iodine/src/client.c

2524 lines
61 KiB
C

/*
* Copyright (c) 2006-2009 Bjorn Andersson <flex@kryo.se>, Erik Ekman <yarrick@kryo.se>
*
* 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 <ctype.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <signal.h>
#include <unistd.h>
#include <sys/param.h>
#include <sys/time.h>
#include <fcntl.h>
#include <zlib.h>
#include <time.h>
#ifdef WINDOWS32
#include "windows.h"
#include <winsock2.h>
#else
#ifdef ANDROID
#include "android_dns.h"
#endif
#include <arpa/nameser.h>
#ifdef DARWIN
#define BIND_8_COMPAT
#include <arpa/nameser_compat.h>
#endif
#include <grp.h>
#include <pwd.h>
#include <netdb.h>
#endif
#include "common.h"
#include "encoding.h"
#include "base32.h"
#include "base64.h"
#include "base64u.h"
#include "base128.h"
#include "dns.h"
#include "login.h"
#include "tun.h"
#include "version.h"
#include "client.h"
static void handshake_lazyoff(int dns_fd);
static int running;
static const char *password;
static struct sockaddr_in nameserv;
static struct sockaddr_in raw_serv;
static const char *topdomain;
static uint16_t rand_seed;
/* Current up/downstream IP packet */
static struct packet outpkt;
static struct packet inpkt;
int outchunkresent = 0;
/* My userid at the server */
static char userid;
static char userid_char; /* used when sending (lowercase) */
static char userid_char2; /* also accepted when receiving (uppercase) */
/* DNS id for next packet */
static uint16_t chunkid;
static uint16_t chunkid_prev;
static uint16_t chunkid_prev2;
/* Base32 encoder used for non-data packets and replies */
static struct encoder *b32;
/* Base64 etc encoders for replies */
static struct encoder *b64;
static struct encoder *b64u;
static struct encoder *b128;
/* The encoder used for data packets
* Defaults to Base32, can be changed after handshake */
static struct encoder *dataenc;
/* The encoder to use for downstream data */
static char downenc = ' ';
/* set query type to send */
static unsigned short do_qtype = T_UNSET;
/* My connection mode */
static enum connection conn;
static int selecttimeout; /* RFC says timeout minimum 5sec */
static int lazymode;
static long send_ping_soon;
static time_t lastdownstreamtime;
static long send_query_sendcnt = -1;
static long send_query_recvcnt = 0;
static int hostname_maxlen = 0xFF;
void
client_init()
{
running = 1;
b32 = get_base32_encoder();
b64 = get_base64_encoder();
b64u = get_base64u_encoder();
b128 = get_base128_encoder();
dataenc = get_base32_encoder();
rand_seed = ((unsigned int) rand()) & 0xFFFF;
send_ping_soon = 1; /* send ping immediately after startup */
conn = CONN_DNS_NULL;
chunkid = ((unsigned int) rand()) & 0xFFFF;
chunkid_prev = 0;
chunkid_prev2 = 0;
outpkt.len = 0;
outpkt.seqno = 0;
outpkt.fragment = 0;
outchunkresent = 0;
inpkt.len = 0;
inpkt.seqno = 0;
inpkt.fragment = 0;
}
void
client_stop()
{
running = 0;
}
enum connection
client_get_conn()
{
return conn;
}
void
client_set_nameserver(const char *cp, int port)
{
#ifdef ANDROID
struct addrinfo hints, *result, *p;
memset(&hints, 0, sizeof(hints));
hints.ai_family = AF_INET;
char sport[10];
sprintf(sport, "%d", port);
getaddrinfo(cp, sport, &hints, &result);
if (result == NULL)
errx(1, "Cannot resolve %s:%s (no network?)", cp, sport);
else {
for (p = result;p != NULL; p = p->ai_next) {
if (p->ai_family == AF_INET) { /* IPv4 */
struct sockaddr_in *ipv4 = (struct sockaddr_in *)p->ai_addr;
memset(&nameserv, 0, sizeof(nameserv));
nameserv.sin_family = AF_INET;
nameserv.sin_port = htons(port);
nameserv.sin_addr = ipv4->sin_addr;
freeaddrinfo(result);
return;
}
}
freeaddrinfo(result);
}
#endif
struct in_addr addr;
if (inet_aton(cp, &addr) != 1) {
/* try resolving if a domain is given */
struct hostent *host;
const char *err;
host = gethostbyname(cp);
if (host != NULL && h_errno > 0) {
int i = 0;
while (host->h_addr_list[i] != 0) {
addr = *(struct in_addr *) host->h_addr_list[i++];
fprintf(stderr, "Resolved %s to %s\n", cp, inet_ntoa(addr));
goto setaddr;
}
}
#ifndef WINDOWS32
err = hstrerror(h_errno);
#else
{
DWORD wserr = WSAGetLastError();
switch (wserr) {
case WSAHOST_NOT_FOUND:
err = "Host not found";
break;
case WSANO_DATA:
err = "No data record found";
break;
default:
err = "Unknown error";
break;
}
}
#endif /* !WINDOWS32 */
errx(1, "error resolving nameserver '%s': %s", cp, err);
}
setaddr:
memset(&nameserv, 0, sizeof(nameserv));
nameserv.sin_family = AF_INET;
nameserv.sin_port = htons(port);
nameserv.sin_addr = addr;
}
void
client_set_topdomain(const char *cp)
{
topdomain = cp;
}
void
client_set_password(const char *cp)
{
password = cp;
}
void
set_qtype(char *qtype)
{
if (!strcasecmp(qtype, "NULL"))
do_qtype = T_NULL;
else if (!strcasecmp(qtype, "CNAME"))
do_qtype = T_CNAME;
else if (!strcasecmp(qtype, "A"))
do_qtype = T_A;
else if (!strcasecmp(qtype, "MX"))
do_qtype = T_MX;
else if (!strcasecmp(qtype, "SRV"))
do_qtype = T_SRV;
else if (!strcasecmp(qtype, "TXT"))
do_qtype = T_TXT;
}
char *
get_qtype()
{
char *c = "UNDEFINED";
if (do_qtype == T_NULL) c = "NULL";
else if (do_qtype == T_CNAME) c = "CNAME";
else if (do_qtype == T_A) c = "A";
else if (do_qtype == T_MX) c = "MX";
else if (do_qtype == T_SRV) c = "SRV";
else if (do_qtype == T_TXT) c = "TXT";
return c;
}
void
set_downenc(char *encoding)
{
if (!strcasecmp(encoding, "base32"))
downenc = 'T';
else if (!strcasecmp(encoding, "base64"))
downenc = 'S';
else if (!strcasecmp(encoding, "base64u"))
downenc = 'U';
else if (!strcasecmp(encoding, "base128"))
downenc = 'V';
else if (!strcasecmp(encoding, "raw"))
downenc = 'R';
}
void
client_set_selecttimeout(int select_timeout)
{
selecttimeout = select_timeout;
}
void
client_set_lazymode(int lazy_mode)
{
lazymode = lazy_mode;
}
void
client_set_hostname_maxlen(int i)
{
if (i <= 0xFF)
hostname_maxlen = i;
}
const char *
client_get_raw_addr()
{
return inet_ntoa(raw_serv.sin_addr);
}
static void
send_query(int fd, char *hostname)
{
char packet[4096];
struct query q;
size_t len;
chunkid_prev2 = chunkid_prev;
chunkid_prev = chunkid;
chunkid += 7727;
if (chunkid == 0)
/* 0 is used as "no-query" in iodined.c */
chunkid = 7727;
q.id = chunkid;
q.type = do_qtype;
len = dns_encode(packet, sizeof(packet), &q, QR_QUERY, hostname, strlen(hostname));
if (len < 1) {
warnx("dns_encode doesn't fit");
return;
}
#if 0
fprintf(stderr, " Sendquery: id %5d name[0] '%c'\n", q.id, hostname[0]);
#endif
sendto(fd, packet, len, 0, (struct sockaddr*)&nameserv, sizeof(nameserv));
/* There are DNS relays that time out quickly but don't send anything
back on timeout.
