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The version of contract attachments that are whitelisted should be read from NetworkParameters.whitelistedContractImplementations. It use the lattes network map from db with the highest epoch.
346 lines
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346 lines
23 KiB
ReStructuredText
API: Contract Constraints
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=========================
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.. note:: Before reading this page, you should be familiar with the key concepts of :doc:`key-concepts-contracts`.
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.. contents::
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Contract constraints
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--------------------
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Corda separates verification of states from their definition. Whilst you might have expected the ``ContractState``
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interface to define a verify method, or perhaps to do verification logic in the constructor, instead it is primarily
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done by a method on a ``Contract`` class. This is because what we're actually checking is the
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validity of a *transaction*, which is more than just whether the individual states are internally consistent.
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The transition between two valid states may be invalid, if the rules of the application are not being respected.
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For instance, two cash states of $100 and $200 may both be internally valid, but replacing the first with the second
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isn't allowed unless you're a cash issuer - otherwise you could print money for free.
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For a transaction to be valid, the ``verify`` function associated with each state must run successfully. However,
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for this to be secure, it is not sufficient to specify the ``verify`` function by name as there may exist multiple
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different implementations with the same method signature and enclosing class. This normally will happen as applications
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evolve, but could also happen maliciously as anyone can create a JAR with a class of that name.
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Contract constraints solve this problem by allowing a state creator to constrain which ``verify`` functions out of
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the universe of implementations can be used (i.e. the universe is everything that matches the class name and contract
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constraints restrict this universe to a subset). Constraints are satisfied by attachments (JARs). You are not allowed to
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attach two JARs that both define the same application due to the *no overlap rule*. This rule specifies that two
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attachment JARs may not provide the same file path. If they do, the transaction is considered invalid. Because each
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state specifies both a constraint over attachments *and* a Contract class name to use, the specified class must appear
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in only one attachment.
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.. note:: With the introduction of signature constraints in Corda 4, a new attachments classloader will verify that
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both signed and unsigned versions of an associated contract jar contain identical classes. This allows for automatic
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migration of hash-constrained states (created with pre-Corda 4 unsigned contract jars) to signature constrained states
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when used as outputs in new transactions using signed Corda 4 contract jars.
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Recap: A corda transaction transitions input states to output states. Each state is composed of data, the name of the class that verifies the transition(contract), and
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the contract constraint. The transaction also contains a list of attachments (normal JARs) from where these classes will be loaded. There must be only one JAR containing each contract.
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The contract constraints are responsible to ensure the attachment JARs are following the rules set by the creators of the input states (in a continuous chain to the issue).
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This way, we have both valid data and valid code that checks the transition packed into the transaction.
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So who picks the attachment to use? It is chosen by the creator of the transaction but has to satisfy the constraints of the input states.
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This is because any node doing transaction resolution will actually verify the selected attachment against all constraints,
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so the transaction will only be valid if it passes those checks.
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For example, when the input state is constrained by the ``HashAttachmentConstraint``, can only attach the JAR with that hash to the transaction.
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The transaction creator also gets to pick the constraints used by any output states.
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When building a transaction, the default constraint on output states is ``AutomaticPlaceholderConstraint``, which means that corda will select the appropriate constraint.
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Unless specified otherwise, attachment constraints will propagate from input to output states. (The rules are described below)
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Constraint propagation is also enforced during transaction verification, where for normal transactions (not explicit upgrades, or notary changes),
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the constraints of the output states are required to "inherit" the constraint of the input states. ( See below for details)
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There are two ways of handling upgrades to a smart contract in Corda:
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1. *Implicit:* By allowing multiple implementations of the contract ahead of time, using constraints.
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2. *Explicit:* By creating a special *contract upgrade transaction* and getting all participants of a state to sign it using the
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contract upgrade flows.
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This article focuses on the first approach. To learn about the second please see :doc:`upgrading-cordapps`.
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The advantage of pre-authorising upgrades using constraints is that you don't need the heavyweight process of creating
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upgrade transactions for every state on the ledger. The disadvantage is that you place more faith in third parties,
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who could potentially change the app in ways you did not expect or agree with. The advantage of using the explicit
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upgrade approach is that you can upgrade states regardless of their constraint, including in cases where you didn't
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anticipate a need to do so. But it requires everyone to sign, requires everyone to manually authorise the upgrade,
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consumes notary and ledger resources, and is just in general more complex.
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.. _implicit_constraint_types:
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Contract/State Agreement
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------------------------
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Starting with Corda 4, a ``ContractState`` must explicitly indicate which ``Contract`` it belongs to. When a transaction is
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verified, the contract bundled with each state in the transaction must be its "owning" contract, otherwise we cannot guarantee that
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the transition of the ``ContractState`` will be verified against the business rules that should apply to it.
