/* * Copyright (c) 2006-2009 Bjorn Andersson , Erik Ekman * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #ifdef WINDOWS32 #include "windows.h" #include #else #include #ifdef DARWIN #include #endif #include #include #include #include #include #include #include #endif #include "common.h" #include "encoding.h" #include "base32.h" #include "base64.h" #include "dns.h" #include "login.h" #include "tun.h" #include "version.h" #ifdef WINDOWS32 WORD req_version = MAKEWORD(2, 2); WSADATA wsa_data; #endif #define PING_TIMEOUT(t) ((t) >= (conn == CONN_DNS_NULL ? 1 : 20)) static void send_ping(int fd); static void send_chunk(int fd); static void send_raw_data(int fd); static int build_hostname(char *buf, size_t buflen, const char *data, const size_t datalen, const char *topdomain, struct encoder *encoder); static int running = 1; static char password[33]; static struct sockaddr_in nameserv; static struct sockaddr_in raw_serv; static char *topdomain; static uint16_t rand_seed; static int downstream_seqno; static int downstream_fragment; static int down_ack_seqno; static int down_ack_fragment; /* Current up/downstream IP packet */ static struct packet outpkt; static struct packet inpkt; /* My userid at the server */ static char userid; /* DNS id for next packet */ static uint16_t chunkid; /* Base32 encoder used for non-data packets */ static struct encoder *b32; /* The encoder used for data packets * Defaults to Base32, can be changed after handshake */ static struct encoder *dataenc; /* My connection mode */ static enum connection conn; #if !defined(BSD) && !defined(__GLIBC__) static char *__progname; #endif static void sighandler(int sig) { running = 0; } static void send_query(int fd, char *hostname) { char packet[4096]; struct query q; size_t len; q.id = ++chunkid; q.type = T_NULL; len = dns_encode(packet, sizeof(packet), &q, QR_QUERY, hostname, strlen(hostname)); sendto(fd, packet, len, 0, (struct sockaddr*)&nameserv, sizeof(nameserv)); } static void send_raw(int fd, char *buf, int buflen, int user, int cmd) { char packet[4096]; int len; len = MIN(sizeof(packet) - RAW_HDR_LEN, buflen); memcpy(packet, raw_header, RAW_HDR_LEN); if (len) { memcpy(&packet[RAW_HDR_LEN], buf, len); } len += RAW_HDR_LEN; packet[RAW_HDR_CMD] = cmd | (user & 0x0F); sendto(fd, packet, len, 0, (struct sockaddr*)&raw_serv, sizeof(raw_serv)); } static void send_packet(int fd, char cmd, const char *data, const size_t datalen) { char buf[4096]; buf[0] = cmd; build_hostname(buf + 1, sizeof(buf) - 1, data, datalen, topdomain, b32); send_query(fd, buf); } static int build_hostname(char *buf, size_t buflen, const char *data, const size_t datalen, const char *topdomain, struct encoder *encoder) { int encsize; size_t space; char *b; space = MIN(0xFF, buflen) - strlen(topdomain) - 7; if (!encoder->places_dots()) space -= (space / 57); /* space for dots */ memset(buf, 0, buflen); encsize = encoder->encode(buf, &space, data, datalen); if (!encoder->places_dots()) inline_dotify(buf, buflen); b = buf; b += strlen(buf); if (*b != '.') *b++ = '.'; strncpy(b, topdomain, strlen(topdomain)+1); return space; } static int is_sending() { return (outpkt.len != 0); } static int read_dns(int dns_fd, int tun_fd, char *buf, int buflen) /* FIXME: tun_fd needed for raw handling */ { struct sockaddr_in from; char data[64*1024]; socklen_t addrlen; struct query q; int r; addrlen = sizeof(struct