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606 lines
25 KiB
ReStructuredText
.. highlight:: kotlin
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<script type="text/javascript" src="_static/jquery.js"></script>
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<script type="text/javascript" src="_static/codesets.js"></script>
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Object serialization
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====================
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.. contents::
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Introduction
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------------
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Object serialization is the process of converting objects into a stream of bytes and, deserialization, the reverse
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process of creating objects from a stream of bytes. It takes place every time nodes pass objects to each other as
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messages, when objects are sent to or from RPC clients from the node, and when we store transactions in the database.
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Corda pervasively uses a custom form of type safe binary serialisation. This stands in contrast to some other systems that use
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weakly or untyped string-based serialisation schemes like JSON or XML. The primary drivers for this were:
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* A desire to have a schema describing what has been serialized alongside the actual data:
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#. To assist with versioning, both in terms of being able to interpret data archived long ago (e.g. trades from
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a decade ago, long after the code has changed) and between differing code versions.
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#. To make it easier to write generic code e.g. user interfaces that can navigate the serialized form of data.
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#. To support cross platform (non-JVM) interaction, where the format of a class file is not so easily interpreted.
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* A desire to use a documented and static wire format that is platform independent, and is not subject to change with
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3rd party library upgrades, etc.
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* A desire to support open-ended polymorphism, where the number of subclasses of a superclass can expand over time
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and the subclasses do not need to be defined in the schema *upfront*. This is key to many Corda concepts, such as states.
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* Increased security by constructing deserialized objects through supported constructors, rather than having
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data inserted directly into their fields without an opportunity to validate consistency or intercept attempts to manipulate
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supposed invariants.
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* Binary formats work better with digital signatures than text based formats, as there's much less scope for
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changes that modify syntax but not semantics.
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Whitelisting
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------------
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In classic Java serialization, any class on the JVM classpath can be deserialized. This is a source of exploits and
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vulnerabilities that exploit the large set of third-party libraries that are added to the classpath as part of a JVM
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application's dependencies and carefully craft a malicious stream of bytes to be deserialized. In Corda, we strictly
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control which classes can be deserialized (and, pro-actively, serialized) by insisting that each (de)serializable class
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is part of a whitelist of allowed classes.
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To add a class to the whitelist, you must use either of the following mechanisms:
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#. Add the ``@CordaSerializable`` annotation to the class. This annotation can be present on the
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class itself, on any super class of the class, on any interface implemented by the class or its super classes, or any
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interface extended by an interface implemented by the class or its super classes.
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#. Implement the ``SerializationWhitelist`` interface and specify a list of whitelisted classes.
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There is also a built-in Corda whitelist (see the ``DefaultWhitelist`` class) that whitelists common JDK classes for
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convenience. This whitelist is not user-editable.
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The annotation is the preferred method for whitelisting. An example is shown in :doc:`tutorial-clientrpc-api`.
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It's reproduced here as an example of both ways you can do this for a couple of example classes.
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.. literalinclude:: example-code/src/main/kotlin/net/corda/docs/kotlin/ClientRpcTutorial.kt
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:language: kotlin
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:start-after: START 7
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:end-before: END 7
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.. note:: Several of the core interfaces at the heart of Corda are already annotated and so any classes that implement
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them will automatically be whitelisted. This includes ``Contract``, ``ContractState`` and ``CommandData``.
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.. warning:: Java 8 Lambda expressions are not serializable except in flow checkpoints, and then not by default. The syntax to declare a serializable Lambda
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expression that will work with Corda is ``Runnable r = (Runnable & Serializable) () -> System.out.println("Hello World");``, or
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``Callable<String> c = (Callable<String> & Serializable) () -> "Hello World";``.
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AMQP
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----
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Corda uses an extended form of AMQP 1.0 as its binary wire protocol. You can learn more about the :doc:`wire-format` Corda
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uses if you intend to parse Corda messages from non-JVM platforms.
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Corda serialisation is currently used for:
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#. Peer-to-peer networking.
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#. Persisted messages, like signed transactions and states.
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For the checkpointing of flows Corda uses a private scheme that is subject to change. It is currently based on the Kryo
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framework, but this may not be true in future.
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This separation of serialization schemes into different contexts allows us to use the most suitable framework for that context rather than
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attempting to force a one-size-fits-all approach. Kryo is more suited to the serialization of a program's stack frames, as it is more flexible
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than our AMQP framework in what it can construct and serialize. However, that flexibility makes it exceptionally difficult to make secure. Conversely,
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our AMQP framework allows us to concentrate on a secure framework that can be reasoned about and thus made safer, with far fewer
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security holes.
