13 Distribution Protocol
This description is far from complete. It will be updated if the protocol is updated. However, the protocols, both from Erlang nodes to the Erlang Port Mapper Daemon (EPMD) and between Erlang nodes are stable since many years.
The distribution protocol can be divided into four parts:
-
Low-level socket connection (1)
-
Handshake, interchange node name, and authenticate (2)
-
Authentication (done by
net_kernel(3)
) (3) -
Connected (4)
A node fetches the port number of another node through the EPMD (at the other host) to initiate a connection request.
For each host, where a distributed Erlang node is running, also an EPMD is to be running. The EPMD can be started explicitly or automatically as a result of the Erlang node startup.
By default the EPMD listens on port 4369.
(3) and (4) above are performed at the same level but the net_kernel
disconnects the other node if it communicates using an invalid cookie (after 1 second).
The integers in all multibyte fields are in big-endian order.
The Erlang Distribution protocol is not by itself secure and does not aim to be so. In order to get secure distribution the distributed nodes should be configured to use distribution over tls. See the Using SSL for Erlang Distribution
User's Guide for details on how to setup a secure distributed node.
13.1 EPMD Protocol
The requests served by the EPMD are summarized in the following figure.
Each request *_REQ
is preceded by a 2 byte length field. Thus, the overall request format is as follows:
2 | n |
Length | Request |
Register a Node in EPMD
When a distributed node is started it registers itself in the EPMD. The message ALIVE2_REQ
described below is sent from the node to the EPMD. The response from the EPMD is ALIVE2_RESP
.
1 | 2 | 1 | 1 | 2 | 2 | 2 | Nlen | 2 | Elen |
120 | PortNo | NodeType | Protocol | HighestVersion | LowestVersion | Nlen | NodeName | Elen | Extra |
PortNo
-
The port number on which the node accept connection requests.
NodeType
-
77 = normal Erlang node, 72 = hidden node (C-node), ...
Protocol
-
0 = TCP/IPv4, ...
HighestVersion
-
The highest distribution version that this node can handle. The value in Erlang/OTP R6B and later is 5.
LowestVersion
-
The lowest distribution version that this node can handle. The value in Erlang/OTP R6B and later is 5.
Nlen
-
The length (in bytes) of field
NodeName
. NodeName
-
The node name as an UTF-8 encoded string of
Nlen
bytes. Elen
-
The length of field
Extra
. Extra
-
Extra field of
Elen
bytes.
The connection created to the EPMD must be kept as long as the node is a distributed node. When the connection is closed, the node is automatically unregistered from the EPMD.
The response message ALIVE2_RESP
is as follows:
1 | 1 | 2 |
121 | Result | Creation |
Result = 0 -> ok, result > 0 -> error.
Unregister a Node from EPMD
A node unregisters itself from the EPMD by closing the TCP connection to EPMD established when the node was registered.
Get the Distribution Port of Another Node
When one node wants to connect to another node it starts with a PORT_PLEASE2_REQ
request to the EPMD on the host where the node resides to get the distribution port that the node listens to.
1 | N |
122 | NodeName |
where N = Length
- 1.
1 | 1 |
119 | Result |
or
1 | 1 | 2 | 1 | 1 | 2 | 2 | 2 | Nlen | 2 | Elen |
119 | Result | PortNo | NodeType | Protocol | HighestVersion | LowestVersion | Nlen | NodeName | Elen | >Extra |
If Result
> 0, the packet only consists of [119, Result]
.
The EPMD closes the socket when it has sent the information.
Get All Registered Names from EPMD
This request is used through the Erlang function net_adm:names/1,2
. A TCP connection is opened to the EPMD and this request is sent.
1 |
110 |
The response for a NAMES_REQ
is as follows:
4 | |
EPMDPortNo | NodeInfo* |
NodeInfo
is a string written for each active node. When all NodeInfo
has been written the connection is closed by the EPMD.
NodeInfo
is, as expressed in Erlang:
io:format("name ~ts at port ~p~n", [NodeName, Port]).
Dump All Data from EPMD
This request is not really used, it is to be regarded as a debug feature.
1 |
100 |
The response for a DUMP_REQ
is as follows:
4 | |
EPMDPortNo | NodeInfo* |
NodeInfo
is a string written for each node kept in the EPMD. When all NodeInfo
has been written the connection is closed by the EPMD.
NodeInfo
is, as expressed in Erlang:
io:format("active name ~ts at port ~p, fd = ~p~n", [NodeName, Port, Fd]).
or
io:format("old/unused name ~ts at port ~p, fd = ~p ~n", [NodeName, Port, Fd]).
Kill EPMD
This request kills the running EPMD. It is almost never used.
