#76 start merging common and docs

2024-11-16 12:53:17 +00:00 · 2009-09-20 21:10:38 +00:00 · 2009-09-20 21:10:38 +00:00 · eb0bf45396
parent ed36bbdf65
commit eb0bf45396
4 changed files with 185 additions and 2 deletions
--- a/130
+++ b/130
@ -94,6 +94,41 @@ should always work. For more bandwidth, try Base64 or Raw (TXT only) via the
 -O option. If Base64/Raw doesn't work, you'll see many failures in the
 fragment size autoprobe.
 Normal operation now is for the server to _not_ answer a DNS request until
 the next DNS request has come in, a.k.a. being "lazy". This way, the server
 will always have a DNS request handy when new downstream data has to be sent.
 This greatly improves (interactive) performance and latency, and allows to
 slow down the quiescent ping requests to 4 second intervals by default.
 In fact, the main purpose of the pings now is to force a reply to the previous
 ping, and prevent DNS server timeouts (usually 5-10 seconds per RFC1035).
 In the unlikely case that you do experience DNS server timeouts (SERVFAIL),
 decrease the -I option to 1. If you are running on a local network without
 any DNS server in-between, try -I 50 (iodine and iodined time out after 60
 seconds). The only time you'll notice a slowdown, is when DNS reply packets
 go missing; the iodined server then has to wait for a new ping to re-send the
 data. You can speed this up by generating some upstream traffic (keypress,
 ping). If this happens often, check your network for bottlenecks and/or run
 with -I1 .
 Some DNS servers appear to be quite impatient and start retrying DNS requests
 (with _different_ DNS ids!) when an answer does not appear within a few
 milliseconds. Usually they scale back retries when iodined's lazy mode
 repeatedly takes several seconds to answer; and they scale up retries again
 when iodined answers fast during heavy data transfer. Some commercial DNS
 servers advertise this as "carrier-grade adaptive retransmission techniques".
 The effect will only be visible in the network traffic at the iodined server,
 and will not affect the client's connection. Iodined has rather elaborate
 logic to deal with (i.e., ignore) these unwanted duplicates.
 Other DNS servers, notably the opendns.com network, seem to regard iodined's
 lazyness as incompetency, and will start shuffling requests around, possibly
 in an attempt to reduce iodined's workload. The resulting out-of-sequence DNS
 traffic works quite badly for lazy mode. The iodine client will detect this,
 and switch back to legacy mode ("immediate ping-pong") automatically. In these
 cases, start the iodine client with -L0 to prevent it from operating in lazy
 mode altogether. Note that this will negatively affect interactive performance
 and latency, especially in the downstream direction.
 If you have problems, try inspecting the traffic with network monitoring tools
 and make sure that the relaying DNS server has not cached the response. A
 cached error message could mean that you started the client before the server.
@ -109,12 +144,103 @@ iptables -t nat -A PREROUTING -i eth0 -p udp --dport 53 -j DNAT --to :5353
 (Sent in by Tom Schouten)
 Iodined will reject data from clients that have not been active (data/pings)
-for more than 60 seconds. In case of a long network outage or similar, just
+for more than 60 seconds. Similarly, iodine will exit when no downstream
-stop iodine and restart (re-login), possibly multiple times until you get
+data has been received for 60 seconds. In case of a long network outage or
 similar, just restart iodine (re-login), possibly multiple times until you get
 your old IP address back. Once that's done, just wait a while, and you'll
 eventually see the tunneled TCP traffic continue to flow from where it left
 off before the outage.
 With the introduction of the downstream packet queue in the server, its memory
 usage has increased with several megabytes in the default configuration.
 For use in low-memory environments (e.g. running on your DSL router), you can
 decrease USERS and undefine OUTPACKETQ_LEN in user.h without any ill conse-
 quence, assuming at most one client will be connected at any time. A small
 DNSCACHE_LEN is still advised, preferably 2 or higher, however you can also
 undefine it to save a few more kilobytes.
 PERFORMANCE:
 This section tabulates some performance measurements. To view properly, use
 a fixed-width font like Courier.
 Measurements were done in protocol 00000500 with lazy mode unless indicated
 otherwise. Upstream encoding always Base64.
 Upstream/downstream throughput was measured by scp'ing a file previously
 read from /dev/urandom (i.e. incompressible), and measuring size with
 "ls -l ; sleep 30 ; ls -l" on a separate non-tunneled connection. Given the
 large scp block size of 16 kB, this gives a resolution of 4.3 kbit/s, which
 explains why many values are exactly equal.
 Ping round-trip times measured with "ping -c100", presented are average rtt
 and mean deviation (indicating spread around the average), in milliseconds.