sockaddr); if ((r = recvfrom(dns_fd, data, sizeof(data), 0, (struct sockaddr*)&from, &addrlen)) == -1) { warn("recvfrom"); return 0; } if (conn == CONN_DNS_NULL) { int rv; rv = dns_decode(buf, buflen, &q, QR_ANSWER, data, r); /* decode the data header, update seqno and frag before next request */ if (rv >= 2) { downstream_seqno = (buf[1] >> 5) & 7; downstream_fragment = (buf[1] >> 1) & 15; } if (is_sending()) { if (chunkid == q.id) { /* Got ACK on sent packet */ outpkt.offset += outpkt.sentlen; if (outpkt.offset == outpkt.len) { /* Packet completed */ outpkt.offset = 0; outpkt.len = 0; outpkt.sentlen = 0; /* If the ack contains unacked frag number but no data, * send a ping to ack the frag number and get more data*/ if (rv == 2 && ( downstream_seqno != down_ack_seqno || downstream_fragment != down_ack_fragment )) { send_ping(dns_fd); } } else { /* More to send */ send_chunk(dns_fd); } } } return rv; } else { /* CONN_RAW_UDP */ unsigned long datalen; char buf[64*1024]; /* minimum length */ if (r < RAW_HDR_LEN) return 0; /* should start with header */ if (memcmp(data, raw_header, RAW_HDR_IDENT_LEN)) return 0; /* should be data packet */ if (RAW_HDR_GET_CMD(data) != RAW_HDR_CMD_DATA) return 0; /* should be my user id */ if (RAW_HDR_GET_USR(data) != userid) return 0; r -= RAW_HDR_LEN; datalen = sizeof(buf); if (uncompress((uint8_t*)buf, &datalen, (uint8_t*) &data[RAW_HDR_LEN], r) == Z_OK) { write_tun(tun_fd, buf, datalen); } return 0; } } static int tunnel_tun(int tun_fd, int dns_fd) { unsigned long outlen; unsigned long inlen; char out[64*1024]; char in[64*1024]; ssize_t read; if ((read = read_tun(tun_fd, in, sizeof(in))) <= 0) return -1; outlen = sizeof(out); inlen = read; compress2((uint8_t*)out, &outlen, (uint8_t*)in, inlen, 9); memcpy(outpkt.data, out, MIN(outlen, sizeof(outpkt.data))); outpkt.sentlen = 0; outpkt.offset = 0; outpkt.len = outlen; outpkt.seqno++; outpkt.fragment = 0; if (conn == CONN_DNS_NULL) { send_chunk(dns_fd); } else { send_raw_data(dns_fd); } return read; } static int tunnel_dns(int tun_fd, int dns_fd) { unsigned long datalen; char buf[64*1024]; size_t read; if ((read = read_dns(dns_fd, tun_fd, buf, sizeof(buf))) <= 2) return -1; if (downstream_seqno != inpkt.seqno) { /* New packet */ inpkt.seqno = downstream_seqno; inpkt.fragment = downstream_fragment; inpkt.len = 0; } else if (downstream_fragment <= inpkt.fragment) { /* Duplicate fragment */ return -1; } inpkt.fragment = downstream_fragment; datalen = MIN(read - 2, sizeof(inpkt.data) - inpkt.len); /* Skip 2 byte data header and append to packet */ memcpy(&inpkt.data[inpkt.len], &buf[2], datalen); inpkt.len += datalen; if (buf[1] & 1) { /* If last fragment flag is set */ /* Uncompress packet and send to tun */ datalen = sizeof(buf); if (uncompress((uint8_t*)buf, &datalen, (uint8_t*) inpkt.data, inpkt.len) == Z_OK) { write_tun(tun_fd, buf, datalen); } inpkt.len = 0; } /* If we have nothing to send, send a ping to get more data */ if (!is_sending()) send_ping(dns_fd); return read; } static int tunnel(int tun_fd, int dns_fd) { struct timeval tv; fd_set fds; int rv; int i; int seconds; rv = 0; seconds = 0; while (running) { tv.tv_sec = 1; tv.tv_usec = 0; FD_ZERO(&fds); if ((!is_sending()) || conn == CONN_RAW_UDP) { FD_SET(tun_fd, &fds); } FD_SET(dns_fd, &fds); i = select(MAX(tun_fd, dns_fd) + 1, &fds, NULL, NULL, &tv); if (running == 0) break; if (i < 0) err(1, "select"); if (i == 0) { /* timeout */ seconds++; } else { if (FD_ISSET(tun_fd, &fds)) { seconds = 0; if (tunnel_tun(tun_fd, dns_fd) <= 0) continue; } if (FD_ISSET(dns_fd, &fds)) { if (tunnel_dns(tun_fd, dns_fd) <= 0) continue; } } if (PING_TIMEOUT(seconds)) { send_ping(dns_fd); seconds = 0; } } return rv; } static void send_raw_data(int dns_fd) { send_raw(dns_fd, outpkt.data, outpkt.len, userid, RAW_HDR_CMD_DATA); } static void send_chunk(int fd) { char hex[] = "0123456789ABCDEF"; char buf[4096]; int avail; int code; char *p; p = outpkt.data; p += outpkt.offset; avail = outpkt.len - outpkt.offset; outpkt.sentlen = build_hostname(buf + 4, sizeof(buf) - 4, p, avail, topdomain, dataenc); /* Build upstream data header (see doc/proto_xxxxxxxx.txt) */ buf[0] = hex[userid & 15]; /* First byte is 4 bits userid */ code = ((outpkt.seqno & 7) << 2) | ((outpkt.fragment & 15) >> 2); buf[1] = b32_5to8(code); /* Second byte is 3 bits seqno, 2 upper bits fragment count */ code = ((outpkt.fragment & 3) << 3) | (downstream_seqno & 7); buf[2] = b32_5to8(code); /* Third byte is 2 bits lower fragment count, 3 bits downstream packet seqno */ code = ((downstream_fragment & 15) << 1) | (outpkt.sentlen == avail); buf[3] = b32_5to8(code); /* Fourth byte is 4 bits downstream fragment count, 1 bit last frag flag */ down_ack_seqno = downstream_seqno; down_ack_fragment = downstream_fragment; outpkt.fragment++; send_query(fd, buf); } static void send_login(int fd, char *login, int len) { char data[19]; memset(data, 0, sizeof(data)); data[0] = userid; memcpy(&data[1], login, MIN(len, 16)); data[17] = (rand_seed >> 8) & 0xff; data[18] = (rand_seed >> 0) & 0xff; rand_seed++; send_packet(fd, 'L', data, sizeof(data)); } static void send_ping(int fd) { if (conn == CONN_DNS_NULL) { char data[4]; if (is_sending()) { outpkt.sentlen = 0; outpkt.offset = 0; outpkt.len = 0; } data[0] = userid; data[1] = ((downstream_seqno & 7) << 4) | (downstream_fragment & 15); data[2] = (rand_seed >> 8) & 0xff; data[3] = (rand_seed >> 0) & 0xff; down_ack_seqno = downstream_seqno; down_ack_fragment = downstream_fragment; rand_seed++; send_packet(fd, 'P', data, sizeof(data)); } else { send_raw(fd, NULL, 0, userid, RAW_HDR_CMD_PING); } } static void send_fragsize_probe(int fd, int fragsize) { char probedata[256]; char buf[4096]; /* build a large query domain which is random and maximum size */ memset(probedata, MIN(1, rand_seed & 0xff), sizeof(probedata)); probedata[1] = MIN(1, (rand_seed >> 8) & 0xff); rand_seed++; build_hostname(buf + 4, sizeof(buf) - 4, probedata, sizeof(probedata), topdomain, dataenc); fragsize &= 2047; buf[0] = 'r'; /* Probe downstream fragsize packet */ buf[1] = b32_5to8((userid << 1) | ((fragsize >> 10) & 1)); buf[2] = b32_5to8((fragsize >> 5) & 31); buf[3] = b32_5to8(fragsize & 31); send_query(fd, buf); } static void send_set_downstream_fragsize(int fd, int fragsize) { char data[5]; data[0] = userid; data[1] = (fragsize & 0xff00) >> 8; data[2] = (fragsize & 0x00ff); data[3] = (rand_seed >> 8) & 0xff; data[4] = (rand_seed >> 0) & 0xff; rand_seed++; send_packet(fd, 'N', data, sizeof(data)); } static void send_version(int fd, uint32_t version) { char data[6]; data[0] = (version >> 24) & 0xff; data[1] = (version >> 16) & 0xff; data[2] = (version >> 8) & 0xff; data[3] = (version >> 0) & 0xff; data[4] = (rand_seed >> 8) & 0xff; data[5] = (rand_seed >> 0) & 0xff; rand_seed++; send_packet(fd, 