#include "common-static.h" #include "option.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __linux__ # include # include #endif #include #ifndef O_CLOEXEC #define O_CLOEXEC 0 #endif #define GT_BUFFER_SIZE (4*1024*1024) struct netio { int fd; struct { buffer_t buf; ssize_t ret; } write, read; }; struct crypto_ctx { crypto_aead_aes256gcm_state state; uint8_t nonce_r[crypto_aead_aes256gcm_NPUBBYTES]; uint8_t nonce_w[crypto_aead_aes256gcm_NPUBBYTES]; uint8_t skey[crypto_generichash_KEYBYTES]; }; volatile sig_atomic_t running; static void gt_not_available (const char *name) { fprintf(stderr, "%s is not available on your platform!\n", name); } static int64_t dt_ms (struct timeval *ta, struct timeval *tb) { const int64_t s = ta->tv_sec-tb->tv_sec; const int64_t n = ta->tv_usec-tb->tv_usec; return s*1000LL+n/1000LL; } static void fd_set_nonblock (int fd) { int ret; do { ret = fcntl(fd, F_GETFL, 0); } while (ret==-1 && errno==EINTR); int flags = (ret==-1)?0:ret; do { ret = fcntl(fd, F_SETFL, flags|O_NONBLOCK); } while (ret==-1 && errno==EINTR); if (ret==-1) perror("fcntl O_NONBLOCK"); } static void sk_set_nodelay (int fd) { int val = 1; if (setsockopt(fd, IPPROTO_TCP, TCP_NODELAY , &val, sizeof(val))==-1) perror("setsockopt TCP_NODELAY"); } static void sk_set_reuseaddr (int fd) { int val = 1; if (setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &val, sizeof(val))==-1) perror("setsockopt SO_REUSEADDR"); } #ifdef TCP_CONGESTION static void sk_set_congestion (int fd, const char *name) { size_t len = str_len(name); if (!len) return; if (setsockopt(fd, IPPROTO_TCP, TCP_CONGESTION, name, len+1)==-1) perror("setsockopt TCP_CONGESTION"); } #else static void sk_set_congestion (_unused_ int fd, _unused_ const char *name) { gt_not_available("TCP_CONGESTION"); } #endif static int sk_listen (int fd, struct addrinfo *ai) { sk_set_reuseaddr(fd); int ret = bind(fd, ai->ai_addr, ai->ai_addrlen); if (ret==-1) { perror("bind"); return -1; } ret = listen(fd, 1); if (ret==-1) { perror("listen"); return -1; } return 0; } static int sk_connect (int fd, struct addrinfo *ai) { int ret = connect(fd, ai->ai_addr, ai->ai_addrlen); if (ret==-1 && errno==EINTR) return 0; return ret; } static int sk_create (struct addrinfo *res, int(*func)(int, struct addrinfo *)) { for (struct addrinfo *ai=res; ai; ai=ai->ai_next) { int fd = socket(ai->ai_family, ai->ai_socktype, ai->ai_protocol); if (fd==-1) continue; if (func(fd, ai)!=-1) return fd; close(fd); } return -1; } static int sk_accept (int fd) { struct sockaddr_storage addr; socklen_t addr_size = sizeof(addr); int ret = accept(fd, (struct sockaddr *)&addr, &addr_size); if (ret==-1 && errno!=EINTR) perror("accept"); return ret; } static char *sk_get_name (int fd) { struct sockaddr_storage addr; socklen_t addr_size = sizeof(addr); if (getpeername(fd, (struct sockaddr *)&addr, &addr_size)==-1) { perror("getpeername"); return NULL; } char host[64] = {0}; char port[32] = {0}; int ret = getnameinfo((struct sockaddr *)&addr, addr_size, host, sizeof(host), port, sizeof(port), NI_NUMERICHOST|NI_NUMERICSERV); switch (ret) { case 0: break; case EAI_MEMORY: errno = ENOMEM; case EAI_SYSTEM: perror("getnameinfo"); return NULL; } const char *const strs[] = { host, ".", port }; return str_cat(strs, COUNT(strs)); } #ifdef TCP_INFO static socklen_t sk_get_info (int fd, struct tcp_info *ti) { socklen_t len = sizeof(struct tcp_info); if (getsockopt(fd, SOL_TCP, TCP_INFO, ti, &len)==-1) { perror("getsockopt