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* Retired the rst doc source structure under /docs and updated the /docs/README.md *Rollback of /example-code and /whitepaper dirs back under /docs dir until new code example process is in place
2491 lines
189 KiB
TeX
2491 lines
189 KiB
TeX
\documentclass{article}
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\author{Mike Hearn, Richard Gendal Brown}
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\date{\today}
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\title{Corda: A distributed ledger}
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\begin{document}
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\maketitle
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\begin{center}
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Version 1.0
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\end{center}
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\vspace{10mm}
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\begin{abstract}
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A decentralised database with minimal trust between nodes would allow for the creation of a global ledger. Such a ledger
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would have many useful applications in finance, trade, healthcare and more. We present Corda, a decentralised
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global database, and describe in detail how it achieves the goal of providing a platform for decentralised app
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development. We elaborate on the high level description provided in the paper \emph{Corda: An
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introduction}\cite{CordaIntro} and provide a detailed technical discussion.
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\end{abstract}
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\vfill
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\newpage
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\tableofcontents
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\newpage
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\section{Introduction}
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In many industries significant effort is needed to keep organisation specific databases in sync with each other.
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The effort of keeping different databases synchronised, reconciling them to ensure they actually are synchronised,
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managing inter-firm workflows to change those databases and resolving the `breaks' that occur when they get out
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of sync represents a significant fraction of the total work some organisations actually do.
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Why not just use a shared relational database? This would certainly solve a lot of problems using only existing
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technology, but it would also raise more questions than answers:
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\begin{itemize}
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\item Who would run this database? Where would we find a sufficient supply of incorruptible angels to own it?
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\item In which countries would it be hosted? What would stop that country abusing the mountain of sensitive information it would have?
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\item What if it were hacked?
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\item Can you actually scale a relational database to fit the entire financial system?
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\item What happens if the database needs to go down for maintenance? Does the economy stop?
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\item What kind of nightmarish IT bureaucracy would guard schema changes?
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\item How would you manage access control?
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\end{itemize}
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We can imagine many other questions. A decentralised database attempts to answer them.
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In this paper we differentiate between a \emph{decentralised} database and a \emph{distributed} database. A
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distributed database like BigTable\cite{BigTable} scales to large datasets and transaction volumes by spreading the
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data over many computers. However it is assumed that the computers in question are all run by a single homogeneous
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organisation and that the nodes comprising the database all trust each other not to misbehave or leak data. In a
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decentralised database, such as the one underpinning Bitcoin\cite{Bitcoin}, the nodes make much weaker trust
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assumptions and actively cross-check each other's work. Such databases trade performance and usability for security
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and global acceptance.
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\emph{Corda} is a decentralised database platform with the following novel features:
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\begin{itemize}
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\item Nodes are arranged in an authenticated peer to peer network. All communication is direct. A gossip protocol is not used.
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\item New transaction types can be defined using JVM\cite{JVM} bytecode. The bytecode is statically analyzed and rewritten
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on the fly to be fully deterministic, and to implement deterministic execution time quotas. This bytecode is mutually
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verified by all counterparties relevant to the transaction, ensuring the validity of ledger updates contained therein.
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\item Transactions may execute in parallel, on different nodes, without either node being aware of the other's transactions.
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\item There is no block chain\cite{Bitcoin}. Transaction races are deconflicted using pluggable \emph{notaries}. A single
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Corda network may contain multiple notaries that provide their guarantees using a variety of different algorithms. Thus
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Corda is not tied to any particular consensus algorithm. (\cref{sec:notaries})
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\item Data is shared on a need-to-know basis. Nodes provide the dependency graph of a transaction they are sending to
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another node on demand, but there is no global broadcast of \emph{all} transactions.
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\item Bytecode-to-bytecode transformation is used to allow complex, multi-step transaction building protocols called
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\emph{flows} to be modelled as blocking code. The code is transformed into an asynchronous state machine, with
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checkpoints written to the node's backing database when messages are sent and received. A node may potentially have
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millions of flows active at once and they may last days, across node restarts and even certain kinds of upgrade. Flows expose progress
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information to node administrators and users and may interact with people as well as other nodes. A library of flows is provided
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to enable developers to re-use common protocols such as notarisation, membership broadcast and so on.
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\item The data model allows for arbitrary object graphs to be stored in the ledger. These graphs are called \emph{states} and are the atomic unit of data.
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\item Nodes are backed by a relational database and data placed in the ledger can be queried using SQL as well as joined
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with private tables. States can declare a relational mapping using the Java Persistence Architecture standard (JPA)~\cite{JPA}.
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\item The platform provides a rich type system for the representation of things like dates, currencies, legal entities and
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financial entities such as cash, issuance, deals and so on.
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\item The network can support rapid bulk data imports from other database systems without placing load on the network.
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Events on the ledger are exposed via an embedded JMS compatible message broker.
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\item States can declare scheduled events. For example a bond state may declare an automatic transition to an
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``in default'' state if it is not repaid in time.
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\item Advanced privacy controls allow users to anonymize identities, and initial support is provided for running
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smart contracts inside memory spaces encrypted and protected by Intel SGX.
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\end{itemize}
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Corda follows a general philosophy of reusing existing proven software systems and infrastructure where possible.
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Comparisons with Bitcoin and Ethereum will be provided throughout.
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\newpage
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\section{Overview}
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Corda is a platform for the writing and execution of ``CorDapps'': applications that extend the global database
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with new capabilities. Such apps define new data types, new inter-node protocol flows and the so-called ``smart
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contracts'' that determine allowed changes.
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What is a smart contract? That depends on the model of computation we are talking about. There are two competing
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computational models used in decentralised databases: the virtual computer model and the UTXO model. The virtual
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computer model is used by Ethereum\cite{Ethereum} and Hyperledger Fabric. It models the database as the in-memory
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state of a global computer with a single thread of execution determined by the block chain. In the UTXO model, as
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used in Bitcoin, the database is a set of immutable rows keyed by \texttt{(hash:output index)}. Transactions define
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outputs that append new rows and inputs which consume existing rows. The term ``smart contract'' has a different
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meaning in each model. A deeper discussion of the tradeoffs and terminology in the different approaches can be
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found in the Corda introductory paper\cite{CordaIntro}.
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We use the UTXO model and as a result our transactions are structurally similar to Bitcoin transactions: they have
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inputs, outputs and signatures. Unlike Bitcoin, Corda database rows can contain arbitrary data, not just a value
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field. Because the data consumed and added by transactions is not necessarily a set of key/value pairs, we don't
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talk about rows but rather \emph{states}. Like Bitcoin, Corda states are associated with bytecode programs that
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must accept a transaction for it to be valid, but unlike Bitcoin, a transaction must satisfy the programs for both
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the input and output states at once. Issuance transactions may append new states to the database without consuming
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any existing states but unlike in Bitcoin these transactions are not special. In Bitcoin, issuance transactions
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represent value creation and provide a crypto-economic incentive. This, in turn, motivates validators or miners.
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In Corda, there is no need for a crypto-economic incentive and so issuance transactions may be created at any
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time, by anyone to issue arbitrary data onto the ledger.
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In contrast to both Bitcoin and Ethereum, Corda does not order transactions using a block chain and by implication
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does not use miners or proof-of-work. Instead each state points to a \emph{notary}, which is a service that
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guarantees it will sign a transaction only if all the input states are un-consumed. A transaction is not allowed to
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consume states controlled by multiple notaries and thus there is never any need for two-phase commit between
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notaries. If a combination of states would cross notaries then a special transaction type is used to move them onto
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a single notary first. See~\cref{sec:notaries} for more information.
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The Corda transaction format has various other features which are described in later sections.
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\section{The peer to peer network}
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\subsection{Overview}
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A Corda network consists of the following components:
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\begin{itemize}
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\item Nodes, operated by \emph{parties}, communicating using AMQP/1.0 over TLS.
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\item An \emph{identity} service which runs an X.509 certificate authority.
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\item A network map service that publishes information about how to connect to nodes on the network.
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\item One or more notary services. A notary may be decentralised over a coalition of different parties.
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\item Zero or more oracle services. An oracle is a well known service that signs transactions if they state a fact
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and that fact is considered to be true. They may also optionally also provide the facts. This is how the ledger can be
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connected to the real world, despite being fully deterministic.
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\end{itemize}
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% TODO: Add section on zones and network parameters
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Oracles and notaries are covered in later sections.
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\subsection{The identity root}\label{subsec:the-identity-root}
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Taking part in a Corda network as a node requires an identity certificate. These certificates bind a human readable
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name to a public key and are signed by the network operator. Having a signed identity grants the ability to take
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part in the top layer of the network, but it's important to understand that users and programs can participate in the ledger
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\emph{without} having an issued identity. Only a raw key pair is necessary if a node that \emph{does} have an
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identity is willing to route traffic on your behalf. This structure is similar to the email network, in which users
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without servers can take part by convincing a server operator to grant them an account. How network identities and
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accounts relate to each other is discussed in a later section (section~\cref{sec:identity}).
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This `identity' does not have to be a legal or true name. In the same way that an email address is a globally
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unique pseudonym that is ultimately rooted by the top of the DNS hierarchy, so too can a Corda network use
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arbitrary self-selected usernames. The permissioning service can implement any policy it likes as long as the
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identities it signs are globally unique. Thus it's possible to build an entirely pseudonymous Corda network.
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However, when a network has a way to map identities to some sort of real world thing that's difficult to bulk create,
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many efficient and useful algorithms become available. Most importantly, all efficient byzantine fault tolerant
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consensus algorithms require nodes to be usefully distinct such that users can reason about the likelihood of cluster
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members going bad simultaneously. In the worst case where a BFT cluster consists of a single player pretending to be
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several, the security of the system is completely voided in an undetectable manner. Useful privacy techniques like
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mix networks (see~\cref{subsec:privacy-upgrades}) and Tor\cite{Dingledine:2004:TSO:1251375.1251396} also make the assumption of unique, sybil-free
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identities. For these reasons and more the mainline Corda network performs identity verification to require that
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top-level members be companies, and it's recommended that all networks do so.
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Identity is covered further in section~\cref{sec:identity}.
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\subsection{The network map}
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Every network requires a network map. This is similar to Tor's concept of \emph{directory authorities}. The network
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map service publishes information about each node such as the set of IP addresses it listens on (multiple IP
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addresses are supported for failover and load balancing purposes), the version of the protocol it speaks, and which
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identity certificates it hosts. Each data structure describing a node is signed by the identity keys it claims to
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host. The network map service is therefore not trusted to specify node data correctly, only to distribute it.
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The network map abstracts the underlying network locations of the nodes to more useful business concepts like
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identities and services. Domain names for the underlying IP addresses may be helpful for debugging but are not
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required. User interfaces and APIs always work in terms of identities -- there is thus no equivalent to Bitcoin's
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notion of an address (hashed public key), and user-facing applications rely on auto-completion and search to
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specify human-readable legal identities rather than specific public keys -- which in the bitcoin ecosystem are
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often distributed as QR codes.
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It is possible to subscribe to network map changes and registering with the map is the first thing a node does at
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startup.
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The map is a set of files that may be cached and distributed via HTTP based content delivery networks. The
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underlying map infrastructure is therefore not required to be highly available: if the map service becomes
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unreachable nodes may not join the network or change IP addresses, but otherwise things continue as normal.
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\subsection{Message delivery}
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The network is structurally similar to the email network. Nodes are expected to be long lived but may depart
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temporarily due to crashes, connectivity interruptions or maintenance. Messages are written to disk and delivery is
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retried until the remote node has acknowledged a message, at which point it is expected to have either reliably
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stored the message or processed it completely. Connections between nodes are built and torn down as needed: there
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is no assumption of constant connectivity. An ideal network would be entirely flat with high quality connectivity
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between all nodes, but Corda recognises that this is not always compatible with common network setups and thus the
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message routing component of a node can be separated from the rest and run outside the firewall. Being outside the
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firewall or in the firewall's `de-militarised zone' (DMZ) is required to ensure that nodes can connect to anyone on
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the network, and be connected to in turn. In this way a node can be split into multiple sub-services that do not
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have duplex connectivity yet can still take part in the network as first class citizens.
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The reference implementation provides this functionality using the Apache Artemis message broker, through which it
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obtains journalling, load balancing, flow control, high availability clustering, streaming of messages too large to
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fit in RAM and many other useful features. The network uses the \emph{AMQP/1.0}\cite{AMQP} protocol which is a
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widely implemented binary messaging standard, combined with TLS to secure messages in transit and authenticate the
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endpoints.
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\subsection{Serialization}\label{subsec:serialization}
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All messages are encoded using an extended form of the AMQP/1.0 binary format (\emph{Advanced Message Queue
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Protocol}\cite{AMQP}). Each message has a UUID set in an AMQP header which is used as a deduplication key, thus
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accidentally redelivered messages will be ignored.
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Messages may also have an associated organising 64-bit \emph{session ID}. Note that this is distinct from the AMQP
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notion of a session. Sessions can be long lived and persist across node restarts and network outages. They exist in
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order to group messages that are part of a \emph{flow}, described in more detail below.
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Corda uses AMQP and extends it with more advanced types and embedded binary schemas, such that all messages are
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self describing. Because ledger data typically represents business agreements and data, it may persist for years
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and survive many upgrades and infrastructure changes. We require that data is always interpretable in strongly
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typed form, even if that data has been stored to a context-free location like a file, or the clipboard.
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Although based on AMQP, Corda's type system is fundamentally the Java type system. Java types are mapped to
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AMQP/1.0 types whenever practical, but ledger data will frequently contain business types that the AMQP type system
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does not define. Fortunately, AMQP is extensible and supports standard concepts like polymorphism and interfaces,
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so it is straightforward to define a natural Java mapping. Type schemas are hashed to form a compact `fingerprint'
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that identifies the type, which allows types to be connected to the embedded binary schemas that describe them and
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which are useful for caching. The AMQP type system and schema language supports a form of annotations that we map
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to Java annotations.
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Object serialization frameworks must always consider security. Corda requires all types that may appear in
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serialized streams to mark themselves as safe for deserialization, and objects are only created via their
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constructors. Thus any data invariants that are enforced by constructors or setter methods are also enforced for
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deserialized data. Additionally, requests to deserialize an object specify the expected types. These two mechanisms
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block gadget-based attacks\cite{DeserialisingPickles}. Such attacks frequently affect any form of data
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deserialization regardless of format, for example, they have been found not only in Java object serialization
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frameworks but also JSON and XML parsers. They occur when a deserialization framework may instantiate too large a
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space of types which were not written with malicious input in mind.
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The serialization framework supports advanced forms of data evolution. When a stream is deserialized Corda attempts
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to map it to the named Java classes. If those classes don't exactly match, a process called `evolution' is
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triggered, which automatically maps the data as smoothly as possible. For example, deserializing an old object will
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attempt to use a constructor that matches the serialized schema, allowing default values in new code to fill in the
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gaps. When old code reads data from the future, new fields will be discarded if safe to do so. Various forms of
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type adaptation are supported, and type-safe enums can have unknown values mapped to a default enum value as well.
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If no suitable class is found at all, the framework performs \emph{class synthesis}. The embedded schema data will
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be used to generate the bytecode for a suitable holder type and load it into the JVM on the fly. These new classes
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will then be instantiated to hold the deserialized data. The new classes will implement any interfaces the schema
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is specified as supporting if those interfaces are found on the Java classpath. In this way the framework supports
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a form of generic programming. Tools can work with serialized data without having a copy of the app that generated
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it. The returned objects can be accessed either using reflection, or a simple interface that automates accessing
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properties by name and is just a friendlier way to access fields reflectively. Creating genuine object graphs like
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this is superior to the typical approach of defining a format specific generic data holder type (XML's DOM
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\texttt{Element}, \texttt{JSONObject} etc) because there is already a large ecosystem of tools and technologies
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that know how to work with objects via reflection. Synthesised object graphs can be fed straight into JSON or YaML
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serializers to get back text, inserted into a scripting engine for usage with dynamic languages like JavaScript or
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Python, fed to JPA for database persistence and query or a Bean Validation engine for integrity checking, or even
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used to automatically generate GUIs using a toolkit like MetaWidget\cite{MetaWidget} or
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ReflectionUI\cite{ReflectionUI}.