And there are relays where, in lazy mode, our new query apparently
_replaces_ our previous query, and we get no answers at all in
lazy mode while legacy immediate-ping-pong works just fine.
Here we detect and fix these situations.
(Can't very well do this anywhere else; this is the only place
we'll reliably get to in such situations.)
*/
if (send_query_sendcnt >= 0 && send_query_sendcnt < 100 && lazymode) {
send_query_sendcnt++;
if ((send_query_sendcnt > 6 && send_query_recvcnt <= 0) ||
(send_query_sendcnt > 10 &&
4 * send_query_recvcnt < send_query_sendcnt)) {
if (selecttimeout > 1) {
warnx("Receiving too few answers. Setting interval to 1 (-I1)");
selecttimeout = 1;
/* restart counting */
send_query_sendcnt = 0;
send_query_recvcnt = 0;
} else if (lazymode) {
warnx("Receiving too few answers. Will try to switch lazy mode off, but that may not always work any more. Start with -L0 next time on this network.");
lazymode = 0;
selecttimeout = 1;
handshake_lazyoff(fd);
}
}
}
}
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_raw_data(int dns_fd)
{
send_raw(dns_fd, outpkt.data, outpkt.len, userid, RAW_HDR_CMD_DATA);
outpkt.len = 0;
}
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, hostname_maxlen);
send_query(fd, buf);
}
static inline int
is_sending()
{
return (outpkt.len != 0);
}
static void
send_chunk(int fd)
{
char buf[4096];
int avail;
int code;
char *p;
static int datacmc = 0;
char *datacmcchars = "abcdefghijklmnopqrstuvwxyz0123456789";
p = outpkt.data;
p += outpkt.offset;
avail = outpkt.len - outpkt.offset;
/* Note: must be same, or smaller than send_fragsize_probe() */
outpkt.sentlen = build_hostname(buf + 5, sizeof(buf) - 5, p, avail,
topdomain, dataenc, hostname_maxlen);
/* Build upstream data header (see doc/proto_xxxxxxxx.txt) */
buf[0] = userid_char; /* First byte is hex 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) | (inpkt.seqno & 7);
buf[2] = b32_5to8(code); /* Third byte is 2 bits lower fragment count, 3 bits downstream packet seqno */
code = ((inpkt.fragment & 15) << 1) | (outpkt.sentlen == avail);
buf[3] = b32_5to8(code); /* Fourth byte is 4 bits downstream fragment count, 1 bit last frag flag */
buf[4] = datacmcchars[datacmc]; /* Fifth byte is data-CMC */
datacmc++;
if (datacmc >= 36)
datacmc = 0;
#if 0
fprintf(stderr, " Send: down %d/%d up %d/%d, %d bytes\n",
inpkt.seqno, inpkt.fragment, outpkt.seqno, outpkt.fragment,
outpkt.sentlen);
#endif
send_query(fd, buf);
}
static void
send_ping(int fd)
{
if (conn == CONN_DNS_NULL) {
char data[4];
data[0] = userid;
data[1] = ((inpkt.seqno & 7) << 4) | (inpkt.fragment & 15);
data[2] = (rand_seed >> 8) & 0xff;
data[3] = (rand_seed >> 0) & 0xff;
rand_seed++;
#if 0
fprintf(stderr, " Send: down %d/%d (ping)\n",
inpkt.seqno, inpkt.fragment);
#endif
send_packet(fd, 'p', data, sizeof(data));
} else {
send_raw(fd, NULL, 0, userid, RAW_HDR_CMD_PING);
}
}
static void
write_dns_error(struct query *q, int ignore_some_errors)
/* This is called from:
1. handshake_waitdns() when already checked that reply fits to our
latest query.
2. tunnel_dns() when already checked that reply is for our ping or data
packet, but not necessarily the most recent (SERVFAIL mostly comes
after long delay).
So ignorable errors are never printed.
*/
{
if (!q) return;
switch (q->rcode) {
case NOERROR: /* 0 */
if (!ignore_some_errors)
warnx("Got reply without error, but also without question and/or answer");
break;
case FORMERR: /* 1 */
warnx("Got FORMERR as reply: server does not understand our request");
break;
case SERVFAIL: /* 2 */
if (!ignore_some_errors)
warnx("Got SERVFAIL as reply: server failed or recursion timeout");
break;
case NXDOMAIN: /* 3 */
warnx("Got NXDOMAIN as reply: domain does not exist");
break;
case NOTIMP: /* 4 */
warnx("Got NOTIMP as reply: server does not support our request");
break;
case REFUSED: /* 5 */
warnx("Got REFUSED as reply");
break;
default:
warnx("Got RCODE %u as reply", q->rcode);
break;
}
}
static int
dns_namedec(char *outdata, int outdatalen, char *buf, int buflen)
/* Decodes *buf to *outdata.
* *buf WILL be changed by undotify.
* Note: buflen must be _exactly_ strlen(buf) before undotifying.
* (undotify of reduced-len won't copy \0, base-X decode will decode too much.)
* Returns #bytes usefully filled in outdata.
*/
{
size_t outdatalenu = outdatalen;
switch (buf[0]) {
case 'h': /* Hostname with base32 */
case 'H':
/* Need 1 byte H, 3 bytes ".xy", >=1 byte data */
if (buflen < 5)
return 0;
/* this also does undotify */
return unpack_data(outdata, outdatalen, buf + 1, buflen - 4,
b32);
case 'i': /* Hostname++ with base64 */
case 'I':
/* Need 1 byte I, 3 bytes ".xy", >=1 byte data */
if (buflen < 5)
return 0;
/* this also does undotify */
return unpack_data(outdata, outdatalen, buf + 1, buflen - 4,
b64);
case 'j': /* Hostname++ with base64u */
case 'J':
/* Need 1 byte J, 3 bytes ".xy", >=1 byte data */
if (buflen < 5)
return 0;
/* this also does undotify */
return unpack_data(outdata, outdatalen, buf + 1, buflen - 4,
b64u);
case 'k': /* Hostname++ with base128 */
case 'K':
/* Need 1 byte J, 3 bytes ".xy", >=1 byte data */
if (buflen < 5)
return 0;
/* this also does undotify */
return unpack_data(outdata, outdatalen, buf + 1, buflen - 4,
b128);
case 't': /* plain base32(Thirty-two) from TXT */
case 'T':
if (buflen < 2)
return 0;
return b32->decode(outdata, &outdatalenu, buf + 1, buflen - 1);
case 's': /* plain base64(Sixty-four) from TXT */
case 'S':
if (buflen < 2)
return 0;
return b64->decode(outdata, &outdatalenu, buf + 1, buflen - 1);
case 'u': /* plain base64u (Underscore) from TXT */
case 'U':
if (buflen < 2)
return 0;
return b64u->decode(outdata, &outdatalenu, buf + 1, buflen - 1);
case 'v': /* plain base128 from TXT */
case 'V':
if (buflen < 2)
return 0;
return b128->decode(outdata, &outdatalenu, buf + 1, buflen - 1);
case 'r': /* Raw binary from TXT */
case 'R':
/* buflen>=1 already checked */
buflen--;
buflen = MIN(buflen, outdatalen);
memcpy(outdata, buf + 1, buflen);
return buflen;
default:
warnx("Received unsupported encoding");
return 0;
}
/* notreached */
return 0;
}
static int
read_dns_withq(int dns_fd, int tun_fd, char *buf, int buflen, struct query *q)
/* FIXME: tun_fd needed for raw handling */
/* Returns -1 on receive error or decode error, including DNS error replies.
