* RPC Client using HA addresses. * Fix incorrect document code snippets by referencing working, compilable code. * Minor updates following PR review.
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Interacting with a node
Overview
To interact with your node, you need to write a client in a JVM-compatible language using the CordaRPCClient class. This class allows you to connect to your node via a message queue protocol and provides a simple RPC interface for interacting with the node. You make calls on a JVM object as normal, and the marshalling back-and-forth is handled for you.
Warning
The built-in Corda webserver is deprecated and unsuitable for production use. If you want to interact with your node via HTTP, you will need to stand up your own webserver that connects to your node using the CordaRPCClient class. You can find an example of how to do this using the popular Spring Boot server here.
Connecting to a node via RPC
To use CordaRPCClient, you must add net.corda:corda-rpc:$corda_release_version
as a cordaCompile
dependency in your client's build.gradle
file.
CordaRPCClient has a start
method that takes the node's RPC address and returns a CordaRPCConnection. CordaRPCConnection has a proxy
method that takes an RPC username and password and returns a CordaRPCOps object that you can use to interact with the node.
Here is an example of using CordaRPCClient to connect to a node and log the current time on its internal clock:
example-code/src/main/kotlin/net/corda/docs/kotlin/ClientRpcExample.kt
example-code/src/main/java/net/corda/docs/java/ClientRpcExample.java
Warning
The returned CordaRPCConnection is somewhat expensive to create and consumes a small amount of server side resources. When you're done with it, call close
on it. Alternatively you may use the use
method on CordaRPCClient which cleans up automatically after the passed in lambda finishes. Don't create a new proxy for every call you make - reuse an existing one.
For further information on using the RPC API, see tutorial-clientrpc-api
.
RPC permissions
For a node's owner to interact with their node via RPC, they must define one or more RPC users. Each user is authenticated with a username and password, and is assigned a set of permissions that control which RPC operations they can perform. Permissions are not required to interact with the node via the shell, unless the shell is being accessed via SSH.
RPC users are created by adding them to the rpcUsers
list in the node's node.conf
file:
rpcUsers=[
{
username=exampleUser
password=examplePass
permissions=[]
},
...
]
By default, RPC users are not permissioned to perform any RPC operations.
Granting flow permissions
You provide an RPC user with the permission to start a specific flow using the syntax StartFlow.<fully qualified flow name>
:
rpcUsers=[
{
username=exampleUser
password=examplePass
permissions=[
"StartFlow.net.corda.flows.ExampleFlow1",
"StartFlow.net.corda.flows.ExampleFlow2"
]
},
...
]
You can also provide an RPC user with the permission to start any flow using the syntax InvokeRpc.startFlow
:
rpcUsers=[
{
username=exampleUser
password=examplePass
permissions=[
"InvokeRpc.startFlow"
]
},
...
]
Granting other RPC permissions
You provide an RPC user with the permission to perform a specific RPC operation using the syntax InvokeRpc.<rpc method name>
:
rpcUsers=[
{
username=exampleUser
password=examplePass
permissions=[
"InvokeRpc.nodeInfo",
"InvokeRpc.networkMapSnapshot"
]
},
...
]
Granting all permissions
You can provide an RPC user with the permission to perform any RPC operation (including starting any flow) using the ALL
permission:
rpcUsers=[
{
username=exampleUser
password=examplePass
permissions=[
"ALL"
]
},
...
]
RPC security management
Setting rpcUsers
provides a simple way of granting RPC permissions to a fixed set of users, but has some obvious shortcomings. To support use cases aiming for higher security and flexibility, Corda offers additional security features such as:
- Fetching users credentials and permissions from an external data source (e.g.: a remote RDBMS), with optional in-memory caching. In particular, this allows credentials and permissions to be updated externally without requiring nodes to be restarted.
- Password stored in hash-encrypted form. This is regarded as must-have when security is a concern. Corda currently supports a flexible password hash format conforming to the Modular Crypt Format provided by the Apache Shiro framework
These features are controlled by a set of options nested in the security
field of node.conf
. The following example shows how to configure retrieval of users credentials and permissions from a remote database with passwords in hash-encrypted format and enable in-memory caching of users data:
security = {
authService = {
dataSource = {
type = "DB"
passwordEncryption = "SHIRO_1_CRYPT"
connection = {
jdbcUrl = "<jdbc connection string>"
username = "<db username>"
password = "<db user password>"
driverClassName = "<JDBC driver>"
}
}
options = {
cache = {
expireAfterSecs = 120
maxEntries = 10000
}
}
}
}
It is also possible to have a static list of users embedded in the security
structure by specifying a dataSource
of INMEMORY
type:
security = {
authService = {
dataSource = {
type = "INMEMORY"
users = [
{
username = "<username>"
password = "<password>"
permissions = ["<permission 1>", "<permission 2>", ...]