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\subsection{Network parameters}\label{subsec:network-parameters}
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In any DLT system there are various tunable parameters whose correct values may not be known ahead of time, may
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change, or may be things upon which reasonable people will always disagree. Corda extracts these into a notion of
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\emph{network parameters}. Network parameters are encoded in a data structure, signed by the network operator and
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distributed via the same infrastructure as the network map. All nodes in a network must follow the configuration
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provided, otherwise consensus may not be achieved.
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Some examples of network parameters are:
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\begin{itemize}
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\item The list of notaries acceptable for use within the network.
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\item The largest acceptable peer to peer message in bytes.
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\item The largest acceptable transaction size in bytes.
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\item The event horizon (see below).
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\item The minimum platform version required to take part in the network.
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\end{itemize}
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This list is not exhaustive and new parameters are added from time to time.
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The \emph{event horizon} is the span of time that is allowed to elapse before an offline node is considered to be
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permanently gone. Once a peer has been offline for longer than the event horizon, any nodes that have been
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communicating with it may kill any outstanding flows and erase knowledge of it from their databases. Typical values
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for the event horizon are long, for example, 30 days. This gives nodes that are only intermittently connected
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plenty of time to come online and resynchronise. Shorter values may lead to business processes being interrupted
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due to transient infrastructure outages for which repairs are already in progress.
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\paragraph{Flag days vs hard forks.}There must be a mechanism for the parameters to be updated. Each signed
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parameter structure contains an incrementing integer epoch. When a new set of parameters is being introduced, it
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starts to be referenced by hash from the current network map and an activation date is supplied. Nodes download the
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new parameters, validate them and then alert the administrator that the network is changing. For some parameters
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the administrator is expected to manually review the change and accept it. Failure to do so before the activation
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date (the ``flag day'') results in the node shutting down, as it would no longer be able to fulfil its purpose.
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Network operators are expected to communicate and coordinate this process out of band; the protocol allows nodes to
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publish what parameters they have accepted so acceptance can be monitored and the flag day can be changed if
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so desired. In proof-of-work based block chain systems a hard fork creates two split views of the ledger that
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then proceed to evolve independently, with each side remaining in some strictly technical sense `usable' by parties
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on each side of the fork. Consensus will only be lost over transactions where both sides do really disagree and for
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any transaction that traces its origin back to a post-fork coinbase transaction. But in Corda, there is no way
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to continue past an unacceptable change in the network parameters and remain on the `losing side'.
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Thus the notion of flag days is subtly different to the notion of a hard fork.
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\subsection{Protocol versioning}\label{subsec:protocol-versioning}
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The network protocol is versioned using a simple incrementing integer version number. There are no minor or patch
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versions in the protocol definition itself: the versioning scheme is based on a commitment for the protocol
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to always be backwards compatible. All nodes publish their current highest supported version in their signed
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\texttt{NodeInfo} structure, so peers can always known ahead of time which protocol features are available to them
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before creating or receiving connections.
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The protocol data structures are reflected in the platform API, which is therefore versioned in an identical
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manner. Apps may specify the minimum platform version they require, such that nodes will refuse to load apps that
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would need newer features than are supported. The decision to unify the protocol and API versions implies that some
|
|
protocol versions may be effectively identical despite having different version numbers: this was deemed preferable
|
|
to requiring developers to understand and keep track of two similar-but-different versioning streams.
|
|
|
|
\paragraph{Mandatory upgrades.}The network operator may choose to require that nodes meet a minimum version number
|
|
via setting a network parameter.
|
|
|
|
This is useful because in DLT systems some types of new feature require everyone in a network to upgrade before
|
|
anyone can use it. This is usually because the feature affects how transactions should be validated, and thus any
|
|
node may encounter the new data during transaction verification even if no installed app uses it itself. In this
|
|
case the API will throw an exception if an attempt is made to use a new feature on a network where the minimum
|
|
version number is lower than the version in which the new feature was introduced. The network can then use a flag
|
|
day to increase the minimum platform version and thus activate the new features. Nodes that aren't new
|
|
enough to handle the network's minimum version shut down automatically unless overridden. Because mandatory
|
|
upgrades may be difficult to coordinate and enforce, future versions of the platform may support outsourcing of
|
|
transaction verification to third party nodes or remote SGX enclaves.
|
|
|
|
Flag days mark the end of a process: it is the point by which the overwhelming majority of network participants are
|
|
expected to have upgraded to some minimum version, and whose date is expected to be set by the network operator to
|
|
achieve the right balance for their network between meeting the needs of those who wish to use features that
|
|
require that version, and those for whom upgrading is difficult. It should be noted that flag days are expected to
|
|
be relatively rare once Corda matures. In any case the majority of new features do not change the data model and so
|
|
don't require everybody on the network to upgrade before they can be used.
|
|
|
|
\paragraph{Target versioning.}The node supports `target versioning', in which the latest version the app was
|
|
tested against is advertised in its metadata. The node can use this to activate or deactivate workarounds for buggy
|
|
apps that may have accidentally baked in dependencies on undefined platform behaviours, or to enable the semantics
|
|
of an API to evolve without breaking backwards compatibility. For example, if an API returns a list of elements
|
|
that happened to be sorted in previous versions, but then ceases to be sorted due to performance optimisations,
|
|
this could potentially break apps that assumed a certain value would always be found at a certain index. Target
|
|
versioning can be used to keep apps working even as the platform underneath it evolves.
|
|
|
|
\subsection{Business networks}
|
|
|
|
The infrastructure described so far is sufficient to establish a Corda network of nodes which can interoperate
|
|
with each other from a purely technical perspective. But application authors frequently require that users
|
|
of their software form a different kind of network layered on top; we call this a \emph{business network}.
|
|
Business networks define their own subgroup of nodes, membership of which is required to interact with the
|
|
others. The platform provides a notion of membership management via the `business network management service'
|
|
but otherwise defines nothing relevant to this concept: it is up to app developers to decide on the rules for
|
|
joining a business network and how it will be governed (if at all).
|
|
|
|
Business networks are discussed further in section 5.1 of the introductory white paper.
|
|
|
|
\section{Flow framework}\label{sec:flows}
|
|
|
|
\subsection{Overview}
|
|
|
|
It is common in decentralised ledger systems for complex multi-party protocols to be needed. The Bitcoin payment
|
|
channel protocol\cite{PaymentChannels} involves two parties putting money into a multi-signature pot, then
|
|
iterating with your counterparty a shared transaction that spends that pot, with extra transactions used for the
|
|
case where one party or the other fails to terminate properly. Such protocols typically involve reliable private
|
|
message passing, checkpointing to disk, signing of transactions, interaction with the p2p network, reporting
|
|
progress to the user, maintaining a complex state machine with timeouts and error cases, and possibly interacting
|
|
with internal systems on either side. All this can become quite involved. The implementation of payment channels in
|
|
the \texttt{bitcoinj} library is approximately 9000 lines of Java, very little of which involves cryptography.
|
|
|
|
As another example, the core Bitcoin protocol only allows you to append transactions to the ledger. Transmitting
|
|
other information that might be useful such as a text message, refund address, identity information and so on is
|
|
not supported and must be handled in some other way -- typically by wrapping the raw ledger transaction bytes in a
|
|
larger message that adds the desired metadata and giving responsibility for broadcasting the embedded transaction
|
|
to the recipient, as in Bitcoin's BIP 70\cite{BIP70}.
|
|
|
|
In Corda transaction data is not globally broadcast. Instead it is transmitted to the relevant parties only when
|
|
they need to see it. Moreover even quite simple use cases -- like sending cash -- may involve a multi-step
|
|
negotiation between counterparties and the involvement of a third party such as a notary. Additional information
|
|
that isn't put into the ledger is considered essential, as opposed to nice-to-have. Thus unlike traditional block
|
|
chain systems in which the primary form of communication is global broadcast, in Corda \emph{all} communication
|
|
takes the form of small multi-party sub-protocols called flows.
|
|
|
|
The flow framework presents a programming model that looks to the developer as if they have the ability to run
|
|
millions of long lived threads which can survive node restarts. APIs are provided to send and receive serialized
|
|
object graphs to and from other identities on the network, embed sub-flows, handle version evolution and report
|
|
progress to observers. In this way business logic can be expressed at a very high level, with the details of making
|
|
it reliable and efficient abstracted away. This is achieved with the following components.
|
|
|
|
\paragraph{Just-in-time state machine compiler.}Code that is written in a blocking manner typically cannot be
|
|
stopped and transparently restarted later. The first time a flow's \texttt{call} method is invoked a
|
|
bytecode-to-bytecode transformation occurs that rewrites the classes into a form that implements a resumable state
|
|
machine. These state machines are sometimes called coroutines, and the transformation engine Corda uses (Quasar) is
|
|
capable of rewriting code arbitrarily deep in the stack on the fly. The developer may thus break his or her logic
|
|
into multiple methods and classes, use loops, and generally structure their program as if it were executing in a
|
|
single blocking thread. There's only a small list of things they should not do: sleeping, accessing the
|
|
network outside of the framework, and blocking for long periods of time (upgrades require in-flight flows to finish).
|
|
|
|
\paragraph{Transparent checkpointing.}When a flow wishes to wait for a message from another party (or input from a
|
|
human being) the underlying stack frames are suspended onto the heap, then crawled and serialized into the node's
|
|
underlying relational database (however, the AMQP framework isn't used in this case). The written objects are
|
|
prefixed with small schema definitions that allow some measure of portability across changes to the layout of
|
|
objects, although portability across changes to the stack layout is left for future work. Flows are resumed and
|
|
suspended on demand, meaning it is feasible to have far more flows active at once than would fit in memory. The
|
|
checkpointing process is atomic with respect to changes to the database and acknowledgement of network messages.
|
|
|
|
\paragraph{Identity to IP address mapping.}Flows are written in terms of identities. The framework takes care of
|
|
routing messages to the right IP address for a given identity, following movements that may take place whilst the
|
|
flow is active and handling load balancing for multi-homed parties as appropriate.
|
|
|
|
\paragraph{A library of subflows.}Flows can invoke sub-flows, and a library of flows is provided to automate common
|
|
tasks like notarising a transaction or atomically swapping ownership of two assets.
|
|
|
|
\paragraph{Progress reporting.}Flows can provide a progress tracker that indicates which step they are up to. Steps
|
|
can have human-meaningful labels, along with other tagged data like a progress bar. Progress trackers are
|
|
hierarchical and steps can have sub-trackers for invoked sub-flows.
|
|
|
|
\paragraph{Flow hospital.}Flows can pause if they throw exceptions or explicitly request human assistance. A flow
|
|
that has stopped appears in the \emph{flow hospital} where the node's administrator may decide to kill the flow or
|
|
provide it with a solution. Some flows that end up in the hospital will be retried automatically by the node
|
|
itself, for example in case of database deadlocks that require a retry. Future versions of the framework may add
|
|
the ability to request manual solutions, which would be useful for cases where the other side isn't sure why
|
|
you are contacting them. For example, if the specified reason for sending a payment is not recognised, or
|
|
when the asset used for a payment is not considered acceptable.
|
|
|
|
For performance reasons messages sent over flows are protected only with TLS. This means messages sent via flows
|
|
are deniable unless explicitly signed by the application. Automatic signing and recording of flow contents may be
|
|
added in future.
|
|
|
|
Flows are identified using Java class names i.e. reverse DNS notation, and several are defined by the base
|
|
protocol. Note that the framework is not required to implement the wire protocols, it is just a development aid.
|
|
|
|
% TODO: Revisit this diagram once it matches the text more closely.
|
|
%\begin{figure}[H]
|
|
%\includegraphics[scale=0.16, center]{trading-flow}
|
|
%\caption{A diagram showing the two party trading flow with notarisation}
|
|
%\end{figure}
|
|
|
|
\subsection{Data visibility and dependency resolution}\label{subsec:data-visibility-and-dependency-resolution}
|
|
|
|
When a transaction is presented to a node as part of a flow it may need to be checked. Simply sending you a message
|
|
saying that I am paying you \pounds1000 is only useful if you are sure I own the money I'm using to pay you.
|
|
Checking transaction validity is the responsibility of the \texttt{ResolveTransactions} flow. This flow performs a
|
|
breadth-first search over the transaction graph, downloading any missing transactions into local storage from the
|
|
counterparty, and validating them. The search bottoms out at the issuance transactions. A transaction is not
|
|
considered valid if any of its transitive dependencies are invalid.
|
|
|
|
It is required that a node be able to present the entire dependency graph for a transaction it is asking another
|
|
node to accept. Thus there is never any confusion about where to find transaction data and there is never any need
|
|
to reach out to dozens of nodes which may or may not be currently available. Because transactions are always
|
|
communicated inside a flow, and flows embed the resolution flow, the necessary dependencies are fetched and checked
|
|
automatically from the correct peer. Transactions propagate around the network lazily and there is no need for
|
|
distributed hash tables.
|
|
|
|
This approach has several consequences. One is that transactions that move highly liquid assets like cash may end
|
|
up becoming a part of a very long chain of transactions. The act of resolving the tip of such a graph can involve
|
|
many round-trips and thus take some time to fully complete. How quickly a Corda network can send payments is thus
|
|
difficult to characterise: it depends heavily on usage and distance between nodes. Whilst nodes could pre-push
|
|
transactions in anticipation of them being fetched anyway, such optimisations are left for future work.
|
|
|
|
Whilst this system is simpler than creating rigid data partitions and clearly provides better privacy than global
|
|
broadcast, in the absence of additional privacy measures it is nonetheless still difficult to reason about who may
|
|
get to see transaction data. This uncertainty is mitigated by several factors.
|
|
|
|
\paragraph{Small-subgraph transactions.}Some uses of the ledger do not involve widely circulated asset states. For
|
|
example, two institutions that wish to keep their view of a particular deal synchronised but who are making related
|
|
payments off-ledger may use transactions that never go outside the involved parties. A discussion of on-ledger vs
|
|
off-ledger cash can be found in a later section.
|
|
|
|
\paragraph{Transaction privacy techniques.}Corda supports a variety of transaction data hiding techniques. For
|
|
example, public keys can be randomised to make it difficult to link transactions to an identity. ``Tear-offs''
|
|
(\cref{sec:tear-offs}) allow some parts of a transaction to be presented without the others. In future versions of
|
|
the system secure hardware and/or zero knowledge proofs could be used to convince a party of the validity of a
|
|
transaction without revealing the underlying data.
|
|
|
|
\paragraph{State re-issuance.}In cases where a state represents an asset that is backed by a particular issuer, and
|
|
the issuer is trusted to behave atomically even when the ledger isn't forcing atomicity, the state can simply be
|
|
`exited' from the ledger and then re-issued. Because there are no links between the exit and reissue transactions
|
|
this shortens the chain. In practice most issuers of highly liquid assets are already trusted with far more
|
|
sensitive tasks than reliably issuing pairs of signed data structures, so this approach is unlikely to be an issue.
|
|
|
|
\section{Identity}\label{sec:identity}
|
|
|
|
In all decentralised ledger systems data access is controlled using asymmetric key pairs. Because public keys are
|
|
difficult for humans to reliably remember or write down, a naming layer is added on top based on X.509 certificate
|
|
hierarchies rooted at a single certificate authority for each network (see~\cref{subsec:the-identity-root}). This
|
|
is beneficial for security. Many large attacks on cryptocurrencies have exploited the fact that destination
|
|
addresses are raw (hashes of) public keys, thus all look the same and it's up to users or app developers to map
|
|
these to more natural forms. Phishing attacks, viruses that detect addresses being copied to the clipboard and
|
|
substitute them, hacks on web forums to replace addresses and more have all been reported. By allowing both
|
|
apps and users to work in terms of natural language identities, multiple avenues for attack are closed.
|
|
|
|
More complex notions of identity that may attest to many time-varying attributes are not handled at this layer of
|
|
the system: the base identity is always just an X.500 name. Note that even though messaging is always identified,
|
|
ledger data itself may contain anonymous public keys that aren't linked to any part of the network's PKI.
|
|
|
|
In most implementations, the network map will only agree to list nodes that have a valid identity certificate.
