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116 lines
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ReStructuredText
116 lines
7.9 KiB
ReStructuredText
Networking and messaging
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========================
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Corda uses AMQP/1.0 over TLS between nodes which is currently implemented using Apache Artemis, an embeddable message
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queue broker. Building on established MQ protocols gives us features like persistence to disk, automatic delivery
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retries with backoff and dead-letter routing, security, large message streaming and so on.
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Artemis is hidden behind a thin interface that also has an in-memory only implementation suitable for use in
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unit tests and visualisation tools.
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.. note:: A future version of Corda will allow the MQ broker to be split out of the main node and run as a
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separate server. We may also support non-Artemis implementations via JMS, allowing the broker to be swapped
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out for alternative implementations.
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There are multiple ways of interacting with the network. When writing an application you typically won't use the
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messaging subsystem directly. Instead you will build on top of the :doc:`flow framework <flow-state-machines>`,
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which adds a layer on top of raw messaging to manage multi-step flows and let you think in terms of identities
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rather than specific network endpoints.
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.. _network-map-service:
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Network Map Service
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-------------------
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Supporting the messaging layer is a network map service, which is responsible for tracking public nodes on the network.
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Nodes have an internal component, the network map cache, which contains a copy of the network map (which is backed up in the database
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to persist that information across the restarts in case the network map server is down). When a node starts up its cache
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fetches a copy of the full network map (from the server or from filesystem for development mode). After that it polls on
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regular time interval for network map and applies any related changes locally.
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Nodes do not automatically deregister themselves, so (for example) nodes going offline briefly for maintenance are retained
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in the network map, and messages for them will be queued, minimising disruption.
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Additionally, on every restart and on daily basis nodes submit signed ``NodeInfo`` s to the map service. When network map gets
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signed, these changes are distributed as new network data. ``NodeInfo`` republishing is treated as a heartbeat from the node,
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based on that network map service is able to figure out which nodes can be considered as stale and removed from the network
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map document after ``eventHorizon`` time.
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Message queues
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--------------
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The node makes use of various queues for its operation. The more important ones are described below. Others are used
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for maintenance and other minor purposes.
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:``p2p.inbound.$identity``:
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The node listens for messages sent from other peer nodes on this queue. Only clients who are authenticated to be
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nodes on the same network are given permission to send. Messages which are routed internally are also sent to this
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queue (e.g. two flows on the same node communicating with each other).
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:``internal.peers.$identity``:
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These are a set of private queues only available to the node which it uses to route messages destined to other peers.
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The queue name ends in the base 58 encoding of the peer's identity key. There is at most one queue per peer. The broker
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creates a bridge from this queue to the peer's ``p2p.inbound.$identity`` queue, using the network map service to lookup the
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peer's network address.
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:``internal.services.$identity``:
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These are private queues the node may use to route messages to services. The queue name ends in the base 58 encoding
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of the service's owning identity key. There is at most one queue per service identity (but note that any one service
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may have several identities). The broker creates bridges to all nodes in the network advertising the service in
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question. When a session is initiated with a service counterparty the handshake is pushed onto this queue, and a
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corresponding bridge is used to forward the message to an advertising peer's p2p queue. Once a peer is picked the
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session continues on as normal.
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:``rpc.server``:
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RPC clients send their requests here, and it's only open for sending by clients authenticated as RPC users.
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:``rpc.client.$user.$random``:
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RPC clients are given permission to create a temporary queue incorporating their username (``$user``) and sole
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permission to receive messages from it. RPC requests are required to include a random number (``$random``) from
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which the node is able to construct the queue the user is listening on and send the response to that. This mechanism
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prevents other users from being able listen in on the responses.
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Security
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--------
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Clients attempting to connect to the node's broker fall in one of four groups:
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#. Anyone connecting with the username ``SystemUsers/Node`` or ``SystemUsers/NodeRPC`` is treated as the node hosting the brokers, or a logical
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component of the node. The TLS certificate they provide must match the one broker has for the node. If that's the case
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they are given full access to all valid queues, otherwise they are rejected.
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#. Anyone connecting with the username ``SystemUsers/Peer`` is treated as a peer on the same Corda network as the node. Their
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TLS root CA must be the same as the node's root CA -- the root CA is the doorman of the network and having the same root CA
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implies we've been let in by the same doorman. If they are part of the same network then they are only given permission
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to send to our ``p2p.inbound.$identity`` queue, otherwise they are rejected.
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#. Every other username is treated as a RPC user and authenticated against the node's list of valid RPC users. If that
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is successful then they are only given sufficient permission to perform RPC, otherwise they are rejected.
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#. Clients connecting without a username and password are rejected.
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Artemis provides a feature of annotating each received message with the validated user. This allows the node's messaging
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service to provide authenticated messages to the rest of the system. For the first two client types described above the
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validated user is the X.500 subject of the client TLS certificate. This allows the flow framework to authentically determine
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the ``Party`` initiating a new flow. For RPC clients the validated user is the username itself and the RPC framework uses
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this to determine what permissions the user has.
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The broker also does host verification when connecting to another peer. It checks that the TLS certificate subject matches
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with the advertised X.500 legal name from the network map service.
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Implementation details
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~~~~~~~~~~~~~~~~~~~~~~
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The components of the system that need to communicate and authenticate each other are:
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- The Artemis P2P broker (currently runs inside the node's JVM process, but in the future it will be able to run as a separate server):
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* Opens Acceptor configured with the doorman's certificate in the trustStore and the node's SSL certificate in the keyStore.
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- The Artemis RPC broker (currently runs inside the node's JVM process, but in the future it will be able to run as a separate server):
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* Opens "Admin" Acceptor configured with the doorman's certificate in the trustStore and the node's SSL certificate in the keyStore.
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* Opens "Client" Acceptor with the SSL settings configurable. This acceptor does not require SSL client-auth.
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- The current node hosting the brokers:
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* Connects to the P2P broker using the ``SystemUsers/Node`` user and the node's keyStore and trustStore.
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* Connects to the "Admin" Acceptor of the RPC broker using the ``SystemUsers/NodeRPC`` user and the node's keyStore and trustStore.
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- RPC clients (third party applications that need to communicate with the node):
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* Connect to the "Client" Acceptor of the RPC broker using the username/password provided by the node's admin. The client verifies the node's certificate using a trustStore provided by the node's admin.
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- Peer nodes (other nodes on the network):
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* Connect to the P2P broker using the ``SystemUsers/Peer`` user and a doorman signed certificate. The authentication is performed based on the root CA. |