 Situation 1:
 Laptop  ->   Wifi AP   ->  Home server  ->  DSL provider  ->  Datacenter
 iodine    DNS "relay"        bind9           DNS cache        iodined
                        downstr.  upstream downstr.  ping-up       ping-down
                        fragsize   kbit/s   kbit/s  avg +/-mdev   avg +/-mdev
 ------------------------------------------------------------------------------
 iodine -> Wifi AP :53
  -Tnull (= -Oraw)           982    39.3    148.5   26.7    3.1   26.6    3.0
 iodine -> Home server :53
  -Tnull (= -Oraw)          1174    43.6    174.7   25.2    4.0   25.5    3.4
 iodine -> DSL provider :53  
  -Tnull (= -Oraw)          1174    52.4    200.9   20.3    3.2   20.3    2.7
  -Ttxt -Obase32             730    52.4    192.2*
  -Ttxt -Obase64             874    52.4    192.2
  -Ttxt -Oraw               1162    52.4    192.2
  -Tcname -Obase32           148    52.4     48.0
  -Tcname -Obase64           181    52.4     61.1
 iodine -> DSL provider :53  
  wired (no Wifi) -Tnull    1174    65.5    244.6   17.7    1.9   17.8    1.6
 [192.2* : nice, because still 2frag/packet]
 Situation 2:
 Laptop -> (wire) -> (Home server) -> (DSL) ->  opendns.com ->  Datacenter
 iodine                                         DNS cache       iodined
                        downstr.  upstream downstr.  ping-up       ping-down
                        fragsize   kbit/s   kbit/s  avg +/-mdev   avg +/-mdev
 ------------------------------------------------------------------------------
 iodine -> opendns.com :53
  -Tnull -L1 (lazy mode)     230      -        -   404.4  196.2  663.8  679.6
                                                    (20% lost)     (2% lost)
  -Tnull -L0 (legacy mode)   230     5.6      7.4  197.3    4.7  610.8  323.5
 [Note: Throughput measured over 300 seconds to get better resolution]
 Situation 3:
 Laptop  ->  Wifi+vpn / wired  ->  Home server
 iodine                            iodined
                        downstr.  upstream downstr.  ping-up       ping-down
                        fragsize   kbit/s   kbit/s  avg +/-mdev   avg +/-mdev
 ------------------------------------------------------------------------------
 wifi + openvpn  -Tnull      1186   183.5    611.6    5.7    1.4    7.0    2.7
 wired  -Tnull               1186   685.9   2350.5    1.3    0.1    1.4    0.4
 Performance is strongly coupled to low ping times, as iodine requires
 confirmation for every data fragment before moving on to the next. Allowing
 multiple fragments in-flight like TCP could possibly increase performance,
 but it would likely cause serious overload for the intermediary DNS servers.
 The current protocol scales performance with DNS responsivity, since the
 DNS servers are on average handling at most one DNS request per client.
 PORTABILITY:
--- a/doc/proto_00000501.txt
+++ b/doc/proto_00000501.txt
@ -83,6 +83,12 @@ Server sends:
 	Server may disregard this option; client must always use the downstream
 	encoding type indicated in every downstream DNS packet.
 	l or L: Lazy mode, server will keep one request unanswered until the
 	next one comes in. Applies only to data transfer; handshake is always
 	answered immediately.
 	i or I: Immediate (non-lazy) mode, server will answer all requests
 	(nearly) immediately.
 Probe downstream fragment size:
 Client sends:
 	First byte r or R
@ -162,6 +168,39 @@ If server has something to send, it will send a downstream data packet,
 prefixed with 2 bytes header as shown above.
 "Lazy-mode" operation
 =====================
 Client-server DNS traffic sequence has been reordered to provide increased
 (interactive) performance and greatly reduced latency.
 Idea taken from Lucas Nussbaum's slides (24th IFIP International Security
 Conference, 2009) at http://www.loria.fr/~lnussbau/tuns.html. Current
 implementation is original to iodine, no code or documentation from any other
 project was consulted during development.
 Server:
 Upstream data is acked immediately*, to keep the slow upstream data flowing
 as fast as possible (client waits for ack to send next frag).
 Upstream pings are answered _only_ when 1) downstream data arrives from tun,
 OR 2) new upstream ping/data arrives from client.
 In most cases, this means we answer the previous DNS query instead of the
 current one. The current query is kept in queue and used as soon as
 downstream data has to be sent.
 *: upstream data ack is usually done as reply on the previous ping packet,
 and the upstream-data packet itself is kept in queue.
 Client:
 Downstream data is acked immediately, to keep it flowing fast (includes a
 ping after last downstream frag).
 Also, after all available upstream data is sent & acked by the server (which
 in some cases uses up the last query), send an additional ping to prime the
 server for the next downstream data.
 ======================================================
 2. Raw UDP protocol
 ======================================================
--- a/src/common.c
+++ b/src/common.c
@ -333,3 +333,18 @@ errx(int eval, const char *fmt, ...)
 }
 #endif
 int recent_seqno(int ourseqno, int gotseqno)
 /* Return 1 if we've seen gotseqno recently (current or up to 3 back).
   Return 0 if gotseqno is new (or very old).
 */
 {
 	int i;
 	for (i = 0; i < 4; i++, ourseqno--) {
 		if (ourseqno < 0)
 			ourseqno = 7;
 		if (gotseqno == ourseqno)
 			return 1;
 	}
 	return 0;
 }
--- a/src/common.h
+++ b/src/common.h
@ -88,6 +88,7 @@ struct query {
 	char name[QUERY_NAME_SIZE];
 	unsigned short type;
 	unsigned short id;
 	unsigned short iddupe;		/* only used for dupe checking */
 	struct in_addr destination;
 	struct sockaddr from;
 	int fromlen;
@ -121,4 +122,6 @@ void errx(int eval, const char *fmt, ...);
 void warnx(const char *fmt, ...);
 #endif
 int recent_seqno(int , int);
 #endif