},
...
]
}
}
}
Warning
A valid configuration cannot specify both the rpcUsers
and security
fields. Doing so will trigger an exception at node startup.
Authentication/authorisation data
The dataSource
structure defines the data provider supplying credentials and permissions for users. There exist two supported types of such data source, identified by the dataSource.type
field:
- INMEMORY
A static list of user credentials and permissions specified by the
users
field.- DB
An external RDBMS accessed via the JDBC connection described by
connection
. Note that, unlike theINMEMORY
case, in a user database permissions are assigned to roles rather than individual users. The current implementation expects the database to store data according to the following schema:
- Table
users
containing columnsusername
andpassword
. Theusername
column must have unique values.- Table
user_roles
containing columnsusername
androle_name
associating a user to a set of roles.- Table
roles_permissions
containing columnsrole_name
andpermission
associating a role to a set of permission strings.Note
There is no prescription on the SQL type of each column (although our tests were conducted on
username
androle_name
declared of SQL typeVARCHAR
andpassword
ofTEXT
type). It is also possible to have extra columns in each table alongside the expected ones.
Password encryption
Storing passwords in plain text is discouraged in applications where security is critical. Passwords are assumed to be in plain format by default, unless a different format is specified by the passwordEncryption
field, like:
passwordEncryption = SHIRO_1_CRYPT
SHIRO_1_CRYPT
identifies the Apache Shiro fully reversible Modular Crypt Format, it is currently the only non-plain password hash-encryption format supported. Hash-encrypted passwords in this format can be produced by using the Apache Shiro Hasher command line tool.
Caching user accounts data
A cache layer on top of the external data source of users credentials and permissions can significantly improve performances in some cases, with the disadvantage of causing a (controllable) delay in picking up updates to the underlying data. Caching is disabled by default, it can be enabled by defining the options.cache
field in security.authService
, for example:
options = {
cache = {
expireAfterSecs = 120
maxEntries = 10000
}
}
This will enable a non-persistent cache contained in the node's memory with maximum number of entries set to maxEntries
where entries are expired and refreshed after expireAfterSecs
seconds.
Observables
The RPC system handles observables in a special way. When a method returns an observable, whether directly or as a sub-object of the response object graph, an observable is created on the client to match the one on the server. Objects emitted by the server-side observable are pushed onto a queue which is then drained by the client. The returned observable may even emit object graphs with even more observables in them, and it all works as you would expect.
This feature comes with a cost: the server must queue up objects emitted by the server-side observable until you download them. Note that the server side observation buffer is bounded, once it fills up the client is considered slow and will be disconnected. You are expected to subscribe to all the observables returned, otherwise client-side memory starts filling up as observations come in. If you don't want an observable then subscribe then unsubscribe immediately to clear the client-side buffers and to stop the server from streaming. For Kotlin users there is a convenience extension method called notUsed()
which can be called on an observable to automate this step.
If your app quits then server side resources will be freed automatically.
Warning
If you leak an observable on the client side and it gets garbage collected, you will get a warning printed to the logs and the observable will be unsubscribed for you. But don't rely on this, as garbage collection is non-deterministic. If you set -Dnet.corda.client.rpc.trackRpcCallSites=true
on the JVM command line then this warning comes with a stack trace showing where the RPC that returned the forgotten observable was called from. This feature is off by default because tracking RPC call sites is moderately slow.
Note
Observables can only be used as return arguments of an RPC call. It is not currently possible to pass Observables as parameters to the RPC methods. In other words the streaming is always server to client and not the other way around.
Futures
A method can also return a CordaFuture
in its object graph and it will be treated in a similar manner to observables. Calling the cancel
method on the future will unsubscribe it from any future value and release any resources.