|
|
Because nodes will only accept connections from other nodes in the network map by default, this provides a form of
|
|
abuse control in which abusive parties can be evicted from the network. `Abuse' in this context has a technical
|
|
connotation, for example, mounting application level denial of service attacks, being discovered using a
|
|
fraudulently obtained identity or failing to meet network policy, for example by falling too far behind the
|
|
minimum required platform version.
|
|
|
|
The design attempts to constrain what malicious or compromised network operators can do. A compromised network
|
|
operator may decide to delist a node for reasons that were not previously agreed to. Such an operator can be
|
|
overridden locally by providing signed \texttt{NodeInfo} files to a node, which would allow flows and transactions
|
|
to continue. It's possible that in future a way to override the identity root may also be provided.
|
|
|
|
An important point is that naming is only used for \emph{resolution} to public keys or IP addresses, however, names
|
|
are not \emph{required} for this resolution. They're just a convenience. The ledger is intended to contain resolved
|
|
public keys for access control purposes: this design creates an important limitation on the power of the naming
|
|
authority. Maliciously issuing a certificate binding a pre-existing name to a new key owned by the attacker doesn't
|
|
allow them to edit any of the existing data on the ledger, nor steal assets, as the states contain only keys which
|
|
cannot be changed after a state is created. This in turn implies that, like with all block chain systems, there's
|
|
no way to recover from losing your keys. A future version of the platform may add limited support for key rotation
|
|
by having both key owner and identity root sign a key change message, but the design does not anticipate ever
|
|
allowing the identity root to unilaterally re-assign identities to someone else.
|
|
|
|
An additional impact of this decision is that public keys can be discovered via alternate means and then used on
|
|
ledger. QR codes, Bluetooth discovery, alternate or even competing naming services and direct input are all
|
|
possible ways to obtain public keys.
|
|
|
|
\subsection{Hierarchical identity}\label{subsec:hierarchical-identity}
|
|
|
|
The peer-to-peer network is flat and requires that any node can directly connect to any other. However it would be
|
|
useful to extend the network to be multi-level, such that entities without nodes can nonetheless take part in a
|
|
limited way via a proxy or hosting node of some kind. This requires a way to identify these entities such that they
|
|
can be linked to their hosting node.
|
|
|
|
The certificate hierarchy is designed to create a flexible global namespace in which organisations, individuals,
|
|
devices and groups can all be bound to public keys. The standard web PKI uses X.509 path length constraints to
|
|
prevent holders of certificates issuing themselves more sub-certificates, but Corda uses X.509 name constraints to
|
|
enable sub-certificates. A holder of a certificate with a name like \texttt{C=US, S=CA, O=MegaCorp} (a company
|
|
called MegaCorp in California) can issue certificates for names with additional components, for example,
|
|
\texttt{C=US, S=CA, O=MegaCorp, CN=user@megacorp.com}. These components could reflect employees, account holders or
|
|
machines manufactured by the firm. Future versions of the flow framework will understand how to route flow sessions
|
|
based on these names via their controlling organisational nodes by simply finding the most precise match for the
|
|
name (after discarding suffixes) in the network map, thus enabling apps to start structured conversations with
|
|
those entities.
|
|
|
|
The identity hierarchy has a single root: the node's network operator. In effect there is only one root certificate
|
|
authority. This may appear different to the web PKI (in which there are many competing CAs) but is actually the
|
|
same. On the web, the identity hierarchy root is your browser or operating system vendor. These vendors select which
|
|
certificate authorities are a part of the `root store' and thus trusted to verify identities. Authority is ultimately
|
|
only delegated by the software vendors. Corda doesn't ship a root store, as that would make the software maintainers
|
|
be the ultimate identity root of all networks granting too much power. Consider a software update that added a CA
|
|
to the trust store controlled by a rogue developer, for example - this would grant that rogue developer full read/write
|
|
access to every Corda network.
|
|
|
|
Instead, the network operator is the root and may delegate authority as they see fit. Whilst normally used to
|
|
delegate authority over the sub-namespace of a single legal entity, as described above, it is theoretically also
|
|
possible to delegate in other ways, for example, along national boundaries, or simply to grant unconstrained
|
|
certificate-issuing power to other firms, as is done in the web PKI. In such a configuration care would have to be
|
|
taken to ensure only a single certificate laying claim to a name/key pair was issued, as the platform at this time
|
|
cannot handle the ambiguity of multiple live certificates for the same identity in different parts of the
|
|
hierarchy. The issues involved in having multiple certificate issuers for a single network may be addressed in
|
|
future work, but would not remove the requirement to have a single coherent set of network parameters.
|
|
|
|
\subsection{Confidential identities}\label{subsec:confidential-identities}
|
|
|
|
A standard privacy technique in block chain systems is the use of randomised unlinkable public keys to stand in for
|
|
actual verified identities. The platform allows an identity to be obfuscated on the ledger by generating keys not
|
|
linked anywhere in the PKI and then using them in the ledger. Ownership of these pseudonyms may be revealed to a
|
|
counterparty using a simple interactive protocol in which Alice selects a random nonce (`number used once') and
|
|
sends it to Bob, who then signs the nonce with the private key corresponding to the public key he is proving
|
|
ownership of. The resulting signature is then checked and the association between the anonymous key and the primary
|
|
identity key is recorded by the requesting node. This protocol is provided to application developers as a set of
|
|
subflows they can incorporate into their apps. Resolution of transaction chains thus doesn't reveal anything about
|
|
who took part in the transaction.
|
|
|
|
Generating fresh keys for each new deal or asset transfer rapidly results in many private keys being created. These
|
|
keys must all be backed up and kept safe, which poses a significant management problem when done at scale. The
|
|
canonical way to resolve this problem is through the use of deterministic key derivation, as pioneered by the
|
|
Bitcoin community in BIP 32 `Hierarchical Deterministic Wallets'\cite{BIP32}. Deterministic key derivation allows
|
|
all private key material needed to be derived from a single, small pool of entropy (e.g. a carefully protected and
|
|
backed up 128 bits of random data). More importantly, when the full BIP 32 technique is used in combination with an
|
|
elliptic curve that supports it, public keys may also be deterministically derived \emph{without} access to the
|
|
underlying private key material. This allows devices to provide fresh public keys to counterparties without being
|
|
able to sign with those keys, enabling better security along with operational efficiencies.
|
|
|
|
There are constraints on the mathematical properties of the digital signature algorithms parties use, and the
|
|
protocol signature algorithms for which deterministic derivation isn't possible. Additionally it's common for nodes
|
|
to keep their private keys in hardware security modules that may also not support deterministic derivation.
|
|
The reference implementation does not support BIP32 at the time of writing, however, other implementations are
|
|
recommended to use hierarchical deterministic key derivation when possible.
|
|
|
|
\subsection{Non-verified keys}\label{subsec:non-verified-keys}
|
|
|
|
The ability for nodes to use confidential identities isn't only useful for anonymising the node owner. It's
|
|
possible to locally mark anonymous keys with private, randomly generated \emph{universally unique identifiers}
|
|
(UUIDs). These UUIDs can be used for any purpose, but a typical use is to assign keys as owned by some node user
|
|
that isn't otherwise exposed to the ledger. The flow framework understands how to start a flow with a
|
|
confidential identity if the subflows discussed above have been used to establish ownership beforehand.
|
|
|
|
There are a variety of uses for non-verified keys:
|
|
|
|
\begin{itemize}
|
|
\item Oracles may use them to separate their oracular identity from their mainline business identity.
|
|
See~\cref{sec:tear-offs}.
|
|
\item Enclaves (see~\cref{subsec:sgx}) and other services exposed by the nodes may require separated
|
|
signing authority.
|
|
\item States may be directly assigned to groups of employees and the keys stored in off-node hardware.
|
|
See~\cref{sec:secure-signing-devices}.
|
|
\item The node may act as a host for users with \emph{micronodes}: nodes that can't directly take part
|
|
in the peer-to-peer network but still wish to have ultimate control over states. See~\cref{subsec:micronodes}.
|
|
\end{itemize}
|
|
|
|
In the general case, the desire to move signing authority out of a node is to move from a model whereby an entity
|
|
external to the node authorises the node to sign a transaction to a model where the individual (or external entity)
|
|
signs for themselves. This is often driven by the observation that, in situations where the authoriser and the node
|
|
operator are different entities, there is a power balance in favour of the operator, since the operator could in
|
|
fact sign anything they wanted. So moving signing authority out of the node is often driven by a desire to reset
|
|
this power balance and thus to reduce the ability of the node operator to subvert the interests of the authoriser.
|
|
|
|
It is important to note that there are subtle tradeoffs involved here. For example, if the node loses its ability
|
|
to sign some sets of transactions then the responsibility for careful generation, protection and management of the
|
|
keys with that power now resides with the external party; if the keys are lost then the node, by definition, cannot
|
|
step in to rescue you. Similarly, if the third party relies on the node to explain to them what a transaction means
|
|
or to attest to its validity (or that of its dependencies) then the node operator still retains all or nearly all
|
|
the same powers they had beforehand.
|
|
|
|
So Corda's design attempts to optimise for scenarios where moving keys out of nodes creates desirable new power
|
|
balances.
|
|
|
|
% TODO: Add a section discussing balance-of-powers analysis.
|
|
|
|
\section{Data model}
|
|
|
|
\subsection{Transaction structure}\label{subsec:transaction-structure}
|
|
|
|
States are the atomic unit of information in Corda. They are never altered: they are either current (`unspent') or
|
|
consumed (`spent') and hence no longer valid. Transactions read zero or more states (inputs), consume zero or more
|
|
of the read states, and create zero or more new states (outputs). Because states cannot exist outside of the
|
|
transactions that created them, any state whether consumed or not can be identified by the identifier of the
|
|
creating transaction and the index of the state in the outputs list.
|
|
|
|
A basic need is to represent pointers to data on the ledger. A \texttt{StateRef} type models the combination of a
|
|
transaction identifier and an output index. StateRefs can identify any piece of data on the ledger at any point in
|
|
its history in a compact, unified form. The \texttt{StatePointer} type unifies a standard JVM memory reference with
|
|
its cryptographic ledger counterpart. There are two kinds of pointer: static and linear. A static pointer is simply
|
|
a wrapped \texttt{StateRef} which can be easily resolved to the pointed-to state if it's available in the vault. A
|
|
linear pointer contains a UUID (universally unique identifier, a 128-bit random number) that identifies a chain of
|
|
\emph{linear states}. Linear states copy the UUID from input to output, thus allowing you to talk about the latest
|
|
version of a piece of data independent of its hash-based ledger coordinates.
|
|
|
|
Transactions consist of the following components:
|
|
|
|
\begin{labeling}{Input references}
|
|
\item [Consuming input references.] These are \texttt{(hash, output index)} pairs that point to the states a
|
|
transaction is consuming.
|
|
\item [Output states.] Each state specifies the notary for the new state, the contract(s) that define its allowed
|
|
transition functions and finally the data itself.
|
|
\item [Non-consuming input references.] These are also \texttt{(hash, output index)} pairs, however these `reference
|
|
states' are not consumed by the act of referencing them. Reference states are useful for importing data that gives
|
|
context to a verifying smart contract, but which is only changed from time to time. Note that the pointed to state must be unconsumed
|
|
at the time the transaction is notarised: if it's been consumed itself as part of a different transaction, the referencing
|
|
transaction will not be notarised. In this way, non-consuming input references can help prevent the execution of
|
|
transactions that rely on out-of-date reference data.
|
|
\item [Attachments.] Transactions specify an ordered list of zip file hashes. Each zip file may contain
|
|
code and data for the transaction. Contract code has access to the contents of the attachments when checking the
|
|
transaction for validity. Attachments have no concept of `spentness' and are useful for things like holiday
|
|
calendars, timezone data, bytecode that defines the contract logic and state objects, and so on.
|
|
\item [Commands.] There may be multiple allowed output states from any given input state. For instance
|
|
an asset can be moved to a new owner on the ledger, or issued, or exited from the ledger if the asset has been
|
|
redeemed by the owner and no longer needs to be tracked. A command is essentially a parameter to the contract
|
|
that specifies more information than is obtainable from examination of the states by themselves (e.g. data from an oracle
|
|
service). Each command has an associated list of public keys. Like states, commands are object graphs. Commands therefore
|
|
define what a transaction \emph{does} in a conveniently accessible form.
|
|
\item [Signatures.] The set of required signatures is equal to the union of the commands' public keys. Signatures can use
|
|
a variety of cipher suites - Corda implements cryptographic agility.
|
|
\item [Type.] Transactions can either be normal, notary-changing or explicit upgrades. The validation rules for each are
|
|
different.
|
|
\item [Timestamp.] When present, a timestamp defines a time range in which the transaction is considered to
|
|
have occurred. This is discussed in section \cref{sec:timestamps}.
|
|
\item [Network parameters.] Specifies the hash and epoch of the network parameters that were in force at the time the
|
|
transaction was notarised. See \cref{subsec:network-parameters} for more details.
|
|
% \item [Summaries] Textual summaries of what the transaction does, checked by the involved smart contracts. This field
|
|
% is useful for secure signing devices (see \cref{sec:secure-signing-devices}).
|
|
\end{labeling}
|
|
|
|
% TODO: This description ignores the participants field in states, because it probably needs a rethink.
|
|
% TODO: Summaries aren't implemented.
|
|
|
|
The platform provides a \texttt{TransactionBuilder} class which, amongst many other features, automatically
|
|
searches the object graph of each state and command to locate linear pointers, resolve them to the latest known
|
|
state and add that state as a non-consumed input, then searches the resolved state recursively. Note that the `latest' version is determined relative to an
|
|
individual node's viewpoint, thus, it may not be truly the latest version at the time the transaction is built. The
|
|
state's notary cluster will reject the transaction if this occurs, at which point the node may take some action to
|
|
discover the latest version of the state and try again.
|
|
|
|
Transactions are identified by the root of a Merkle tree computed over the components. The transaction format is
|
|
structured so that it's possible to deserialize some components but not others: a \emph{filtered transaction} is
|
|
one in which only some components are retained (e.g. the inputs) and a Merkle branch is provided that proves the
|
|
inclusion of those components in the original full transaction. We say these components have been `torn off'. This
|
|
feature is particularly useful for keeping data private from notaries and oracles. See~\cref{sec:tear-offs}.
|
|
|
|
Signatures are appended to the end of a transaction thus signature malleability as seen in the Bitcoin protocol is
|
|
not a problem. There is never a need to identify a transaction with its accompanying signatures by hash. Signatures
|
|
can be both checked and generated in parallel, and they are not directly exposed to contract code. Instead
|
|
contracts check that the set of public keys specified by a command is appropriate, knowing that the transaction
|
|
will not be valid unless every key listed in every command has a matching signature. Public key structures are
|
|
themselves opaque. In this way high performance through parallelism is possible and algorithmic agility is
|
|
retained. New signature algorithms can be deployed without adjusting the code of the smart contracts themselves.
|
|
|
|
This transaction structure is fairly complex relative to competing systems. The Corda data model is designed for
|
|
richness, evolution over time and high performance. The cost of this is that transactions have more components than
|
|
in simpler systems.
|
|
|
|
\begin{figure}[H]
|
|
\includegraphics[width=\textwidth]{cash}
|
|
\caption{An example of a cash issuance transaction}
|
|
\end{figure}
|
|
|
|
\paragraph{Example.}In the diagram above, we see an example of a cash issuance transaction. The transaction (shown
|
|
lower left) contains zero inputs and one output, a newly issued cash state. The cash state (shown expanded top
|
|
right) contains several important pieces of information: 1) details about the cash that has been issued -- amount,
|
|
currency, issuer, owner and so forth, 2) the contract code whose verify() function will be responsible for
|
|
verifying this issuance transaction and also any transaction which seeks to consume this state in the future, 3) a
|
|
hash of a document which may contain overarching legal prose to ground the behaviour of this state and its contract
|
|
code in a governing legal context.