TCP_INFO"); return 0; } return len; } static void print_tcp_info (struct tcp_info *ti) { fprintf(stderr, "tcpinfo" " rto:%" PRIu32 " ato:%" PRIu32 " snd_mss:%" PRIu32 " rcv_mss:%" PRIu32 " unacked:%" PRIu32 " sacked:%" PRIu32 " lost:%" PRIu32 " retrans:%" PRIu32 " fackets:%" PRIu32 " pmtu:%" PRIu32 " rcv_ssthresh:%" PRIu32 " rtt:%" PRIu32 " rttvar:%" PRIu32 " snd_ssthresh:%" PRIu32 " snd_cwnd:%" PRIu32 " advmss:%" PRIu32 " reordering:%" PRIu32 "\n", ti->tcpi_rto, ti->tcpi_ato, ti->tcpi_snd_mss, ti->tcpi_rcv_mss, ti->tcpi_unacked, ti->tcpi_sacked, ti->tcpi_lost, ti->tcpi_retrans, ti->tcpi_fackets, ti->tcpi_pmtu, ti->tcpi_rcv_ssthresh, ti->tcpi_rtt, ti->tcpi_rttvar, ti->tcpi_snd_ssthresh, ti->tcpi_snd_cwnd, ti->tcpi_advmss, ti->tcpi_reordering); } #endif static struct addrinfo *ai_create (const char *host, const char *port, int listener) { if (!port || !port[0]) { fprintf(stderr, "port is not valid\n"); return NULL; } struct addrinfo hints = { .ai_family = AF_UNSPEC, .ai_socktype = SOCK_STREAM, .ai_protocol = IPPROTO_TCP, }; if (listener) hints.ai_flags = AI_PASSIVE; struct addrinfo *ai = NULL; int ret = getaddrinfo(host, port, &hints, &ai); switch (ret) { case 0: return ai; case EAI_MEMORY: errno = ENOMEM; case EAI_SYSTEM: perror("getaddrinfo"); break; case EAI_FAIL: case EAI_AGAIN: fprintf(stderr, "the name server returned a failure\n"); break; default: fprintf(stderr, "%s.%s is not valid\n", host?:"", port); } return NULL; } #ifdef __linux__ static int tun_create (char *name, int multiqueue) { int fd = open("/dev/net/tun", O_RDWR); if (fd<0) { perror("open /dev/net/tun"); return -1; } struct ifreq ifr = { .ifr_flags = IFF_TUN|IFF_NO_PI, }; if (multiqueue) { #ifdef IFF_MULTI_QUEUE ifr.ifr_flags |= IFF_MULTI_QUEUE; #else gt_not_available("IFF_MULTI_QUEUE"); #endif } str_cpy(ifr.ifr_name, name, IFNAMSIZ-1); int ret = ioctl(fd, TUNSETIFF, &ifr); if (ret<0) { perror("ioctl TUNSETIFF"); return -1; } printf("tun name: %s\n", ifr.ifr_name); return fd; } #else static int tun_create (_unused_ char *name, _unused_ int mq) { for (unsigned dev_id = 0U; dev_id < 32U; dev_id++) { char dev_path[11U]; snprintf(dev_path, sizeof(dev_path), "/dev/tun%u", dev_id); int fd = open(dev_path, O_RDWR); if (fd!=-1) return fd; } return -1; } #endif static void gt_sa_stop (int sig) { switch (sig) { case SIGINT: case SIGTERM: running = 0; } } static void gt_set_signal (void) { struct sigaction sa; byte_set(&sa, 0, sizeof(sa)); running = 1; sa.sa_handler = gt_sa_stop; sigaction(SIGINT, &sa, NULL); sigaction(SIGTERM, &sa, NULL); sa.sa_handler = SIG_IGN; sigaction(SIGHUP, &sa, NULL); sigaction(SIGPIPE, &sa, NULL); } static ssize_t fd_read (int fd, void *data, size_t size) { if (!size) return -2; ssize_t ret = read(fd, data, size); if (ret==-1) { if (errno==EAGAIN || errno==EINTR) return -1; if (errno) perror("read"); return 0; } return ret; } static ssize_t fd_write (int fd, const void *data, size_t size) { if (!size) return -2; ssize_t ret = write(fd, data, size); if (ret==-1) { if (errno==EAGAIN || errno==EINTR) return -1; if (errno) perror("write"); return 0; } return ret; } static ssize_t fd_read_all (int fd, void *data, size_t size) { size_t done = 0; struct pollfd pollfd = { .fd = fd, .events = POLLIN, }; while (donewrite, packet, size); crypto_aead_aes256gcm_encrypt_afternm( buffer->write + hs, NULL, packet + hs, size - hs, packet, hs, NULL, ctx->nonce_w, (const crypto_aead_aes256gcm_state *)&ctx->state); sodium_increment(ctx->nonce_w, crypto_aead_aes256gcm_NPUBBYTES); buffer->write += ws; return 0; } static int decrypt_packet (struct crypto_ctx *ctx, uint8_t *packet, size_t size, buffer_t *buffer) { const size_t rs = size + crypto_aead_aes256gcm_ABYTES; if (buffer_read_size(buffer) < rs) return 1; const int hs = 4; byte_cpy(packet, buffer->read, hs); if (crypto_aead_aes256gcm_decrypt_afternm( packet + hs, NULL, NULL, buffer->read + hs, rs - hs, packet, hs, ctx->nonce_r, (const crypto_aead_aes256gcm_state *)&ctx->state)) return -1; sodium_increment(ctx->nonce_r, crypto_aead_aes256gcm_NPUBBYTES); buffer->read += rs; return 0; } static void dump_ip_header (uint8_t *data, size_t size) { if (size<20) return; const char tbl[] = "0123456789ABCDEF"; char hex[41]; for (size_t i=0; i<20; i++) { hex[(i<<1)+0] = tbl[0xF&(data[i]>>4)]; hex[(i<<1)+1] = tbl[0xF&(data[i])]; } hex[40] = 0; fprintf(stderr, "DUMP(%zu): %s\n", size, hex); } static void set_ip_size (uint8_t *data, size_t size) { data[2] = 0xFF&(size>>8); data[3] = 0xFF&(size); } static ssize_t get_ip_size (const uint8_t *data, size_t size) { if (size<20) return -1; if ((data[0]>>4)==4) return (data[2]<<8)|data[3]; return 0; } static int gt_setup_secretkey (struct crypto_ctx *ctx, char *keyfile) { size_t size = sizeof(ctx->skey); byte_set(ctx->skey, 1, size); if (!keyfile) return 0; int fd = open(keyfile, O_RDONLY|O_CLOEXEC); if (fd<0) { perror("open keyfile"); return -1; } if (fd_read_all(fd, ctx->skey, size)!=size) { fprintf(stderr, "unable to read secret key in `%s'\n", keyfile); close(fd); return -1; } // TODO: check key close(fd); return 0; } static int gt_setup_crypto (struct crypto_ctx *ctx, int fd, int listener) { const size_t nonce_size = crypto_aead_aes256gcm_NPUBBYTES; const size_t public_size = crypto_scalarmult_SCALARBYTES; const size_t hkey_size = crypto_generichash_BYTES; const size_t size = nonce_size + public_size + hkey_size; uint8_t secret[crypto_scalarmult_SCALARBYTES]; uint8_t shared[crypto_scalarmult_BYTES]; uint8_t key[crypto_aead_aes256gcm_KEYBYTES]; uint8_t data_r[size], data_w[size], data_x[size]; uint8_t hkey_c[hkey_size]; randombytes_buf(data_w, nonce_size); randombytes_buf(secret, sizeof(secret)); crypto_scalarmult_base(&data_w[nonce_size], secret); crypto_generichash(&data_w[size-hkey_size], hkey_size, data_w, size-hkey_size, ctx->skey, sizeof(ctx->skey)); if (!listener && fd_write_all(fd, data_w, size)!=size) return -1; if (fd_read_all(fd, data_r, size)!=size) return -1; crypto_generichash(hkey_c, hkey_size, data_r, size-hkey_size, ctx->skey, sizeof(ctx->skey)); if (sodium_memcmp(&data_r[size-hkey_size], hkey_c, hkey_size)) return -2; if (listener && fd_write_all(fd, data_w, size)!=size) return -1; for (size_t i=0; iskey, sizeof(ctx->skey), sizeof(key)); crypto_generichash_update(&state, shared, sizeof(shared)); crypto_generichash_update(&state, data_x, size); crypto_generichash_final(&state, key, sizeof(key)); crypto_aead_aes256gcm_beforenm(&ctx->state, key); sodium_memzero(secret, sizeof(secret)); sodium_memzero(shared, sizeof(shared)); sodium_memzero(key, sizeof(key)); byte_cpy(ctx->nonce_r, data_r, nonce_size); byte_cpy(ctx->nonce_w, data_w, nonce_size); return 0; } int main (int argc, char **argv) { gt_set_signal(); int listener = 0; char *host = NULL; char *port = "5000"; char *dev = PACKAGE_NAME; char *keyfile = NULL; char *congestion = NULL; int nodelay = 0; int multiqueue = 0; int version = 0; #ifdef TCP_INFO struct { struct timeval time; struct tcp_info info; } tcpinfo = {0}; #endif struct option opts[] = { { "listener", &listener, option_flag }, { "host", &host, option_str }, { "port", &port, option_str }, { "dev", &dev, option_str }, { "keyfile", &keyfile, option_str }, { "congestion", &congestion, option_str }, { "nodelay", &nodelay, option_flag }, { "multiqueue", &multiqueue, option_flag }, { "version", &version, option_flag }, { NULL }, }; if (option(opts, argc, argv)) return 1; if (version) { printf(PACKAGE_STRING"\n"); return 0; } if (sodium_init()==-1) { fprintf(stderr, "libsodium initialization has failed!\n"); return 1; } if (!crypto_aead_aes256gcm_is_available()) { gt_not_available("AES-256-GCM"); return 1; } struct crypto_ctx ctx; if (gt_setup_secretkey(&ctx, keyfile)) return 1; struct addrinfo *ai = ai_create(host, port, listener); if (!ai) return 1; struct netio tun = { .fd = -1 }; struct netio sock = { .fd = -1 }; tun.fd = tun_create(dev, multiqueue); if (tun.fd==-1) return 1; fd_set_nonblock(tun.fd); buffer_setup(&sock.write.buf, NULL, GT_BUFFER_SIZE); buffer_setup(&sock.read.buf, NULL, GT_BUFFER_SIZE); int fd = -1; if (listener) { fd = sk_create(ai, sk_listen); if (fd==-1) return 1; } while (running) { sock.fd = listener?sk_accept(fd):sk_create(ai, sk_connect); if (sock.fd==-1) { usleep(100000); continue; } char *sockname = sk_get_name(sock.fd); if (!sockname) goto restart; fprintf(stderr, "%s: connected\n", sockname); if (nodelay) sk_set_nodelay(sock.fd); fd_set_nonblock(sock.fd); sk_set_congestion(sock.fd, congestion); switch (gt_setup_crypto(&ctx, sock.fd, listener)) { case -2: fprintf(stderr, "%s: key exchange could not be verified!\n", sockname); case -1: goto restart; default: break; } struct pollfd fds[] = { { .fd = tun.fd, .events = POLLIN }, { .fd = sock.fd, .events = POLLIN }, }; struct { uint8_t buf[2048]; size_t size; } tunr, tunw; tunr.size = 0; tunw.size = 0; while (running) { if (poll(fds, COUNT(fds), -1)==-1 && errno!=EINTR) { perror("poll"); return 1; } #ifdef TCP_INFO struct timeval now; gettimeofday(&now, NULL); if (dt_ms(&now, &tcpinfo.time)>1000LL) { tcpinfo.time = now; if (sk_get_info(sock.fd, &tcpinfo.info)) print_tcp_info(&tcpinfo.info); } #endif buffer_shift(&sock.write.buf); if (fds[0].revents & POLLIN) { while (1) { if (buffer_write_size(&sock.write.buf)0) sock.write.buf.read += sock.write.ret; } buffer_shift(&sock.read.buf); if (fds[1].revents & POLLIN) { sock.read.ret = fd_read(fds[1].fd, sock.read.buf.write, buffer_write_size(&sock.read.buf)); if (!sock.read.ret) goto restart; if (sock.read.ret>0) sock.read.buf.write += sock.read.ret; } if (fds[0].revents & POLLOUT) fds[0].events = POLLIN; while (1) { if (!tunw.size) { size_t size = buffer_read_size(&sock.read.buf); ssize_t ip_size = get_ip_size(sock.read.buf.read, size); if (!ip_size) goto restart; if (ip_size<0 || (size_t)ip_size+16>size) break; if (decrypt_packet(&ctx, tunw.buf, ip_size, &sock.read.buf)) { fprintf(stderr, "%s: message could not be verified!\n", sockname); goto restart; } tunw.size = ip_size; } if (tunw.size) { ssize_t r = fd_write(fds[0].fd, tunw.buf, tunw.size); if (!r) return 2; if (r==-1) fds[0].events = POLLIN|POLLOUT; if (r<0) break; tunw.size = 0; } } } restart: if (sockname) { free(sockname); sockname = NULL; } close(sock.fd); sock.fd = -1; } freeaddrinfo(ai); free(sock.write.buf.data); free(sock.read.buf.data); return 0; }