Returns 0 on replies that could be correct but are useless, and are not
DNS error replies.
Returns >0 on correct replies; value is #valid bytes in *buf.
*/
{
struct sockaddr_in from;
char data[64*1024];
socklen_t addrlen;
int r;
addrlen = sizeof(struct sockaddr);
if ((r = recvfrom(dns_fd, data, sizeof(data), 0,
(struct sockaddr*)&from, &addrlen)) < 0) {
warn("recvfrom");
return -1;
}
if (conn == CONN_DNS_NULL) {
int rv;
if (r <= 0)
/* useless packet */
return 0;
rv = dns_decode(buf, buflen, q, QR_ANSWER, data, r);
if (rv <= 0)
return rv;
if (q->type == T_CNAME || q->type == T_TXT)
/* CNAME can also be returned from an A question */
{
/*
* buf is a hostname or txt stream that we still need to
* decode to binary
*
* also update rv with the number of valid bytes
*
* data is unused here, and will certainly hold the smaller binary
*/
rv = dns_namedec(data, sizeof(data), buf, rv);
rv = MIN(rv, buflen);
if (rv > 0)
memcpy(buf, data, rv);
} else if (q->type == T_MX || q->type == T_SRV) {
/* buf is like "Hname.com\0Hanother.com\0\0" */
int buftotal = rv; /* idx of last \0 */
int bufoffset = 0;
int dataoffset = 0;
int thispartlen, dataspace, datanew;
while (1) {
thispartlen = strlen(buf);
thispartlen = MIN(thispartlen, buftotal-bufoffset);
dataspace = sizeof(data) - dataoffset;
if (thispartlen <= 0 || dataspace <= 0)
break;
datanew = dns_namedec(data + dataoffset, dataspace,
buf + bufoffset, thispartlen);
if (datanew <= 0)
break;
bufoffset += thispartlen + 1;
dataoffset += datanew;
}
rv = dataoffset;
rv = MIN(rv, buflen);
if (rv > 0)
memcpy(buf, data, rv);
}
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 my user id */
if (RAW_HDR_GET_USR(data) != userid) return 0;
if (RAW_HDR_GET_CMD(data) == RAW_HDR_CMD_DATA ||
RAW_HDR_GET_CMD(data) == RAW_HDR_CMD_PING)
lastdownstreamtime = time(NULL);
/* should be data packet */
if (RAW_HDR_GET_CMD(data) != RAW_HDR_CMD_DATA) 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);
}
/* don't process any further */
return 0;
}
}
static int
handshake_waitdns(int dns_fd, char *buf, int buflen, char c1, char c2, int timeout)
/* Wait for DNS reply fitting to our latest query and returns it.
Returns length of reply = #bytes used in buf.
Returns 0 if fitting reply happens to be useless.
Returns -2 on (at least) DNS error that fits to our latest query,
error message already printed.
Returns -3 on timeout (given in seconds).
Returns -1 on other errors.
Timeout is restarted when "wrong" (previous/delayed) replies are received,
so effective timeout may be longer than specified.
*/
{
struct query q;
int r, rv;
fd_set fds;
struct timeval tv;
while (1) {
tv.tv_sec = timeout;
tv.tv_usec = 0;
FD_ZERO(&fds);
FD_SET(dns_fd, &fds);
r = select(dns_fd + 1, &fds, NULL, NULL, &tv);
if (r < 0)
return -1; /* select error */
if (r == 0)
return -3; /* select timeout */
q.id = 0;
q.name[0] = '\0';
rv = read_dns_withq(dns_fd, 0, buf, buflen, &q);
if (q.id != chunkid || (q.name[0] != c1 && q.name[0] != c2)) {
#if 0
fprintf(stderr, "Ignoring unfitting reply id %d starting with '%c'\n", q.id, q.name[0]);
#endif
continue;
}
/* if still here: reply matches our latest query */
/* Non-recursive DNS servers (such as [a-m].root-servers.net)
return no answer, but only additional and authority records.
Can't explicitly test for that here, just assume that
NOERROR is such situation. Only trigger on the very first
requests (Y or V, depending if -T given).
*/
if (rv < 0 && q.rcode == NOERROR &&
(q.name[0] == 'Y' || q.name[0] == 'y' ||
q.name[0] == 'V' || q.name[0] == 'v')) {
fprintf(stderr, "Got empty reply. This nameserver may not be resolving recursively, use another.\n");
fprintf(stderr, "Try \"iodine [options] ns.%s %s\" first, it might just work.\n",
topdomain, topdomain);
return -2;
}
/* If we get an immediate SERVFAIL on the handshake query
we're waiting for, wait a while before sending the next.
SERVFAIL reliably happens during fragsize autoprobe, but
mostly long after we've moved along to some other queries.
However, some DNS relays, once they throw a SERVFAIL, will
for several seconds apply it immediately to _any_ new query
for the same topdomain. When this happens, waiting a while
is the only option that works.
*/
if (rv < 0 && q.rcode == SERVFAIL)
sleep(1);
if (rv < 0) {
write_dns_error(&q, 1);
return -2;
}
/* rv either 0 or >0, return it as is. */
return rv;
}
/* not reached */
return -1;
}
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;
/* We may be here only to empty the tun device; then return -1
to force continue in select loop. */
if (is_sending())
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.seqno = (outpkt.seqno + 1) & 7;
outpkt.len = outlen;
outpkt.fragment = 0;
outchunkresent = 0;
if (conn == CONN_DNS_NULL) {
send_chunk(dns_fd);
send_ping_soon = 0;
} else {
send_raw_data(dns_fd);
}
return read;
}
static int
tunnel_dns(int tun_fd, int dns_fd)
{
static long packrecv = 0;
static long packrecv_oos = 0;
static long packrecv_servfail = 0;
int up_ack_seqno;
int up_ack_fragment;
int new_down_seqno;
int new_down_fragment;
struct query q;
unsigned long datalen;
char buf[64*1024];
int read;
int send_something_now = 0;
memset(q.name, 0, sizeof(q.name));
read = read_dns_withq(dns_fd, tun_fd, buf, sizeof(buf), &q);
if (conn != CONN_DNS_NULL)
return 1; /* everything already done */
#if 0
fprintf(stderr, " Recv: id %5d name[0]='%c'\n",
q.id, q.name[0]);
#endif
/* Don't process anything that isn't data for us; usually error
replies from fragsize probes etc. However a sequence of those,
mostly 1 sec apart, will continuously break the >=2-second select
timeout, which means we won't send a proper ping for a while.
