corda/docs/source/api-identity.rst
2017-10-06 16:08:27 +01:00

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API: Identity

Note

Before reading this page, you should be familiar with the key concepts of key-concepts-identity.

Party

Identities on the network are represented by AbstractParty. There are two types of AbstractParty:

  • Party, identified by a PublicKey and a CordaX500Name
  • AnonymousParty, identified by a PublicKey

For example, in a transaction sent to your node as part of a chain of custody it is important you can convince yourself of the transaction's validity, but equally important that you don't learn anything about who was involved in that transaction. In these cases AnonymousParty should be used by flows constructing when transaction states and commands. In contrast, for internal processing where extended details of a party are required, the Party class should be used instead. The identity service provides functionality for flows to resolve anonymous parties to full parties, dependent on the anonymous party's identity having been registered with the node earlier (typically this is handled by SwapIdentitiesFlow or IdentitySyncFlow, discussed below).

Party names are held within the CordaX500Name data class, which enforces the structure of names within Corda, as well as ensuring a consistent rendering of the names in plain text.

The support for both Party and AnonymousParty classes in Corda enables sophisticated selective disclosure of identity information. For example, it is possible to construct a Transaction using an AnonymousParty, so nobody can learn of your involvement by inspection of the transaction, yet prove to specific counterparts that this AnonymousParty actually is owned by your well known identity. This disclosure is achieved through the use of the PartyAndCertificate data class which can be propagated to those who need to know, and contains the Party's X.509 certificate path to provide proof of ownership by a well known identity.

The PartyAndCertificate class is also used in the network map service to represent well known identities, in which scenario the certificate path proves its issuance by the Doorman service.

Confidential Identities

Confidential identities are key pairs where the corresponding X.509 certificate (and path) are not made public, so that parties who are not involved in the transaction cannot identify its participants. They are owned by a well known identity, which must sign the X.509 certificate. Before constructing a new transaction the involved parties must generate and send new confidential identities to each other, a process which is managed using SwapIdentitiesFlow (discussed below). The public keys of these confidential identities are then used when generating output states and commands for the transaction.

Where using outputs from a previous transaction in a new transaction, counterparties may need to know who the involved parties are. One example is in TwoPartyTradeFlow which delegates to CollectSignaturesFlow to gather certificates from both parties. CollectSignaturesFlow requires that a confidential identity of the initiating node has signed the transaction, and verifying this requires the receiving node has a copy of the confidential identity for the input state. IdentitySyncFlow can be used to synchronize the confidential identities we have the certificate paths for, in a single transaction, to another node.

Note

CollectSignaturesFlow requires that the initiating node has signed the transaction, and as such all nodes providing signatures must recognise the signing key used by the initiating node as being either its well known identity or a confidential identity they have the certificate for.

Swap identities flow

SwapIdentitiesFlow takes the party to swap identities with in its constructor (the counterparty), and is typically run as a subflow of another flow. It returns a mapping from well known identities of the calling flow and our counterparty to the new confidential identities; in future this will be extended to handle swapping identities with multiple parties. You can see an example of it being used in TwoPartyDealFlow.kt:

../../finance/src/main/kotlin/net/corda/finance/flows/TwoPartyDealFlow.kt

The swap identities flow goes through the following key steps:

  1. Generate a nonce value to form a challenge to the other nodes.
  2. Send nonce value to all counterparties, and receive their nonce values.
  3. Generate a new confidential identity from our well known identity.
  4. Create a data blob containing the new confidential identity (public key, name and X.509 certificate path), and the hash of the nonce values.
  5. Sign the resulting data blob with the confidential identity's private key.
  6. Send the confidential identity and data blob signature to all counterparties, while receiving theirs.
  7. Verify the signatures to ensure that identities were generated by the involved set of parties.
  8. Verify the confidential identities are owned by the expected well known identities.
  9. Store the confidential identities and return them to the calling flow.

This ensures not only that the confidential identity X.509 certificates are signed by the correct well known identities, but also that the confidential identity private key is held by the counterparty, and that a party cannot claim ownership another party's confidential identities belong to its well known identity.

Identity synchronization flow

When constructing a transaction whose input states reference confidential identities, it is common for other signing entities (counterparties) to require to know which well known identities those confidential identities map to. The IdentitySyncFlow handles this process, and you can see an example of its use in TwoPartyTradeFlow.kt:

../../finance/src/main/kotlin/net/corda/finance/flows/TwoPartyTradeFlow.kt

The identity synchronization flow goes through the following key steps:

  1. Extract participant identities from all input and output states and remove any well known identities. Required signers on commands are currently ignored as they are presumed to be included in the participants on states, or to be well known identities of services (such as an oracle service).
  2. For each counterparty node, send a list of the public keys of the confidential identities, and receive back a list of those the counterparty needs the certificate path for.
  3. Verify the requested list of identities contains only confidential identities in the offered list, and abort otherwise.
  4. Send the requested confidential identities as PartyAndCertificate instances to the counterparty.

Note

IdentitySyncFlow works on a push basis. The initiating node can only send confidential identities it has the X.509 certificates for, and the remote nodes can only request confidential identities being offered (are referenced in the transaction passed to the initiating flow). There is no standard flow for nodes to collect confidential identities before assembling a transaction, and this is left for individual flows to manage if required.

IdentitySyncFlow will serve all confidential identities in the provided transaction, irrespective of well known identity. This is important for more complex transaction cases with 3+ parties, for example:

  • Alice is building the transaction, and provides some input state x owned by a confidential identity of Alice
  • Bob provides some input state y owned by a confidential identity of Bob
  • Charlie provides some input state z owned by a confidential identity of Charlie

Alice may know all of the confidential identities ahead of time, but Bob not know about Charlie's and vice-versa. The assembled transaction therefore has three input states x, y and z, for which only Alice possesses certificates for all confidential identities. IdentitySyncFlow must send not just Alice's confidential identity but also any other identities in the transaction to the Bob and Charlie.