Versioning
The client RPC protocol is versioned using the node's platform version number (see versioning
). When a proxy is created the server is queried for its version, and you can specify your minimum requirement. Methods added in later versions are tagged with the @RPCSinceVersion
annotation. If you try to use a method that the server isn't advertising support of, an UnsupportedOperationException
is thrown. If you want to know the version of the server, just use the protocolVersion
property (i.e. getProtocolVersion
in Java).
The RPC client library defaults to requiring the platform version it was built with. That means if you use the client library released as part of Corda N, then the node it connects to must be of version N or above. This is checked when the client first connects. If you want to override this behaviour, you can alter the minimumServerProtocolVersion
field in the CordaRPCClientConfiguration
object passed to the client. Alternatively, just link your app against an older version of the library.
Thread safety
A proxy is thread safe, blocking, and allows multiple RPCs to be in flight at once. Any observables that are returned and you subscribe to will have objects emitted in order on a background thread pool. Each Observable stream is tied to a single thread, however note that two separate Observables may invoke their respective callbacks on different threads.
Error handling
If something goes wrong with the RPC infrastructure itself, an RPCException
is thrown. If you call a method that requires a higher version of the protocol than the server supports, UnsupportedOperationException
is thrown. Otherwise the behaviour depends on the devMode
node configuration option.
In devMode
, if the server implementation throws an exception, that exception is serialised and rethrown on the client side as if it was thrown from inside the called RPC method. These exceptions can be caught as normal.
When not in devMode
, the server will mask exceptions not meant for clients and return an InternalNodeException
instead. This does not expose internal information to clients, strengthening privacy and security. CorDapps can have exceptions implement ClientRelevantError
to allow them to reach RPC clients.
Connection management
It is possible to not be able to connect to the server on the first attempt. In that case, the CordaRPCClient.start()
method will throw an exception. The following code snippet is an example of how to write a simple retry mechanism for such situations:
../../samples/bank-of-corda-demo/src/main/kotlin/net/corda/bank/api/BankOfCordaClientApi.kt
Warning
The list of NetworkHostAndPort
passed to this function should represent one or more addresses reflecting the number of instances of a node configured to service the client RPC request. See haAddressPool
in CordaRPCClient for further information on using an RPC Client for load balancing and failover.
After a successful connection, it is possible for the server to become unavailable. In this case, all RPC calls will throw an exception and created observables will no longer receive observations. Below is an example of how to reconnect and back-fill any data that might have been missed while the connection was down. This is done by using the onError
handler on the Observable
returned by CordaRPCOps
.
../../samples/bank-of-corda-demo/src/main/kotlin/net/corda/bank/api/BankOfCordaClientApi.kt
In this code snippet it is possible to see that the function performRpcReconnect
creates an RPC connection and implements the error handler upon subscription to an Observable
. The call to this onError
handler will be triggered upon failover, at which point the client will terminate its existing subscription, close its RPC connection and recursively call performRpcReconnect
, which will re-subscribe once the RPC connection is re-established.
Within the body of the subscribe
function itself, the client code receives instances of StateMachineInfo
. Upon re-connecting, this code receives all the instances of StateMachineInfo
, some of which may already been delivered to the client code prior to previous disconnect. It is the responsibility of the client code to handle potential duplicated instances of StateMachineInfo
as appropriate.
Wire security
If TLS communications to the RPC endpoint are required the node should be configured with rpcSettings.useSSL=true
see corda-configuration-file
. The node admin should then create a node specific RPC certificate and key, by running the node once with generate-rpc-ssl-settings
command specified (see node-commandline
). The generated RPC TLS trust root certificate will be exported to a certificates/export/rpcssltruststore.jks
file which should be distributed to the authorised RPC clients.
The connecting CordaRPCClient
code must then use one of the constructors with a parameter of type ClientRpcSslOptions
(JavaDoc) and set this constructor argument with the appropriate path for the rpcssltruststore.jks
file. The client connection will then use this to validate the RPC server handshake.
Note that RPC TLS does not use mutual authentication, and delegates fine grained user authentication and authorisation to the RPC security features detailed above.
Whitelisting classes with the Corda node
CorDapps must whitelist any classes used over RPC with Corda's serialization framework, unless they are whitelisted by default in DefaultWhitelist
. The whitelisting is done either via the plugin architecture or by using the @CordaSerializable
annotation. See serialization
. An example is shown in tutorial-clientrpc-api
.