Detailed specification of protocol in version 00000502 ====================================================== Note: work in progress!! ====================================================== 1. DNS protocol ====================================================== Quick alphabetical index / register: 0-9 Data packet A-F Data packet I IP address L Login N Downstream fragsize (NS.topdomain A-type reply) O Options P Ping R Downstream fragsize probe S Switch upstream codec V Version W (WWW.topdomain A-type reply) Y Downstream codec check Z Upstream codec check CMC = 2 byte Cache Miss Counter, increased every time it is used Version: Client sends: First byte v or V Rest encoded with base32: 4 bytes big endian protocol version CMC Server replies: 4 chars: VACK (version ok), followed by login challenge VNAK (version differs), followed by server protocol version VFUL (server has no free slots), followed by max users 4 byte value: means login challenge/server protocol version/max users 1 byte userid of the new user, or any byte if not VACK Login: Client sends: First byte l or L Rest encoded with base32: 1 byte userid 16 bytes MD5 hash of: (first 32 bytes of password) xor (8 repetitions of login challenge) CMC Server replies: LNAK means not accepted x.x.x.x-y.y.y.y-mtu-netmask means accepted (server ip, client ip, mtu, netmask bits) IP Request: Client sends: First byte i or I 5 bits coded as Base32 char, meaning userid CMC as 3 Base32 chars Server replies BADIP if bad userid, or I and then 4 bytes network order external IP address of iodined server Upstream codec check / bounce: Client sends: First byte z or Z Lots of data that should not be decoded Server replies: The requested domain copied raw, in the lowest-grade downstream codec available for the request type. Downstream codec check: Client sends: First byte y or Y 1 char, meaning downstream codec to use 5 bits coded as Base32 char, meaning check variant CMC as 3 Base32 chars Possibly extra data, depending on check variant Server sends: Data encoded with requested downstream codec; data content depending on check variant number. BADCODEC if requested downstream codec not available. BADLEN if check variant is not available, or problem with extra data. Downstream codec chars are same as in 'O' Option request, below. Check variants: 1: Send encoded DOWNCODECCHECK1 string as defined in encoding.h (Other variants reserved; possibly variant that sends a decoded-encoded copy of Base32-encoded extra data in the request) Switch codec: Client sends: First byte s or S 5 bits coded as Base32 char, meaning userid 5 bits coded as Base32 char, representing number of raw bits per encoded byte: 5: Base32 (a-z0-5) 6: Base64 (a-zA-Z0-9+-) 26: Base64u (a-zA-Z0-9_-) 7: Base128 (a-zA-Z0-9\274-\375) CMC as 3 Base32 chars Server sends: Name of codec if accepted. After this all upstream data packets must be encoded with the new codec. BADCODEC if not accepted. Client must then revert to previous codec BADLEN if length of query is too short Options: Client sends: First byte o or O 5 bits coded as Base32 char, meaning userid 1 char, meaning option CMC as 3 Base32 chars Server sends: Full name of option if accepted. After this, option immediately takes effect in server. BADCODEC if not accepted. Previous situation remains. All options affect only the requesting client. Option chars: t or T: Downstream encoding Base32, for TXT/CNAME/A/MX (default) s or S: Downstream encoding Base64, for TXT/CNAME/A/MX u or U: Downstream encoding Base64u, for TXT/CNAME/A/MX v or V: Downstream encoding Base128, for TXT/CNAME/A/MX r or R: Downstream encoding Raw, for PRIVATE/TXT/NULL (default for PRIVATE and NULL) If codec unsupported for request type, server will use Base32; note that server will answer any mix of request types that a client 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 15 bits coded as 3 Base32 chars: UUUUF FFFFF FFFFF meaning 4 bits userid, 11 bits fragment size Then follows a long random query which contents does not matter Server sends: Requested number of bytes as a response. The first two bytes contain the requested length. The third byte is 107 (0x6B). The fourth byte is a random value, and each following byte is incremented with 107. This is checked by the client to determine corruption. BADFRAG if requested length not accepted. Set downstream fragment size: Client sends: First byte n or N Rest encoded with base32: 1 byte userid 2 bytes new downstream fragment size CMC Server sends: 2 bytes new downstream fragment size. After this all downstream payloads will be max (fragsize + 2) bytes long. BADFRAG if not accepted. Data: Upstream data header: 3210 432 10 43 210 4321 0 43210 +----+---+--+--+---+----+-+-----+ |UUUU|SSS|FF|FF|DDD|GGGG|L|UDCMC| +----+---+--+--+---+----+-+-----+ Downstream data header: 7 654 3210 765 4321 0 +-+---+----+---+----+-+ |C|SSS|FFFF|DDD|GGGG|L| +-+---+----+---+----+-+ UUUU = Userid L = Last fragment in packet flag SS = Upstream packet sequence number FFFF = Upstream fragment number DDD = Downstream packet sequence number GGGG = Downstream fragment number C = Compression enabled for downstream packet UDCMC = Upstream Data CMC, 36 steps a-z0-9, case-insensitive Upstream data packet starts with 1 byte ASCII hex coded user byte; then 3 bytes Base32 encoded header; then 1 char data-CMC; then comes the payload data, encoded with the chosen upstream codec. Downstream data starts with 2 byte header. Then payload data, which may be compressed. In NULL and PRIVATE responses, downstream data is always raw. In all other response types, downstream data is encoded (see Options above). Encoding type is indicated by 1 prefix char: TXT: End result is always DNS-chopped (series of len-prefixed strings <=255 bytes) t or T: Base32 encoded before chop, decoded after un-chop s or S: Base64 encoded before chop, decoded after un-chop u or U: Base64u encoded before chop, decoded after un-chop v or V: Base128 encoded before chop, decoded after un-chop r or R: Raw no encoding, only DNS-chop SRV/MX/CNAME/A: h or H: Hostname encoded with Base32 i or I: Hostname encoded with Base64 j or J: Hostname encoded with Base64u k or K: Hostname encoded with Base128 SRV and MX may reply with multiple hostnames, each encoded separately. Each has a 10-multiple priority, and encoding/decoding is done in strictly increasing priority sequence 10, 20, 30, etc. without gaps. Note that some DNS relays will shuffle the answer records in the response. Ping: Client sends: First byte p or P Rest encoded with Base32: 1 byte with 4 bits userid 1 byte with: 3 bits downstream seqno 4 bits downstream fragment CMC The server response to Ping and Data packets is a DNS NULL/TXT/.. type response, always starting with the 2 bytes downstream data header as shown above. If server has nothing to send, no data is added after the header. If server has something to send, it will add the downstream data packet (or some fragment of it) after the header. "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 ====================================================== All Raw UDP protcol messages start with a 3 byte header: 0x10d19e This is not the start of a valid DNS message so it is easy to identify. The fourth byte contains the command and the user id. 7654 3210 +----+----+ |CCCC|UUUU| +----+----+ Login message (command = 1): The header is followed by a MD5 hash with the same password as in the DNS login. The client starts the raw mode by sending this message, and uses the login challenge +1, and the server responds using the login challenge -1. After the login message has been exchanged, both the server and the client switch to raw udp mode for the rest of the connection. Data message (command = 2): After the header comes the payload data, which may be compressed. Ping message (command = 3): Sent from client to server and back to keep session open. Has no payload.