|
|
|
|
The transaction also contains a command, which specifies that the intent of this transaction is to issue cash and
|
|
the command specifies a public key. The cash state's verify function is responsible for checking that the public
|
|
key(s) specified on the command(s) are those of the parties whose signatures would be required to make this
|
|
transaction valid. In this case, it means that the verify() function must check that the command has specified a
|
|
key corresponding to the identity of the issuer of the cash state. The Corda framework is responsible for checking
|
|
that the transaction has been signed by all keys listed by all commands in the transaction. In this way, a verify()
|
|
function only needs to ensure that all parties who need to sign the transaction are specified in commands, with the
|
|
framework responsible for ensuring that the transaction has been signed by all parties listed in all commands.
|
|
|
|
\subsection{Composite keys}\label{sec:composite-keys}
|
|
|
|
The term ``public key'' in the description above actually refers to a \emph{composite key}. Composite keys are
|
|
trees in which leaves are regular cryptographic public keys with an accompanying algorithm identifiers. Nodes in
|
|
the tree specify both the weights of each child and a threshold weight that must be met. The validity of a set of
|
|
signatures can be determined by walking the tree bottom-up, summing the weights of the keys that have a valid
|
|
signature and comparing against the threshold. By using weights and thresholds a variety of conditions can be
|
|
encoded, including boolean formulas with AND and OR.
|
|
|
|
\begin{figure}[H]
|
|
\includegraphics[width=\textwidth]{composite-keys}
|
|
\caption{Examples of composite keys}
|
|
\end{figure}
|
|
|
|
Composite keys are useful in multiple scenarios. For example, assets can be placed under the control of a 2-of-2
|
|
composite key where one leaf key is owned by a user, and the other by an independent risk analysis system. The risk
|
|
analysis system refuses to sign if the transaction seems suspicious, like if too much value has been transferred in
|
|
too short a time window. Another example involves encoding corporate structures into the key, allowing a CFO to
|
|
sign a large transaction alone but their subordinates are required to work together.
|
|
|
|
Composite keys are also useful for byzantine fault tolerant notaries. Each participant in a distributed notary is
|
|
represented by a leaf, and the threshold is set such that some participants can be offline or refusing to sign yet
|
|
the signature of the group is still valid.
|
|
|
|
Whilst there are threshold signature schemes in the literature that allow composite keys and signatures to be
|
|
produced mathematically, we choose the less space efficient explicit form in order to allow a mixture of keys using
|
|
different algorithms. In this way old algorithms can be phased out and new algorithms phased in without requiring
|
|
all participants in a group to upgrade simultaneously.
|
|
|
|
\subsection{Time handling}\label{sec:timestamps}
|
|
|
|
Transaction timestamps specify a \texttt{[start, end]} time window within which the transaction is asserted to have
|
|
occurred. Timestamps are expressed as windows because in a distributed system there is no true time, only a large
|
|
number of desynchronised clocks. This is not only implied by the laws of physics but also by the nature of shared
|
|
transactions - especially if the signing of a transaction requires multiple human authorisations, the process of
|
|
constructing a joint transaction could take hours or even days.
|
|
|
|
It is important to note that the purpose of a transaction timestamp is to communicate the transaction's position on
|
|
the timeline to the smart contract code for the enforcement of contractual logic. Whilst such timestamps may also
|
|
be used for other purposes, such as regulatory reporting or ordering of events in a user interface, there is no
|
|
requirement to use them like that and locally observed timestamps may sometimes be preferable even if they will not
|
|
exactly match the time observed by other parties. Alternatively if a precise point on the timeline is required and
|
|
it must also be agreed by multiple parties, the midpoint of the time window may be used by convention. Even though
|
|
this may not precisely align to any particular action (like a keystroke or verbal agreement) it is often useful
|
|
nonetheless.
|
|
|
|
Timestamp windows may be open ended in order to communicate that the transaction occurred before a certain time or
|
|
after a certain time, but how much before or after is unimportant. This can be used in a similar way to Bitcoin's
|
|
\texttt{nLockTime} transaction field, which specifies a \emph{happens-after} constraint.
|
|
|
|
Timestamps are checked and enforced by notary services. As the participants in a notary service will themselves not
|
|
have precisely aligned clocks, whether a transaction is considered valid or not at the moment it is submitted to a
|
|
notary may be unpredictable if submission occurs right on a boundary of the given window. However, from the
|
|
perspective of all other observers the notary's signature is decisive: if the signature is present, the transaction
|
|
is assumed to have occurred within that time.
|
|
|
|
\paragraph{Reference clocks.}In order to allow for relatively tight time windows to be used when transactions are
|
|
fully under the control of a single party, notaries are expected to be synchronised to international atomic time
|
|
(TIA). Accurate feeds of this clock can be obtained from GPS satellites and long-wave radio. Note that Corda uses
|
|
the Google/Amazon timeline\cite{GoogleTime}, which is UTC with a leap smear from noon to noon across leap second events. Each day thus
|
|
always has exactly 86400 seconds.
|
|
|
|
\paragraph{Timezones.}Business agreements typically specify times in local time zones rather than offsets from
|
|
midnight UTC on January 1st 1970, although the latter would be more civilised. Because the Corda type system is the
|
|
Java type system, developers can embed \texttt{java.time.ZonedDateTime} in their states to represent a time
|
|
specified in a specific time zone. This allows ensure correct handling of daylight savings transitions and timezone
|
|
definition changes. Future versions of the platform will allow timezone data files to be attached to transactions,
|
|
to make such calculations entirely deterministic.
|
|
|
|
\subsection{Attachments and contract bytecodes}\label{subsec:attachments-and-contract-bytecodes}
|
|
|
|
Transactions may have a number of \emph{attachments}, identified by the hash of the file. Attachments are stored
|
|
and transmitted separately to transaction data and are fetched by the standard resolution flow only when the
|
|
attachment has not previously been seen before.
|
|
|
|
Attachments are always zip files\cite{ZipFormat}. The files within the zips are collapsed together into a single
|
|
logical file system and class path.
|
|
|
|
Smart contracts in Corda are defined using a restricted form of JVM bytecode as specified in \emph{``The Java
|
|
Virtual Machine Specification SE 8 Edition''}\cite{JVM}, with some small differences that are described in a later
|
|
section. A contract is simply a class that implements the \texttt{Contract} interface, which in turn exposes a
|
|
single function called \texttt{verify}. The verify function is passed a transaction and either throws an exception
|
|
if the transaction is considered to be invalid, or returns with no result if the transaction is valid. The set of
|
|
verify functions to use is the union of the contracts specified by each state, which are expressed as a class name
|
|
combined with a \emph{constraint} (see~\cref{sec:contract-constraints}). Embedding the JVM specification in the
|
|
Corda specification enables developers to write code in a variety of languages, use well developed toolchains, and
|
|
to reuse code already authored in Java or other JVM compatible languages. A good example of this feature in action
|
|
is the ability to embed the ISDA Common Domain Model\cite{ISDACDM} directly into CorDapps. The CDM is
|
|
a large collection of types mapped to Java classes that model derivatives trading in a standardised way. It is
|
|
common for industry groups to define such domain models and for them to have a Java mapping.
|
|
|
|
Attachments containing bytecode are executed using a deterministic Java bytecode rewriting system, sometimes called
|
|
the DJVM. See~\cref{sec:djvm} for more information.
|
|
|
|
The Java standards also specify a comprehensive type system for expressing common business data. Time and calendar
|
|
handling is provided by an implementation of the JSR 310 specification, decimal calculations can be performed
|
|
either using portable (`\texttt{strictfp}') floating point arithmetic or the provided bignum library, and so on.
|
|
These libraries have been carefully engineered by the business Java community over a period of many years and it
|
|
makes sense to build on this investment.
|
|
|
|
Contract bytecode also defines the states themselves, which may be directed acyclic object graphs. States may label
|
|
their properties with a small set of standardised annotations. These can be useful for controlling how states are
|
|
serialized to JSON and XML (using JSR 367 and JSR 222 respectively), for expressing static validation constraints
|
|
(JSR 349) and for controlling how states are inserted into relational databases (JSR 338). This feature is
|
|
discussed further in section~\cref{subsec:direct-sql-access}. Future versions of the platform may additionally support cyclic object graphs.
|
|
|
|
\paragraph{Data files.}Attachments may also contain data files that support the contract code. These may be in the
|
|
same zip as the bytecode files, or in a different zip that must be provided for the transaction to be valid.
|
|
Examples of such data files might include currency definitions, timezone data and public holiday calendars. Any
|
|
public data may be referenced in this way. Attachments are intended for data on the ledger that many parties may
|
|
wish to reuse over and over again. Data files are accessed by contract code using the same APIs as any file on the
|
|
classpath would be accessed. The platform imposes some restrictions on what kinds of data can be included in
|
|
attachments along with size limits, to avoid people placing inappropriate files on the global ledger (videos,
|
|
PowerPoints etc).
|
|
|
|
Note that the creator of a transaction gets to choose which files are attached. Therefore, it is typical that
|
|
states place constraints on the application JARs they're willing to accept. This enables the software that imposes
|
|
logic on the ledger to evolve independently of the stored data, whilst still remaining secure against malicious
|
|
evolutions that would, for example, allow an adversary to print money. These mechanisms are discussed
|
|
in~\cref{sec:contract-constraints}.
|
|
|
|
\paragraph{Signing.}Attachments may be signed using the JAR signing standard. No particular certificate is
|
|
necessary for this: Corda accepts self signed certificates for JARs. The signatures are useful for two purposes.
|
|
Firstly, it allows states to express that they can be satisfied by any attachment signed by a particular provider.
|
|
This allows on-ledger code to be upgraded over time. And secondly, signed JARs may provide classes in
|
|
`\emph{claimed packages}', which are discussed below.
|
|
|
|
\subsection{Contract constraints}\label{sec:contract-constraints}
|
|
|
|
In Bitcoin contract logic is embedded inside every transaction. Programs are small and data is inlined into the
|
|
bytecode, so upgrading code that's been added to the ledger is neither possible nor necessary. There's no need for
|
|
a mechanism to tie code and data together. In Corda contract logic may be far more complex. It will usually reflect
|
|
a changing business world which means it may need to be upgraded from time to time.
|
|
|
|
The easiest way of tying states to the contract code that defines them is by hash. This is equivalent to other
|
|
ledger platforms and is referred to as an \emph{hash constraint}. They work well for very simple and stable
|
|
programs, but more complicated contracts may need to be upgraded. In this case it may be preferable for states to
|
|
refer to contracts by the identity of the signer (a \emph{signature constraint}). Because contracts are stored in
|
|
zip files, and because a Java Archive (JAR) file is just a zip with some extra files inside, it is possible to use
|
|
the standard JAR signing infrastructure to identify the source of contract code. Simple constraints such as ``any
|
|
contract of this name signed by these keys'' allow for some upgrade flexibility, at the cost of increased exposure
|
|
to rogue contract developers. Requiring combinations of signatures helps reduce the risk of a rogue or hacked
|
|
developer publishing a bad contract version, at the cost of increased difficulty in releasing new versions. State
|
|
creators may also specify third parties they wish to review contract code. Regardless of which set of tradeoffs is
|
|
chosen, the framework can accommodate them.
|
|
|
|
A contract constraint may use a composite key of the type described in~\cref{sec:composite-keys}. The standard JAR
|
|
signing protocol allows for multiple signatures from different private keys, thus being able to satisfy composite
|
|
keys. The allowed signing algorithms are \texttt{SHA256withRSA} and \texttt{SHA256withECDSA}. Note that the
|
|
cryptographic algorithms used for code signing may not always be the same as those used for transaction signing, as
|
|
for code signing we place initial focus on being able to re-use the infrastructure.
|
|
|
|
\subsection{Precise naming}\label{subsec:precise-naming}
|
|
|
|
In any system that combines typed data with potentially malicious adversaries, it's important to always ensure
|
|
names are not allowed to become ambiguous or mixed up. Corda achieves this via a combination of different features.
|
|
|
|
\paragraph{No overlap rule.}Within a transaction, attachments form a Java classpath. Class names are resolved by
|
|
locating the defining class file within the set of attachments and loading them via the deterministic JVM.
|
|
Unfortunately, out of the box Java allows different JAR files to define the same class name. Whichever JAR happens
|
|
to come first on the classpath is the one that gets used, but conventionally a classpath is not meant to have an
|
|
important ordering. This problem is a frequent source of confusion and bugs in Java software, especially when
|
|
different versions of the same module are combined into one program. On the ledger an adversary can craft a
|
|
malicious transaction that attempts to trick a node or application into thinking it does one thing whilst actually
|
|
doing another. To prevent attackers from building deliberate classpath conflicts to change the behaviour of code, a
|
|
transaction in which two file paths overlap between attachments is invalid. A small number of files that are
|
|
expected to overlap normally, such as files in the \texttt{META-INF} directory, are excluded.
|
|
|
|
\paragraph{Package namespace ownership.}Corda allows parts of the Java package namespace to be reserved for
|
|
particular developers within a network, identified by a public key (which may or may not be linked to an identity). Any JAR
|
|
that exports a class in an owned package namespace but which is not signed by the owning key is considered to be
|
|
invalid. Reserving a package namespace is optional but can simplify the data model and make applications more
|
|
secure.
|
|
|
|
The reason for this is related to a mismatch between the way the ledger names code and the way programming
|
|
languages do. In the distributed ledger world a bundle of code is referenced by hash or signing key, but in source
|
|
code English-like module names are used. In the Java ecosystem these names are broken into components separated by
|
|
dots, and there's a strong convention that names are chosen to start with the reversed domain name of the
|
|
developer's website. For example a developer who works for MegaCorp may use
|
|
\texttt{com.megacorp.superproduct.submodule} as a prefix for the names used in that specific product and submodule.
|
|
|
|
However this is only a convention. Nothing prevents anyone from publishing code that uses MegaCorp's package
|
|
namespace. Normally this isn't a problem as developers learn the correct names via some secure means, like browsing
|
|
an encrypted website of good reputation. But on a distributed ledger data can be encountered which was crafted by a
|
|
malicious adversary, usually a trading partner who hasn't been extensively verified or who has been compromised.
|
|
Such an adversary could build a transaction with a custom state and attachment that defined classes with the same
|
|
name as used by a real app. Whilst the core ledger can differentiate between the two applications, if data is
|
|
serialized or otherwise exposed via APIs that rely on ordinary types and class names the hash or signer of the
|
|
original attachment can easily get lost.
|
|
|
|
For example, if a state is serialized to JSON at any point then \emph{any} type that has the same shape can appear
|
|
legitimate. In Corda serialization types are ultimately identified by class name, as is true for all other forms of
|
|
serialization. Thus deserializing data and assuming the data represents a state only reachable by the contract
|
|
logic would be risky if the developer forgot to check that the original smart contract was the intended contract
|
|
and not one violating the naming convention.
|
|
|
|
By enforcing the Java naming convention cryptographically and elevating it to the status of a consensus rule,
|
|
developers can assume that a \texttt{com.megacorp.superproduct.DealState} type always obeys the rules enforced by
|
|
the smart contract published by that specific company. They cannot get confused by a mismatch between the human
|
|
readable self-assigned name and the cryptographic but non-human readable hash or key based name the ledger really
|
|
uses.
|
|
|
|
% TODO: Discuss confidential identities.
|
|
% TODO: Discuss the crypto suites used in Corda.
|
|
|
|
\subsection{Dispute resolution}\label{subsec:bug-fixes-and-dispute-resolution}
|
|
|
|
Decentralised ledger systems often differ in their underlying political ideology as well as their technical
|
|
choices. The Ethereum project originally promised ``unstoppable apps'' which would implement ``code as law''. After
|
|
a prominent smart contract was hacked\cite{TheDAOHack}, an argument took place over whether what had occurred could
|
|
be described as a hack at all given the lack of any non-code specification of what the program was meant to do. The
|
|
disagreement eventually led to a split in the community.
|
|
|
|
As Corda contracts are simply zip files, it is easy to include a PDF or other documents describing what a contract
|
|
is meant to actually do. A \texttt{@LegalProseReference} annotation is provided which by convention contains a URL
|
|
or URI to a specification document. There is no requirement to use this mechanism, and there is no requirement that
|
|
these documents have any legal weight. However in financial use cases it's expected that they would be legal
|
|
contracts that take precedence over the software implementations in case of disagreement.