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Selection of serialization context should, for the most part, be opaque to CorDapp developers, the Corda framework selecting
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the correct context as configured.
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This document describes what is currently and what will be supported in the Corda AMQP format from the perspective
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of CorDapp developers, to allow CorDapps to take into consideration the future state. The AMQP serialization format will
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continue to apply the whitelisting functionality that is already in place and described in :doc:`serialization`.
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Core Types
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----------
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This section describes the classes and interfaces that the AMQP serialization format supports.
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Collection Types
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````````````````
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The following collection types are supported. Any implementation of the following will be mapped to *an* implementation
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of the interface or class on the other end. For example, if you use a Guava implementation of a collection, it will
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deserialize as the primitive collection type.
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The declared types of properties should only use these types, and not any concrete implementation types (e.g.
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Guava implementations). Collections must specify their generic type, the generic type parameters will be included in
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the schema, and the element's type will be checked against the generic parameters when deserialized.
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::
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java.util.Collection
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java.util.List
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java.util.Set
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java.util.SortedSet
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java.util.NavigableSet
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java.util.NonEmptySet
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java.util.Map
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java.util.SortedMap
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java.util.NavigableMap
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However, as a convenience, we explicitly support the concrete implementation types below, and they can be used as the
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declared types of properties.
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::
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java.util.LinkedHashMap
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java.util.TreeMap
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java.util.EnumSet
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java.util.EnumMap (but only if there is at least one entry)
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JVM primitives
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``````````````
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All the primitive types are supported.
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::
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boolean
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byte
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char
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double
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float
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int
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long
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short
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Arrays
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``````
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Arrays of any type are supported, primitive or otherwise.
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JDK Types
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`````````
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The following JDK library types are supported:
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::
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java.io.InputStream
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java.lang.Boolean
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java.lang.Byte
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java.lang.Character
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java.lang.Class
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java.lang.Double
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java.lang.Float
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java.lang.Integer
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java.lang.Long
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java.lang.Short
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java.lang.StackTraceElement
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java.lang.String
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java.lang.StringBuffer
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java.math.BigDecimal
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java.security.PublicKey
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java.time.DayOfWeek
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java.time.Duration
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java.time.Instant
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java.time.LocalDate
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java.time.LocalDateTime
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java.time.LocalTime
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java.time.Month
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java.time.MonthDay
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java.time.OffsetDateTime
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java.time.OffsetTime
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java.time.Period
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java.time.YearMonth
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java.time.Year
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java.time.ZonedDateTime
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java.time.ZonedId
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java.time.ZoneOffset
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java.util.BitSet
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java.util.Currency
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java.util.UUID
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Third-Party Types
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`````````````````
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The following 3rd-party types are supported:
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::
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kotlin.Unit
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kotlin.Pair
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org.apache.activemq.artemis.api.core.SimpleString
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Corda Types
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```````````
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Any classes and interfaces in the Corda codebase annotated with ``@CordaSerializable`` are supported.
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All Corda exceptions that are expected to be serialized inherit from ``CordaThrowable`` via either ``CordaException`` (for
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checked exceptions) or ``CordaRuntimeException`` (for unchecked exceptions). Any ``Throwable`` that is serialized but does
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not conform to ``CordaThrowable`` will be converted to a ``CordaRuntimeException``, with the original exception type
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and other properties retained within it.
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Custom Types
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------------
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You own types must adhere to the following rules to be supported:
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Classes
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```````
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General Rules
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'''''''''''''
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#. The class must be compiled with parameter names included in the ``.class`` file. This is the default in Kotlin
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but must be turned on in Java using the ``-parameters`` command line option to ``javac``
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.. note:: In circumstances where classes cannot be recompiled, such as when using a third-party library, a
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proxy serializer can be used to avoid this problem. Details on creating such an object can be found on the
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:doc:`cordapp-custom-serializers` page.