So make select a bit faster, <1sec. */
if (q.name[0] != 'P' && q.name[0] != 'p' &&
q.name[0] != userid_char && q.name[0] != userid_char2) {
send_ping_soon = 700;
return -1; /* nothing done */
}
if (read < 2) {
/* Maybe SERVFAIL etc. Send ping to get things back in order,
but wait a bit to prevent fast ping-pong loops. */
if (read < 0)
write_dns_error(&q, 0);
if (read < 0 && q.rcode == SERVFAIL && lazymode &&
selecttimeout > 1) {
if (packrecv < 500 && packrecv_servfail < 4) {
packrecv_servfail++;
warnx("Hmm, that's %ld. Your data should still go through...", packrecv_servfail);
} else if (packrecv < 500 && packrecv_servfail == 4) {
packrecv_servfail++;
warnx("I think %ld is too many. Setting interval to 1 to hopefully reduce SERVFAILs. But just ignore them if data still comes through. (Use -I1 next time on this network.)", packrecv_servfail);
selecttimeout = 1;
send_query_sendcnt = 0;
send_query_recvcnt = 0;
} else if (packrecv >= 500 && packrecv_servfail > 0) {
warnx("(Sorry, stopped counting; try -I1 if you experience hiccups.)");
packrecv_servfail = 0;
}
}
/* read==1 happens with "QMEM" illegal replies, caused by
heavy reordering, or after short disconnections when
data-CMC has looped around into the "duplicate" values.
All these cases are helped by faster pinging. */
#if 0
if (read == 1)
fprintf(stderr, " q=%c id %5d 1-byte illegal \"QMEM\" reply\n", q.name[0], q.id);
#endif
send_ping_soon = 900;
return -1; /* nothing done */
}
if (read == 5 && !strncmp("BADIP", buf, 5)) {
warnx("BADIP: Server rejected sender IP address (maybe iodined -c will help), or server kicked us due to timeout. Will exit if no downstream data is received in 60 seconds.");
return -1; /* nothing done */
}
if (send_ping_soon) {
send_something_now = 1;
send_ping_soon = 0;
}
/* Decode the data header, update seqno and frag;
already checked read>=2
Note that buf[] gets overwritten when down-pkt complete */
new_down_seqno = (buf[1] >> 5) & 7;
new_down_fragment = (buf[1] >> 1) & 15;
up_ack_seqno = (buf[0] >> 4) & 7;
up_ack_fragment = buf[0] & 15;
#if 0
fprintf(stderr, " Recv: id %5d down %d/%d up %d/%d, %d bytes\n",
q.id, new_down_seqno, new_down_fragment, up_ack_seqno,
up_ack_fragment, read);
#endif
/* Downstream data traffic */
if (read > 2 && new_down_seqno != inpkt.seqno &&
recent_seqno(inpkt.seqno, new_down_seqno)) {
/* This is the previous seqno, or a bit earlier.
Probably out-of-sequence dupe due to unreliable
intermediary DNS. Don't get distracted, but send
ping quickly to get things back in order.
Ping will send our current seqno idea.
If it's really a new packet that skipped multiple seqnos
(why??), server will re-send and drop a few times and
eventually everything will work again. */
read = 2;
send_ping_soon = 500;
/* Still process upstream ack, if any */
}
if (!(packrecv & 0x1000000))
packrecv++;
send_query_recvcnt++; /* overflow doesn't matter */
/* Don't process any non-recent stuff any further.
No need to remember more than 3 ids: in practice any older replies
arrive after new/current replies, and whatever data the old replies
have, it has become useless in the mean time.
Actually, ever since iodined is replying to both the original query
and the last dupe, this hardly triggers any more.
*/
if (q.id != chunkid && q.id != chunkid_prev && q.id != chunkid_prev2) {
packrecv_oos++;
#if 0
fprintf(stderr, " q=%c Packs received = %8ld Out-of-sequence = %8ld\n", q.name[0], packrecv, packrecv_oos);
#endif
if (lazymode && packrecv < 1000 && packrecv_oos == 5) {
if (selecttimeout > 1)
warnx("Hmm, getting some out-of-sequence DNS replies. Setting interval to 1 (use -I1 next time on this network). If data traffic still has large hiccups, try if -L0 works better.");
else
warnx("Hmm, getting some out-of-sequence DNS replies. If data traffic often has large hiccups, try running with -L0 .");
selecttimeout = 1;
send_query_sendcnt = 0;
send_query_recvcnt = 0;
}
if (send_something_now) {
send_ping(dns_fd);
send_ping_soon = 0;
}
return -1; /* nothing done */
}
#if 0
fprintf(stderr, " q=%c Packs received = %8ld Out-of-sequence = %8ld\n", q.name[0], packrecv, packrecv_oos);
#endif
/* Okay, we have a recent downstream packet */
lastdownstreamtime = time(NULL);
/* In lazy mode, we shouldn't get much replies to our most-recent
query, only during heavy data transfer. Since this means the server
doesn't have any packets left, send one relatively fast (but not
too fast, to avoid runaway ping-pong loops..) */
if (q.id == chunkid && lazymode) {
if (!send_ping_soon || send_ping_soon > 900)
send_ping_soon = 900;
}
if (read == 2 && new_down_seqno != inpkt.seqno &&
!recent_seqno(inpkt.seqno, new_down_seqno)) {
/* This is a seqno that we didn't see yet, but it has
no data any more. Possible since iodined will send
fitting packs just once and not wait for ack.
Real data got lost, or will arrive shortly.
Update our idea of the seqno, and drop any waiting
old pack. Send ping to get things back on track. */
inpkt.seqno = new_down_seqno;
inpkt.fragment = new_down_fragment;
inpkt.len = 0;
send_ping_soon = 500;
}
while (read > 2) {
/* "if" with easy exit */
if (new_down_seqno != inpkt.seqno) {
/* New packet (and not dupe of recent; checked above) */
/* Forget any old packet, even if incomplete */
inpkt.seqno = new_down_seqno;
inpkt.fragment = new_down_fragment; /* hopefully 0 */
inpkt.len = 0;
} else if (inpkt.fragment == 0 && new_down_fragment == 0 &&
inpkt.len == 0) {
/* Weird situation: we probably got a no-data reply
for this seqno (see above), and the actual data
is following now. */
/* okay, nothing to do here, just so that next else-if
doesn't trigger */
} else if (new_down_fragment <= inpkt.fragment) {
/* Same packet but duplicate fragment, ignore.
If the server didn't get our ack for it, the next
ping or chunk will do that. */
send_ping_soon = 500;
break;
} else if (new_down_fragment > inpkt.fragment + 1) {
/* Quite impossible. We missed a fragment, but the
server got our ack for it and is sending the next
fragment already. Don't handle it but let server
re-send and drop. */
send_ping_soon = 500;
break;
}
inpkt.fragment = new_down_fragment;
datalen = MIN(read - 2, sizeof(inpkt.data) - inpkt.len);
/* we are here only when read > 2, so datalen "always" >=1 */
/* 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 */
/* RE-USES buf[] */
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;
/* Keep .seqno and .fragment as is, so that we won't
reassemble from duplicate fragments */
}
/* Send anything to ack the received seqno/frag, and get more */
if (inpkt.len == 0) {
/* was last frag; wait just a trifle because our
tun will probably return TCP-ack immediately.