|
|
|
|
It is technically possible to write a contract that cannot be upgraded. If such a contract governed an asset that
|
|
existed only on the ledger, like a cryptocurrency, then that would provide an approximation of ``code as law''. We
|
|
leave discussion of the wisdom of this concept to political scientists and reddit.
|
|
|
|
% TODO: Rewrite the section on confidential identities and move it under a new privacy section.
|
|
|
|
\subsection{Oracles and tear-offs}\label{sec:tear-offs}
|
|
|
|
It is sometimes convenient to reveal a small part of a transaction to a counterparty in a way that allows them to
|
|
both check and create signatures over the entire transaction. One typical use case for this is an \emph{oracle},
|
|
defined as a network service that is trusted to sign transactions containing statements about the world outside the
|
|
ledger only if the statements are true. Another use case is to outsource signing to small devices that can't or
|
|
won't process the entire transaction, which can potentially get very large for multi-party transactions. To make
|
|
this safe additional infrastructure is required, described in~\cref{sec:secure-signing-devices}.
|
|
|
|
Here are some example statements an oracle might check:
|
|
|
|
\begin{itemize}
|
|
\item The price of a stock at a particular moment was X.
|
|
\item An agreed upon interest rate at a particular moment was Y.
|
|
\item If a specific organisation has declared bankruptcy.
|
|
\item Weather conditions in a particular place at a particular time.
|
|
\end{itemize}
|
|
|
|
It is worth asking why a smart contract cannot simply fetch this information from some internet server itself: why
|
|
do we insist on this notion of an oracle. The reason is that all calculations on the ledger must be deterministic.
|
|
Everyone must be able to check the validity of a transaction and arrive at exactly the same answer, at any time
|
|
(including years into the future), on any kind of computer. If a smart contract could do things like read the
|
|
system clock or fetch arbitrary web pages then it would be possible for some computers to conclude a transaction
|
|
was valid, whilst others concluded it was not (e.g. if the remote server had gone offline). Solving this problem
|
|
means all the data needed to check the transaction must be in the ledger, which in turn implies that we must accept
|
|
the point of view of some specific observer. That way there can be no disagreement about what happened.
|
|
|
|
One way to implement oracles would be to have them sign a small data structure which is then embedded somewhere in
|
|
a transaction (in a state or command). We take a different approach in which oracles sign the entire transaction,
|
|
and data the oracle doesn't need to see is ``torn off'' before the transaction is sent. This is done by structuring
|
|
the transaction as a Merkle hash tree so that the hash used for the signing operation is the root. By presenting a
|
|
counterparty with the data elements that are needed along with the Merkle branches linking them to the root hash,
|
|
as seen in the diagrams below, that counterparty can sign the entire transaction whilst only being able to see some
|
|
of it. Additionally, if the counterparty needs to be convinced that some third party has already signed the
|
|
transaction, that is also straightforward. Typically an oracle will be presented with the Merkle branches for the
|
|
command or state that contains the data, and the timestamp field, and nothing else. If an oracle also takes part
|
|
in the ledger as a direct participant it should therefore derive a separate key for oracular usage, to avoid
|
|
being tricked into blind-signing a transaction that might also affect its own states.
|
|
|
|
\begin{figure}[H]
|
|
\includegraphics[width=\textwidth]{tearoffs1}
|
|
\caption{How the transaction's identifier hash is calculated}
|
|
\end{figure}
|
|
|
|
\begin{figure}[H]
|
|
\includegraphics[width=\textwidth]{tearoffs2}
|
|
\caption{Construction of a Merkle branch}
|
|
\end{figure}
|
|
|
|
There are several reasons to take this more indirect approach. One is to keep a single signature checking code
|
|
path. By ensuring there is only one place in a transaction where signatures may be found, algorithmic agility and
|
|
parallel/batch verification are easy to implement. When a signature may be found in any arbitrary location in a
|
|
transaction's data structures, and where verification may be controlled by the contract code itself (as in
|
|
Bitcoin), it becomes harder to maximise signature checking efficiency. As signature checks are often one of the
|
|
slowest parts of a block chain system, it is desirable to preserve these capabilities.
|
|
|
|
Another reason is to provide oracles with a business model. If oracles just signed statements and nothing else then
|
|
it would be difficult to run an oracle in which there are only a small number of potential statements, but
|
|
determining their truth is very expensive. People could share the signed statements and reuse them in many
|
|
different transactions, meaning the cost of issuing the initial signatures would have to be very high, perhaps
|
|
unworkably high. Because oracles sign specific transactions, not specific statements, an oracle that is charging
|
|
for its services can amortise the cost of determining the truth of a statement over many users who cannot then
|
|
share the signature itself (because it covers a one-time-use structure by definition).
|
|
|
|
A final reason is that by signing transactions, the signature automatically covers the embedded time window, as
|
|
discussed in~\cref{sec:timestamps}. This provides a theoretically robust method of anchoring the oracle's statement
|
|
into the ledger's timeline.
|
|
|
|
\subsection{Encumbrances}\label{sec:encumbrances}
|
|
|
|
Each state in a transaction specifies a contract (boolean function) that is invoked with the entire transaction as
|
|
input. All contracts must accept in order for the transaction to be considered valid. Sometimes we would like to
|
|
compose the behaviours of multiple different contracts. Consider the notion of a ``time lock'' -- a restriction on
|
|
a state that prevents it being modified (e.g. sold) until a certain time. This is a general piece of logic that
|
|
could apply to many kinds of assets. Whilst such logic could be implemented in a library and then called from every
|
|
contract that might want to benefit from it, that requires all contract authors to think ahead and include the
|
|
functionality. It would be better if we could mandate that the time lock logic ran along side the contract that
|
|
governs the locked state.
|
|
|
|
Consider an asset that is supposed to remain frozen until a time is reached. Encumbrances allow a state to specify
|
|
another state that must be present in any transaction that consumes it. For example, a time lock contract can
|
|
define a state that contains the time at which the lock expires, and a simple contract that just compares that time
|
|
against the transaction timestamp. The asset state can be included in a spend-to-self transaction that doesn't
|
|
change the ownership of the asset but does include a time lock state in the outputs. Now if the asset state is
|
|
used, the time lock state must also be used, and that triggers the execution of the time lock contract.
|
|
|
|
Encumbered states can only point to one encumbrance state, but that state can itself point to another and so on,
|
|
resulting in a chain of encumbrances all of which must be satisfied.
|
|
|
|
% TODO: Diagram for how this is arranged
|
|
|
|
An encumbrance state must be present in the same transaction as the encumbered state, as states refer to each other
|
|
by index alone.
|
|
|
|
% TODO: Interaction of enumbrances with notary change transactions.
|
|
|
|
\subsection{Event scheduling}\label{sec:event-scheduling}
|
|
|
|
State classes may request flows to be started at given times. When a state is considered relevant by the vault and
|
|
the implementing CorDapp is installed and whitelisted by the administrator, the node may react to the passage of
|
|
time by starting new interactions with other nodes, people, or internal systems. As financial contracts often have
|
|
a notion of time in them this feature can be useful for many kinds of state transitions, for example, expiry of an
|
|
option contract, management of a default event, re-fixing of an interest rate swap and so on.
|
|
|
|
To request scheduled events, a state may implement the \texttt{SchedulableState} interface and then return a
|
|
request from the \texttt{nextScheduledActivity} function. The state will be queried when it is committed to the
|
|
vault and the scheduler will ensure the relevant flow is started at the right time.
|
|
|
|
\subsection{Tokens}\label{sec:tokens}
|
|
|
|
Some basic concepts occur in many kinds of application, regardless of what industry or use case it is for. The
|
|
platform provides a comprehensive type system for modelling of \emph{tokens}: abstract countable objects highly
|
|
suited to representing value.
|
|
|
|
Tokens can be used to model agreements with an issuer, like fiat money, securities, derivatives, debts and
|
|
other financial instruments. They could also be used to model any sort of claim on physical resources,
|
|
like CPU time, network bandwidth, barrels of oil and so on. Finally, as a special case tokens can be used to
|
|
implement cryptocurrencies (this is modelled as a claim on a null issuer).
|
|
|
|
We define the notion of an \texttt{OwnableState}, implemented as an interface which any state may conform to.
|
|
Ownable states are required to have an \texttt{owner} field which is a composite key
|
|
(see~\cref{sec:composite-keys}). This is utilised by generic code in the vault (see~\cref{sec:vault}) to manipulate
|
|
ownable states.
|
|
|
|
From \texttt{OwnableState} we derive a \texttt{FungibleState} concept to represent an aggregation in which units
|
|
are sufficiently similar to be represented together in a single ledger state. Making that concrete, pound notes are
|
|
a fungible asset: regardless of whether you represent \pounds10 as a single \pounds10 note or two notes of \pounds5
|
|
each the total value is the same. Other kinds of fungible asset could be barrels of Brent Oil (but not all kinds of
|
|
crude oil worldwide, because oil comes in different grades which are not interchangeable), litres of clean water,
|
|
kilograms of bananas, units of a stock and so on.
|
|
|
|
Quantities are represented with an \texttt{Amount<T>} type which defines an integer amount parameterised by some
|
|
other type, usually a singleton object. To support tokens that have a fractional part, as some national currencies
|
|
do, the ``display token size'' is tracked explicitly. \texttt{Amount<T>} provides operator overloads to allow
|
|
addition, subtraction and multiplication with safety checks to prevent different tokens being combined together and
|
|
to catch integer overflow/underflow. These conditions normally indicate a programmer error or attack attempt.
|
|
Amounts may not be negative as in many critical contexts a negative quantity is undefined and reachable only
|
|
through an error condition. Transfers of value are modelled explicitly with an \texttt{AmountTransfer} type that
|
|
encodes direction.
|
|
|
|
\paragraph{Token SDK.}On top of these universal core types, Corda provides a dedicated `token software development
|
|
kit' module that extends the type system with more sophisticated concepts.
|
|
|
|
\begin{figure}[H]
|
|
\includegraphics[width=\textwidth]{state-class-hierarchy}
|
|
\caption{Class hierarchy diagram showing the relationships between different state types}
|
|
\end{figure}
|
|
|
|
\texttt{TokenType} refers to a ``type of thing'' as opposed to the vehicle which is used to assign units of a token
|
|
to a particular owner. For that we use the \texttt{NonFungibleToken} state for assigning non-fungible tokens to a
|
|
holder and the \texttt{FungibleToken} state for assigning amounts of some fungible token to a holder. Because
|
|
tokens frequently represent claims on an issuer the \texttt{IssuedTokenType} class links a token type with an
|
|
issuing party. Whilst static token types never change, an \texttt{EvolvableTokenType} is an abstract linear state
|
|
that contains data defining the rules of the token or reference data related to it. For example a token type
|
|
representing a stock may include various metadata about that stock, such as regional identifiers. Token states are
|
|
linked to their defining token type states (when evolvable) using linear pointers
|
|
(see~\cref{subsec:transaction-structure}). This enables reference data about a token to be evolved such that
|
|
everyone always uses the latest version, ensuring a `golden source'. The lack of such global yet evolvable
|
|
definitions is a frequent problem in industry. Tokens with an issuer are \emph{not} fungible with each other: two
|
|
pools of pound sterling are considered to be separate types of token if they come from different issuers. This is
|
|
to avoid commingling and losing track of counterparty risk.
|
|
|
|
The token SDK provides APIs and flows to do standard tasks for UTXO based ledgers, such as moving tokens between
|
|
parties, issuing tokens, updating the definition of an evolvable token and efficient coin selection. This is the
|
|
task of selecting a group of states from the vault that add up to a certain value whilst minimising fragmentation,
|
|
transaction size and optimising other desirable characteristics. Although the term ``coin selection'' is an
|
|
anachronistic holdover from Bitcoin, Corda continues to use it due to the wealth of published literature exploring
|
|
algorithms for the task under this name.
|
|
|
|
Together, this functionality provides Corda's equivalent of the Ethereum ERC-20 standard\cite{ERC20}.
|
|
|
|
Having defined various kinds of abstract token, the SDK defines \texttt{Money} and \texttt{FiatCurrency} types.
|
|
Interop with the JSR 354 standard for representing financial amounts is left to future work.
|
|
|
|
%\subsection{Market infrastructure}
|
|
%
|
|
%Trade is the lifeblood of the economy. A distributed ledger needs to provide a vibrant platform on which trading may
|
|
%take place. However, the decentralised nature of such a network makes it difficult to build competitive
|
|
%market infrastructure on top of it, especially for highly liquid assets like securities. Markets typically provide
|
|
%features like a low latency order book, integrated regulatory compliance, price feeds and other things that benefit
|
|
%from a central meeting point.
|
|
%
|
|
%The Corda data model allows for integration of the ledger with existing markets and exchanges. A sell order for
|
|
%an asset that exists on-ledger can have a \emph{partially signed transaction} attached to it. A partial
|
|
%signature is a signature that allows the signed data to be changed in controlled ways after signing. Partial signatures
|
|
%are directly equivalent to Bitcoin's \texttt{SIGHASH} flags and work in the same way -- signatures contain metadata
|
|
%describing which parts of the transaction are covered. Normally all of a transaction would be covered, but using this
|
|
%metadata it is possible to create a signature that only covers some inputs and outputs, whilst allowing more to be
|
|
%added later.
|
|
%
|
|
%This feature is intended for integration of the ledger with the order books of markets and exchanges. Consider a stock
|
|
%exchange. A buy order can be submitted along with a partially signed transaction that signs a cash input state
|
|
%and a output state representing some quantity of the stock owned by the buyer. By itself this transaction is invalid,
|
|
%as the cash does not appear in the outputs list and there is no input for the stock. A sell order can be combined with
|
|
%a mirror-image partially signed transaction that has a stock state as the input and a cash state as the output. When
|
|
%the two orders cross on the order book, the exchange itself can take the two partially signed transactions and merge
|
|
%them together, creating a valid transaction that it then notarises and distributes to both buyer and seller. In this
|
|
%way trading and settlement become atomic, with the ownership of assets on the ledger being synchronised with the view
|
|
%of market participants. Note that in this design the distributed ledger itself is \emph{not} a marketplace, and does
|
|
%not handle distribution or matching of orders. Rather, it focuses on management of the pre- and post- trade lifecycles.
|
|
%
|
|
%\paragraph{Central counterparties.}In many markets, central infrastructures such as clearing houses (also known as
|
|
%Central Counterparties, or CCPs) and Central Securities Depositories (CSD) have been created. They provide governance,
|
|
%rules definition and enforcement, risk management and shared data and processing services. The partial data visibility,
|
|
%flexible transaction verification logic and pluggable notary design means Corda could be a particularly good fit for
|
|
%future distributed ledger services contemplated by CCPs and CSDs.
|
|
%
|
|
%% TODO: Move this section to "Future work"
|
|
|
|
\section{Notaries and consensus}\label{sec:notaries}
|
|
|
|
Corda does not organise time into blocks. This is sometimes considered strange, given that it can be described as a
|
|
block chain system or `block chain inspired'. Instead a Corda network has one or more notary clusters that provide
|
|
transaction ordering and timestamping services, thus abstracting the role miners play in other systems into a
|
|
pluggable component.
|
|
|
|
A notary is expected to be composed of multiple mutually distrusting parties who use a crash or byzantine fault
|
|
tolerant consensus algorithm. Notaries are identified by and sign with composite public keys
|
|
(\cref{sec:composite-keys})that conceptually follow the Interledger Crypto-Conditions specification\cite{ILPCC}.
|
|
Note that whilst it would be conventional to use a BFT algorithm for a notary service, there is no requirement to
|
|
do so and in cases where the legal system is sufficient to ensure protocol compliance a higher performance
|
|
algorithm like Raft\cite{Ongaro:2014:SUC:2643634.2643666} or ordinary database replication may be used. Because
|
|
multiple notaries can co-exist a single network may provide a single global BFT notary for general use and
|
|
region-specific Raft notaries for lower latency trading within a unified regulatory area, for example London or New
|
|
York.