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#. The class must be annotated with ``@CordaSerializable``
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#. The declared types of constructor arguments, getters, and setters must be supported, and where generics are used, the
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generic parameter must be a supported type, an open wildcard (``*``), or a bounded wildcard which is currently
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widened to an open wildcard
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#. Any superclass must adhere to the same rules, but can be abstract
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#. Object graph cycles are not supported, so an object cannot refer to itself, directly or indirectly
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Constructor Instantiation
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'''''''''''''''''''''''''
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The primary way Corda's AMQP serialization framework instantiates objects is via a specified constructor. This is
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used to first determine which properties of an object are to be serialised, then, on deserialization, it is used to
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instantiate the object with the serialized values.
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It is recommended that serializable objects in Corda adhere to the following rules, as they allow immutable state
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objects to be deserialised:
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#. A Java Bean getter for each of the properties in the constructor, with a name of the form ``getX``. For example, for a constructor
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parameter ``foo``, there must be a getter called ``getFoo()``. If ``foo`` is a boolean, the getter may
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optionally be called ``isFoo()`` (this is why the class must be compiled with parameter names turned on)
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#. A constructor which takes all of the properties that you wish to record in the serialized form. This is required in
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order for the serialization framework to reconstruct an instance of your class
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#. If more than one constructor is provided, the serialization framework needs to know which one to use. The ``@ConstructorForDeserialization``
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annotation can be used to indicate which one. For a Kotlin class, without the ``@ConstructorForDeserialization`` annotation, the
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*primary constructor* will be selected
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In Kotlin, this maps cleanly to a data class where there getters are synthesized automatically. For example, suppose we
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have the following data class:
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.. container:: codeset
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.. sourcecode:: kotlin
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data class Example (val a: Int, val b: String)
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Properties ``a`` and ``b`` will be included in the serialised form.
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However, properties not mentioned in the constructor will not be serialised. For example, in the following code,
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property ``c`` will not be considered part of the serialised form:
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.. container:: codeset
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.. sourcecode:: kotlin
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data class Example (val a: Int, val b: String) {
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var c: Int = 20
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}
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var e = Example (10, "hello")
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e.c = 100;
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val e2 = e.serialize().deserialize() // e2.c will be 20, not 100!!!
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Setter Instantiation
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''''''''''''''''''''
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As an alternative to constructor-based initialisation, Corda can also determine the important elements of an
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object by inspecting the getter and setter methods present on the class. If a class has **only** a default
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constructor **and** properties then the serializable properties will be determined by the presence of
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both a getter and setter for that property that are both publicly visible (i.e. the class adheres to
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the classic *idiom* of mutable JavaBeans).
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On deserialization, a default instance will first be created, and then the setters will be invoked on that object to
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populate it with the correct values.
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For example:
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.. container:: codeset
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.. sourcecode:: kotlin
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class Example(var a: Int, var b: Int, var c: Int)
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.. sourcecode:: java
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class Example {
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private int a;
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private int b;
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private int c;
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public int getA() { return a; }
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public int getB() { return b; }
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public int getC() { return c; }
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public void setA(int a) { this.a = a; }
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public void setB(int b) { this.b = b; }
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public void setC(int c) { this.c = c; }
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}
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.. warning:: We do not recommend this pattern! Corda tries to use immutable data structures throughout, and if you
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rely heavily on mutable JavaBean style objects then you may sometimes find the API behaves in unintuitive ways.
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Inaccessible Private Properties
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```````````````````````````````
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Whilst the Corda AMQP serialization framework supports private object properties without publicly
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accessible getter methods, this development idiom is strongly discouraged.
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For example.
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.. container:: codeset
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.. sourcecode:: kotlin
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class C(val a: Int, private val b: Int)
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.. sourcecode:: java
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class C {
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public Integer a;
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private Integer b;
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public C(Integer a, Integer b) {
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this.a = a;
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this.b = b;
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}
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}
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When designing Corda states, it should be remembered that they are not, despite appearances, traditional
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OOP style objects. They are signed over, transformed, serialised, and relationally mapped. As such,
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all elements should be publicly accessible by design.
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.. warning:: IDEs will indicate erroneously that properties can be given something other than public visibility. Ignore
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this, as whilst it will work, as discussed above there are many reasons why this isn't a good idea.
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Providing a public getter, as per the following example, is acceptable:
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.. container:: codeset
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.. sourcecode:: kotlin
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class C(val a: Int, b: Int) {
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var b: Int = b
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private set
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}
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.. sourcecode:: java
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class C {
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public Integer a;
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private Integer b;
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C(Integer a, Integer b) {
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this.a = a;
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this.b = b;
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}
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public Integer getB() {
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return b;
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}
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}
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Mismatched Class Properties / Constructor Parameters
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````````````````````````````````````````````````````
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Consider an example where you wish to ensure that a property of class whose type is some form of container is always sorted using some specific criteria yet you wish to maintain the immutability of the class.