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There are two mechanisms for indicating ownership. One is to annotate the ``ContractState`` with the ``BelongsToContract`` annotation,
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indicating the ``Contract`` class to which it is tied:
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.. sourcecode:: java
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@BelongToContract(MyContract.class)
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public class MyState implements ContractState {
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// implementation goes here
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}
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.. sourcecode:: kotlin
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@BelongsToContract(MyContract::class)
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data class MyState(val value: Int) : ContractState {
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// implementation goes here
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}
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The other is to define the ``ContractState`` class as an inner class of the ``Contract`` class
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.. sourcecode:: java
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public class MyContract implements Contract {
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public static class MyState implements ContractState {
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// state implementation goes here
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}
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// contract implementation goes here
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}
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.. sourcecode:: kotlin
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class MyContract : Contract {
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data class MyState(val value: Int) : ContractState
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}
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If a ``ContractState``'s owning ``Contract`` cannot be identified by either of these mechanisms, and the ``targetVersion`` of the
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CorDapp is 4 or greater, then transaction verification will fail with a ``TransactionRequiredContractUnspecifiedException``. If
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the owning ``Contract`` *can* be identified, but the ``ContractState`` has been bundled with a different contract, then
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transaction verification will fail with a ``TransactionContractConflictException``.
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How constraints work
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--------------------
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In Corda 4 there are three types of constraint that can be used in production environments: hash, zone whitelist and signature.
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For development purposes the ``AlwaysAcceptAttachmentConstraint`` allows any attachment to be selected.
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Hash and zone whitelist constraints were available in Corda 3, with hash constraints being used as default.
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In Corda 4 the default constraint is the signature constraint if the jar is signed. Otherwise,
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the default constraint type is either a zone constraint, if the network parameters in effect when the
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transaction is built contain an entry for that contract class, or a hash constraint if not.
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**Hash constraints.** The behaviour provided by public blockchain systems like Bitcoin and Ethereum is that once data is placed on the ledger,
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the program that controls it is fixed and cannot be changed. There is no support for upgrades at all. This implements a
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form of "code is law", assuming you trust the community of that blockchain to not release a new version of the platform
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that invalidates or changes the meaning of your program.
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This is supported by Corda using a hash constraint. This specifies exactly one hash of a CorDapp JAR that contains the
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contract and states any consuming transaction is allowed to use. Once such a state is created, other nodes will only
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accept a transaction if it uses that exact JAR file as an attachment. By implication, any bugs in the contract code
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or state definitions cannot be fixed except by using an explicit upgrade process via ``ContractUpgradeFlow``.
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.. note:: Corda does not support any way to create states that can never be upgraded at all, but the same effect can be
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obtained by using a hash constraint and then simply refusing to agree to any explicit upgrades. Hash
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constraints put you in control by requiring an explicit agreement to any upgrade.
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**Zone constraints.** Often a hash constraint will be too restrictive. You do want the ability to upgrade an app,
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and you don't mind the upgrade taking effect "just in time" when a transaction happens to be required for other business
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reasons. In this case you can use a zone constraint. This specifies that the network parameters of a compatibility zone
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(see :doc:`network-map`) is expected to contain a map of class name to hashes of JARs that are allowed to provide that
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class. The process for upgrading an app then involves asking the zone operator to add the hash of your new JAR to the
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parameters file, and trigger the network parameters upgrade process. This involves each node operator running a shell
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command to accept the new parameters file and then restarting the node. Node owners who do not restart their node in
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time effectively stop being a part of the network.
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**Signature constraints.** These enforce an association between a state and its associated contract JAR which must be
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signed by a specified identity, via the regular Java ``jarsigner`` tool. This is the most flexible type
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and the smoothest to deploy: no restarts or contract upgrade transactions are needed.
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When a CorDapp is build using :ref:`corda-gradle-plugin <cordapp_build_system_signing_cordapp_jar_ref>` the JAR is signed
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by Corda development key by default, an external keystore can be configured or signing can be disabled.
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.. warning:: CorDapps can only use signature constraints when participating in a Corda network using a minimum platform version of 4.
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An auto downgrade rule applies to signed CorDapps built and tested with Corda 4 but running on a Corda network of a lower version:
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if the associated contract class is whitelisted in the network parameters then zone constraints are applied, otherwise hash constraints are 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``, or adds a state using ``TransactionBuilder.addOutput(ContractState)`` without
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specifying the constraint parameter, a default value (``AutomaticPlaceholderConstraint``) is used. This default will be
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automatically resolved to a specific ``HashAttachmentConstraint`` or a ``WhitelistedByZoneAttachmentConstraint``.
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This automatic resolution occurs when a ``TransactionBuilder`` is converted to a ``WireTransaction``. This reduces
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the boilerplate that would otherwise be involved.