|
|
|
|
Notaries accept transactions submitted to them for processing and either return a signature over the transaction,
|
|
or a rejection error that states that a double spend has occurred. The presence of a notary signature from the
|
|
state's chosen notary indicates transaction finality. An app developer triggers notarisation by invoking the
|
|
\texttt{Finality} flow on the transaction once all other necessary signatures have been gathered. Once the finality
|
|
flow returns successfully, the transaction can be considered committed to the database.
|
|
|
|
\subsection{Comparison to Nakamoto block chains}
|
|
|
|
Bitcoin organises the timeline into a chain of blocks, with each block pointing to a previous block the miner has
|
|
chosen to build upon. Blocks also contain a rough timestamp. Miners can choose to try and extend the block chain
|
|
from any previous block, but are incentivised to build on the most recently announced block by the fact that other
|
|
nodes in the system only recognise a block if it's a part of the chain with the most accumulated proof-of-work. As
|
|
each block contains a reward of newly issued bitcoins, an unrecognised block represents a loss and a recognised
|
|
block typically represents a profit.
|
|
|
|
Bitcoin uses proof-of-work because it has a design goal of allowing an unlimited number of identityless parties to
|
|
join and leave the consensus forming process at will, whilst simultaneously making it hard to execute Sybil attacks (attacks in which
|
|
one party creates multiple identities to gain undue influence over the network). This is an appropriate design to
|
|
use for a peer to peer network formed of volunteers who can't/won't commit to any long term relationships up front,
|
|
and in which identity verification is not done. Using proof-of-work then leads naturally to a requirement to
|
|
quantise the timeline into chunks, due to the probabilistic nature of searching for a proof. The chunks must then
|
|
be ordered relative to each other. The incentive to build on the most recently announced proof of work is in
|
|
tension with the reality that it takes time for a proof to circulate around the network. This means it is desirable
|
|
that proofs are produced at a rate that is slow enough that very few are circulating at the same time. Given that
|
|
transactions are likely to be produced at a higher rate than this, it implies a need for the proofs to consolidate
|
|
multiple transactions. Hence the need for blocks.
|
|
|
|
A Corda network is email-like in the sense that nodes have long term stable identities, which they can prove
|
|
ownership of to others. Sybil attacks are blocked by the network entry process. This allows us to discard
|
|
proof-of-work along with its multiple unfortunate downsides:
|
|
|
|
\begin{itemize}
|
|
\item Energy consumption is excessively high for such a simple task, being comparable at the time of writing to the
|
|
electricity consumption of an entire country\cite{BitcoinEnergy}. At a time when humanity needs to use less energy
|
|
rather than more this is ecologically undesirable.
|
|
\item High energy consumption forces concentration of mining power in regions with cheap or free electricity.
|
|
This results in unpredictable geopolitical complexities that many users would rather do without.
|
|
\item Identityless participants mean all transactions must be broadcast to all network nodes, as there's no reliable
|
|
way to know who the miners are. This worsens privacy.
|
|
\item The algorithm does not provide finality, only a probabilistic approximation, which is a poor fit for existing
|
|
business and legal assumptions.\cite{Swanson}
|
|
\item It is theoretically possible for large numbers of miners or even all miners to drop out simultaneously without
|
|
any protocol commitments being violated.
|
|
\end{itemize}
|
|
|
|
Once proof-of-work is disposed of there is no longer any need to quantise the timeline into blocks because there is
|
|
no longer any need to slow the publication of conflict resolution proposals, and because the parties asserting the
|
|
correctness of the ordering are known ahead of time regular signatures are sufficient.
|
|
|
|
\subsection{Algorithmic agility}
|
|
|
|
Consensus algorithms are a hot area of research and new algorithms are frequently developed that improve upon the
|
|
state of the art. Unlike most distributed ledger systems Corda does not tightly integrate one specific approach.
|
|
This is not only to support upgrades as new algorithms are developed, but also to reflect the fact that different
|
|
tradeoffs may make sense for different situations and networks.
|
|
|
|
As a simple example, a notary that uses Raft between nodes that are all within the same city will provide extremely
|
|
good performance and latency, at the cost of being more exposed to malicious attacks or errors by whichever node
|
|
has been elected leader. In situations where the members making up a distributed notary service are all large,
|
|
regulated institutions that are not expected to try and corrupt the ledger in their own favour trading off security
|
|
to gain performance may make sense. In other situations where existing legal or trust relationships are less
|
|
robust, slower but byzantine fault tolerant algorithms like BFT-SMaRT\cite{Bessani:2014:SMR:2671853.2672428} may be
|
|
preferable. Alternatively, hardware security features like Intel SGX\textregistered may be used to convert non-BFT
|
|
algorithms into a more trusted form using remote attestation and hardware protection.
|
|
|
|
Being able to support multiple notaries in the same network has other advantages:
|
|
|
|
\begin{itemize}
|
|
\item It is possible to phase out notaries (i.e. sets of participants) that no longer wish to provide that service by
|
|
migrating states.
|
|
\item The scalability of the system can be increased by bringing online new notaries that run in parallel. As long
|
|
as access to the ledger has some locality (i.e. states aren't constantly being migrated between notaries) this
|
|
allows for the scalability limits of common consensus algorithms or node hardware to be worked around.
|
|
\item In some but not all cases, regulatory constraints on data propagation can be respected by having
|
|
jurisdictionally specific notaries. This would not work well when two jurisdictions have mutually incompatible
|
|
constraints or for assets that may frequently travel around the world, but it can work when using the ledger to
|
|
track the state of deals or other facts that are inherently region specific.
|
|
\item Notaries can compete on their availability and performance.
|
|
\item Users can pick between \emph{validating} and \emph{non-validating} notaries. See below.
|
|
\item In some models for how these technologies will be adopted, it is possible that issuers of assets will find it
|
|
convenient to 'self-notarise' transactions that pertain to assets they have issued and this necessarily requires
|
|
support for multiple notaries in the same network. Such a model is likely to be a transitional state, not least
|
|
because such a model is inherently limited in the range of operations that can be supported.
|
|
\item Separate networks can start independent and be merged together later (see below).
|
|
\end{itemize}
|
|
|
|
\subsection{Validating and non-validating notaries}\label{sec:non-validating-notaries}
|
|
|
|
Validating notaries resolve and fully check transactions they are asked to deconflict. Thus in the degenerate case
|
|
of a network with just a single notary and without the use of any privacy features, they gain full visibility into
|
|
every transaction. Non-validating notaries assume transaction validity and do not request transaction data or their
|
|
dependencies beyond the list of states consumed. With such a notary it is possible for the ledger to become
|
|
`wedged', as anyone who knows the hash and index of a state may consume it without checks. If the cause of the
|
|
problem is accidental, the incorrect data can be presented to a non-validating notary to convince it to roll back
|
|
the commit, but if the error is malicious then states controlled by such a notary may become permanently corrupted.
|
|
|
|
It is therefore possible for users to select their preferred point on a privacy/security spectrum for each state
|
|
individually depending on how they expect the data to be used. When the states are unlikely to live long or
|
|
propagate far and the only entities who will learn their transaction hashes are somewhat trustworthy, the user may
|
|
select to keep the data from the notary. For liquid assets a validating notary should always be used to prevent
|
|
value destruction and theft if the transaction identifiers leak.
|
|
|
|
\section{The node}\label{sec:node}
|
|
|
|
Corda comes with an open source reference implementation of the node. A more advanced `Corda Enterprise' node is
|
|
available on a commercial basis from R3. The node acts as an application server which loads JARs containing
|
|
CorDapps and provides them with access to the peer-to-peer network, signing keys, a relational database that may
|
|
be used for any purpose, and a `vault' that stores states. Although the open source reference implementation is
|
|
a single server, more advanced nodes may be decomposed into multiple cooperating services. For example, the
|
|
commercial node from R3 offers a cryptographic firewall component that separates the node from the internet and
|
|
terminates/relays connections through the organisation's DMZ. The message queue broker plays an integral role
|
|
in connecting different services together in this kind of multi-component architecture.
|
|
|
|
An occasional source of confusion is related to whether the open source nature of the node has any implications for
|
|
ledger integrity. It doesn't, because as with all DLT systems, Corda nodes cross check each other's transactions.
|
|
When executing well written applications a node owner cannot gain any advantage by corrupting their node's code or
|
|
state. A future version of Corda may provide a formal protocol specification, easing the task of creating
|
|
alternatives to the reference implementation.
|
|
|
|
This guarantee does not presently extend to apps installed in a node attacking each other. The reference
|
|
implementation provides no inter-app isolation: it is assumed that (outside of contract logic) code executing in
|
|
the node was installed by the administrator and is trusted. Applications are granted access to the underlying
|
|
relational database and can thus read each others states directly. Nodes capable of sandboxing potentially
|
|
malicious flows and in-process services whilst still enabling application interop are a topic for future work.
|
|
The platform is built with a combination of JVM-level type security sandboxing and process isolation in mind; a
|
|
plausible candidate architecture is one in which flows are load balanced by the MQ broker between multiple flow
|
|
workers that can run on different machines and in different firewall zones.
|
|
|
|
\subsection{The vault}\label{sec:vault}
|
|
|
|
In any block chain based system most nodes have a wallet, or as we call it, a vault.
|
|
|
|
The vault contains data extracted from the ledger that is considered \emph{relevant} to the node's owner, stored in
|
|
a form that can be easily queried and worked with. It also contains private key material that is needed to sign
|
|
transactions consuming states in the vault. Like with a cryptocurrency wallet, the Corda vault understands how to
|
|
create transactions that send value to someone else by combining asset states and possibly adding a change output
|
|
that makes the values balance. This process is usually referred to as `coin selection'. Coin selection can be a
|
|
complex process. In Corda there are no per transaction network fees, which is a significant source of complexity in
|
|
other systems. However transactions must respect the fungibility rules in order to ensure that the issuer and
|
|
reference data is preserved as the assets pass from hand to hand.
|
|
|
|
Advanced vault implementations may also perform splitting and merging of states in the background. The purpose of
|
|
this is to increase the amount of transaction creation parallelism supported. Because signing a transaction may
|
|
involve human intervention (see~\cref{sec:secure-signing-devices}) and thus may take a significant amount of time,
|
|
it can become important to be able to create multiple transactions in parallel. The vault must manage state `soft
|
|
locks' to prevent multiple transactions trying to use the same output simultaneously. Violation of a soft lock
|
|
would result in a double spend being created and rejected by the notary. If a vault were to contain the entire cash
|
|
balance of a user in just one state, there could only be a single transaction being constructed at once and this
|
|
could impose unacceptable operational overheads on an organisation. By automatically creating send-to-self
|
|
transactions that split the big state into multiple smaller states, the number of transactions that can be created
|
|
in parallel is increased. Alternatively many tiny states may need to be consolidated into a smaller number of more
|
|
valuable states in order to avoid hitting transaction size limits. Finally, in some cases the vault may send asset
|
|
states back to the issuer for re-issuance, thus pruning long transaction chains and improving privacy.
|
|
|
|
The vault is also responsible for managing scheduled events requested by node-relevant states when the implementing
|
|
app has been installed (see~\cref{sec:event-scheduling}).
|
|
|
|
\subsection{Direct SQL access}\label{subsec:direct-sql-access}
|
|
|
|
A distributed ledger is ultimately just a shared database, albeit one with some unique features. The following
|
|
features are therefore highly desirable for improving the productivity of app developers:
|
|
|
|
\begin{itemize}
|
|
\item Ability to store private data linked to the semi-public data in the ledger.
|
|
\item Ability to query the ledger data using widely understood tools like SQL.
|
|
\item Ability to perform joins between entirely app-private data (like customer notes) and ledger data.
|
|
\item Ability to define relational constraints and triggers on the underlying tables.
|
|
\item Ability to do queries at particular points in time e.g. midnight last night.
|
|
\item Re-use of industry standard and highly optimised database engines.
|
|
\item Independence from any particular database engine, without walling off too many useful features.
|
|
\end{itemize}
|
|
|
|
Corda states are defined using a subset of the JVM bytecode language which includes annotations. The vault
|
|
recognises annotations from the JPA specification defined in JSR 338\cite{JPA}. These annotations define how a class maps to a relational table schema including which member is the
|
|
primary key, what SQL types to map the fields to and so on. When a transaction is submitted to the vault by a flow,
|
|
the vault finds states it considers relevant (i.e. which contains a key owned by the node) and the relevant CorDapp
|
|
has been installed into the node as a plugin, the states are fed through an object relational mapper which
|
|
generates SQL \texttt{UPDATE} and \texttt{INSERT} statements. Note that data is not deleted when states are
|
|
consumed, however a join can be performed with a dedicated metadata table to eliminate consumed states from the
|
|
dataset. This allows data to be queried at a point in time, with rows being evicted to historical tables using
|
|
external tools.
|
|
|
|
Nodes come with an embedded database engine out of the box, but may also be configured to point to a separate
|
|
RDBMS. The node stores not only state data but also all node working data in the database, including flow
|
|
checkpoints. Thus the state of a node and all communications it is engaged in can be backed up by simply backing up
|
|
the database itself. The JPA annotations are independent of any particular database engine or SQL dialect and thus
|
|
states cannot use any proprietary column types or other features, however, because the ORM is only used on the
|
|
write paths users are free to connect to the backing database directly and issue SQL queries that utilise any
|
|
features of their chosen database engine that they like. They can also create their own tables and create merged
|
|
views of the underlying data for end user applications, as long as they don't impose any constraints that would
|
|
prevent the node from syncing the database with the actual contents of the ledger.
|
|
|
|
States are arbitrary object graphs. Whilst nothing stops a state from containing multiple classes intended for
|
|
different tables, it is typical that the relational representation will not be a direct translation of the
|
|
object-graph representation. States are queried by the vault for the ORM mapped class to use, which will often skip
|
|
ledger-specific data that's irrelevant to the user like opaque public keys and may expand single fields like an
|
|
\texttt{Amount<Issued<Currency>>} type into multiple database columns.
|
|
|
|
It's worth noting here that although the vault only responds to JPA annotations it is often useful for states to be
|
|
annotated in other ways, for instance to customise its mapping to XML/JSON, or to impose validation
|
|
constraints~\cite{BeanValidation}. These annotations won't affect the behaviour of the node directly but may be
|
|
useful when working with states in surrounding software.
|
|
|
|
\subsection{Client RPC and reactive collections}\label{sec:client-rpc-and-reactive-collections}
|
|
|
|
Any realistic deployment of a distributed ledger faces the issue of integration with an existing ecosystem of
|
|
surrounding tools and processes. Ideally, programs that interact with the node will be loosely coupled,
|
|
authenticated, robust against transient node outages and restarts, and speed differences (e.g. production of work
|
|
being faster than completion of work) will be handled transparently.
|
|
|
|
To meet these needs, Corda nodes expose a simple RPC mechanism that has a couple of unusual features. The
|
|
underlying transport is message queues (AMQP) and methods can return object graphs that contain ReactiveX
|
|
observables\cite{Rx} which may in turn emit more observables.
|
|
|
|
It is a common pattern for RPCs to return a snapshot of some data structure, along with an observable that emits
|
|
objects representing a delta on that data structure. The client library has functionality to reconstruct the
|
|
snapshot + diffs into a observable collections of the type that can be bound directly to a JavaFX user interface.
|
|
In this way, rendering data structures in the global ledger in a rich client app that stays fresh becomes a
|
|
straightforward operation that requires minimal work from the developer: simply wiring the pieces together in a
|
|
functional way is sufficient. Reactive transforms over these observable collections such as mappings, filterings,
|
|
sortings and so on make it easy to build user interfaces in a functional programming style.
|
|
|
|
It can be asked why Corda does not use the typical REST+JSON approach to communicating with the node. The reasons
|
|
are:
|
|
|
|
\begin{itemize}
|
|
\item A preference for binary protocols over textual protocols, as text based protocols tend to be more
|
|
susceptible to escaping and other buffer management problems that can lead to security issues.
|
|
\item Message queue brokers provide significant amounts of infrastructure for building reliable apps
|
|
which plain HTTP does not such as backpressure management, load balancing, queue browsing, management of speed
|
|
differences and so on.
|
|
\item REST based protocols have multiple conventions for streaming of results back to the client, none of which
|
|
are ideal for the task.