5msec = 200 DNSreq/sec */
send_ping_soon = 5;
} else {
/* server certainly has more data */
send_something_now = 1;
}
break;
}
/* NOTE: buf[] was overwritten when down-packet complete */
/* Upstream data traffic */
if (is_sending()) {
/* already checked read>=2 */
#if 0
fprintf(stderr, "Got ack for %d,%d - expecting %d,%d - id=%d cur=%d prev=%d prev2=%d\n",
up_ack_seqno, up_ack_fragment, outpkt.seqno, outpkt.fragment,
q.id, chunkid, chunkid_prev, chunkid_prev2);
#endif
if (up_ack_seqno == outpkt.seqno &&
up_ack_fragment == outpkt.fragment) {
/* Okay, previously sent fragment has arrived */
outpkt.offset += outpkt.sentlen;
if (outpkt.offset >= outpkt.len) {
/* Packet completed */
outpkt.offset = 0;
outpkt.len = 0;
outpkt.sentlen = 0;
outchunkresent = 0;
/* Normally, server still has a query in queue,
but sometimes not. So send a ping.
(Comment this out and you'll see occasional
hiccups.)
But since the server often still has a
query and we can expect a TCP-ack returned
from our tun device quickly in many cases,
don't be too fast.
20msec still is 50 DNSreq/second... */
if (!send_ping_soon || send_ping_soon > 20)
send_ping_soon = 20;
} else {
/* More to send */
outpkt.fragment++;
outchunkresent = 0;
send_chunk(dns_fd);
send_ping_soon = 0;
send_something_now = 0;
}
}
/* else: Some wrong fragment has arrived, or old fragment is
acked again, mostly by ping responses.
Don't resend chunk, usually not needed; select loop will
re-send on timeout (1sec if is_sending()). */
}
/* Send ping if we didn't send anything yet */
if (send_something_now) {
send_ping(dns_fd);
send_ping_soon = 0;
}
return read;
}
int
client_tunnel(int tun_fd, int dns_fd)
{
struct timeval tv;
fd_set fds;
int rv;
int i;
rv = 0;
lastdownstreamtime = time(NULL);
send_query_sendcnt = 0; /* start counting now */
while (running) {
tv.tv_sec = selecttimeout;
tv.tv_usec = 0;
if (is_sending()) {
/* fast timeout for retransmits */
tv.tv_sec = 1;
tv.tv_usec = 0;
}
if (send_ping_soon) {
tv.tv_sec = 0;
tv.tv_usec = send_ping_soon * 1000;
}
FD_ZERO(&fds);
if (!is_sending() || outchunkresent >= 2) {
/* If re-sending upstream data, chances are that
we're several seconds behind already and TCP
will start filling tun buffer with (useless)
retransmits.
Get up-to-date fast by simply dropping stuff,
that's what TCP is designed to handle. */
FD_SET(tun_fd, &fds);
}
FD_SET(dns_fd, &fds);
i = select(MAX(tun_fd, dns_fd) + 1, &fds, NULL, NULL, &tv);
if (lastdownstreamtime + 60 < time(NULL)) {
warnx("No downstream data received in 60 seconds, shutting down.");
running = 0;
}
if (running == 0)
break;
if (i < 0)
err(1, "select");
if (i == 0) {
/* timeout */
if (is_sending()) {
/* Re-send current fragment; either frag
or ack probably dropped somewhere.
But problem: no cache-miss-counter,
so hostname will be identical.
Just drop whole packet after 3 retries,
and TCP retransmit will solve it.
NOTE: tun dropping above should be
>=(value_here - 1) */
if (outchunkresent < 3) {
outchunkresent++;
send_chunk(dns_fd);
} else {
outpkt.offset = 0;
outpkt.len = 0;
outpkt.sentlen = 0;
outchunkresent = 0;
send_ping(dns_fd);
}
} else {
send_ping(dns_fd);
}
send_ping_soon = 0;
} else {
if (FD_ISSET(tun_fd, &fds)) {
if (tunnel_tun(tun_fd, dns_fd) <= 0)
continue;
/* Returns -1 on error OR when quickly
dropping data in case of DNS congestion;
we need to _not_ do tunnel_dns() then.
If chunk sent, sets send_ping_soon=0. */
}
if (FD_ISSET(dns_fd, &fds)) {
if (tunnel_dns(tun_fd, dns_fd) <= 0)
continue;
}
}
}
return rv;
}
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_fragsize_probe(int fd, int fragsize)
{
char probedata[256];
char buf[4096];
/*
* build a large query domain which is random and maximum size,
* will also take up maximal space in the return packet
*/
memset(probedata, MAX(1, rand_seed & 0xff), sizeof(probedata));
probedata[1] = MAX(1, (rand_seed >> 8) & 0xff);
rand_seed++;
/* Note: must either be same, or larger, than send_chunk() */
build_hostname(buf + 5, sizeof(buf) - 5, probedata, sizeof(probedata),
topdomain, dataenc, hostname_maxlen);
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);
buf[4] = 'd'; /* dummy to match send_chunk() */
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_upenctest(int fd, char *s)
/* NOTE: String may be at most 63-4=59 chars to fit in 1 dns chunk. */
{
char buf[512] = "z___";
buf[1] = b32_5to8((rand_seed >> 10) & 0x1f);
buf[2] = b32_5to8((rand_seed >> 5) & 0x1f);
buf[3] = b32_5to8((rand_seed ) & 0x1f);
rand_seed++;
strncat(buf, s, 512);
strncat(buf, ".", 512);
strncat(buf, topdomain, 512 - strlen(buf));
send_query(fd, buf);
}
static void
send_downenctest(int fd, char downenc, int variant, char *s, int slen)
/* Note: content/handling of s is not defined yet. */
{
char buf[512] = "y_____.";
buf[1] = tolower(downenc);
buf[2] = b32_5to8(variant);
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 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 void
send_downenc_switch(int fd, int userid)
{
char buf[512] = "o_____.";
buf[1] = b32_5to8(userid);
buf[2] = tolower(downenc);
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 void
send_lazy_switch(int fd, int userid)
{
char buf[512] = "o_____.";
buf[1] = b32_5to8(userid);
if (lazymode)
buf[2] = 'l';
else
buf[2] = 'i';
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)
{
char hex[] = "0123456789abcdef";
char hex2[] = "0123456789ABCDEF";
char in[4096];
uint32_t payload;
int i;
int read;
for (i = 0; running && i < 5; i++) {
send_version(dns_fd, VERSION);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'v', 'V', i+1);
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];
userid_char = hex[userid & 15];
userid_char2 = hex2[userid & 15];
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 if (read > 0)
warnx("did not receive proper login challenge");
fprintf(stderr, "Retrying version check...\n");
}
warnx("couldn't connect to server (maybe other -T options will work)");
return 1;
}
static int
handshake_login(int dns_fd, int seed)
{
char in[4096];
char login[16];
char server[65];
char client[65];
int mtu;
int i;
int read;
login_calculate(login, 16, password, seed);
for (i=0; running && i<5 ;i++) {
