View Source Distributed Erlang

Distributed Erlang System

A distributed Erlang system consists of a number of Erlang runtime systems communicating with each other. Each such runtime system is called a node. Message passing between processes at different nodes, as well as links and monitors, are transparent when pids are used. Registered names, however, are local to each node. This means that the node must be specified as well when sending messages, and so on, using registered names.

The distribution mechanism is implemented using TCP/IP sockets. How to implement an alternative carrier is described in the ERTS User's Guide.


Starting a distributed node without also specifying -proto_dist inet_tls will expose the node to attacks that may give the attacker complete access to the node and in extension the cluster. When using un-secure distributed nodes, make sure that the network is configured to keep potential attackers out. See the Using SSL for Erlang Distribution User's Guide for details on how to setup a secure distributed node.


A node is an executing Erlang runtime system that has been given a name, using the command-line flag -name (long names) or -sname (short names).

The format of the node name is an atom name@host. name is the name given by the user. host is the full host name if long names are used, or the first part of the host name if short names are used. Function node() returns the name of the node.


% erl -name dilbert
(> node().

% erl -sname dilbert
(dilbert@uab)1> node().

The node name can also be given in runtime by calling net_kernel:start/1.


% erl
1> node().
2> net_kernel:start([dilbert,shortnames]).
(dilbert@uab)3> node().


A node with a long node name cannot communicate with a node with a short node name.

Node Connections

The nodes in a distributed Erlang system are loosely connected. The first time the name of another node is used, for example, if spawn(Node, M, F, A) or net_adm:ping(Node) is called, a connection attempt to that node is made.

Connections are by default transitive. If a node A connects to node B, and node B has a connection to node C, then node A also tries to connect to node C. This feature can be turned off by using the command-line flag -connect_all false, see erl in ERTS.

If a node goes down, all connections to that node are removed. Calling erlang:disconnect_node(Node) forces disconnection of a node.

The list of (visible) nodes currently connected to is returned by nodes/0.


The Erlang Port Mapper Daemon epmd is automatically started at every host where an Erlang node is started. It is responsible for mapping the symbolic node names to machine addresses. See the epmd in ERTS.

Hidden Nodes

In a distributed Erlang system, it is sometimes useful to connect to a node without also connecting to all other nodes. An example is some kind of Operation and Maintenance functionality used to inspect the status of a system, without disturbing it. For this purpose, a hidden node can be used.

A hidden node is a node started with the command-line flag -hidden. Connections between hidden nodes and other nodes are not transitive, they must be set up explicitly. Also, hidden nodes does not show up in the list of nodes returned by nodes/0. Instead, nodes(hidden) or nodes(connected) must be used. This means, for example, that the hidden node is not added to the set of nodes that global is keeping track of.

Dynamic Node Name

If the node name is set to undefined the node will be started in a special mode to be the temporary client of another node. The node will then request a dynamic node name from the first node it connects to. In addition these distribution settings will be set:

-dist_listen false -hidden -kernel dist_auto_connect never

As -dist_auto_connect is set to never, net_kernel:connect_node/1 must be called in order to setup connections. If the first established connection is closed (which gave the node its dynamic name), then any other connections will also be closed and the node will lose its dynamic node name. A new call to net_kernel:connect_node/1 can be made to get a new dynamic node name. The node name may change if the distribution is dropped and then set up again.


The dynamic node name feature is supported from Erlang/OTP 23. Both the temporary client node and the first connected peer node (supplying the dynamic node name) must be at least Erlang/OTP 23 for it to work.

C Nodes

A C node is a C program written to act as a hidden node in a distributed Erlang system. The library Erl_Interface contains functions for this purpose. For more information about C nodes, see the Erl_Interface application and Interoperability Tutorial..



"Security" here does not mean cryptographically secure, but rather security against accidental misuse, such as preventing a node from connecting to a cluster with which it is not intended to communicate.

