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Key Concepts
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============
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States
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------
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What is a state?
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A State Object represents an agreement between two or more parties, governed by machine-readable Contract Code.
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This code references, and is intended to implement, portions of human-readable Legal Prose.
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A state object is a digital document which records the existence, content and current state of an agreement between
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two or more parties. It is intended to be shared only with those who have a legitimate reason to see it.
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The ledger is defined as a set of immutable state objects.
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An objective of Corda is to ensure that all parties to the agreement remain in consensus as to this state as it evolves.
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The following diagram illustrates a State object:
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.. image:: whitepaper/images/partiesto.png
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What can we represent in a state?
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Contracts
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---------
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What's a contract?
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Corda enforces business logic through smart contract code, which is constructed as a pure function that either accepts
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or rejects a transaction, and which can be composed from simpler, reusable functions. The functions interpret transactions
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as taking states as inputs and producing output states through the application of (smart contract) commands, and accept
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the transaction if the proposed actions are valid.
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What does a contract contain?
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Relationship to states
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Verify()
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A contract is pure function; contracts do not have storage or the ability to interact with anything.
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Given the same transaction, a contract’s “verify” function always yields exactly the same result.
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Clauses
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Contracts sandbox / Deterministic JVM?
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Contracts define part of the business logic of the ledger, and they are mobile: nodes will download and run contracts
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inside a sandbox without any review in some deployments, although we envisage the use of signed code for Corda deployments in the regulated sphere.
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Corda uses an augmented JVM custom sandbox that is radically more restrictive than the ordinary JVM sandbox, and it enforces
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not only security requirements but also deterministic execution.
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<diags>
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Ledger construct model
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----------------------
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The Corda model focused on states of agreements is in contrast to systems where the data over which participants much
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reach consensus is the state of an entire ledger or the state of an entire virtual machine.
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Corda provides three main tools to achieve global distributed consensus:
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• Smart contract logic to ensure state transitions are valid according to the pre-agreed rules.
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• Uniqueness and timestamping services to order transactions temporally and eliminate conflicts.
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• An orchestration framework which simplifies the process of writing com- plex multi-step protocols between multiple different parties.
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Why we chose the UTXO model
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There are two competing computational models used in distributed ledger technology: the virtual computer model (as used
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by Ethereum) and the UTXO model (as popularised by Bitcoin). In this model the database is a set of immutable rows keyed
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by (hash:output index). Transactions define outputs that append new rows and inputs which consume existing rows.
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Corda follows the UTXO (unspent transaction output set) model:
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• Immutable states are consumed and created by transactions
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• Transactions have multiple inputs and outputs
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• A contract is pure function; contracts do not have storage or the ability to interact with anything.
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Given the same transaction, a contract’s “verify” function always yields exactly the same result.
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with additional features:
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• Corda states can include arbitrary typed data.
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• Transactions invoke not only input contracts but also the contracts of the outputs.
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• Corda uses the term “contract” to refer to a bundle of business logic that may handle various different tasks,
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beyond transaction verification.
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• Corda contracts are Turing-complete and can be written in any ordinary programming language that targets the JVM.
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• Corda allows arbitrarily-precise time-bounds to be specified in transactions (which must be attested to by a trusted timestamper)
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• Corda's primary consensus implementations use block-free conflict resolution algorithms.
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• Corda does not order transactions using a block chain and by implication does not use miners or proof-of-work. Instead
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each state points to a notary, which is a service that guarantees it will sign a transaction only if all the input states are un-consumed.
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<diags>
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Transactions
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------------
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What is a transaction in Corda?
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Transactions transition state objects through a lifecycle.
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Transaction are used to update the ledger by consuming existing state objects and producing new state objects.
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A transaction update is accepted according to the following two aspects of consensus:
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1. Transaction validity: parties can reach certainty that a proposed update transaction defining output states is valid
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by checking that the associated contract code runs successfully and has all the required signatures; and that any
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transactions to which this transaction refers are also valid.
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2. Transaction uniqueness: parties can reach certainty that the transaction in question is the unique consumer of all its
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input states. That is: there exists no other transaction, over which we have previously reached consensus (validity and uniqueness), that consumes any of the same states.
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The following diagram illustrates a simple Issuance Transaction:
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.. image:: whitepaper/images/cash.png
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<diags>
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Elements of a transaction
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When is a transaction valid? / invalid?
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Parties can agree on transaction validity by independently running the same contract code and validation logic.