send_login(dns_fd, login, 16);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'l', 'L', i+1);
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, server, netmask) == 0 &&
tun_setmtu(mtu) == 0) {
fprintf(stderr, "Server tunnel IP is %s\n", server);
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)");
for (i=0; running && i<3 ;i++) {
send_ip_request(dns_fd, userid);
len = handshake_waitdns(dns_fd, in, sizeof(in), 'i', 'I', i+1);
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;
}
fprintf(stderr, ".");
fflush(stderr);
}
fprintf(stderr, "\n");
if (!running)
return 0;
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_upenctest(int dns_fd, char *s)
/* NOTE: *s may be max 59 chars; must start with "aA" for case-swap check
Returns:
-1: case swap, no need for any further test: error printed; or Ctrl-C
0: not identical or error or timeout
1: identical string returned
*/
{
char in[4096];
unsigned char *uin = (unsigned char *) in;
unsigned char *us = (unsigned char *) s;
int i;
int read;
int slen;
slen = strlen(s);
for (i=0; running && i<3 ;i++) {
send_upenctest(dns_fd, s);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'z', 'Z', i+1);
if (read == -2)
return 0; /* hard error */
if (read > 0 && read < slen + 4)
return 0; /* reply too short (chars dropped) */
if (read > 0) {
int k;
#if 0
/* in[56] = '@'; */
/* in[56] = '_'; */
/* if (in[29] == '\344') in[29] = 'a'; */
in[read] = '\0';
fprintf(stderr, "BounceReply: >%s<\n", in);
#endif
/* quick check if case swapped, to give informative error msg */
if (in[4] == 'A') {
fprintf(stderr, "DNS queries get changed to uppercase, keeping upstream codec Base32\n");
return -1;
}
if (in[5] == 'a') {
fprintf(stderr, "DNS queries get changed to lowercase, keeping upstream codec Base32\n");
return -1;
}
for (k = 0; k < slen; k++) {
if (in[k+4] != s[k]) {
/* Definitely not reliable */
if (in[k+4] >= ' ' && in[k+4] <= '~' &&
s[k] >= ' ' && s[k] <= '~') {
fprintf(stderr, "DNS query char '%c' gets changed into '%c'\n",
s[k], in[k+4]);
} else {
fprintf(stderr, "DNS query char 0x%02X gets changed into 0x%02X\n",
(unsigned int) us[k],
(unsigned int) uin[k+4]);
}
return 0;
}
}
/* if still here, then all okay */
return 1;
}
fprintf(stderr, "Retrying upstream codec test...\n");
}
if (!running)
return -1;
/* timeout */
return 0;
}
static int
handshake_upenc_autodetect(int dns_fd)
/* Returns:
0: keep Base32
1: Base64 is okay
2: Base64u is okay
3: Base128 is okay
*/
{
/* Note: max 59 chars, must start with "aA".
pat64: If 0129 work, assume 3-8 are okay too.
RFC1035 par 2.3.1 states that [A-Z0-9-] allowed, but only
[A-Z] as first, and [A-Z0-9] as last char _per label_.
Test by having '-' as last char.
*/
char *pat64="aAbBcCdDeEfFgGhHiIjJkKlLmMnNoOpPqQrRsStTuUvVwWxXyYzZ+0129-";
char *pat64u="aAbBcCdDeEfFgGhHiIjJkKlLmMnNoOpPqQrRsStTuUvVwWxXyYzZ_0129-";
char *pat128a="aA-Aaahhh-Drink-mal-ein-J\344germeister-";
char *pat128b="aA-La-fl\373te-na\357ve-fran\347aise-est-retir\351-\340-Cr\350te";
char *pat128c="aAbBcCdDeEfFgGhHiIjJkKlLmMnNoOpPqQrRsStTuUvVwWxXyYzZ";
char *pat128d="aA0123456789\274\275\276\277"
"\300\301\302\303\304\305\306\307\310\311\312\313\314\315\316\317";
char *pat128e="aA"
"\320\321\322\323\324\325\326\327\330\331\332\333\334\335\336\337"
"\340\341\342\343\344\345\346\347\350\351\352\353\354\355\356\357"
"\360\361\362\363\364\365\366\367\370\371\372\373\374\375";
int res;
/* Try Base128, starting very gently to not draw attention */
while (1) {
res = handshake_upenctest(dns_fd, pat128a);
if (res < 0) {
/* DNS swaps case, msg already printed; or Ctrl-C */
return 0;
} else if (res == 0) {
/* Probably not okay, skip Base128 entirely */
break;
}
res = handshake_upenctest(dns_fd, pat128b);
if (res < 0)
return 0;
else if (res == 0)
break;
/* if this works, we can test the real stuff */
res = handshake_upenctest(dns_fd, pat128c);
if (res < 0)
return 0;
else if (res == 0)
break;
res = handshake_upenctest(dns_fd, pat128d);
if (res < 0)
return 0;
else if (res == 0)
break;
res = handshake_upenctest(dns_fd, pat128e);
if (res < 0)
return 0;
else if (res == 0)
break;
/* if still here, then base128 works completely */
return 3;
}
/* Try Base64 (with plus sign) */
res = handshake_upenctest(dns_fd, pat64);
if (res < 0) {
/* DNS swaps case, msg already printed; or Ctrl-C */
return 0;
} else if (res > 0) {
/* All okay, Base64 msg will be printed later */
return 1;
}
/* Try Base64u (with _u_nderscore) */
res = handshake_upenctest(dns_fd, pat64u);
if (res < 0) {
/* DNS swaps case, msg already printed; or Ctrl-C */
return 0;
} else if (res > 0) {
/* All okay, Base64u msg will be printed later */
return 2;
}
/* if here, then nonthing worked */
fprintf(stderr, "Keeping upstream codec Base32\n");
return 0;
}
static int
handshake_downenctest(int dns_fd, char trycodec)
/* Returns:
0: not identical or error or timeout
1: identical string returned
*/
{
char in[4096];
int i;
int read;
char *s = DOWNCODECCHECK1;
int slen = DOWNCODECCHECK1_LEN;
for (i=0; running && i<3 ;i++) {
send_downenctest(dns_fd, trycodec, 1, NULL, 0);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'y', 'Y', i+1);
if (read == -2)
return 0; /* hard error */
if (read > 0 && read != slen)
return 0; /* reply incorrect = unreliable */
if (read > 0) {
int k;
for (k = 0; k < slen; k++) {
if (in[k] != s[k]) {
/* Definitely not reliable */
return 0;
}
}
/* if still here, then all okay */
return 1;
}
fprintf(stderr, "Retrying downstream codec test...\n");
}
/* timeout */
return 0;
}
static char
handshake_downenc_autodetect(int dns_fd)
/* Returns codec char (or ' ' if no advanced codec works) */
{
int base64ok = 0;
int base64uok = 0;
int base128ok = 0;
if (do_qtype == T_NULL) {
/* no other choice than raw */
fprintf(stderr, "No alternative downstream codec available, using default (Raw)\n");
return ' ';
}
fprintf(stderr, "Autodetecting downstream codec (use -O to override)\n");
/* Try Base64 */
if (handshake_downenctest(dns_fd, 'S'))
base64ok = 1;
else if (running && handshake_downenctest(dns_fd, 'U'))
base64uok = 1;
/* Try Base128 only if 64 gives us some perspective */
if (running && (base64ok || base64uok)) {
if (handshake_downenctest(dns_fd, 'V'))
base128ok = 1;
}