Furthermore, the communication between nodes is per default in clear text. If you need strong security, please see Using TLS for Erlang Distribution in the SSL application's User's Guide.

Also, the default random cookie mentioned in the following text is not very unpredictable. A better one can be generated using primitives in the crypto module, though this still does not make the initial handshake cryptographically secure. And inter-node communication is still in clear text.

Authentication determines which nodes are allowed to communicate with each other. In a network of different Erlang nodes, it is built into the system at the lowest possible level. All nodes use a magic cookie, which is an Erlang atom, when connecting another node.

During the connection setup, after node names have been exchanged, the magic cookies the nodes present to each other are compared. If they do not match, the connection is rejected. The cookies themselves are never transferred, instead they are compared using hashed challenges, although not in a cryptographically secure manner.

At start-up, a node has a random atom assigned as its default magic cookie and the cookie of other nodes is assumed to be nocookie. The first action of the Erlang network authentication server (auth) is then to search for a file named .erlang.cookie in the user's home directory and then in filename:basedir(user_config, "erlang"). If none of the files exist, a .erlang.cookie file is created in the user's home directory. The UNIX permissions mode of the file is set to octal 400 (read-only by user) and its content is a random string. An atom Cookie is created from the contents of the file and the cookie of the local node is set to this using erlang:set_cookie(Cookie). This sets the default cookie that the local node will use for all other nodes.

Thus, groups of users with identical cookie files get Erlang nodes that can communicate freely since they use the same magic cookie. Users who want to run nodes where the cookie files are on different file systems must make certain that their cookie files are identical.

For a node Node1 using magic cookie Cookie to be able to connect to, and to accept a connection from, another node Node2 that uses a different cookie DiffCookie, the function erlang:set_cookie(Node2, DiffCookie) must first be called at Node1. Distributed systems with multiple home directories (differing cookie files) can be handled in this way.


With this setup Node1 and Node2 agree on which cookie to use: Node1 uses its explicitly configured DiffCookie for Node2, and Node2 uses its default cookie DiffCookie.

You can also use a DiffCookie that neither Node1 nor Node2 has as its default cookie, if you also call erlang:set_cookie(Node1, DiffCookie) in Node2 before establishing connection

Because node names are exchanged during connection setup before cookies are selected, connection setup works regardless of which node that initiates it.

Note that to configure Node1 to use Node2's default cookie when communicating with Node2, and vice versa results in a broken configuration (if the cookies are different) because then both nodes use the other node's (differing) cookie.

The default when a connection is established between two nodes, is to immediately connect all other visible nodes as well. This way, there is always a fully connected network. If there are nodes with different cookies, this method can be inappropriate (since it may not be feasible to configure different cookies for all possible nodes) and the command-line flag -connect_all false must be set, see the erl executable in ERTS.

The magic cookie of the local node can be retrieved by calling erlang:get_cookie().

Distribution BIFs

Here are some BIFs that are useful for distributed programming:

Table: Distribution BIFs

Distribution Command-Line Flags

Examples of command-line flags used for distributed programming (for more information, see the erl executable in ERTS):

Command-Line FlagDescription
-connect_all falseOnly explicit connection setups are used.
-hiddenMakes a node into a hidden node.
-name NameMakes a runtime system into a node, using long node names.
-setcookie CookieSame as calling erlang:set_cookie(Cookie).
-setcookie Node CookieSame as calling erlang:set_cookie(Node, Cookie).
-sname NameMakes a runtime system into a node, using short node names.

Table: Distribution Command-Line Flags

Distribution Modules

Examples of modules useful for distributed programming in the Kernel application:

globalA global name registration facility.
global_groupGrouping nodes to global name registration groups.
net_admVarious Erlang net administration routines.
net_kernelErlang networking kernel.

Table: Kernel Modules Useful For Distribution.

In the STDLIB application:

peerStart and control of peer nodes.

Table: STDLIB Modules Useful For Distribution.