corda/docs/source/setting-up-a-corda-network.rst

Creating a Corda network

A Corda network consists of a number of machines running nodes. These nodes communicate using persistent protocols in order to create and validate transactions.

There are three broader categories of functionality one such node may have. These pieces of functionality are provided as services, and one node may run several of them.

• Notary: Nodes running a notary service witness state spends and have the final say in whether a transaction is a double-spend or not
• Oracle: Network services that link the ledger to the outside world by providing facts that affect the validity of transactions
• Regular node: All nodes have a vault and may start protocols communicating with other nodes, notaries and oracles and evolve their private ledger

Setting up your own network

Certificates

Every node in a given Corda network must have an identity certificate signed by the network's root CA. See permissioning for more information.

Configuration

A node can be configured by adding/editing node.conf in the node's directory. For details see corda-configuration-file.

An example configuration:

example-code/src/main/resources/example-node.conf

The most important fields regarding network configuration are:

• p2pAddress: This specifies a host and port to which Artemis will bind for messaging with other nodes. Note that the address bound will NOT be my-corda-node, but rather :: (all addresses on all network interfaces). The hostname specified is the hostname that must be externally resolvable by other nodes in the network. In the above configuration this is the resolvable name of a machine in a VPN.
• rpcAddress: The address to which Artemis will bind for RPC calls.
• webAddress: The address the webserver should bind. Note that the port must be distinct from that of p2pAddress and rpcAddress if they are on the same machine.

Bootstrapping the network

The nodes see each other using the network map. This is a collection of statically signed node-info files, one for each node in the network. Most production deployments will use a highly available, secure distribution of the network map via HTTP.

For test deployments where the nodes (at least initially) reside on the same filesystem, these node-info files can be placed directly in the node's additional-node-infos directory from where the node will pick them up and store them in its local network map cache. The node generates its own node-info file on startup.

In addition to the network map, all the nodes on a network must use the same set of network parameters. These are a set of constants which guarantee interoperability between nodes. The HTTP network map distributes the network parameters which the node downloads automatically. In the absence of this the network parameters must be generated locally. This can be done with the network bootstrapper. This is a tool that scans all the node configurations from a common directory to generate the network parameters file which is copied to the nodes' directories. It also copies each node's node-info file to every other node so that they can all transact with each other.

The bootstrapper tool can be built with the command:

gradlew buildBootstrapperJar

The resulting jar can be found in tools/bootstrapper/build/libs/.

To use it, create a directory containing a node.conf file for each node you want to create. Then run the following command:

java -jar network-bootstrapper.jar <nodes-root-dir>

For example running the command on a directory containing these files :

.
├── notary.conf             // The notary's node.conf file
├── partya.conf             // Party A's node.conf file
└── partyb.conf             // Party B's node.conf file

Would generate directories containing three nodes: notary, partya and partyb.

This tool only bootstraps a network. It cannot dynamically update if a new node needs to join the network or if an existing one has changed something in their node-info, e.g. their P2P address. For this the new node-info file will need to be placed in the other nodes' additional-node-infos directory. A simple way to do this is to use rsync. However, if it's known beforehand the set of nodes that will eventually the node folders can be pregenerated in the bootstrap and only started when needed.

Starting the nodes

You may now start the nodes in any order. You should see a banner, some log lines and eventually Node started up and registered, indicating that the node is fully started.

In terms of process management there is no prescribed method. You may start the jars by hand or perhaps use systemd and friends.

Logging

Only a handful of important lines are printed to the console. For details/diagnosing problems check the logs.

Logging is standard log4j2 and may be configured accordingly. Logs are by default redirected to files in NODE_DIRECTORY/logs/.

Connecting to the nodes

Once a node has started up successfully you may connect to it as a client to initiate protocols/query state etc. Depending on your network setup you may need to tunnel to do this remotely.

See the tutorial-clientrpc-api on how to establish an RPC link.

Sidenote: A client is always associated with a single node with a single identity, which only sees their part of the ledger.