'V', data, sizeof(data)); } static void send_ip_request(int fd, int userid) { char buf[512] = "I____."; buf[1] = b32_5to8(userid); buf[2] = b32_5to8((rand_seed >> 10) & 0x1f); buf[3] = b32_5to8((rand_seed >> 5) & 0x1f); buf[4] = b32_5to8((rand_seed ) & 0x1f); rand_seed++; strncat(buf, topdomain, 512 - strlen(buf)); send_query(fd, buf); } static void send_raw_udp_login(int dns_fd, int userid, int seed) { char buf[16]; login_calculate(buf, 16, password, seed + 1); send_raw(dns_fd, buf, sizeof(buf), userid, RAW_HDR_CMD_LOGIN); } static void send_case_check(int fd) { /* The '+' plus character is not allowed according to RFC. * Expect to get SERVFAIL or similar if it is rejected. */ char buf[512] = "zZ+-aAbBcCdDeEfFgGhHiIjJkKlLmMnNoOpPqQrRsStTuUvVwWxXyY1234."; strncat(buf, topdomain, 512 - strlen(buf)); send_query(fd, buf); } static void send_codec_switch(int fd, int userid, int bits) { char buf[512] = "S_____."; buf[1] = b32_5to8(userid); buf[2] = b32_5to8(bits); buf[3] = b32_5to8((rand_seed >> 10) & 0x1f); buf[4] = b32_5to8((rand_seed >> 5) & 0x1f); buf[5] = b32_5to8((rand_seed ) & 0x1f); rand_seed++; strncat(buf, topdomain, 512 - strlen(buf)); send_query(fd, buf); } static int handshake_version(int dns_fd, int *seed) { struct timeval tv; char in[4096]; fd_set fds; uint32_t payload; int i; int r; int read; for (i = 0; running && i < 5; i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_version(dns_fd, VERSION); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if(read <= 0) { if (read == 0) { warn("handshake read"); } /* if read < 0 then warning has been printed already */ continue; } if (read >= 9) { payload = (((in[4] & 0xff) << 24) | ((in[5] & 0xff) << 16) | ((in[6] & 0xff) << 8) | ((in[7] & 0xff))); if (strncmp("VACK", in, 4) == 0) { *seed = payload; userid = in[8]; fprintf(stderr, "Version ok, both using protocol v 0x%08x. You are user #%d\n", VERSION, userid); return 0; } else if (strncmp("VNAK", in, 4) == 0) { warnx("You use protocol v 0x%08x, server uses v 0x%08x. Giving up", VERSION, payload); return 1; } else if (strncmp("VFUL", in, 4) == 0) { warnx("Server full, all %d slots are taken. Try again later", payload); return 1; } } else warnx("did not receive proper login challenge"); } fprintf(stderr, "Retrying version check...\n"); } warnx("couldn't connect to server"); return 1; } static int handshake_login(int dns_fd, int seed) { struct timeval tv; char in[4096]; char login[16]; char server[65]; char client[65]; int mtu; fd_set fds; int i; int r; int read; login_calculate(login, 16, password, seed); for (i=0; running && i<5 ;i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_login(dns_fd, login, 16); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if(read <= 0) { warn("read"); continue; } if (read > 0) { int netmask; if (strncmp("LNAK", in, 4) == 0) { fprintf(stderr, "Bad password\n"); return 1; } else if (sscanf(in, "%64[^-]-%64[^-]-%d-%d", server, client, &mtu, &netmask) == 4) { server[64] = 0; client[64] = 0; if (tun_setip(client, netmask) == 0 && tun_setmtu(mtu) == 0) { return 0; } else { errx(4, "Failed to set IP and MTU"); } } else { fprintf(stderr, "Received bad handshake\n"); } } } fprintf(stderr, "Retrying login...