|
|
\end{itemize}
|
|
|
|
Being able to connect live data structures directly to UI toolkits also contributes to the avoidance of XSS
|
|
exploits, XSRF exploits and similar security problems based on losing track of buffer boundaries.
|
|
|
|
\section{Deterministic JVM}\label{sec:djvm}
|
|
|
|
It is important that all nodes that process a transaction always agree on whether it is valid or not. Because
|
|
transaction types are defined using JVM bytecode, this means the execution of that bytecode must be fully
|
|
deterministic. Out of the box a standard JVM is not fully deterministic, thus we must make some modifications in
|
|
order to satisfy our requirements. Non-determinism could come from the following sources:
|
|
|
|
\begin{itemize}
|
|
\item Sources of external input e.g. the file system, network, system properties, clocks.
|
|
\item Random number generators.
|
|
\item Different decisions about when to terminate long running programs.
|
|
\item \texttt{Object.hashCode()}, which is typically implemented either by returning a pointer address or by
|
|
assigning the object a random number. This can surface as different iteration orders over hash maps and hash sets.
|
|
\item Differences in hardware floating point arithmetic.
|
|
\item Multi-threading.
|
|
\item Differences in API implementations between nodes.
|
|
\item Garbage collector callbacks.
|
|
\end{itemize}
|
|
|
|
To ensure that the contract verify function is fully pure even in the face of infinite loops we construct a new
|
|
type of JVM sandbox. It utilises a set of bytecode static analyses and rewriting passes.
|
|
Classes are rewritten the first time they are loaded.
|
|
|
|
The bytecode analysis and rewrite performs the following tasks:
|
|
|
|
\begin{itemize}
|
|
\item Inserts calls to an accounting object before expensive bytecodes. The goal of this rewrite is to deterministically
|
|
terminate code that has run for an unacceptably long amount of time or used an unacceptable amount of memory. Expensive
|
|
bytecodes include method invocation, allocation, backwards jumps and throwing exceptions.
|
|
\item Prevents exception handlers from catching \texttt{Throwable}, \texttt{Error} or \texttt{ThreadDeath}.
|
|
\item Adjusts constant pool references to relink the code against a `shadow' JDK, which duplicates a subset of the regular
|
|
JDK but inside a dedicated sandbox package. The shadow JDK is missing functionality that contract code shouldn't have access
|
|
to, such as file IO or external entropy. It can be loaded into an IDE like IntellJ IDEA to give developers interactive
|
|
feedback whilst coding, so they can avoid non-deterministic code.
|
|
\item Sets the \texttt{strictfp} flag on all methods, which requires the JVM to do floating point arithmetic in a hardware
|
|
independent fashion. Whilst we anticipate that floating point arithmetic is unlikely to feature in most smart contracts
|
|
(big integer and big decimal libraries are available), it is available for those who want to use it.
|
|
\item Forbids \texttt{invokedynamic} bytecode except in special cases, as the libraries that support this functionality have
|
|
historically had security problems and it is primarily needed only by scripting languages. Support for the specific
|
|
lambda and string concatenation metafactories used by Java code itself are allowed.
|
|
% TODO: The sandbox doesn't allow lambda/string concat(j9) metafactories at the moment.
|
|
\item Forbids native methods.
|
|
\item Forbids finalizers.
|
|
\end{itemize}
|
|
|
|
The cost instrumentation strategy used is a simple one: just counting bytecodes that are known to be expensive to
|
|
execute. Method size is limited and jumps count towards the budget, so such a strategy is guaranteed to eventually
|
|
terminate. However it is still possible to construct bytecode sequences by hand that take excessive amounts of time
|
|
to execute. The cost instrumentation is designed to ensure that infinite loops are terminated and that if the cost
|
|
of verifying a transaction becomes unexpectedly large (e.g. contains algorithms with complexity exponential in
|
|
transaction size) that all nodes agree precisely on when to quit. It is \emph{not} intended as a protection against
|
|
denial of service attacks. If a node is sending you transactions that appear designed to simply waste your CPU time
|
|
then simply blocking that node is sufficient to solve the problem, given the lack of global broadcast.
|
|
|
|
Opcode budgets are separated into a few categories, so there is no unified cost model. Additionally the instrumentation is
|
|
high overhead. A more sophisticated design would be to statically calculate bytecode costs as much as possible
|
|
ahead of time, by instrumenting only the entry point of `accounting blocks', i.e. runs of basic blocks that end
|
|
with either a method return or a backwards jump. Because only an abstract cost matters (this is not a profiler
|
|
tool) and because the limits are expected to bet set relatively high, there is no need to instrument every basic
|
|
block. Using the max of both sides of a branch is sufficient when neither branch target contains a backwards jump.
|
|
This sort of design will be investigated if the per category opcode-at-a-time accounting turns out to be
|
|
insufficient.
|
|
|
|
A further complexity comes from the need to constrain memory usage. The sandbox imposes a quota on bytes
|
|
\emph{allocated} rather than bytes \emph{retained} in order to simplify the implementation. This strategy is
|
|
unnecessarily harsh on smart contracts that churn large quantities of garbage yet have relatively small peak heap
|
|
sizes and, again, it may be that in practice a more sophisticated strategy that integrates with the garbage
|
|
collector is required in order to set quotas to a usefully generic level.
|
|
|
|
\section{Scalability}\label{sec:scalability}
|
|
|
|
Scalability of block chains and block chain inspired systems has been a constant topic of discussion since Nakamoto
|
|
first proposed the technology in 2008. Corda provides much better scalability than other competing systems, via a
|
|
variety of choices and tradeoffs that affect and ensure scalability. Scalability can be measured in many different
|
|
dimensions, extending even to factors like how many apps the ecosystem can handle.
|
|
|
|
The primary techniques used to scale better than classical systems are as follows.
|
|
|
|
\subsection{Partial visibility}\label{subsec:partial-visibility}
|
|
|
|
Nodes only encounter transactions if they are involved in some way, or if the transactions are dependencies of
|
|
transactions that involve them in some way. This loosely connected design means that it is entirely possible for
|
|
most nodes to never see most of the transaction graph, and thus they do not need to process it. This makes direct
|
|
scaling comparisons with other distributed and decentralised database systems difficult, as they invariably measure
|
|
performance in transactions/second per network rather than per node, but Corda nodes scale depending on how much
|
|
\emph{business relevant} work they do.
|
|
|
|
Because of this, a group of businesses doing high-throughput traffic between each other won't affect the load on
|
|
other nodes belonging to unrelated businesses. Nodes can handle large numbers of transactions per second.
|
|
As of the time of writing, a node has been demonstrated doing a sustained 800 transactions per second and an
|
|
independent test has demonstrated a multi-notary network processing over 20,000 transactions per second\cite{DTCCStudy}. Very few
|
|
businesses directly generate such large quantities of traffic - all of PayPal does only about 320 transactions per
|
|
second on average\cite{PayPalTrafficVolume}, so we believe this is sufficient to enable virtually all business use
|
|
cases, especially as one transaction can update many parts of the ledger simultaneously.
|
|
|
|
\subsection{Multiple notaries}
|
|
|
|
The primary bottleneck on ledger update speed is how fast notaries can commit transactions to resolve conflicts.
|
|
Whereas most blockchain systems provide a single shard and a single consensus mechanism, Corda allows multiple
|
|
shards (in our lingo, notary clusters), which can run potentially different consensus algorithms, all
|
|
simultaneously in the same interoperable network (see~\cref{sec:notaries}). Therefore it is possible to increase
|
|
scalability in some cases by bringing online additional notary clusters. States can be moved between notaries if
|
|
necessary to rebalance them.
|
|
|
|
Note that this only adds capacity if the transaction graph has underlying exploitable structure (e.g. geographical
|
|
biases), as a purely random transaction graph would end up constantly crossing notaries and the additional
|
|
transactions to move states from one notary to another would negate the benefit. In real trading however the
|
|
transaction graph is not random at all, and thus this approach may be helpful.
|
|
|
|
The primary constraint on this technique is that all notaries must be equally trusted by participants. If a Corda
|
|
network were to contain one very robust, large byzantine fault tolerant notary and additionally a small notary
|
|
which used non-BFT algorithms, the trustworthiness of the network's consensus would be equal to the weakest link,
|
|
as states are allowed to migrate between notaries. Therefore a network operator must be careful to ensure that new
|
|
notary clusters or the deployment of new algorithms don't undermine confidence in the existing clusters.
|
|
|
|
\subsection{Parallel processing}
|
|
|
|
A classic constraint on the scalability of blockchain systems is their nearly non-existent support for parallelism.
|
|
The primary unit of parallelism in Corda is the flow. Many flows and thus ledger updates can be running
|
|
simultaneously; some node implementations can execute flows on multiple CPU cores concurrently and the potential
|
|
for sharding them across a multi-server node also exists. In such a design the MQ broker would take responsibility
|
|
for load balancing inbound protocol messages and scheduling them to provide flow affinity; the checkpointing
|
|
mechanism allows flows to migrate across flow workers transparently as workers are added and removed. Notary
|
|
clusters can commit transactions in batches, and multiple independent notary clusters may be processing
|
|
transactions in parallel.
|
|
|
|
Not only updates (writes) are concurrent. Transactions may also be verified in parallel. Because transactions are
|
|
not globally ordered but rather only ordered relative to each other via the input list, dependencies of a
|
|
transaction don't depend on each other and may be verified simultaneously. Corda transaction identifiers are the
|
|
root of a Merkle tree calculated over its contents excluding signatures. This has the downside that a signed and
|
|
partially signed transaction cannot be distinguished by their canonical identifier, but means that signatures can
|
|
easily be verified using multiple CPU cores and modern elliptic curve batching techniques. Signature verification
|
|
has in the past been a bottleneck for verifying block chains, so this is a significant win. Corda smart contracts
|
|
are deliberately isolated from the underlying cryptography: they are run \emph{after} signature verification has
|
|
taken place and don't execute at all if required signatures are missing. This ensures that signatures for a single
|
|
transaction can be checked concurrently even though the smart contract code for the transaction itself must be
|
|
fully deterministic and thus doesn't have access to threading.
|
|
|
|
\subsection{Chain snipping}
|
|
|
|
In the case where the issuer of an asset is both trustworthy and online, they may exit and re-issue an asset state
|
|
back onto the ledger with a new reference field. This effectively truncates the dependency graph of that asset
|
|
which both improves privacy and scalability, at the cost of losing atomicity - it is possible for the issuer to
|
|
exit the asset but not re-issue it, either through incompetence or malice. However, usually the asset issuer is
|
|
trusted in much more fundamental ways than that, e.g. to not steal the money, and thus this doesn't seem likely to
|
|
be a big problem in practice.
|
|
|
|
Although the platform doesn't do this today, a node implementation could potentially snip chains automatically once
|
|
they cross certain lengths or complexity costs - assuming the issuer is online. Because they're optional, an extended
|
|
outage at the issuer would simply mean the snip happens later.
|
|
|
|
\subsection{Signatures of validity}
|
|
|
|
The overhead of checking a transaction for validity before it is notarised is likely to be the main overhead for
|
|
both notaries and nodes. In the case where raw throughput is more important than ledger integrity it is possible to use a
|
|
non-validating notary which doesn't do these checks. See~\cref{sec:non-validating-notaries}.
|
|
|
|
Using Intel SGX it's possible to reduce the load on notaries without compromising robustness by having the node itself
|
|
verify its own transaction using an enclave. The resulting `signature of validity' can then be checked using remote
|
|
attestation by the notary cluster, to ensure the verification work was done correctly. See~\cref{subsec:sgx}.
|
|
|
|
This outsourcing technique can also be used to run nodes on smaller devices that don't have any way to directly check
|
|
the ledger themselves. If a transaction is signed by a fully or semi-validating notary, or has an enclave signature of
|
|
validity on it, the transaction can be accepted as valid and the outputs processed directly. This can be considered
|
|
a more efficient equivalent to Bitcoin's `simplified payment verification' mode, as described in the original Bitcoin
|
|
white paper.
|
|
|
|
\subsection{JIT compilation}
|
|
|
|
It is common for blockchain systems to execute smart contract logic very slowly due to the lack of efficient
|
|
optimising compilers for their custom programming languages. Because Corda runs smart contract logic on a JVM it
|
|
benefits automatically from just-in-time compilation to machine code of contract logic. After a contract has been
|
|
encountered a few times it will be scheduled for conversion to machine code, yielding speedups of many orders of
|
|
magnitude. Contract logic only executed a few times will be run interpreted, avoiding the overhead of
|
|
compilation for rarely used business logic. The process is entirely transparent to developer, thus as JVMs improve
|
|
over time the throughput of nodes automatically gets better too. JVMs have over thousands of accumulated man-years
|
|
of work put into their optimising compilers already, and are still improving. The upgrade from Java 8 to Java 11
|
|
resulted in an immediate 20\% performance boost to the throughput of one node implementation. Because JVMs are
|
|
multi-language runtimes, these benefits also apply to a variety of non-Java languages that can also execute on it,
|
|
thus this benefit isn't invalidated by the use of DSLs as long as they compile to bytecode.
|
|
|
|
\subsubsection{Optimised and scalable data storage}
|
|
|
|
It's standard for classical DLT platforms to place all data in simple key/value stores. This is especially true for
|
|
Ethereum derivatives. This makes it difficult or impossible to do sophisticated queries, let alone do such queries
|
|
with good performance and in parallel. App developers are expected to handle data query implementation on their own.
|
|
|
|
Corda's extensive support for mapping strongly typed on-ledger data into relational database tables makes available
|
|
the decades of optimisations for querying data in scalable storage, including but not limited to:
|
|
|
|
\begin{itemize}
|
|
\item Query planners, which use continual profiling and statistical analysis to optimise the usage of IO
|
|
resources like disk seeks.
|
|
\item Multi-server databases with read replicas, enabling read throughput to be scaled to arbitrarily levels
|
|
by adding more hardware (writes of course must go through the ledger infrastructure, the scalability of
|
|
which is discussed above).
|
|
\item Multi-column indexing, JIT compilation of SQL to machine code, excellent monitoring and diagnostics tools.
|
|
\end{itemize}
|
|
|
|
\subsubsection{Additional scaling and performance techniques}
|
|
|
|
Corda also utilises a variety of smaller techniques that significantly improve scalability and optimise cost:
|
|
|
|
\begin{itemize}
|
|
\item Hardware accelerated AES/GCM encryption used for peer to peer traffic, when the CPU supports it.
|
|
\item Extremely modern and fast elliptic curve cryptography, using the carefully tuned Ed25519 curve.
|
|
\item Checkpoint elimination when flows are known to be idempotent and safely replayable. Corda is crash-safe
|
|
by default (something alternative platforms sometimes lack), but crash-safety can be optimised out when
|
|
analysis shows it is safe to do so.
|
|
\item Network map data is distributable via caching content delivery networks, and only changed entries are
|
|
fetched by nodes. This ensures the network map data for a Corda network can be easily distributed around
|
|
the world, making it hard to take down using denial-of-service attacks and cheap to serve.
|
|
\end{itemize}
|
|
|
|
\section{Privacy}\label{sec:privacy}
|
|
|
|
Privacy is not a standalone feature in the way that many other aspects described in this paper are, so this section
|
|
summarises features described elsewhere. Corda exploits multiple techniques to improve user privacy over other
|
|
distributed ledger systems:
|
|
|
|
\paragraph{Partial data visibility.}Transactions are not globally broadcast as in many other systems.
|
|
See~\cref{subsec:data-visibility-and-dependency-resolution}~and~\cref{subsec:partial-visibility}.
|
|
|
|
\paragraph{Transaction tear-offs.}Transactions are structured as Merkle trees, and may have individual
|
|
subcomponents be revealed to parties who already know the Merkle root hash. Additionally, they may sign the
|
|
transaction without being able to see all of it. See~\cref{sec:tear-offs}
|
|
|
|
\paragraph{Key randomisation.}The node's key management service generates and uses random keys that are unlinkable to an identity.
|
|
See~\cref{sec:vault}.
|
|
|
|
\paragraph{Graph pruning.}Large transaction graphs that involve liquid assets can be `pruned' by requesting the asset
|
|
issuer to re-issue the asset onto the ledger with a new reference field. This operation is not atomic, but effectively
|
|
unlinks the new version of the asset from the old, meaning that nodes won't attempt to explore the original dependency
|
|
graph during verification. See~\cref{sec:privacy}.