1 |
107 |
The response for a KILL_REQ
is as follows:
2 |
OKString |
where OKString
is "OK".
STOP_REQ (Not Used)
1 | n |
115 | NodeName |
where n = Length
- 1.
The current implementation of Erlang does not care if the connection to the EPMD is broken.
The response for a STOP_REQ
is as follows:
7 |
OKString |
where OKString
is "STOPPED".
A negative response can look as follows:
7 |
NOKString |
where NOKString
is "NOEXIST".
13.2 Distribution Handshake
This section describes the distribution handshake protocol introduced in Erlang/OTP R6. This description was previously located in $ERL_TOP/lib/kernel/internal_doc/distribution_handshake.txt
and has more or less been copied and "formatted" here. It has been almost unchanged since 1999, but the handshake has not changed much since then either.
General
The TCP/IP distribution uses a handshake that expects a connection-based protocol, that is, the protocol does not include any authentication after the handshake procedure.
This is not entirely safe, as it is vulnerable against takeover attacks, but it is a tradeoff between fair safety and performance.
The cookies are never sent in cleartext and the handshake procedure expects the client (called A
) to be the first one to prove that it can generate a sufficient digest. The digest is generated with the MD5 message digest algorithm and the challenges are expected to be random numbers.
Definitions
A challenge is a 32-bit integer in big-endian order. Below the function gen_challenge()
returns a random 32-bit integer used as a challenge.
A digest is a (16 bytes) MD5 hash of the challenge (as text) concatenated with the cookie (as text). Below, the function gen_digest(Challenge, Cookie)
generates a digest as described above.
An out_cookie
is the cookie used in outgoing communication to a certain node, so that A
's out_cookie
for B
is to correspond with B
's in_cookie
for A
and conversely. A
's out_cookie
for B
and A
's in_cookie
for B
need not be the same. Below the function out_cookie(Node)
returns the current node's out_cookie
for Node
.
An in_cookie
is the cookie expected to be used by another node when communicating with us, so that A
's in_cookie
for B
corresponds with B
's out_cookie
for A
. Below the function in_cookie(Node)
returns the current node's in_cookie
for Node
.
The cookies are text strings that can be viewed as passwords.
Every message in the handshake starts with a 16-bit big-endian integer, which contains the message length (not counting the two initial bytes). In Erlang this corresponds to option {packet, 2}
in gen_tcp(3)
. Notice that after the handshake, the distribution switches to 4 byte packet headers.
The Handshake in Detail
Imagine two nodes, A
that initiates the handshake and B
that accepts the connection.
- 1) connect/accept
-
A
connects toB
through TCP/IP andB
accepts the connection. - 2)
send_name
/receive_name
-
A
sends an initial identification toB
, which receives the message. The message looks as follows (every "square" is one byte and the packet header is removed):+---+--------+--------+-----+-----+-----+-----+-----+-----+-...-+-----+ |'n'|Version0|Version1|Flag0|Flag1|Flag2|Flag3|Name0|Name1| ... |NameN| +---+--------+--------+-----+-----+-----+-----+-----+-----+-... +-----+
'n' is the message tag. 'Version0' and 'Version1' is the distribution version selected by
A
, based on information from the EPMD. (16-bit big-endian) 'Flag0' ... 'Flag3' are capability flags, the capabilities are defined in$ERL_TOP/lib/kernel/include/dist.hrl
. (32-bit big-endian) 'Name0' ... 'NameN' is the full node name ofA
, as a string of bytes (the packet length denotes how long it is). - 3)
recv_status
/send_status
-
B
sends a status message toA
, which indicates if the connection is allowed. The following status codes are defined:ok
-
The handshake will continue.
ok_simultaneous
-
The handshake will continue, but
A
is informed thatB
has another ongoing connection attempt that will be shut down (simultaneous connect whereA
's name is greater thanB
's name, compared literally). nok
-
The handshake will not continue, as
B
already has an ongoing handshake, which it itself has initiated (simultaneous connect whereB
's name is greater thanA
's). not_allowed
-
The connection is disallowed for some (unspecified) security reason.
alive
-
A connection to the node is already active, which either means that node
A
is confused or that the TCP connection breakdown of a previous node with this name has not yet reached nodeB
. See step 3B below.
The format of the status message is as follows:
+---+-------+-------+-...-+-------+ |'s'|Status0|Status1| ... |StatusN| +---+-------+-------+-...-+-------+
's' is the message tag. 'Status0' ... 'StatusN' is the status as a string (not terminated).