\n"); } warnx("couldn't login to server"); return 1; } static int handshake_raw_udp(int dns_fd, int seed) { struct timeval tv; char in[4096]; fd_set fds; int i; int r; int len; unsigned remoteaddr = 0; struct in_addr server; fprintf(stderr, "Testing raw UDP data to the server (skip with -r)\n"); for (i=0; running && i<3 ;i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_ip_request(dns_fd, userid); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { len = read_dns(dns_fd, 0, in, sizeof(in)); if (len == 5 && in[0] == 'I') { /* Received IP address */ remoteaddr = (in[1] & 0xff); remoteaddr <<= 8; remoteaddr |= (in[2] & 0xff); remoteaddr <<= 8; remoteaddr |= (in[3] & 0xff); remoteaddr <<= 8; remoteaddr |= (in[4] & 0xff); server.s_addr = ntohl(remoteaddr); break; } } else { fprintf(stderr, "."); fflush(stderr); } } if (!remoteaddr) { fprintf(stderr, "Failed to get raw server IP, will use DNS mode.\n"); return 0; } fprintf(stderr, "Server is at %s, trying raw login: ", inet_ntoa(server)); fflush(stderr); /* Store address to iodined server */ memset(&raw_serv, 0, sizeof(raw_serv)); raw_serv.sin_family = AF_INET; raw_serv.sin_port = htons(53); raw_serv.sin_addr = server; /* do login against port 53 on remote server * based on the old seed. If reply received, * switch to raw udp mode */ for (i=0; running && i<4 ;i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_raw_udp_login(dns_fd, userid, seed); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { /* recv() needed for windows, dont change to read() */ len = recv(dns_fd, in, sizeof(in), 0); if (len >= (16 + RAW_HDR_LEN)) { char hash[16]; login_calculate(hash, 16, password, seed - 1); if (memcmp(in, raw_header, RAW_HDR_IDENT_LEN) == 0 && RAW_HDR_GET_CMD(in) == RAW_HDR_CMD_LOGIN && memcmp(&in[RAW_HDR_LEN], hash, sizeof(hash)) == 0) { fprintf(stderr, "OK\n"); return 1; } } } fprintf(stderr, "."); fflush(stderr); } fprintf(stderr, "failed\n"); return 0; } static int handshake_case_check(int dns_fd) { struct timeval tv; char in[4096]; fd_set fds; int i; int r; int read; int case_preserved; case_preserved = 0; for (i=0; running && i<5 ;i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_case_check(dns_fd); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if (read > 0) { if (in[0] == 'z' || in[0] == 'Z') { if (read < (27 * 2)) { fprintf(stderr, "Received short case check reply. Will use base32 encoder\n"); return case_preserved; } else { int k; /* TODO enhance this, base128 is probably also possible */ case_preserved = 1; for (k = 0; k < 27 && case_preserved; k += 2) { if (in[k] == in[k+1]) { /* test string: zZ+-aAbBcCdDeE... */ case_preserved = 0; } } return case_preserved; } } else { fprintf(stderr, "Received bad case check reply\n"); } } else { fprintf(stderr, "Got error on case check, will use base32\n"); return case_preserved; } } fprintf(stderr, "Retrying case check...\n"); } fprintf(stderr, "No reply on case check, continuing\n"); return case_preserved; } static void handshake_switch_codec(int dns_fd) { struct timeval tv; char in[4096]; fd_set fds; int i; int r; int read; dataenc = get_base64_encoder(); fprintf(stderr, "Switching to %s codec\n", dataenc->name); /* Send to server that this user will use base64 from now on */ for (i=0; running && i<5 ;i++) { int bits; tv.tv_sec = i + 1; tv.tv_usec = 0; bits = 6; /* base64 = 6 bits per byte */ send_codec_switch(dns_fd, userid, bits); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if (read > 0) { if (strncmp("BADLEN", in, 6) == 0) { fprintf(stderr, "Server got bad message length. "); goto codec_revert; } else if (strncmp("BADIP", in, 5) == 0) { fprintf(stderr, "Server rejected sender IP address. "); goto codec_revert; } else if (strncmp("BADCODEC", in, 8) == 0) { fprintf(stderr, "Server rejected the selected codec. "); goto codec_revert; } in[read] = 0; /* zero terminate */ fprintf(stderr, "Server switched to codec %s\n", in); return; } } fprintf(stderr, "Retrying codec switch...