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Finally, an ``AlwaysAcceptAttachmentConstraint`` can be used which accepts anything, though this is intended for
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testing only, and a warning will be shown if used by a contract.
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Please note that the ``AttachmentConstraint`` interface is marked as ``@DoNotImplement``. You are not allowed to write
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new constraint types. Only the platform may implement this interface. If you tried, other nodes would not understand
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your constraint type and your transaction would not verify.
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.. warning:: An AlwaysAccept constraint is effectively the same as disabling security for those states entirely.
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Nothing stops you using this constraint in production, but that degrades Corda to being effectively a form
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of distributed messaging with optional contract logic being useful only to catch mistakes, rather than potentially
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malicious action. If you are deploying an app for which malicious actors aren't in your threat model, using an
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AlwaysAccept constraint might simplify things operationally.
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An example below shows how to construct a ``TransactionState`` with an explicitly specified hash constraint from within
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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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tx.addInputState(...)
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tx.addInputState(...)
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DummyState contractState = new DummyState();
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TransactionState transactionState = new TransactionState(contractState, DummyContract.Companion.getPROGRAMID(), notaryParty, null, HashAttachmentConstraint(myhash));
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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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.. _contract_non-downgrade_rule_ref:
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Contract attachment non-downgrade rule
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--------------------------------------
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Contract code is versioned and deployed as an independent JAR that gets imported into a node's database as a contract attachment (either explicitly
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uploaded via RPC or automatically loaded from disk). When constructing new transaction it is paramount to ensure
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that the contract version of code associated with new output states is the same or newer than the highest version of any existing input states.
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This is to prevent the possibility of nodes selecting older, potentially malicious or buggy contract code when creating new states from
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existing consumed states.
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Transactions contain an attachment for each contract. The version of the output states is the version of this contract attachment.
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See :doc:`versioning` for more details on how these versions are set. These can be seen as the version of the code that instantiated and
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serialised those classes.
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The non-downgrade rule specifies that the version of the code used in the transaction that spends a state needs to be greater than or equal to
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the highest version of the input states (i.e. spending_version >= creation_version)
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The contract attachment non-downgrade rule is enforced in two locations:
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1. Transaction building, upon creation of new output states. During this step, the node also selects the latest available attachment
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(i.e. the contract code with the latest contract class version).
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2. Transaction verification, upon resolution of existing transaction chains.
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A version number is stored in the manifest information of the enclosing JAR file. This version identifier should be a whole number starting
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from 1. This information should be set using the Gradle cordapp plugin, or manually, as described in :doc:`versioning`.
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Uniqueness requirement Contract and Version for Signature Constraint
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--------------------------------------------------------------------
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CorDapps in Corda 4 may be signed (to use new signature constraints functionality) or unsigned, and versioned.
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The following controls are enforced for these different types of jars within the attachment store of a node:
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- Signed contract JARs must be uniquely versioned per contract class (or group of).
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At runtime the node will throw a `DuplicateContractClassException`` exception if this condition is violated.
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- Unsigned contract JARs: there should not exist multiple instances of the same contract jar.
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When a whitelisted JARs is imported and it doesn't contain a version number, the version will be copied from the position (counting from 1)
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of this JAR in the whilelist. The same JAR can be present in many lists (if it contains many contracts),
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in such case the version will be equal to the highest position of the JAR in all lists.
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The new whitelist needs to be distributed to the node before the JAR is imported, otherwise it will receive default version.
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At run-time the node will warn of duplicates encountered.
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The most recent version given by insertionDate into the attachment storage will be used upon transaction building/resolution.
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Issues when using the HashAttachmentConstraint
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----------------------------------------------
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When setting up a new network, it is possible to encounter errors when states are issued with the ``HashAttachmentConstraint``,
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but not all nodes have that same version of the CorDapp installed locally.
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In this case, flows will fail with a ``ContractConstraintRejection``, and the failed flow will be sent to the flow hospital.
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From there it's suspended waiting to be retried on node restart.
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This gives the node operator the opportunity to recover from those errors, which in the case of constraint violations means
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adding the right cordapp jar to the ``cordapps`` folder.
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CorDapps as attachments
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-----------------------
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CorDapp JARs (see :doc:`cordapp-overview`) that contain classes implementing the ``Contract`` interface are automatically
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loaded into the ``AttachmentStorage`` of a node, and made available as ``ContractAttachments``.
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They are retrievable by hash using ``AttachmentStorage.openAttachment``.
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These JARs can either be installed on the node or fetched from the network using the ``FetchAttachmentsFlow``.
