msg3; sgx_key_128bit_t dh_aek; // Session Key sgx_dh_session_enclave_identity_t responder_identity; memset(&dh_aek,0, sizeof(sgx_key_128bit_t)); if(decode_msg3_from_protobuf(protobuf_msg3, &dh_msg3)!=0) return -1; //Process Message 3 obtained from the destination enclave ret_status = sgx_dh_initiator_proc_msg3(&dh_msg3, &sgx_dh_session, &dh_aek, &responder_identity); if(SGX_SUCCESS != ret_status) return ret_status; // Verify the identity of the destination enclave ret_status = verify_peer_enclave_trust(&responder_identity, NULL, NULL); if(ret_status != 0) return ret_status; memcpy(global_session_info.active.AEK, &dh_aek, sizeof(sgx_key_128bit_t)); global_session_info.session_id = 1; // TODO: session_id; global_session_info.active.counter = 0; global_session_info.status = ACTIVE; memset(&dh_aek,0, sizeof(sgx_key_128bit_t)); return 0; } uint32_t generate_encrypted_rsa_keypair_hash() { uint8_t hash[32]; uint32_t return_status; unsigned char key[16]; uint32_t count; for(count=0;count<16;count++) key[count]=global_session_info.active.AEK[count]; return_status=generate_rsa_keypair_hash(hash); if(return_status!=0) return return_status; uint8_t ciphertext[48]; uint8_t expected_plaintext[48]; uint8_t encryption_tag[16]; uint8_t decryption_tag[16]; int ciphertext_len=48; int plaintext_len=32; uint8_t iv[12]; memset(ciphertext, 0, 48); memset(expected_plaintext, 0, 48); memset(iv, 0, 12); memset(expected_plaintext, 0, 32); memset(encryption_tag, 0, 16); memset(decryption_tag, 0, 16); return_status=aes_cipher(1, key, iv, hash, 32, ciphertext, &ciphertext_len, encryption_tag); printf("ciphertext len: %d\n", ciphertext_len); fflush(stdout); printf("Encryption return status: 0x%x", return_status); fflush(stdout); return_status=aes_cipher(0, key, iv, ciphertext, ciphertext_len, expected_plaintext, &plaintext_len, encryption_tag); // for(count=0;count<16;count++) // { // if(encryption_tag[count]!=decryption_tag[count]) // return 0xFF; // printf("0x%x 0x%x ", encryption_tag[count], decryption_tag[count]); // } // printf("\n"); // fflush(stdout); for(count=0;count<32;count++) { printf("0x%x 0x%x ", hash[count], expected_plaintext[count]); // if(hash[count]!=expected_plaintext[count]) // return 0xFE; } fflush(stdout); return return_status; } // TODO: Private function uint32_t verify_peer_enclave_trust(sgx_dh_session_enclave_identity_t* peer_enclave_identity, uint8_t* expected_mr_enclave, uint8_t* expected_mr_signer) { int count=0; if(!peer_enclave_identity) return INVALID_PARAMETER_ERROR; sgx_measurement_t actual_mr_enclave = peer_enclave_identity->mr_enclave; sgx_measurement_t actual_mr_signer = peer_enclave_identity->mr_signer; if(expected_mr_enclave != NULL) { for(count=0; count