\n"); } fprintf(stderr, "No reply from server on codec switch. "); codec_revert: fprintf(stderr, "Falling back to base32\n"); dataenc = get_base32_encoder(); } static int handshake_autoprobe_fragsize(int dns_fd) { struct timeval tv; char in[4096]; fd_set fds; int i; int r; int read; int proposed_fragsize = 768; int range = 768; int max_fragsize = 0; max_fragsize = 0; fprintf(stderr, "Autoprobing max downstream fragment size... (skip with -m fragsize)\n"); while (running && range > 0 && (range >= 8 || !max_fragsize)) { for (i=0; running && i<3 ;i++) { tv.tv_sec = 1; tv.tv_usec = 0; send_fragsize_probe(dns_fd, proposed_fragsize); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if (read > 0) { /* We got a reply */ int acked_fragsize = ((in[0] & 0xff) << 8) | (in[1] & 0xff); if (acked_fragsize == proposed_fragsize) { if (read == proposed_fragsize) { fprintf(stderr, "%d ok.. ", acked_fragsize); fflush(stderr); max_fragsize = acked_fragsize; } } if (strncmp("BADIP", in, 5) == 0) { fprintf(stderr, "got BADIP.. "); fflush(stderr); } break; } } fprintf(stderr, "."); fflush(stderr); } range >>= 1; if (max_fragsize == proposed_fragsize) { /* Try bigger */ proposed_fragsize += range; } else { /* Try smaller */ fprintf(stderr, "%d not ok.. ", proposed_fragsize); fflush(stderr); proposed_fragsize -= range; } } if (!running) { fprintf(stderr, "\n"); warnx("stopped while autodetecting fragment size (Try probing manually with -m)"); return 0; } if (range == 0) { /* Tried all the way down to 2 and found no good size */ fprintf(stderr, "\n"); warnx("found no accepted fragment size. (Try probing manually with -m)"); return 0; } fprintf(stderr, "will use %d\n", max_fragsize); return max_fragsize; } static void handshake_set_fragsize(int dns_fd, int fragsize) { struct timeval tv; char in[4096]; fd_set fds; int i; int r; int read; fprintf(stderr, "Setting downstream fragment size to max %d...\n", fragsize); for (i=0; running && i<5 ;i++) { tv.tv_sec = i + 1; tv.tv_usec = 0; send_set_downstream_fragsize(dns_fd, fragsize); FD_ZERO(&fds); FD_SET(dns_fd, &fds); r = select(dns_fd + 1, &fds, NULL, NULL, &tv); if(r > 0) { read = read_dns(dns_fd, 0, in, sizeof(in)); if (read > 0) { int accepted_fragsize; if (strncmp("BADFRAG", in, 7) == 0) { fprintf(stderr, "Server rejected fragsize. Keeping default."); return; } else if (strncmp("BADIP", in, 5) == 0) { fprintf(stderr, "Server rejected sender IP address.\n"); return; } accepted_fragsize = ((in[0] & 0xff) << 8) | (in[1] & 0xff); return; } } fprintf(stderr, "Retrying set fragsize...\n"); } fprintf(stderr, "No reply from server when setting fragsize. Keeping default.