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Consensus over transaction validity is performed only by parties to the transaction in question. Therefore, data is only
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shared with those parties which are required to see it. Other platforms generally reach consensus at the ledger level.
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Thus, any given actor in a Corda system sees only a subset of the overall data managed by the system as a whole.
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Transaction Tear-Off
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Data sharing model
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------------------
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The Shared Ledger Vision is based on a progression from a world where parties to shared facts record and manage their own
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records, with associated discrepancies and duplications (“Bilateral - Reconciliation”) or one where parties delegate control
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and responsibility over critical processing to centralised utilities (“Third Party / Market Infrastructure”), to one where
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they collaborate to maintain a shared record, assured to be consistent between them, consuming the services of existing
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and new service providers and market infrastructure providers on an open and competitive basis.
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This transitional model is illustrated in the following diagram:
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.. image:: whitepaper/images/shared-logic.png
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Consensus / Notaries
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--------------------
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Consensus over transaction validity is performed only by parties to the transaction in question. Therefore, data is only
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shared with those parties which are required to see it. Other platforms generally reach consensus at the ledger level.
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Thus, any given actor in a Corda system sees only a subset of the overall data managed by the system as a whole.
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We say a piece of data is “on- ledger” if at least two actors on the system are in consensus as to its existence and
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details and we allow arbitrary combinations of actors to participate in the consensus process for any given piece of data.
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Data held by only one actor is “off-ledger”.
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Corda has “pluggable” uniqueness services. This is to improve privacy, scalability, legal-system compatibility and
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algorithmic agility. A single service may be composed of many mutually untrusting nodes coordinating via a byzantine
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fault tolerant algorithm, or could be very simple, like a single machine. In some cases, like when evolving a state
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requires the signatures of all relevant parties, there may be no need for a uniqueness service at all.
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It is important to note that these uniqueness services are required only to attest as to whether the states consumed by
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a given transaction have previously been consumed; they are not required to attest as to the validity of the transaction
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itself, which is a matter for the parties to the transaction. This means that the uniqueness services are not required to
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(and, in the general case, will not) see the full contents of any transactions, significantly improving privacy and scalability
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of the system compared with alternative distributed ledger and blockchain designs.
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Flows
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-----
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Flows enable complex multi-party business interactions without a central controller.
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in Corda all communication takes the form of small multi-party sub-protocols called flows.
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The flow framework presents a programming model that looks to the developer as if they have the ability to run millions
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of long lived threads which can survive node restarts, and even node upgrades. APIs are provided to send and receive
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object graphs to and from other identities on the network, embed sub-flows, and report progress to observers.
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The flow framework provide the following:
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* **Just-in-time** state machine compiler. Code that is written in a blocking manner typically cannot be stopped and transparently
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restarted later. The first time a flow’s call method is invoked a bytecode-to-bytecode transformation occurs that
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rewrites the classes into a form that implements a resumable state machine. These state machines are sometimes called fibers
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or coroutines, and the transformation engine Corda uses (Quasar) is capable of rewriting code arbitrarily deep in the stack on the fly.
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* Transparent checkpointing.
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* Identity to IP address mapping.
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* A library of subflows
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* Progress reporting
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* Flow hospital
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Section 4 of the Corda Technical WhitePaper provides a comprehensive description of the above features.
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The following diagram illustrates a sample Multi-party Business Flow:
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.. image:: resources/flow-diagram.png
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Oracles
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-------
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Oracles represent gateways to proprietary (or other) business logic executors (e.g., Central Counterparties or valuation agents)
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that can be verified on-ledger by participants.
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Attachments
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-----------
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Vault
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-----
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CorDapp
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-------
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Corda is a platform for the writing of “CorDapps”: applications that extend the global database with new capabilities.
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Such apps define new data types, new inter-node protocol flows and the “smart contracts” that determine allowed changes.
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The combination of state objects (data), Contract Code (allowable opera- tions), Transaction Protocols (business logic
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choreography), any necessary APIs, Vault plugins, and UI components can be thought of a Shared Ledger application,
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or Corda Distributed Application (“CorDapp”). This is the core set of components a contract developer on the platform
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should expect to build.
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Please see our published White Papers for in depth explanations of these concepts:
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":doc:`https://docs.corda.net/_static/corda-introductory-whitepaper.pdf`
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":doc:`https://docs.corda.net/_static/corda-technical-whitepaper.pdf`
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