Integration testingΒΆ
Integration testing involves bringing up nodes locally and testing invariants about them by starting flows and inspecting their state.
In this tutorial we will bring up three nodes - Alice, Bob and a notary. Alice will issue cash to Bob, then Bob will send this cash back to Alice. We will see how to test some simple deterministic and nondeterministic invariants in the meantime.
Note
This example where Alice is self-issuing cash is purely for demonstration purposes, in reality, cash would be issued by a bank and subsequently passed around.
In order to spawn nodes we will use the Driver DSL. This DSL allows one to start up node processes from code. It manages a network map service and safe shutting down of nodes in the background.
driver(startNodesInProcess = true,
extraCordappPackagesToScan = listOf("net.corda.finance.contracts.asset")) {
val aliceUser = User("aliceUser", "testPassword1", permissions = setOf(
startFlowPermission<CashIssueFlow>(),
startFlowPermission<CashPaymentFlow>()
))
val bobUser = User("bobUser", "testPassword2", permissions = setOf(
startFlowPermission<CashPaymentFlow>()
))
val (alice, bob, notary) = listOf(
startNode(providedName = ALICE.name, rpcUsers = listOf(aliceUser)),
startNode(providedName = BOB.name, rpcUsers = listOf(bobUser)),
startNode(providedName = DUMMY_NOTARY.name, advertisedServices = setOf(ServiceInfo(ValidatingNotaryService.type)))
).transpose().getOrThrow()
The above code starts three nodes:
- Alice, who has user permissions to start the
CashIssueFlowandCashPaymentFlowflows - Bob, who only has user permissions to start the
CashPaymentFlow - A notary that offers a
ValidatingNotaryService. We won’t connect to the notary directly, so there’s no need to provide aUser
The startNode function returns a future that completes once the
node is fully started. This allows starting of the nodes to be
parallel. We wait on these futures as we need the information
returned; their respective NodeHandles s.
val aliceClient = alice.rpcClientToNode()
val aliceProxy = aliceClient.start("aliceUser", "testPassword1").proxy
val bobClient = bob.rpcClientToNode()
val bobProxy = bobClient.start("bobUser", "testPassword2").proxy
aliceProxy.waitUntilNetworkReady().getOrThrow()
bobProxy.waitUntilNetworkReady().getOrThrow()
After getting the handles we wait for both parties to register with the network map to ensure we don’t have race conditions with network map registration. Next we connect to Alice and Bob respectively from the test process using the test user we created. Then we establish RPC links that allow us to start flows and query state.
val bobVaultUpdates = bobProxy.vaultTrackBy<Cash.State>().updates
val aliceVaultUpdates = aliceProxy.vaultTrackBy<Cash.State>().updates
We will be interested in changes to Alice’s and Bob’s vault, so we query a stream of vault updates from each.
Now that we’re all set up we can finally get some cash action going!
val issueRef = OpaqueBytes.of(0)
val notaryParty = aliceProxy.notaryIdentities().first()
(1..10).map { i ->
aliceProxy.startFlow(::CashIssueFlow,
i.DOLLARS,
issueRef,
notaryParty
).returnValue
}.transpose().getOrThrow()
// We wait for all of the issuances to run before we start making payments
(1..10).map { i ->
aliceProxy.startFlow(::CashPaymentFlow,
i.DOLLARS,
bob.nodeInfo.chooseIdentity(),
true
).returnValue
}.transpose().getOrThrow()
bobVaultUpdates.expectEvents {
parallel(
(1..10).map { i ->
expect(
match = { update: Vault.Update<Cash.State> ->
update.produced.first().state.data.amount.quantity == i * 100L
}
) { update ->
println("Bob vault update of $update")
}
}
)
}
The first loop creates 10 threads, each starting a CashFlow flow
on the Alice node. We specify that we want to issue i dollars to
Bob, setting our notary as the notary responsible for notarising the
created states. Note that no notarisation will occur yet as we’re not
spending any states, only creating new ones on the ledger.
We started the flows from different threads for the sake of the
tutorial, to demonstrate how to test non-determinism, which is what
the expectEvents block does.
The Expect DSL allows ordering constraints to be checked on a stream
of events. The above code specifies that we are expecting 10 updates
to be emitted on the bobVaultUpdates stream in unspecified order
(this is what the parallel construct does). We specify an
(otherwise optional) match predicate to identify specific updates
we are interested in, which we then print.
If we run the code written so far we should see 4 nodes starting up (Alice, Bob, the notary and an implicit Network Map service), then 10 logs of Bob receiving 1,2,...10 dollars from Alice in some unspecified order.
Next we want Bob to send this cash back to Alice.
for (i in 1..10) {
bobProxy.startFlow(::CashPaymentFlow, i.DOLLARS, alice.nodeInfo.chooseIdentity()).returnValue.getOrThrow()
}
aliceVaultUpdates.expectEvents {
sequence(
(1..10).map { i ->
expect { update: Vault.Update<Cash.State> ->
println("Alice got vault update of $update")
assertEquals(update.produced.first().state.data.amount.quantity, i * 100L)
}
}
)
}
This time we’ll do it sequentially. We make Bob pay 1,2,..10 dollars
to Alice in order. We make sure that a the CashFlow has finished
by waiting on startFlow ‘s returnValue.
Then we use the Expect DSL again, this time using sequence to test
for the updates arriving in the order we expect them to.
Note that parallel and sequence may be nested into each other
arbitrarily to test more complex scenarios.
That’s it! We saw how to start up several corda nodes locally, how to
connect to them, and how to test some simple invariants about
CashFlow.
To run the complete test you can open
example-code/src/integration-test/kotlin/net/corda/docs/IntegrationTestingTutorial.kt
from IntelliJ and run the test, or alternatively use gradle:
# Run example-code integration tests
./gradlew docs/source/example-code:integrationTest -i