/* If 128 works, then TXT may give us Raw as well */
if (running && (base128ok && do_qtype == T_TXT)) {
if (handshake_downenctest(dns_fd, 'R'))
return 'R';
}
if (!running)
return ' ';
if (base128ok)
return 'V';
if (base64ok)
return 'S';
if (base64uok)
return 'U';
fprintf(stderr, "No advanced downstream codecs seem to work, using default (Base32)\n");
return ' ';
}
static int
handshake_qtypetest(int dns_fd, int timeout)
/* Returns:
0: doesn't work with this timeout
1: works properly
*/
{
char in[4096];
int read;
char *s = DOWNCODECCHECK1;
int slen = DOWNCODECCHECK1_LEN;
int trycodec;
int k;
if (do_qtype == T_NULL)
trycodec = 'R';
else
trycodec = 'T';
/* We could use 'Z' bouncing here, but 'Y' also tests that 0-255
byte values can be returned, which is needed for NULL to work. */
send_downenctest(dns_fd, trycodec, 1, NULL, 0);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'y', 'Y', timeout);
if (read != slen)
return 0; /* incorrect */
for (k = 0; k < slen; k++) {
if (in[k] != s[k]) {
/* corrupted */
return 0;
}
}
/* if still here, then all okay */
return 1;
}
static int
handshake_qtype_numcvt(int num)
{
switch (num) {
case 0: return T_NULL;
case 1: return T_TXT;
case 2: return T_SRV;
case 3: return T_MX;
case 4: return T_CNAME;
case 5: return T_A;
}
return T_UNSET;
}
static int
handshake_qtype_autodetect(int dns_fd)
/* Returns:
0: okay, do_qtype set
1: problem, program exit
*/
{
int highestworking = 100;
int timeout;
int qtypenum;
fprintf(stderr, "Autodetecting DNS query type (use -T to override)");
fflush(stderr);
/* Method: try all "interesting" qtypes with a 1-sec timeout, then try
all "still-interesting" qtypes with a 2-sec timeout, etc.
"Interesting" means: qtypes that (are expected to) have higher
bandwidth than what we know is working already (highestworking).
Note that DNS relays may not immediately resolve the first (NULL)
query in 1 sec, due to long recursive lookups, so we keep trying
to see if things will start working after a while.
*/
for (timeout = 1; running && timeout <= 3; timeout++) {
for (qtypenum = 0; running && qtypenum < highestworking; qtypenum++) {
do_qtype = handshake_qtype_numcvt(qtypenum);
if (do_qtype == T_UNSET)
break; /* this round finished */
fprintf(stderr, ".");
fflush(stderr);
if (handshake_qtypetest(dns_fd, timeout)) {
/* okay */
highestworking = qtypenum;
#if 0
fprintf(stderr, " Type %s timeout %d works\n",
get_qtype(), timeout);
#endif
break;
/* try others with longer timeout */
}
/* else: try next qtype with same timeout */
}
if (highestworking == 0)
/* good, we have NULL; abort immediately */
break;
}
fprintf(stderr, "\n");
if (!running) {
warnx("Stopped while autodetecting DNS query type (try setting manually with -T)");
return 1; /* problem */
}
/* finished */
do_qtype = handshake_qtype_numcvt(highestworking);
if (do_qtype == T_UNSET) {
/* also catches highestworking still 100 */
warnx("No suitable DNS query type found. Are you connected to a network?");
warnx("If you expect very long roundtrip delays, use -T explicitly.");
warnx("(Also, connecting to an \"ancient\" version of iodined won't work.)");
return 1; /* problem */
}
/* "using qtype" message printed in handshake function */
return 0; /* okay */
}
static int
handshake_edns0_check(int dns_fd)
/* Returns:
0: EDNS0 not supported; or Ctrl-C
1: EDNS0 works
*/
{
char in[4096];
int i;
int read;
char *s = DOWNCODECCHECK1;
int slen = DOWNCODECCHECK1_LEN;
char trycodec;
if (do_qtype == T_NULL)
trycodec = 'R';
else
trycodec = 'T';
for (i=0; running && i<3 ;i++) {
send_downenctest(dns_fd, trycodec, 1, NULL, 0);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'y', 'Y', i+1);
if (read == -2)
return 0; /* hard error */
if (read > 0 && read != slen)
return 0; /* reply incorrect = unreliable */
if (read > 0) {
int k;
for (k = 0; k < slen; k++) {
if (in[k] != s[k]) {
/* Definitely not reliable */
return 0;
}
}
/* if still here, then all okay */
return 1;
}
fprintf(stderr, "Retrying EDNS0 support test...\n");
}
/* timeout or Ctrl-C */
return 0;
}
static void
handshake_switch_codec(int dns_fd, int bits)
{
char in[4096];
int i;
int read;
struct encoder *tempenc;
if (bits == 5)
tempenc = get_base32_encoder();
else if (bits == 6)
tempenc = get_base64_encoder();
else if (bits == 26) /* "2nd" 6 bits per byte, with underscore */
tempenc = get_base64u_encoder();
else if (bits == 7)
tempenc = get_base128_encoder();
else return;
fprintf(stderr, "Switching upstream to codec %s\n", tempenc->name);
for (i=0; running && i<5 ;i++) {
send_codec_switch(dns_fd, userid, bits);
read = handshake_waitdns(dns_fd, in, sizeof(in), 's', 'S', i+1);
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 upstream to codec %s\n", in);
dataenc = tempenc;
return;
}
fprintf(stderr, "Retrying codec switch...\n");
}
if (!running)
return;
fprintf(stderr, "No reply from server on codec switch. ");
codec_revert:
fprintf(stderr, "Falling back to upstream codec %s\n", dataenc->name);
}
static void
handshake_switch_downenc(int dns_fd)
{
char in[4096];
int i;
int read;
char *dname;
dname = "Base32";
if (downenc == 'S')
dname = "Base64";
else if (downenc == 'U')
dname = "Base64u";
else if (downenc == 'V')
dname = "Base128";
else if (downenc == 'R')
dname = "Raw";
fprintf(stderr, "Switching downstream to codec %s\n", dname);
for (i=0; running && i<5 ;i++) {
send_downenc_switch(dns_fd, userid);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'o', 'O', i+1);
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 downstream to codec %s\n", in);
return;
}
fprintf(stderr, "Retrying codec switch...\n");
}
if (!running)
return;
fprintf(stderr, "No reply from server on codec switch. ");
codec_revert:
fprintf(stderr, "Falling back to downstream codec Base32\n");
}
static void
handshake_try_lazy(int dns_fd)
{
char in[4096];
int i;
int read;
fprintf(stderr, "Switching to lazy mode for low-latency\n");
for (i=0; running && i<5; i++) {
send_lazy_switch(dns_fd, userid);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'o', 'O', i+1);
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 lazy mode. ");
goto codec_revert;
} else if (strncmp("Lazy", in, 4) == 0) {
fprintf(stderr, "Server switched to lazy mode\n");