- 3B)
send_status
/recv_status
-
If status was
alive
, nodeA
answers with another status message containing eithertrue
, which means that the connection is to continue (the old connection from this node is broken), orfalse
, which means that the connection is to be closed (the connection attempt was a mistake. - 4)
recv_challenge
/send_challenge
-
If the status was
ok
orok_simultaneous
, the handshake continues withB
sendingA
another message, the challenge. The challenge contains the same type of information as the "name" message initially sent fromA
toB
, plus a 32-bit challenge:+---+--------+--------+-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+-...-+-----+ |'n'|Version0|Version1|Flag0|Flag1|Flag2|Flag3|Chal0|Chal1|Chal2|Chal3|Name0|Name1| ... |NameN| +---+--------+--------+-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+-... +-----+
'Chal0' ... 'Chal3' is the challenge as a 32-bit big-endian integer and the other fields are
B
's version, flags, and full node name. - 5)
send_challenge_reply
/recv_challenge_reply
-
Now
A
has generated a digest and its own challenge. Those are sent together in a package toB
:+---+-----+-----+-----+-----+-----+-----+-----+-----+-...-+------+ |'r'|Chal0|Chal1|Chal2|Chal3|Dige0|Dige1|Dige2|Dige3| ... |Dige15| +---+-----+-----+-----+-----+-----+-----+-----+-----+-...-+------+
'r' is the tag. 'Chal0' ... 'Chal3' is
A
's challenge forB
to handle. 'Dige0' ... 'Dige15' is the digest thatA
constructed from the challengeB
sent in the previous step. - 6)
recv_challenge_ack
/send_challenge_ack
-
B
checks that the digest received fromA
is correct and generates a digest from the challenge received fromA
. The digest is then sent toA
. The message is as follows:+---+-----+-----+-----+-----+-...-+------+ |'a'|Dige0|Dige1|Dige2|Dige3| ... |Dige15| +---+-----+-----+-----+-----+-...-+------+
'a' is the tag. 'Dige0' ... 'Dige15' is the digest calculated by
B
forA
's challenge. - 7) check
-
A
checks the digest fromB
and the connection is up.
Semigraphic View
A (initiator) B (acceptor) TCP connect ------------------------------------> TCP accept send_name --------------------------------------> recv_name <---------------------------------------------- send_status recv_status (if status was 'alive' send_status - - - - - - - - - - - - - - - - - -> recv_status) ChB = gen_challenge() (ChB) <---------------------------------------------- send_challenge recv_challenge ChA = gen_challenge(), OCA = out_cookie(B), DiA = gen_digest(ChB, OCA) (ChA, DiA) send_challenge_reply ---------------------------> recv_challenge_reply ICB = in_cookie(A), check: DiA == gen_digest (ChB, ICB)? - if OK: OCB = out_cookie(A), DiB = gen_digest (ChA, OCB) (DiB) <----------------------------------------------- send_challenge_ack recv_challenge_ack DONE ICA = in_cookie(B), - else: check: CLOSE DiB == gen_digest(ChA, ICA)? - if OK: DONE - else: CLOSE
Distribution Flags
The following capability flags are defined:
-define(DFLAG_PUBLISHED,16#1).
-
The node is to be published and part of the global namespace.
-define(DFLAG_ATOM_CACHE,16#2).
-
The node implements an atom cache (obsolete).
-define(DFLAG_EXTENDED_REFERENCES,16#4).
-
The node implements extended (3 × 32 bits) references. This is required today. If not present, the connection is refused.
-define(DFLAG_DIST_MONITOR,16#8).
-
The node implements distributed process monitoring.
-define(DFLAG_FUN_TAGS,16#10).
-
The node uses separate tag for funs (lambdas) in the distribution protocol.
-define(DFLAG_DIST_MONITOR_NAME,16#20).
-
The node implements distributed named process monitoring.
-define(DFLAG_HIDDEN_ATOM_CACHE,16#40).
-
The (hidden) node implements atom cache (obsolete).
-define(DFLAG_NEW_FUN_TAGS,16#80).
-
The node understand new fun tags.
-define(DFLAG_EXTENDED_PIDS_PORTS,16#100).
-
The node can handle extended pids and ports. This is required today. If not present, the connection is refused.
-define(DFLAG_EXPORT_PTR_TAG,16#200).
-define(DFLAG_BIT_BINARIES,16#400).
-define(DFLAG_NEW_FLOATS,16#800).
-
The node understands new float format.
-define(DFLAG_UNICODE_IO,16#1000).
-define(DFLAG_DIST_HDR_ATOM_CACHE,16#2000).
-
The node implements atom cache in distribution header.
-define(DFLAG_SMALL_ATOM_TAGS, 16#4000).
-
The node understand the
SMALL_ATOM_EXT
tag. -define(DFLAG_UTF8_ATOMS, 16#10000).
-
The node understand UTF-8 encoded atoms.
-define(DFLAG_MAP_TAG, 16#20000).
-
The node understand the map tag.