\n"); } static int handshake(int dns_fd, int raw_mode, int autodetect_frag_size, int fragsize) { int seed; int case_preserved; int r; r = handshake_version(dns_fd, &seed); if (r) { return r; } r = handshake_login(dns_fd, seed); if (r) { return r; } if (raw_mode && handshake_raw_udp(dns_fd, seed)) { conn = CONN_RAW_UDP; } else { if (raw_mode == 0) { fprintf(stderr, "Skipping raw mode\n"); } case_preserved = handshake_case_check(dns_fd); if (case_preserved) { handshake_switch_codec(dns_fd); } if (autodetect_frag_size) { fragsize = handshake_autoprobe_fragsize(dns_fd); if (!fragsize) { return 1; } } handshake_set_fragsize(dns_fd, fragsize); } return 0; } static char * get_resolvconf_addr() { static char addr[16]; char *rv; #ifndef WINDOWS32 char buf[80]; FILE *fp; rv = NULL; if ((fp = fopen("/etc/resolv.conf", "r")) == NULL) err(1, "/etc/resolve.conf"); while (feof(fp) == 0) { fgets(buf, sizeof(buf), fp); if (sscanf(buf, "nameserver %15s", addr) == 1) { rv = addr; break; } } fclose(fp); #else /* !WINDOWS32 */ FIXED_INFO *fixed_info; ULONG buflen; DWORD ret; rv = NULL; fixed_info = malloc(sizeof(FIXED_INFO)); buflen = sizeof(FIXED_INFO); if (GetNetworkParams(fixed_info, &buflen) == ERROR_BUFFER_OVERFLOW) { /* official ugly api workaround */ free(fixed_info); fixed_info = malloc(buflen); } ret = GetNetworkParams(fixed_info, &buflen); if (ret == NO_ERROR) { strncpy(addr, fixed_info->DnsServerList.IpAddress.String, sizeof(addr)); addr[15] = 0; rv = addr; } free(fixed_info); #endif return rv; } static void set_nameserver(const char *cp) { struct in_addr addr; if (inet_aton(cp, &addr) != 1) errx(1, "error parsing nameserver address: '%s'", cp); memset(&nameserv, 0, sizeof(nameserv)); nameserv.sin_family = AF_INET; nameserv.sin_port = htons(53); nameserv.sin_addr = addr; } static void usage() { extern char *__progname; fprintf(stderr, "Usage: %s [-v] [-h] [-f] [-r] [-u user] [-t chrootdir] [-d device] " "[-P password] [-m maxfragsize] [-z context] [-F pidfile] " "[nameserver] topdomain\n", __progname); exit(2); } static void help() { extern char *__progname; fprintf(stderr, "iodine IP over DNS tunneling client\n"); fprintf(stderr, "Usage: %s [-v] [-h] [-f] [-r] [-u user] [-t chrootdir] [-d device] " "[-P password] [-m maxfragsize] [-z context] [-F pidfile] " "[nameserver] topdomain\n", __progname); fprintf(stderr, " -v to print version info and exit\n"); fprintf(stderr, " -h to print this help and exit\n"); fprintf(stderr, " -f to keep running in foreground\n"); fprintf(stderr, " -r to skip raw UDP mode attempt\n"); fprintf(stderr, " -u name to drop privileges and run as user 'name'\n"); fprintf(stderr, " -t dir to chroot to directory dir\n"); fprintf(stderr, " -d device to set tunnel device name\n"); fprintf(stderr, " -P password used for authentication (max 32 chars will be used)\n"); fprintf(stderr, " -m maxfragsize, to limit size of downstream packets\n"); fprintf(stderr, " -z context, to apply specified SELinux context after initialization\n"); fprintf(stderr, " -F pidfile to write pid to a file\n"); fprintf(stderr, "nameserver is the IP number of the relaying nameserver, if absent /etc/resolv.conf is used\n"); fprintf(stderr, "topdomain is the FQDN that is delegated to the tunnel endpoint.\n"); exit(0); } static void version() { char *svnver; svnver = "$Rev$ from $Date$"; fprintf(stderr, "iodine IP over DNS tunneling client\n"); fprintf(stderr, "SVN version: %s\n", svnver); exit(0); } int main(int argc, char **argv) { char *nameserv_addr; #ifndef WINDOWS32 struct passwd *pw; #endif char *username; int foreground; char *newroot; char *context; char *device; char *pidfile; int choice; int tun_fd; int dns_fd; int max_downstream_frag_size; int autodetect_frag_size; int retval; int raw_mode; memset(password, 0, 33); nameserv_addr = NULL; #ifndef WINDOWS32 pw = NULL; #endif username = NULL; foreground = 0; newroot = NULL; context = NULL; device = NULL; chunkid = 0; pidfile = NULL; outpkt.seqno = 0; inpkt.len = 0; autodetect_frag_size = 1; max_downstream_frag_size = 3072; raw_mode = 1; b32 = get_base32_encoder(); dataenc = get_base32_encoder(); conn = CONN_DNS_NULL; retval = 0; #ifdef WINDOWS32 WSAStartup(req_version, &wsa_data); #endif srand((unsigned) time(NULL)); rand_seed = rand(); #if !defined(BSD) && !defined(__GLIBC__) __progname = strrchr(argv[0], '/'); if (__progname == NULL) __progname = argv[0]; else __progname++; #endif while ((choice = getopt(argc, argv, "vfhru:t:d:P:m:F:")) != -1) { switch(choice) { case 'v': version(); /* NOTREACHED */ break; case 'f': foreground = 1; break; case 'h': help(); /* NOTREACHED */ break; case 'r': raw_mode = 0; case 'u': username = optarg; break; case 't': newroot = optarg; break; case 'd': device = optarg; break; case 'P': strncpy(password, optarg, sizeof(password)); password[sizeof(password)-1] = 0; /* XXX: find better way of cleaning up ps(1) */ memset(optarg, 0, strlen(optarg)); break; case 'm': autodetect_frag_size = 0; max_downstream_frag_size = atoi(optarg); break; case 'z': context = optarg; break; case 'F': pidfile = optarg; break; default: usage(); /* NOTREACHED */ } } check_superuser(usage); argc -= optind; argv += optind; switch (argc) { case 1: nameserv_addr = get_resolvconf_addr(); topdomain = strdup(argv[0]); break; case 2: nameserv_addr = argv[0]; topdomain = strdup(argv[1]); break; default: usage(); /* NOTREACHED */ } if (max_downstream_frag_size < 1 || max_downstream_frag_size > 0xffff) { warnx("Use a max frag size between 1 and 65535 bytes.\n"); usage(); /* NOTREACHED */ } if (nameserv_addr) { set_nameserver(nameserv_addr); } else { usage(); /* NOTREACHED */ } if (strlen(topdomain) <= 128) { if(check_topdomain(topdomain)) { warnx("Topdomain contains invalid characters.\n"); usage(); /* NOTREACHED */ } } else { warnx("Use a topdomain max 128 chars long.\n"); usage(); /* NOTREACHED */ } if (username != NULL) { #ifndef WINDOWS32 if ((pw = getpwnam(username)) == NULL) { warnx("User %s does not exist!\n", username); usage(); /* NOTREACHED */ } #endif } if (strlen(password) == 0) read_password(password, sizeof(password)); if ((tun_fd = open_tun(device)) == -1) { retval = 1; goto cleanup1; } if ((dns_fd = open_dns(0, INADDR_ANY)) == -1) { retval = 1; goto cleanup2; } signal(SIGINT, sighandler); signal(SIGTERM, sighandler); if (handshake(dns_fd, raw_mode, autodetect_frag_size, max_downstream_frag_size)) { retval = 1; goto cleanup2; } if (conn == CONN_DNS_NULL) { fprintf(stderr, "Sending queries for %s to %s\n", topdomain, nameserv_addr); } else { fprintf(stderr, "Sending raw traffic directly to %s\n", inet_ntoa(raw_serv.sin_addr)); } if (foreground == 0) do_detach(); if (pidfile != NULL) do_pidfile(pidfile); if (newroot != NULL) do_chroot(newroot); if (username != NULL) { #ifndef WINDOWS32 gid_t gids[1]; gids[0] = pw->pw_gid; if (setgroups(1, gids) < 0 || setgid(pw->pw_gid) < 0 || setuid(pw->pw_uid) < 0) { warnx("Could not switch to user %s!\n", username); usage(); /* NOTREACHED */ } #endif } if (context != NULL) do_setcon(context); downstream_seqno = 0; downstream_fragment = 0; down_ack_seqno = 0; down_ack_fragment = 0; tunnel(tun_fd, dns_fd); cleanup2: close_dns(dns_fd); close_tun(tun_fd); cleanup1: return retval; }