lazymode = 1;
return;
}
}
fprintf(stderr, "Retrying lazy mode switch...\n");
}
if (!running)
return;
fprintf(stderr, "No reply from server on lazy switch. ");
codec_revert:
fprintf(stderr, "Falling back to legacy mode\n");
lazymode = 0;
selecttimeout = 1;
}
static void
handshake_lazyoff(int dns_fd)
/* Used in the middle of data transfer, timing is different and no error msgs */
{
char in[4096];
int i;
int read;
for (i=0; running && i<5; i++) {
send_lazy_switch(dns_fd, userid);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'o', 'O', 1);
if (read == 9 && strncmp("Immediate", in, 9) == 0) {
warnx("Server switched back to legacy mode.\n");
lazymode = 0;
selecttimeout = 1;
return;
}
}
if (!running)
return;
warnx("No reply from server on legacy mode switch.\n");
}
static int
fragsize_check(char *in, int read, int proposed_fragsize, int *max_fragsize)
/* Returns: 0: keep checking, 1: break loop (either okay or definitely wrong) */
{
int acked_fragsize = ((in[0] & 0xff) << 8) | (in[1] & 0xff);
int okay;
int i;
unsigned int v;
if (read >= 5 && strncmp("BADIP", in, 5) == 0) {
fprintf(stderr, "got BADIP (Try iodined -c)..\n");
fflush(stderr);
return 0; /* maybe temporary error */
}
if (acked_fragsize != proposed_fragsize) {
/*
* got ack for wrong fragsize, maybe late response for
* earlier query, or ack corrupted
*/
return 0;
}
if (read != proposed_fragsize) {
/*
* correctly acked fragsize but read too little (or too
* much): this fragsize is definitely not reliable
*/
return 1;
}
/* here: read == proposed_fragsize == acked_fragsize */
/* test: */
/* in[123] = 123; */
if ((in[2] & 0xff) != 107) {
fprintf(stderr, "\n");
warnx("corruption at byte 2, this won't work. Try -O Base32, or other -T options.");
*max_fragsize = -1;
return 1;
}
/* Check for corruption */
okay = 1;
v = in[3] & 0xff;
for (i = 3; i < read; i++, v = (v + 107) & 0xff)
if ((in[i] & 0xff) != v) {
okay = 0;
break;
}
if (okay) {
fprintf(stderr, "%d ok.. ", acked_fragsize);
fflush(stderr);
*max_fragsize = acked_fragsize;
return 1;
} else {
if (downenc != ' ' && downenc != 'T') {
fprintf(stderr, "%d corrupted at %d.. (Try -O Base32)\n", acked_fragsize, i);
} else {
fprintf(stderr, "%d corrupted at %d.. ", acked_fragsize, i);
}
fflush(stderr);
return 1;
}
/* notreached */
return 1;
}
static int
handshake_autoprobe_fragsize(int dns_fd)
{
char in[4096];
int i;
int read;
int proposed_fragsize = 768;
int range = 768;
int max_fragsize;
max_fragsize = 0;
fprintf(stderr, "Autoprobing max downstream fragment size... (skip with -m fragsize)\n");
while (running && range > 0 && (range >= 8 || max_fragsize < 300)) {
/* stop the slow probing early when we have enough bytes anyway */
for (i=0; running && i<3 ;i++) {
send_fragsize_probe(dns_fd, proposed_fragsize);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'r', 'R', 1);
if (read > 0) {
/* We got a reply */
if (fragsize_check(in, read, proposed_fragsize, &max_fragsize) == 1)
break;
}
fprintf(stderr, ".");
fflush(stderr);
}
if (max_fragsize < 0)
break;
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 setting manually with -m)");
return 0;
}
if (max_fragsize <= 2) {
/* Tried all the way down to 2 and found no good size.
But we _did_ do all handshake before this, so there must
be some workable connection. */
fprintf(stderr, "\n");
warnx("found no accepted fragment size.");
warnx("try setting -M to 200 or lower, or try other -T or -O options.");
return 0;
}
/* data header adds 2 bytes */
fprintf(stderr, "will use %d-2=%d\n", max_fragsize, max_fragsize - 2);
/* need 1200 / 16frags = 75 bytes fragsize */
if (max_fragsize < 82) {
fprintf(stderr, "Note: this probably won't work well.\n");
fprintf(stderr, "Try setting -M to 200 or lower, or try other DNS types (-T option).\n");
} else if (max_fragsize < 202 &&
(do_qtype == T_NULL || do_qtype == T_TXT ||
do_qtype == T_SRV || do_qtype == T_MX)) {
fprintf(stderr, "Note: this isn't very much.\n");
fprintf(stderr, "Try setting -M to 200 or lower, or try other DNS types (-T option).\n");
}
return max_fragsize - 2;
}
static void
handshake_set_fragsize(int dns_fd, int fragsize)
{
char in[4096];
int i;
int read;
fprintf(stderr, "Setting downstream fragment size to max %d...\n", fragsize);
for (i=0; running && i<5 ;i++) {
send_set_downstream_fragsize(dns_fd, fragsize);
read = handshake_waitdns(dns_fd, in, sizeof(in), 'n', 'N', i+1);
if (read > 0) {
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;
}
/* The server returns the accepted fragsize:
accepted_fragsize = ((in[0] & 0xff) << 8) | (in[1] & 0xff) */
return;
}
fprintf(stderr, "Retrying set fragsize...\n");
}
if (!running)
return;
fprintf(stderr, "No reply from server when setting fragsize. Keeping default.\n");
}
int
client_handshake(int dns_fd, int raw_mode, int autodetect_frag_size, int fragsize)
{
int seed;
int upcodec;
int r;
dnsc_use_edns0 = 0;
/* qtype message printed in handshake function */
if (do_qtype == T_UNSET) {
r = handshake_qtype_autodetect(dns_fd);
if (r) {
return r;
}
}
fprintf(stderr, "Using DNS type %s queries\n", get_qtype());
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;
selecttimeout = 20;
} else {
if (raw_mode == 0) {
fprintf(stderr, "Skipping raw mode\n");
}
dnsc_use_edns0 = 1;
if (handshake_edns0_check(dns_fd) && running) {
fprintf(stderr, "Using EDNS0 extension\n");
} else if (!running) {
return -1;
} else {
fprintf(stderr, "DNS relay does not support EDNS0 extension\n");
dnsc_use_edns0 = 0;
}
upcodec = handshake_upenc_autodetect(dns_fd);
if (!running)
return -1;
if (upcodec == 1) {
handshake_switch_codec(dns_fd, 6);
} else if (upcodec == 2) {
handshake_switch_codec(dns_fd, 26);
} else if (upcodec == 3) {
handshake_switch_codec(dns_fd, 7);
}
if (!running)
return -1;
if (downenc == ' ') {
downenc = handshake_downenc_autodetect(dns_fd);
}
if (!running)
return -1;
if (downenc != ' ') {
handshake_switch_downenc(dns_fd);
}
if (!running)
return -1;
if (lazymode) {
handshake_try_lazy(dns_fd);
}
if (!running)
return -1;
if (autodetect_frag_size) {
fragsize = handshake_autoprobe_fragsize(dns_fd);
if (!fragsize) {
return 1;
}
}
handshake_set_fragsize(dns_fd, fragsize);
if (!running)
return -1;
}
return 0;
}