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.. note:: The obvious way to write a CorDapp is to put all you states, contracts, flows and support code into a single
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Java module. This will work but it will effectively publish your entire app onto the ledger. That has two problems:
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(1) it is inefficient, and (2) it means changes to your flows or other parts of the app will be seen by the ledger
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as a "new app", which may end up requiring essentially unnecessary upgrade procedures. It's better to split your
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app into multiple modules: one which contains just states, contracts and core data types. And another which contains
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the rest of the app. See :ref:`cordapp-structure`.
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Constraints propagation
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-----------------------
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As was mentioned above, the TransactionBuilder API gives the CorDapp developer or even malicious node owner the possibility
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to construct output states with a constraint of his choosing.
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Also, as listed above, some constraints are more restrictive then others.
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For example, the ``HashAttachmentConstraint`` is the most restrictive, basically reducing the universe of possible attachments
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to 1 (see migrating from hash constraints in note below), while the ``AlwaysAcceptAttachmentConstraint`` allows any attachment to be selected.
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For the ledger to remain in a consistent state, the expected behavior is for output state to inherit the constraints of input states.
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This guarantees that for example, a transaction can't output a state with the ``AlwaysAcceptAttachmentConstraint`` when the
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corresponding input state was the ``HashAttachmentConstraint``. Translated, this means that if this rule is enforced, it ensures
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that the output state will be spent under similar conditions as it was created.
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Before version 4, the constraint propagation logic was expected to be enforced in the contract verify code, as it has access to the entire Transaction.
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Starting with version 4 of Corda, the constraint propagation logic has been implemented and enforced directly by the platform,
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unless disabled using ``@NoConstraintPropagation`` - which reverts to the previous behavior.
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For Contracts that are not annotated with ``@NoConstraintPropagation``, the platform implements a fairly simple constraint transition policy
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to ensure security and also allow the possibility to transition to the new ``SignatureAttachmentConstraint``.
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.. note:: Migration from hash to signature constraints is automatic if the transaction building node has a signed version of the
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original contract jar (used in previous transactions generating hash constrained states). Additionally, it is a requirement that
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the owner of this signed jar register the java package namespace of the encompassing contract classes with the network parameters.
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See :ref:`package_namespace_ownership` introduced in Corda 4.
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During transaction building the ``AutomaticPlaceholderConstraint`` for output states will be resolved and the best contract attachment versions
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will be selected based on a variety of factors so that the above holds true.
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If it can't find attachments in storage or there are no possible constraints, the Transaction Builder will fail early.
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For example:
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- In the simple case, if a ``MyContract`` input state is constrained by the ``HashAttachmentConstraint``, then the constraints of all output states of that type will be resolved
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to the ``HashAttachmentConstraint`` with the same hash, and the attachment with that hash will be selected.
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- For upgradeable constraints like the ``WhitelistedByZoneAttachmentConstraint``, the output states will inherit the same,
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and the selected attachment will be the latest version installed on the node.
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- A more complex case is when for ``MyContract``, one input state is constrained by the ``HashAttachmentConstraint``, while another
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state by the ``WhitelistedByZoneAttachmentConstraint``. To respect the rule from above, if the hash of the ``HashAttachmentConstraint``
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is whitelisted by the network, then the output states will inherit the ``HashAttachmentConstraint``, as it is more restrictive.
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If the hash was not whitelisted, then the builder will fail as it is unable to select a correct constraint.
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- The ``SignatureAttachmentConstraint`` is an upgradeable constraint, same as the ``WhitelistedByZoneAttachmentConstraint``.
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By convention we allow states to transition to the ``SignatureAttachmentConstraint`` from the ``WhitelistedByZoneAttachmentConstraint`` as long as the Signatures
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from new constraints are all the jarsigners from the whitelisted attachment. We also allow transitioning of states from ``HashAttachmentConstraint`` to
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``SignatureAttachmentConstraint`` where both the unsigned and signed versions of the associated contract attachment are loaded in a node, and the java
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package namespace of encompassing contract classes is registered with the network parameters using the same signing key as the signed contract jar.
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For Contracts that are annotated with ``@NoConstraintPropagation``, the platform requires that the Transaction Builder specifies
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an actual constraint for the output states (the ``AutomaticPlaceholderConstraint`` can't be used) .
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Debugging
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---------
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If an attachment constraint cannot be resolved, a ``MissingContractAttachments`` exception is thrown. There are two
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common sources of ``MissingContractAttachments`` exceptions:
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Not setting CorDapp packages in tests
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*************************************
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You are running a test and have not specified the CorDapp packages to scan. See the instructions above.
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Wrong fully-qualified contract name
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***********************************
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You are specifying the fully-qualified name of the contract incorrectly. For example, you've defined ``MyContract`` in
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the package ``com.mycompany.myapp.contracts``, but the fully-qualified contract name you pass to the
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``TransactionBuilder`` is ``com.mycompany.myapp.MyContract`` (instead of ``com.mycompany.myapp.contracts.MyContract``). |