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12fa945077
* Introduce MockNetworkParameters
140 lines
7.4 KiB
ReStructuredText
140 lines
7.4 KiB
ReStructuredText
Contract Constraints
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====================
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A basic understanding of contract key concepts, which can be found :doc:`here </key-concepts-contracts>`,
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is required reading for this page.
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Transaction states specify a constraint over the contract that will be used to verify it. For a transaction to be
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valid, the verify() function associated with each state must run successfully. However, for this to be secure, it is
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not sufficient to specify the verify() function by name as there may exist multiple different implementations with the
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same method signature and enclosing class. Contract constraints solve this problem by allowing a contract developer to
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constrain which verify() functions out of the universe of implementations can be used.
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(ie the universe is everything that matches the signature and contract constraints restricts this universe to a subset.)
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A typical constraint is the hash of the CorDapp JAR that contains the contract and states but will in future releases
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include constraints that require specific signers of the JAR, or both the signer and the hash. Constraints can be
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specified when constructing a transaction; if unspecified, an automatic constraint is used.
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A ``TransactionState`` has a ``constraint`` field that represents that state's attachment constraint. When a party
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constructs a ``TransactionState`` without specifying the constraint parameter a default value
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(``AutomaticHashConstraint``) is used. This default will be automatically resolved to a specific
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``HashAttachmentConstraint`` that contains the hash of the attachment which contains the contract of that
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``TransactionState``. This automatic resolution occurs when a ``TransactionBuilder`` is converted to a
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``WireTransaction``. This reduces the boilerplate involved in finding a specific hash constraint when building a transaction.
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It is possible to specify the constraint explicitly with any other class that implements the ``AttachmentConstraint``
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interface. To specify a hash manually the ``HashAttachmentConstraint`` can be used and to not provide any constraint
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the ``AlwaysAcceptAttachmentConstraint`` can be used - though this is intended for testing only. An example below
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shows how to construct a ``TransactionState`` with an explicitly specified hash constraint from within a flow;
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.. sourcecode:: java
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// Constructing a transaction with a custom hash constraint on a state
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TransactionBuilder tx = new TransactionBuilder()
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Party notaryParty = ... // a notary party
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DummyState contractState = new DummyState()
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SecureHash myAttachmentsHash = serviceHub.cordappProvider.getContractAttachmentID(DummyContract.PROGRAM_ID)
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TransactionState transactionState = new TransactionState(contractState, DummyContract.Companion.getPROGRAMID(), notaryParty, new AttachmentHashConstraint(myAttachmentsHash))
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tx.addOutputState(transactionState)
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WireTransaction wtx = tx.toWireTransaction(serviceHub) // This is where an automatic constraint would be resolved
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LedgerTransaction ltx = wtx.toLedgerTransaction(serviceHub)
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ltx.verify() // Verifies both the attachment constraints and contracts
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This mechanism exists both for integrity and security reasons. It is important not to verify against the wrong contract,
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which could happen if the wrong version of the contract is attached. More importantly when resolving transaction chains
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there will, in a future release, be attachments loaded from the network into the attachment sandbox that are used
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to verify the transaction chain. Ensuring the attachment used is the correct one ensures that the verification will
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not be tamperable by providing a fake contract.
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CorDapps as attachments
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-----------------------
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CorDapp JARs (:doc:`cordapp-overview`) that are installed to the node and contain classes implementing the ``Contract``
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interface are automatically loaded into the ``AttachmentStorage`` of a node at startup.
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After CorDapps are loaded into the attachment store the node creates a link between contract classes and the
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attachment that they were loaded from. This makes it possible to find the attachment for any given contract.
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This is how the automatic resolution of attachments is done by the ``TransactionBuilder`` and how, when verifying
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the constraints and contracts, attachments are associated with their respective contracts.
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Implementations
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---------------
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There are three implementations of ``AttachmentConstraints`` with more planned in the future.
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``AlwaysAcceptAttachmentConstraint``: Any attachment (except a missing one) will satisfy this constraint.
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``AutomaticHashConstraint``: This will be resolved to a ``HashAttachmentConstraint`` when a ``TransactionBuilder`` is
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converted to a ``WireTransaction``. The ``HashAttachmentConstraint`` will include the attachment hash of the CorDapp
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that contains the ``ContractState`` on the ``TransactionState.contract`` field.
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``HashAttachmentConstraint``: Will require that the hash of the attachment containing the contract matches the hash
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stored in the constraint.
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We plan to add a future ``AttachmentConstraint`` that will only be satisfied by the presence of signatures on the
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attachment JAR. This allows for trusting of attachments from trusted entities.
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Limitations
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-----------
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An ``AttachmentConstraint`` is verified by running the ``AttachmentConstraint.isSatisfiedBy`` method. When this is called
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it is provided only the relevant attachment by the transaction that is verifying it.
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Testing
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-------
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Since all tests involving transactions now require attachments it is also required to load the correct attachments
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for tests. Unit test environments in JVM ecosystems tend to use class directories rather than JARs, and so CorDapp JARs
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typically aren't built for testing. Requiring this would add significant complexity to the build systems of Corda
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and CorDapps, so the test suite has a set of convenient functions to generate CorDapps from package names or
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to specify JAR URLs in the case that the CorDapp(s) involved in testing already exist.
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MockNetwork/MockNode
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********************
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The most simple way to ensure that a vanilla instance of a MockNode generates the correct CorDapps is to use the
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``cordappPackages`` constructor parameter (Kotlin) or the ``setCordappPackages`` method on ``MockNetworkParameters`` (Java)
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when creating the MockNetwork. This will cause the ``AbstractNode`` to use the named packages as sources for CorDapps. All files
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within those packages will be zipped into a JAR and added to the attachment store and loaded as CorDapps by the
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``CordappLoader``. An example of this usage would be:
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.. sourcecode:: java
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class SomeTestClass {
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MockNetwork network = null
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@Before
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void setup() {
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network = new MockNetwork(new MockNetworkParameters().setCordappPackages(Arrays.asList("com.domain.cordapp")))
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}
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... // Your tests go here
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}
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MockServices
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************
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If your test uses a ``MockServices`` directly you can instantiate it using a constructor that takes a list of packages
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to use as CorDapps using the ``cordappPackages`` parameter.
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.. sourcecode:: java
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MockServices mockServices = new MockServices(Arrays.asList("com.domain.cordapp"))
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Driver
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******
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The driver takes a parameter called ``extraCordappPackagesToScan`` which is a list of packages to use as CorDapps.
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.. sourcecode:: java
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driver(new DriverParameters().setExtraCordappPackagesToScan(Arrays.asList("com.domain.cordapp"))) ...
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Full Nodes
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**********
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When testing against full nodes simply place your CorDapp into the cordapps directory of the node.
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