2018-03-05 23:03:55 +00:00
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Network permissioning
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2017-11-24 18:06:01 +00:00
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=====================
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2016-11-24 16:38:40 +00:00
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2017-11-24 18:06:01 +00:00
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.. contents::
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2016-11-24 16:38:40 +00:00
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2017-11-24 18:06:01 +00:00
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Corda networks are *permissioned*. To connect to a network, a node needs three keystores in its
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``<workspace>/certificates/`` folder:
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* ``truststore.jks``, which stores trusted public keys and certificates (in our case, those of the network root CA)
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* ``nodekeystore.jks``, which stores the node’s identity keypairs and certificates
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* ``sslkeystore.jks``, which stores the node’s TLS keypairs and certificates
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2016-11-24 16:38:40 +00:00
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2018-03-05 23:03:55 +00:00
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Production deployments require a secure certificate authority.
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2017-11-27 13:36:52 +00:00
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Most production deployments will use an existing certificate authority or construct one using software that will be
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made available in the coming months. Until then, the documentation below can be used to create your own certificate
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authority.
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2016-12-09 19:07:32 +00:00
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2018-03-05 23:03:55 +00:00
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Certificate hierarchy
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---------------------
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A Corda network has four types of certificate authorities (CAs):
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* The **root network CA**
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* The **doorman CA**
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* The doorman CA is used instead of the root network CA for day-to-day
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key signing to reduce the risk of the root network CA's private key being compromised
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* The **node CAs**
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* Each node serves as its own CA in issuing the child certificates that it uses to sign its identity
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keys and TLS certificates
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* The **legal identity CAs**
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* Node's well-known legal identity, apart from signing transactions, can also issue certificates for confidential legal identities
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The following constraints are also imposed:
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* Doorman certificates are issued by a network root which certificate doesn't contain the extension
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* Well-known service identity certificates are issued by an entity with a Doorman certificate
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* Node CA certificates are issued by an entity with a Doorman certificate
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* Well known legal identity/TLS certificates are issued by a certificate marked as node CA
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* Confidential legal identity certificates are issued by a certificate marked as well known legal identity
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* Party certificates are marked as either a well known identity or a confidential identity
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* The structure of certificates above Doorman/Network map is intentionally left untouched, as they are not relevant to
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the identity service and therefore there is no advantage in enforcing a specific structure on those certificates. The
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certificate hierarchy consistency checks are required because nodes can issue their own certificates and can set
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their own role flags on certificates, and it's important to verify that these are set consistently with the
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certificate hierarchy design. As as side-effect this also acts as a secondary depth restriction on issued
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certificates
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All the certificates must be issued with the custom role extension (see below).
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We can visualise the permissioning structure as follows:
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.. image:: resources/certificate_structure.png
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:scale: 55%
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:align: center
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Keypair and certificate formats
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-------------------------------
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You can use any standard key tools or Corda's ``X509Utilities`` (which uses Bouncy Castle) to create the required
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public/private keypairs and certificates. The keypairs and certificates should obey the following restrictions:
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* The certificates must follow the `X.509 standard <https://tools.ietf.org/html/rfc5280>`_
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* We recommend X.509 v3 for forward compatibility
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* The TLS certificates must follow the `TLS v1.2 standard <https://tools.ietf.org/html/rfc5246>`_
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* The root network CA, doorman CA and node CA keys, as well as the node TLS
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keys, must follow one of the following schemes:
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* ECDSA using the NIST P-256 curve (secp256r1)
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* RSA with 3072-bit key size
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Certificate role extension
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--------------------------
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Corda certificates have a custom X.509 v3 extension that specifies the role the certificate relates to. This extension
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has the OID ``1.3.6.1.4.1.50530.1.1`` and is non-critical, so implementations outside of Corda nodes can safely ignore it.
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The extension contains a single ASN.1 integer identifying the identity type the certificate is for:
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1. Doorman
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2. Network map
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3. Service identity (currently only used as the shared identity in distributed notaries)
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4. Node certificate authority (from which the TLS and well-known identity certificates are issued)
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5. Transport layer security
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6. Well-known legal identity
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7. Confidential legal identity
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In a typical installation, node administrators needn't be aware of these. However, when node certificates are managed
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by external tools (such as an existing PKI solution deployed within an organisation), it is important to understand
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these constraints.
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Certificate path validation is extended so that a certificate must contain the extension if the extension was present
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in the certificate of the issuer.
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Creating the root and doorman CAs
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---------------------------------
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Creating the root network CA's keystore and truststore
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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1. Create a new keypair
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* This will be used as the root network CA's keypair
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2. Create a self-signed certificate for the keypair. The basic constraints extension must be set to ``true``
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* This will be used as the root network CA's certificate
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3. Create a new keystore and store the root network CA's keypair and certificate in it for later use
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* This keystore will be used by the root network CA to sign the doorman CA's certificate
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4. Create a new Java keystore named ``truststore.jks`` and store the root network CA's certificate in it using the
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alias ``cordarootca``
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* This keystore must then be provisioned to the individual nodes later so they can store it in their ``certificates`` folder
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.. warning:: The root network CA's private key should be protected and kept safe.
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2018-03-05 23:03:55 +00:00
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Creating the doorman CA's keystore
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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1. Create a new keypair
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* This will be used as the doorman CA's keypair
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2. Obtain a certificate for the keypair signed with the root network CA key. The basic constraints extension must be
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set to ``true``
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* This will be used as the doorman CA's certificate
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3. Create a new keystore and store the doorman CA's keypair and certificate chain
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(i.e. the doorman CA certificate *and* the root network CA certificate) in it for later use
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* This keystore will be used by the doorman CA to sign the nodes' identity certificates
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Creating the node CA keystores and TLS keystores
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------------------------------------------------
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Creating the node CA keystores
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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1. For each node, create a new keypair
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2. Obtain a certificate for the keypair signed with the doorman CA key. The basic constraints extension must be
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set to ``true``
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3. Create a new Java keystore named ``nodekeystore.jks`` and store the keypair in it using the alias ``cordaclientca``
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* The node will store this keystore locally to sign its identity keys and anonymous keys
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Creating the node TLS keystores
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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1. For each node, create a new keypair
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2. Create a certificate for the keypair signed with the node CA key. The basic constraints extension must be set to
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``false``
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3. Create a new Java keystore named ``sslkeystore.jks`` and store the key and certificates in it using the alias
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``cordaclienttls``
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* The node will store this keystore locally to sign its TLS certificates
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Installing the certificates on the nodes
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----------------------------------------
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For each node, copy the following files to the node's certificate directory (``<workspace>/certificates/``):
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1. The node's ``nodekeystore.jks`` keystore
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2. The node's ``sslkeystore.jks`` keystore
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3. The root network CA's ``truststore.jks`` keystore
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