-define(DFLAG_BIG_CREATION, 16#40000).
-
The node understand big node creation.
-define(DFLAG_SEND_SENDER, 16#80000).
-
Use the
SEND_SENDER
control message
instead of theSEND
control message and use theSEND_SENDER_TT
control message instead of theSEND_TT
control message.
There is also function dist_util:strict_order_flags/0
returning all flags (bitwise or:ed together) corresponding to features that require strict ordering of data over distribution channels.
13.3 Protocol between Connected Nodes
As from ERTS 5.7.2 the runtime system passes a distribution flag in the handshake stage that enables the use of a distribution header
on all messages passed. Messages passed between nodes have in this case the following format:
4 | d | n | m |
Length | DistributionHeader | ControlMessage | Message |
Length
-
Equal to d + n + m.
ControlMessage
-
A tuple passed using the external format of Erlang.
Message
-
The message sent to another node using the '!' (in external format). Notice that
Message
is only passed in combination with aControlMessage
encoding a send ('!').
Notice that the version number is omitted from the terms that follow a distribution header
.
Nodes with an ERTS version earlier than 5.7.2 does not pass the distribution flag that enables the distribution header. Messages passed between nodes have in this case the following format:
4 | 1 | n | m |
Length | Type | ControlMessage | Message |
Length
-
Equal to 1 + n + m.
Type
-
Equal to
112
(pass through). ControlMessage
-
A tuple passed using the external format of Erlang.
Message
-
The message sent to another node using the '!' (in external format). Notice that
Message
is only passed in combination with aControlMessage
encoding a send ('!').
The ControlMessage
is a tuple, where the first element indicates which distributed operation it encodes:
LINK
-
{1, FromPid, ToPid}
SEND
-
{2, Unused, ToPid}
Followed by
Message
.Unused
is kept for backward compatibility. EXIT
-
{3, FromPid, ToPid, Reason}
UNLINK
-
{4, FromPid, ToPid}
NODE_LINK
-
{5}
REG_SEND
-
{6, FromPid, Unused, ToName}
Followed by
Message
.Unused
is kept for backward compatibility. GROUP_LEADER
-
{7, FromPid, ToPid}
EXIT2
-
{8, FromPid, ToPid, Reason}
13.4 New Ctrlmessages for distrvsn = 1 (Erlang/OTP R4)
SEND_TT
-
{12, Unused, ToPid, TraceToken}
Followed by
Message
.Unused
is kept for backward compatibility. EXIT_TT
-
{13, FromPid, ToPid, TraceToken, Reason}
REG_SEND_TT
-
{16, FromPid, Unused, ToName, TraceToken}
Followed by
Message
.Unused
is kept for backward compatibility. EXIT2_TT
-
{18, FromPid, ToPid, TraceToken, Reason}
13.5 New Ctrlmessages for distrvsn = 2
distrvsn
2 was never used.
13.6 New Ctrlmessages for distrvsn = 3 (Erlang/OTP R5C)
None, but the version number was increased anyway.
13.7 New Ctrlmessages for distrvsn = 4 (Erlang/OTP R6)
These are only recognized by Erlang nodes, not by hidden nodes.
MONITOR_P
-
{19, FromPid, ToProc, Ref}
, whereFromPid
= monitoring process andToProc
= monitored process pid or name (atom) DEMONITOR_P
-
{20, FromPid, ToProc, Ref}
, whereFromPid
= monitoring process andToProc
= monitored process pid or name (atom)We include
FromPid
just in case we want to trace this. MONITOR_P_EXIT
-
{21, FromProc, ToPid, Ref, Reason}
, whereFromProc
= monitored process pid or name (atom),ToPid
= monitoring process, andReason
= exit reason for the monitored process
13.8 New Ctrlmessages for Erlang/OTP 21
SEND_SENDER
-
{22, FromPid, ToPid}
Followed by
Message
.This control messages replace the
SEND
control message and will be sent when the distribution flagDFLAG_SEND_SENDER
has been negotiated in the connection setup handshake.NoteMessages encoded before the connection has been set up may still use the
SEND
control message. However, once aSEND_SENDER
orSEND_SENDER_TT
control message has been sent, no moreSEND
control messages will be sent in the same direction on the connection. SEND_SENDER_TT
-
{23, FromPid, ToPid, TraceToken}
Followed by
Message
.This control messages replace the
SEND_TT
control message and will be sent when the distribution flagDFLAG_SEND_SENDER
has been negotiated in the connection setup handshake.NoteMessages encoded before the connection has been set up may still use the
SEND_TT
control message. However, once aSEND_SENDER
orSEND_SENDER_TT
control message has been sent, no moreSEND_TT
control messages will be sent in the same direction on the connection.
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Licensed under the Apache License, Version 2.0.