.. highlight:: kotlin .. raw:: html Writing the contract ==================== It's easy to imagine that most CorDapps will want to impose some constraints on how their states evolve over time: * A cash CorDapp will not want to allow users to create transactions that generate money out of thin air (at least without the involvement of a central bank or commercial bank) * A loan CorDapp might not want to allow the creation of negative-valued loans * An asset-trading CorDapp will not want to allow users to finalise a trade without the agreement of their counterparty In Corda, we impose constraints on how states can evolve using contracts. .. note:: Contracts in Corda are very different to the smart contracts of other distributed ledger platforms. They are not stateful objects representing the current state of the world. Instead, like a real-world contract, they simply impose rules on what kinds of transactions are allowed. Every state has an associated contract. A transaction is invalid if it does not satisfy the contract of every input and output state in the transaction. The Contract interface ---------------------- Just as every Corda state must implement the ``ContractState`` interface, every contract must implement the ``Contract`` interface: .. container:: codeset .. code-block:: kotlin interface Contract { // Implements the contract constraints in code. @Throws(IllegalArgumentException::class) fun verify(tx: LedgerTransaction) } We can see that ``Contract`` expresses its constraints through a ``verify`` function that takes a transaction as input, and: * Throws an ``IllegalArgumentException`` if it rejects the transaction proposal * Returns silently if it accepts the transaction proposal Controlling IOU evolution ------------------------- What would a good contract for an ``IOUState`` look like? There is no right or wrong answer - it depends on how you want your CorDapp to behave. For our CorDapp, let's impose the constraint that we only want to allow the creation of IOUs. We don't want nodes to transfer them or redeem them for cash. One way to enforce this behaviour would be by imposing the following constraints: * A transaction involving IOUs must consume zero inputs, and create one output of type ``IOUState`` * The transaction should also include a ``Create`` command, indicating the transaction's intent (more on commands shortly) We might also want to impose some constraints on the properties of the issued ``IOUState``: * Its value must be non-negative * The lender and the borrower cannot be the same entity And finally, we'll want to impose constraints on who is required to sign the transaction: * The IOU's lender must sign * The IOU's borrower must sign We can picture this transaction as follows: .. image:: resources/simple-tutorial-transaction-2.png :scale: 15% :align: center Defining IOUContract -------------------- Let's write a contract that enforces these constraints. We'll do this by modifying either ``TemplateContract.java`` or ``StatesAndContracts.kt`` and updating ``TemplateContract`` to define an ``IOUContract``: .. container:: codeset .. literalinclude:: example-code/src/main/kotlin/net/corda/docs/kotlin/tutorial/twoparty/IOUContract.kt :language: kotlin :start-after: DOCSTART 01 :end-before: DOCEND 01 .. literalinclude:: example-code/src/main/java/net/corda/docs/java/tutorial/twoparty/IOUContract.java :language: java :start-after: DOCSTART 01 :end-before: DOCEND 01 If you're following along in Java, you'll also need to rename ``TemplateContract.java`` to ``IOUContract.java``. Let's walk through this code step by step. The Create command ^^^^^^^^^^^^^^^^^^ The first thing we add to our contract is a *command*. Commands serve two functions: * They indicate the transaction's intent, allowing us to perform different verification for different types of transaction. For example, a transaction proposing the creation of an IOU could have to meet different constraints to one redeeming an IOU * They allow us to define the required signers for the transaction. For example, IOU creation might require signatures from the lender only, whereas the transfer of an IOU might require signatures from both the IOU's borrower and lender Our contract has one command, a ``Create`` command. All commands must implement the ``CommandData`` interface. The ``CommandData`` interface is a simple marker interface for commands. In fact, its declaration is only two words long (Kotlin interfaces do not require a body): .. container:: codeset .. code-block:: kotlin interface CommandData The verify logic ^^^^^^^^^^^^^^^^ Our contract also needs to define the actual contract constraints by implementing ``verify``. Our goal in writing the ``verify`` function is to write a function that, given a transaction: * Throws an ``IllegalArgumentException`` if the transaction is considered invalid * Does **not** throw an exception if the transaction is considered valid In deciding whether the transaction is valid, the ``verify`` function only has access to the contents of the transaction: * ``tx.inputs``, which lists the inputs * ``tx.outputs``, which lists the outputs * ``tx.commands``, which lists the commands and their associated signers As well as to the transaction's attachments and time-window, which we won't use here. Based on the constraints enumerated above, we need to write a ``verify`` function that rejects a transaction if any of the following are true: * The transaction doesn't include a ``Create`` command * The transaction has inputs * The transaction doesn't have exactly one output * The IOU itself is invalid * The transaction doesn't require the lender's signature Command constraints ~~~~~~~~~~~~~~~~~~~ Our first constraint is around the transaction's commands. We use Corda's ``requireSingleCommand`` function to test for the presence of a single ``Create`` command. If the ``Create`` command isn't present, or if the transaction has multiple ``Create`` commands, an exception will be thrown and contract verification will fail. Transaction constraints ~~~~~~~~~~~~~~~~~~~~~~~ We also want our transaction to have no inputs and only a single output - an issuance transaction. To impose this and the subsequent constraints, we are using Corda's built-in ``requireThat`` block. ``requireThat`` provides a terse way to write the following: * If the condition on the right-hand side doesn't evaluate to true... * ...throw an ``IllegalArgumentException`` with the message on the left-hand side As before, the act of throwing this exception causes the transaction to be considered invalid. IOU constraints ~~~~~~~~~~~~~~~ We want to impose two constraints on the ``IOUState`` itself: * Its value must be non-negative * The lender and the borrower cannot be the same entity We impose these constraints in the same ``requireThat`` block as before. You can see that we're not restricted to only writing constraints in the ``requireThat`` block. We can also write other statements - in this case, extracting the transaction's single ``IOUState`` and assigning it to a variable. Signer constraints ~~~~~~~~~~~~~~~~~~ Finally, we require both the lender and the borrower to be required signers on the transaction. A transaction's required signers is equal to the union of all the signers listed on the commands. We therefore extract the signers from the ``Create`` command we retrieved earlier. This is an absolutely essential constraint - it ensures that no ``IOUState`` can ever be created on the ledger without the express agreement of both the lender and borrower nodes. Progress so far --------------- We've now written an ``IOUContract`` constraining the evolution of each ``IOUState`` over time: * An ``IOUState`` can only be created, not transferred or redeemed * Creating an ``IOUState`` requires an issuance transaction with no inputs, a single ``IOUState`` output, and a ``Create`` command * The ``IOUState`` created by the issuance transaction must have a non-negative value, and the lender and borrower must be different entities Next, we'll update the ``IOUFlow`` so that it obeys these contract constraints when issuing an ``IOUState`` onto the ledger.