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* Added more docs for reference states to key concepts and api docs. * Updated with requested changes
210 lines
8.7 KiB
ReStructuredText
210 lines
8.7 KiB
ReStructuredText
Transactions
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============
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.. topic:: Summary
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* *Transactions are proposals to update the ledger*
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* *A transaction proposal will only be committed if:*
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* *It doesn't contain double-spends*
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* *It is contractually valid*
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* *It is signed by the required parties*
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.. only:: htmlmode
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Video
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-----
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.. raw:: html
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<iframe src="https://player.vimeo.com/video/213879807" width="640" height="360" frameborder="0" webkitallowfullscreen mozallowfullscreen allowfullscreen></iframe>
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<p></p>
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Overview
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--------
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Corda uses a *UTXO* (unspent transaction output) model where every state on the ledger is immutable. The ledger
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evolves over time by applying *transactions*, which update the ledger by marking zero or more existing ledger states
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as historic (the *inputs*) and producing zero or more new ledger states (the *outputs*). Transactions represent a
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single link in the state sequences seen in :doc:`key-concepts-states`.
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Here is an example of an update transaction, with two inputs and two outputs:
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.. image:: resources/basic-tx.png
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:scale: 25%
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:align: center
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A transaction can contain any number of inputs, outputs and references of any type:
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* They can include many different state types (e.g. both cash and bonds)
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* They can be issuances (have zero inputs) or exits (have zero outputs)
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* They can merge or split fungible assets (e.g. combining a $2 state and a $5 state into a $7 cash state)
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Transactions are *atomic*: either all the transaction's proposed changes are accepted, or none are.
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There are two basic types of transactions:
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* Notary-change transactions (used to change a state's notary - see :doc:`key-concepts-notaries`)
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* General transactions (used for everything else)
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Transaction chains
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------------------
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When creating a new transaction, the output states that the transaction will propose do not exist yet, and must
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therefore be created by the proposer(s) of the transaction. However, the input states already exist as the outputs of
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previous transactions. We therefore include them in the proposed transaction by reference.
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These input states references are a combination of:
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* The hash of the transaction that created the input
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* The input's index in the outputs of the previous transaction
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This situation can be illustrated as follows:
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.. image:: resources/tx-chain.png
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:scale: 25%
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:align: center
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These input state references link together transactions over time, forming what is known as a *transaction chain*.
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Committing transactions
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-----------------------
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Initially, a transaction is just a **proposal** to update the ledger. It represents the future state of the ledger
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that is desired by the transaction builder(s):
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.. image:: resources/uncommitted_tx.png
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:scale: 25%
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:align: center
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To become reality, the transaction must receive signatures from all of the *required signers* (see **Commands**, below). Each
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required signer appends their signature to the transaction to indicate that they approve the proposal:
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.. image:: resources/tx_with_sigs.png
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:scale: 25%
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:align: center
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If all of the required signatures are gathered, the transaction becomes committed:
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.. image:: resources/committed_tx.png
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:scale: 25%
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:align: center
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This means that:
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* The transaction's inputs are marked as historic, and cannot be used in any future transactions
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* The transaction's outputs become part of the current state of the ledger
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Transaction validity
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--------------------
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Each required signers should only sign the transaction if the following two conditions hold:
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* **Transaction validity**: For both the proposed transaction, and every transaction in the chain of transactions
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that created the current proposed transaction's inputs:
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* The transaction is digitally signed by all the required parties
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* The transaction is *contractually valid* (see :doc:`key-concepts-contracts`)
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* **Transaction uniqueness**: There exists no other committed transaction that has consumed any of the inputs to
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our proposed transaction (see :doc:`key-concepts-consensus`)
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If the transaction gathers all the required signatures but these conditions do not hold, the transaction's outputs
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will not be valid, and will not be accepted as inputs to subsequent transactions.
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Reference states
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----------------
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As mentioned in :doc:`key-concepts-states`, some states need to be referred to by the contracts of other input or output
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states but not updated/consumed. This is where reference states come in. When a state is added to the references list of
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a transaction, instead of the inputs or outputs list, then it is treated as a *reference state*. There are two important
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differences between regular states and reference states:
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* The specified notary for the transaction **does** check whether the reference states are current. However, reference
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states are not consumed when the transaction containing them is committed to the ledger.
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* The contracts for reference states are not executed for the transaction containing them.
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Other transaction components
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----------------------------
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As well as input states and output states, transactions contain:
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* Commands
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* Attachments
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* Time-Window
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* Notary
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For example, suppose we have a transaction where Alice uses a £5 cash payment to pay off £5 of an IOU with Bob.
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This transaction has two supporting attachments and will only be notarised by NotaryClusterA if the notary pool
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receives it within the specified time-window. This transaction would look as follows:
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.. image:: resources/full-tx.png
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:scale: 25%
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:align: center
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We explore the role played by the remaining transaction components below.
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Commands
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^^^^^^^^
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.. raw:: html
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<iframe src="https://player.vimeo.com/video/213881538" width="640" height="360" frameborder="0" webkitallowfullscreen mozallowfullscreen allowfullscreen></iframe>
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<p></p>
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Suppose we have a transaction with a cash state and a bond state as inputs, and a cash state and a bond state as
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outputs. This transaction could represent two different scenarios:
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* A bond purchase
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* A coupon payment on a bond
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We can imagine that we'd want to impose different rules on what constitutes a valid transaction depending on whether
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this is a purchase or a coupon payment. For example, in the case of a purchase, we would require a change in the bond's
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current owner, whereas in the case of a coupon payment, we would require that the ownership of the bond does not
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change.
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For this, we have *commands*. Including a command in a transaction allows us to indicate the transaction's intent,
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affecting how we check the validity of the transaction.
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Each command is also associated with a list of one or more *signers*. By taking the union of all the public keys
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listed in the commands, we get the list of the transaction's required signers. In our example, we might imagine that:
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* In a coupon payment on a bond, only the owner of the bond is required to sign
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* In a cash payment, only the owner of the cash is required to sign
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We can visualize this situation as follows:
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.. image:: resources/commands.png
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:scale: 25%
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:align: center
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Attachments
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^^^^^^^^^^^
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.. raw:: html
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<iframe src="https://player.vimeo.com/video/213879328" width="640" height="360" frameborder="0" webkitallowfullscreen mozallowfullscreen allowfullscreen></iframe>
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<p></p>
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Sometimes, we have a large piece of data that can be reused across many different transactions. Some examples:
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* A calendar of public holidays
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* Supporting legal documentation
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* A table of currency codes
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For this use case, we have *attachments*. Each transaction can refer to zero or more attachments by hash. These
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attachments are ZIP/JAR files containing arbitrary content. The information in these files can then be
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used when checking the transaction's validity.
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Time-window
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^^^^^^^^^^^
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In some cases, we want a transaction proposed to only be approved during a certain time-window. For example:
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* An option can only be exercised after a certain date
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* A bond may only be redeemed before its expiry date
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In such cases, we can add a *time-window* to the transaction. Time-windows specify the time window during which the
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transaction can be committed. We discuss time-windows in the section on :doc:`key-concepts-time-windows`.
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Notary
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^^^^^^
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A notary pool is a network service that provides uniqueness consensus by attesting that, for a given transaction,
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it has not already signed other transactions that consume any of the proposed transaction’s input states.
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The notary pool provides the point of finality in the system.
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Note that if the notary entity is absent then the transaction is not notarised at all. This is intended for
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issuance/genesis transactions that don't consume any other states and thus can't double spend anything.
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For more information on the notary services, see :doc:`key-concepts-notaries`. |