// Send a Key EXchange record, containing a random nonce and an ECDHE public key. static bool send_kex(sptps_t *s) { size_t keylen = ECDH_SIZE; // Make room for our KEX message, which we will keep around since send_sig() needs it. if(s->mykex) return false; s->mykex = realloc(s->mykex, 1 + 32 + keylen); if(!s->mykex) return error(s, errno, strerror(errno)); // Set version byte to zero. s->mykex[0] = SPTPS_VERSION; // Create a random nonce. randomize(s->mykex + 1, 32); // Create a new ECDH public key. if(!(s->ecdh = ecdh_generate_public(s->mykex + 1 + 32))) return error(s, EINVAL, "Failed to generate ECDH public key"); return send_record_priv(s, SPTPS_HANDSHAKE, s->mykex, 1 + 32 + keylen); }
int main(int argc, char *argv[]) { ecdsa_t *key1, *key2; ecdh_t *ecdh1, *ecdh2; sptps_t sptps1, sptps2; char buf1[4096], buf2[4096], buf3[4096]; double duration = argc > 1 ? atof(argv[1]) : 10; crypto_init(); randomize(buf1, sizeof buf1); randomize(buf2, sizeof buf2); randomize(buf3, sizeof buf3); // Key generation fprintf(stderr, "Generating keys for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) ecdsa_free(ecdsa_generate()); fprintf(stderr, "%17.2lf op/s\n", rate); key1 = ecdsa_generate(); key2 = ecdsa_generate(); // Ed25519 signatures fprintf(stderr, "Ed25519 sign for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) if(!ecdsa_sign(key1, buf1, 256, buf2)) return 1; fprintf(stderr, "%20.2lf op/s\n", rate); fprintf(stderr, "Ed25519 verify for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) if(!ecdsa_verify(key1, buf1, 256, buf2)) { fprintf(stderr, "Signature verification failed\n"); return 1; } fprintf(stderr, "%18.2lf op/s\n", rate); ecdh1 = ecdh_generate_public(buf1); fprintf(stderr, "ECDH for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) { ecdh2 = ecdh_generate_public(buf2); if(!ecdh2) return 1; if(!ecdh_compute_shared(ecdh2, buf1, buf3)) return 1; } fprintf(stderr, "%28.2lf op/s\n", rate); ecdh_free(ecdh1); // SPTPS authentication phase int fd[2]; if(socketpair(AF_UNIX, SOCK_STREAM, 0, fd)) { fprintf(stderr, "Could not create a UNIX socket pair: %s\n", sockstrerror(sockerrno)); return 1; } struct pollfd pfd[2] = {{fd[0], POLLIN}, {fd[1], POLLIN}}; fprintf(stderr, "SPTPS/TCP authenticate for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) { sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record); sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record); while(poll(pfd, 2, 0)) { if(pfd[0].revents) receive_data(&sptps1); if(pfd[1].revents) receive_data(&sptps2); } sptps_stop(&sptps1); sptps_stop(&sptps2); } fprintf(stderr, "%10.2lf op/s\n", rate * 2); // SPTPS data sptps_start(&sptps1, fd + 0, true, false, key1, key2, "sptps_speed", 11, send_data, receive_record); sptps_start(&sptps2, fd + 1, false, false, key2, key1, "sptps_speed", 11, send_data, receive_record); while(poll(pfd, 2, 0)) { if(pfd[0].revents) receive_data(&sptps1); if(pfd[1].revents) receive_data(&sptps2); } fprintf(stderr, "SPTPS/TCP transmit for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) { if(!sptps_send_record(&sptps1, 0, buf1, 1451)) abort(); receive_data(&sptps2); } rate *= 2 * 1451 * 8; if(rate > 1e9) fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9); else if(rate > 1e6) fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6); else if(rate > 1e3) fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3); sptps_stop(&sptps1); sptps_stop(&sptps2); // SPTPS datagram authentication phase close(fd[0]); close(fd[1]); if(socketpair(AF_UNIX, SOCK_DGRAM, 0, fd)) { fprintf(stderr, "Could not create a UNIX socket pair: %s\n", sockstrerror(sockerrno)); return 1; } fprintf(stderr, "SPTPS/UDP authenticate for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) { sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record); sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record); while(poll(pfd, 2, 0)) { if(pfd[0].revents) receive_data(&sptps1); if(pfd[1].revents) receive_data(&sptps2); } sptps_stop(&sptps1); sptps_stop(&sptps2); } fprintf(stderr, "%10.2lf op/s\n", rate * 2); // SPTPS datagram data sptps_start(&sptps1, fd + 0, true, true, key1, key2, "sptps_speed", 11, send_data, receive_record); sptps_start(&sptps2, fd + 1, false, true, key2, key1, "sptps_speed", 11, send_data, receive_record); while(poll(pfd, 2, 0)) { if(pfd[0].revents) receive_data(&sptps1); if(pfd[1].revents) receive_data(&sptps2); } fprintf(stderr, "SPTPS/UDP transmit for %lg seconds: ", duration); for(clock_start(); clock_countto(duration);) { if(!sptps_send_record(&sptps1, 0, buf1, 1451)) abort(); receive_data(&sptps2); } rate *= 2 * 1451 * 8; if(rate > 1e9) fprintf(stderr, "%14.2lf Gbit/s\n", rate / 1e9); else if(rate > 1e6) fprintf(stderr, "%14.2lf Mbit/s\n", rate / 1e6); else if(rate > 1e3) fprintf(stderr, "%14.2lf kbit/s\n", rate / 1e3); sptps_stop(&sptps1); sptps_stop(&sptps2); // Clean up close(fd[0]); close(fd[1]); ecdsa_free(key1); ecdsa_free(key2); crypto_exit(); return 0; }