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This could be codified as follows:
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.. container:: codeset
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.. sourcecode:: kotlin
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@CordaSerializable
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class ConfirmRequest(statesToConsume: List<StateRef>, val transactionId: SecureHash) {
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companion object {
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private val stateRefComparator = compareBy<StateRef>({ it.txhash }, { it.index })
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}
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private val states = statesToConsume.sortedWith(stateRefComparator)
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}
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The intention in the example is to always ensure that the states are stored in a specific order regardless of the ordering
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of the list used to initialise instances of the class. This is achieved by using the first constructor parameter as the
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basis for a private member. However, because that member is not mentioned in the constructor (whose parameters determine
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what is serializable as discussed above) it would not be serialized. In addition, as there is no provided mechanism to retrieve
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a value for ``statesToConsume`` we would fail to build a serializer for this Class.
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In this case a secondary constructor annotated with ``@ConstructorForDeserialization`` would not be a valid solution as the
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two signatures would be the same. Best practice is thus to provide a getter for the constructor parameter which explicitly
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associates it with the actual member variable.
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.. container:: codeset
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.. sourcecode:: kotlin
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@CordaSerializable
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class ConfirmRequest(statesToConsume: List<StateRef>, val transactionId: SecureHash) {
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companion object {
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private val stateRefComparator = compareBy<StateRef>({ it.txhash }, { it.index })
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}
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private val states = statesToConsume.sortedWith(stateRefComparator)
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//Explicit "getter" for a property identified from the constructor parameters
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fun getStatesToConsume() = states
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}
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Mutable Containers
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``````````````````
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Because Java fundamentally provides no mechanism by which the mutability of a class can be determined this presents a
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problem for the serialization framework. When reconstituting objects with container properties (lists, maps, etc) we
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must chose whether to create mutable or immutable objects. Given the restrictions, we have decided it is better to
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preserve the immutability of immutable objects rather than force mutability on presumed immutable objects.
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.. note:: Whilst we could potentially infer mutability empirically, doing so exhaustively is impossible as it's a design
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decision rather than something intrinsic to the JVM. At present, we defer to simply making things immutable on reconstruction
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with the following workarounds provided for those who use them. In future, this may change, but for now use the following
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examples as a guide.
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For example, consider the following:
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.. sourcecode:: kotlin
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data class C(val l : MutableList<String>)
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val bytes = C(mutableListOf ("a", "b", "c")).serialize()
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val newC = bytes.deserialize()
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newC.l.add("d")
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The call to ``newC.l.add`` will throw an ``UnsupportedOperationException``.
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There are several workarounds that can be used to preserve mutability on reconstituted objects. Firstly, if the class
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isn't a Kotlin data class and thus isn't restricted by having to have a primary constructor.
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.. sourcecode:: kotlin
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class C {
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val l : MutableList<String>
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@Suppress("Unused")
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constructor (l : MutableList<String>) {
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this.l = l.toMutableList()
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}
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}
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val bytes = C(mutableListOf ("a", "b", "c")).serialize()
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val newC = bytes.deserialize()
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// This time this call will succeed
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newC.l.add("d")
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Secondly, if the class is a Kotlin data class, a secondary constructor can be used.
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.. sourcecode:: kotlin
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data class C (val l : MutableList<String>){
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@ConstructorForDeserialization
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@Suppress("Unused")
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constructor (l : Collection<String>) : this (l.toMutableList())
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}
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val bytes = C(mutableListOf ("a", "b", "c")).serialize()
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val newC = bytes.deserialize()
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// This will also work
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newC.l.add("d")
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Thirdly, to preserve immutability of objects (a recommend design principle - Copy on Write semantics) then mutating the
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contents of the class can be done by creating a new copy of the data class with the altered list passed (in this example)
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passed in as the Constructor parameter.
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.. sourcecode:: kotlin
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data class C(val l : List<String>)
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val bytes = C(listOf ("a", "b", "c")).serialize()
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val newC = bytes.deserialize()
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val newC2 = newC.copy (l = (newC.l + "d"))
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.. note:: If mutability isn't an issue at all then in the case of data classes a single constructor can
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be used by making the property var instead of val and in the ``init`` block reassigning the property
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to a mutable instance
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Enums
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`````
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All enums are supported, provided they are annotated with ``@CordaSerializable``. Corda supports interoperability of
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enumerated type versions. This allows such types to be changed over time without breaking backward (or forward)
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compatibility. The rules and mechanisms for doing this are discussed in :doc:`serialization-enum-evolution`.
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Exceptions
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``````````
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The following rules apply to supported ``Throwable`` implementations.
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#. If you wish for your exception to be serializable and transported type safely it should inherit from either
|
|
``CordaException`` or ``CordaRuntimeException``
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|
#. If not, the ``Throwable`` will deserialize to a ``CordaRuntimeException`` with the details of the original
|
|
``Throwable`` contained within it, including the class name of the original ``Throwable``
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|
|
Kotlin Objects
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|
``````````````
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|
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Kotlin's non-anonymous ``object`` s (i.e. constructs like ``object foo : Contract {...}``) are singletons and
|
|
treated differently. They are recorded into the stream with no properties, and deserialize back to the
|
|
singleton instance. Currently, the same is not true of Java singletons, which will deserialize to new instances
|
|
of the class. This is hard to fix because there's no perfectly standard idiom for Java singletons.
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|
|
|
Kotlin's anonymous ``object`` s (i.e. constructs like ``object : Contract {...}``) are not currently supported
|
|
and will not serialize correctly. They need to be re-written as an explicit class declaration.
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|
|
|
Class synthesis
|
|
---------------
|
|
|
|
Corda serialization supports dynamically synthesising classes from the supplied schema when deserializing,
|
|
without the supporting classes being present on the classpath. This can be useful where generic code might expect to
|
|
be able to use reflection over the deserialized data, for scripting languages that run on the JVM, and also for
|
|
ensuring classes not on the classpath can be deserialized without loading potentially malicious code.
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|
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|
If the original class implements some interfaces then the carpenter will make sure that all of the interface methods are
|
|
backed by fields. If that's not the case then an exception will be thrown during deserialization. This check can
|
|
be turned off with ``SerializationContext.withLenientCarpenter``. This can be useful if only the field getters are needed,
|
|
say in an object viewer.
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|
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|
Calculated values
|
|
`````````````````
|
|
|
|
In some cases, for example the `exitKeys` field in ``FungibleState``, a property in an interface may normally be implemented
|
|
as a *calculated* value, with a "getter" method for reading it but neither a corresponding constructor parameter nor a
|
|
"setter" method for writing it. In this case, it will not automatically be included among the properties to be serialized,
|
|
since the receiving class would ordinarily be able to re-calculate it on demand. However, a synthesized class will not
|
|
have the method implementation which knows how to calculate the value, and a cast to the interface will fail because the
|
|
property is not serialized and so the "getter" method present in the interface will not be synthesized.
|
|
|
|
The solution is to annotate the method with the ``SerializableCalculatedProperty`` annotation, which will cause the value
|
|
exposed by the method to be read and transmitted during serialization, but discarded during normal deserialization. The
|
|
synthesized class will then include a backing field together with a "getter" for the serialized calculated value, and will
|
|
remain compatible with the interface.
|
|
|
|
If the annotation is added to the method in the *interface*, then all implementing classes must calculate the value and
|
|
none may have a corresponding backing field; alternatively, it can be added to the overriding method on each implementing
|
|
class where the value is calculated and there is no backing field. If the field is a Kotlin ``val``, then the annotation
|
|
should be targeted at its getter method, e.g. ``@get:SerializableCalculatedProperty``.
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|
|
|
Future enhancements
|
|
```````````````````
|
|
|
|
Possible future enhancements include:
|
|
|
|
#. Java singleton support. We will add support for identifying classes which are singletons and identifying the
|
|
static method responsible for returning the singleton instance
|
|
#. Instance internalizing support. We will add support for identifying classes that should be resolved against an instances map to avoid
|
|
creating many duplicate instances that are equal (similar to ``String.intern()``)
|
|
|
|
.. Type Evolution:
|
|
|
|
Type Evolution
|
|
--------------
|
|
|
|
Type evolution is the mechanism by which classes can be altered over time yet still remain serializable and deserializable across
|
|
all versions of the class. This ensures an object serialized with an older idea of what the class "looked like" can be deserialized
|
|
and a version of the current state of the class instantiated.
|
|
|
|
More detail can be found in :doc:`serialization-default-evolution`.
|
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|