|
|
|
|
\paragraph{Global ledger encryption.} However the primary privacy effort revolves around encrypting the entire
|
|
ledger and validating it using secure hardware enclaves. This can provide the benefits of homomorphic encryption
|
|
and zero knowledge proofs, but without sacrificing scalability/performance or (crucially) auditability in case of
|
|
failure. See~\cref{subsec:sgx}.
|
|
|
|
\section{Future work}
|
|
|
|
Corda has a long term roadmap with many planned extensions. In this section we propose a variety of possible upgrades
|
|
that solve common technical or business problems. These designs are not fixed in stone and will evolve over time as
|
|
the community learns more about the best way to utilise the technology.
|
|
|
|
\subsection{Micronodes}\label{subsec:micronodes}
|
|
|
|
A micronode is a program that performs some but not all of the functions of a regular node. Micronodes may be suitable
|
|
for deployment on smartphones to enable consumer e-cash applications, or embedded in devices which wish to trade with
|
|
other machines autonomously.
|
|
|
|
A typical micronode avoids the resource and connectivity requirements of a full node by making the following compromises:
|
|
|
|
\begin{enumerate}
|
|
|
|
\item \textbf{Connectivity}. A micronode relies on another node's message queue broker to provide internet
|
|
connectivity, network map presence and querying, and message buffering.
|
|
|
|
\item \textbf{Verification}. A micronode doesn't fully resolve transactions. Instead it relies on signatures by
|
|
other entities that have verified the transactions, such as a fully verifying notary or SGX enclave
|
|
(see~\cref{subsec:sgx}).
|
|
|
|
\item \textbf{Dynamic loading}. A micronode has CorDapps baked into it when it's distributed. States and
|
|
contracts from other apps are ignored.
|
|
|
|
\item \textbf{Limited flow support}. A micronode may not support features like flow checkpointing, full
|
|
relational database access from inside flows or scheduled states.
|
|
|
|
\end{enumerate}
|
|
|
|
Because of these limits, apps must be specifically written to support running in a micronode environment. In cases where
|
|
that isn't possible micronode-targeted variants of an app must be written, much as mobile apps may share some code with
|
|
desktop apps but otherwise are separate codebases.
|
|
|
|
In return for accepting these limitations, a micronode would provide several benefits:
|
|
|
|
\begin{itemize}
|
|
|
|
\item \textbf{AOT compilation.} A micronode could be compiled ahead of time to native code, yielding very small
|
|
and efficient binaries. The \texttt{native-image} tool\footnote{A component of the GraalVM, see
|
|
\href{https://www.graalvm.org}{https://www.graalvm.org} for more information} can produce native code
|
|
binaries with no JVM dependencies and no JIT compilation.
|
|
|
|
\item \textbf{Much reduced resources.} The SubstrateVM JVM that \texttt{native-image} uses generally needs
|
|
around 10x less memory, starts around 10x faster than a normal Java program and can produce binaries as small
|
|
as a few megabytes in size even for quite complex programs. A micronode's vault is called a wallet and would
|
|
store only keys, states, directly relevant transactions (without dependencies) and potentially app specific
|
|
private data. This is plenty sufficient for many embedded use cases, although some demanding applications may
|
|
desire even smaller footprints.
|
|
|
|
\item \textbf{Transiency.} Micronodes can be mostly offline rather than mostly online and can automatically
|
|
encrypt and back up their wallets to hosting nodes.
|
|
|
|
\end{itemize}
|
|
|
|
For example, a micronode could be embedded in a desktop or mobile app. This would achieve a new balance of power,
|
|
different to that offered by a full node. In the new balance the user relies more heavily on the trustworthyness of
|
|
the nodes or enclaves that actually verify the transactions, as any breach of that trust would allow someone to
|
|
present an arbitrary view of the ledger e.g. forging payments of tokens that aren't backed by any actual deposits,
|
|
or changing the name on a record to their own. The micronode could choose to rely on multiple sources of
|
|
verification and compare them to reduce this risk. Even with compromised verification, the ability to change the
|
|
database from the perspective of full nodes is not obtained because the micronode will not sign transactions or
|
|
reveal data without user approval.
|
|
|
|
Making micronodes usable and safe would require significant work in at least three areas: key recovery
|
|
(\cref{subsec:social-key-recovery-and-key-rotation}), secure software update and the ability to move between
|
|
hosting nodes. It would also require designs for how users on a global Corda network can find each other
|
|
without directly exchanging public keys or key hashes, as is done in cryptocurrencies.
|
|
|
|
\subsubsection{Secure software update}
|
|
|
|
A micronode embedded into a mobile e-payments app doesn't automatically make the system decentralised. Rather, it
|
|
shifts all power to whoever controls the code signing key for the application itself. If that key is compromised
|
|
the adversary can push an update to the app that implants a back door in it. That back door could steal people's
|
|
private keys, or sign transactions with the keys that e.g. sends the users tokens to the attacker whilst presenting
|
|
a fake view of the ledger indicating that no such transfer has occurred. Alternatively the legitimate developer of
|
|
the app may be pressured, legally or extra-legally, to seize funds or block users/geographies.
|
|
|
|
To resolve this multi-party threshold software updates are required. Corda already implements this for on-ledger
|
|
code via signature constraints (see~\cref{sec:contract-constraints}), and Android supports multi-signed updates
|
|
(but not threshold updates) from Android 9 onwards. iOS does not, however it may be possible to retrofit this
|
|
capability using Shoup's threshold RSA algorithm\cite{shoup2000practical}.
|
|
|
|
As an illustrative example, one of the required signers may be an auditor who reads the source code and verifies
|
|
the natural language description of the application matches what it really does. The auditor may be under agreement
|
|
to refuse to sign an update that would cause the app to violate its `constitution'.
|
|
|
|
\subsection{Social key recovery and key rotation}\label{subsec:social-key-recovery-and-key-rotation}
|
|
|
|
In all blockchain systems loss of a private key is fatal. There is no global administrator who can restore access
|
|
to the system, and the difficulty of coordinating with all possible counterparties means there is no practical
|
|
way to replace a private key that has been destroyed.
|
|
|
|
Whilst this constraint may be viable for professionally run IT organisations it is infeasible for consumers, who
|
|
can be expected to lose keys regularly. Backing up their key to the hosting node simply means the hosting node
|
|
controls the identity and thus those parts of the ledger completely, making the micronode useless. Instead the key
|
|
may be split using Shamir's secret sharing scheme\cite{Shamir:1979:SS:359168.359176} and then distributed to a
|
|
group of parties the user trusts. This may be the user's friends or family, or alternatively a coalition of nodes
|
|
which are assumed to not collaborate against the user (e.g. notary nodes that agreed to take on this additional
|
|
function). In case of key loss the user must approach enough of the holders of the shards and ask them to send back
|
|
the fragments; the holders must verify the user's identity sufficiently well to prevent an imposter fooling them.
|
|
|
|
\paragraph{Key rotation.} If it's suspected that a key may be lost or compromised ahead of time, a backup key
|
|
may be generated and a key rotation message may be signed using the primary key. In case of loss of the primary
|
|
key, the backup key and rotation message may be retrieved from storage. The rotation message must be countersigned
|
|
by the network operator after (re)performing ID verification, to ensure that compromised storage can't be used to
|
|
rotate the live key to the adversary. It can then be announced to the network, so nodes can treat the new key as
|
|
being equivalent to the old key.
|
|
|
|
\subsection{Domain specific languages}
|
|
|
|
Domain specific languages for the expression of financial contracts are a popular area of research. A seminal work
|
|
is `Composing contracts' by Peyton-Jones, Seward and Eber [PJSE2000\cite{PeytonJones:2000:CCA:357766.351267}] in
|
|
which financial contracts are modelled with a small library of Haskell combinators. These models can then be used
|
|
for valuation of the underlying deals. Block chain systems use the term `contract' in a slightly different sense to
|
|
how PJSE do but the underlying concepts can be adapted to our context as well. The platform provides an
|
|
experimental \emph{universal contract} that builds on the language extension features of the Kotlin programming
|
|
language. To avoid linguistic confusion it refers to the combined code/data bundle as an `arrangement' rather than
|
|
a contract. A European FX call option expressed in this language looks like this:
|
|
|
|
\begin{kotlincode}
|
|
val european_fx_option = arrange {
|
|
actions {
|
|
acmeCorp may {
|
|
"exercise" anytime {
|
|
actions {
|
|
(acmeCorp or highStreetBank) may {
|
|
"execute".givenThat(after("2017-09-01")) {
|
|
highStreetBank.owes(acmeCorp, 1.M, EUR)
|
|
acmeCorp.owes(highStreetBank, 1200.K, USD)
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
highStreetBank may {
|
|
"expire".givenThat(after("2017-09-01")) {
|
|
zero
|
|
}
|
|
}
|
|
}
|
|
}
|
|
\end{kotlincode}
|
|
|
|
The programmer may define arbitrary `actions' along with constraints on when the actions may be invoked. The
|
|
\texttt{zero} token indicates the termination of the deal.
|
|
|
|
As can be seen, this DSL combines both \emph{what} is allowed and deal-specific data like \emph{when} and \emph{how
|
|
much} is allowed, therefore blurring the distinction the core model has between code and data. It builds on prior
|
|
work to enable not only valuation/cash flow calculations, but also direct enforcement of the contract's logic at
|
|
the database level as well.
|
|
|
|
\subsubsection{Formally verifiable languages}
|
|
|
|
Corda contracts can be upgraded. However, given the coordination problems inherent in convincing many participants
|
|
in a large network to accept a new version of a contract, a frequently cited desire is for formally verifiable
|
|
languages to be used to try and guarantee the correctness of the implementations.
|
|
|
|
We do not attempt to tackle this problem ourselves. However, because Corda focuses on deterministic execution of
|
|
any JVM bytecode, formally verifiable languages that target this instruction set are usable for the expression
|
|
of smart contracts. A good example of this is the Whiley language by Dr David Pearce\cite{Pearce2015191}, which
|
|
checks program-integrated proofs at compile time. By building on industry-standard platforms, we gain access to
|
|
cutting edge research from the computer science community outside of the distributed systems world.
|
|
|
|
\subsection{Secure signing devices}\label{sec:secure-signing-devices}
|
|
|
|
\subsubsection{Background}
|
|
|
|
A common feature of digital financial systems and block chain-type systems in particular is the use of secure
|
|
client-side hardware to hold private keys and perform signing operations with them. Combined with a zero tolerance
|
|
approach to transaction rollbacks, this is one of the ways they reduce overheads: by attempting to ensure that
|
|
transaction authorisation is robust and secure, and thus that signatures are reliable.
|
|
|
|
It can be useful to move signing keys into hardware controlled directly by authorising users. This ensures that
|
|
if a node is compromised, only private data leaks and the integrity of the ledger is maintained.
|
|
|
|
Many networks have rolled out two factor authenticators to their employees which allow logins to online services
|
|
using a challenge/response protocol, usually to a smartcard. These devices are cheap but tend to have small or
|
|
non-existent screens and so can be subject to confusion attacks if there is malware on the PC, e.g. if the malware
|
|
convinces the user they are performing a login challenge whereas in fact they are authorising a payment to a new
|
|
account. The primary advantage is that the signing key is held in a robust and cheap object that refuses to reveal
|
|
the contained keys, so a stolen authenticator can't be cloned.
|
|
|
|
The state-of-the-art in this space are devices like the TREZOR\cite{TREZOR} by Satoshi Labs or the Ledger Blue.
|
|
These were developed by and for the Bitcoin community. They are more expensive than ordinary two-factor devices and feature better
|
|
screens with USB or Bluetooth connections to eliminate typing. These devices differ from other forms of hardware
|
|
authenticator device in another respect: instead of signing challenge numbers, they actually understand the native
|
|
transaction format of the network to which they're specialised and parse the transaction to figure out the message
|
|
to present to the user, who then confirms that they wish to perform the action printed on the screen by simply
|
|
pressing a button. The transaction is then signed internally before being passed back to the PC.
|
|
|
|
As there is no smartcard equivalent the private key can be exported off the device by writing it down in the form
|
|
of ``wallet words'': 12 random words derived from the contents of the key. Because elliptic curve private keys
|
|
are small (256 bits), this is not as tedious as it would be with the much larger RSA keys that were standard until
|
|
recently.
|
|
|
|
\subsubsection{Confusion attacks}
|
|
|
|
The biggest problem facing anyone wanting to integrate smart signing devices into a distributed ledger system is
|
|
how the device processes transactions. For Bitcoin it's straightforward for devices to process transactions
|
|
directly because their format is very small and simple (in theory -- in practice a fixable quirk of the Bitcoin
|
|
protocol significantly complicates how these devices must work). Thus turning a Bitcoin transaction into a
|
|
human meaningful confirmation screen is quite easy:
|
|
|
|
\indent\texttt{Confirm payment of 1.23 BTC to 1AbCd0123456.......}
|
|
|
|
This confirmation message is susceptible to confusion attacks because the opaque payment address is unpredictable.
|
|
A sufficiently smart virus/attacker could have swapped out a legitimate address of a legitimate counterparty you
|
|
are expecting to pay with one of their own, thus you'd pay the right amount to the wrong place. The same problem
|
|
can affect financial authenticators that verify IBANs and other account numbers: the user's source of the IBAN may
|
|
be an email or website they are viewing through the compromised machine. The BIP 70\cite{BIP70} protocol was
|
|
designed to address this attack by allowing a certificate chain to be presented that linked a target key with a
|
|
stable, human meaningful and verified identity.
|
|
|
|
For a generic ledger we are faced with the additional problem that transactions may be of many different types,
|
|
including new types created after the device was manufactured. Thus creating a succinct confirmation message inside
|
|
the device would become an ever-changing problem requiring frequent firmware updates. As firmware upgrades are a
|
|
potential weak point in any secure hardware scheme, it would be ideal to minimise their number.
|
|
|
|
\subsubsection{Transaction summaries}
|
|
|
|
To solve this problem we add a top level summaries field to the transaction format (joining inputs, outputs,
|
|
commands, attachments etc). This new top level field is a list of strings. Smart contracts get a new
|
|
responsibility. They are expected to generate an English message describing what the transaction is doing, and then
|
|
check that it is present in the transaction. The platform ensures no unexpected messages are present. The field is
|
|
a list of strings rather than a single string because a transaction may do multiple things simultaneously in
|
|
advanced use cases.
|
|
|
|
Because the calculation of the confirmation message has now been moved to the smart contract itself, and is a part
|
|
of the transaction, the transaction can be sent to the signing device: all it needs to do is extract the messages
|
|
and print them to the screen with YES/NO buttons available to decide whether to sign or not. Because the device's
|
|
signature covers the messages, and the messages are checked by the contract based on the machine readable data in
|
|
the states, we can know that the message was correct and legitimate.
|
|
|
|
The design above is simple but has the issue that large amounts of data are sent to the device which it doesn't
|
|
need. As it's common for signing devices to have constrained memory, it would be unfortunate if the complexity of a
|
|
transaction ended up being limited by the RAM available in the users' signing devices. To solve this we can use the
|
|
tear-offs mechanism (see~\cref{sec:tear-offs}) to present only the summaries and the Merkle branch connecting them
|
|
to the root. The device can then sign the entire transaction contents having seen only the textual summaries,
|
|
knowing that the states will trigger the contracts which will trigger the summary checks, thus the signature covers
|
|
the machine-understandable version of the transaction as well.
|
|
|
|
Note, we assume here that contracts are not themselves malicious. Whilst a malicious user could construct a
|
|
contract that generated misleading messages, for a user to see states in their vault and work with them requires
|
|
the accompanying CorDapp to be loaded into the node as a plugin and thus whitelisted. There is never a case where
|
|
the user may be asked to sign a transaction involving contracts they have not previously approved, even though the
|
|
node may execute such contracts as part of verifying transaction dependencies.
|
|
|
|
\subsubsection{Identity substitution}
|
|
|
|
Contract code only works with opaque representations of public keys. Because transactions in a chain of custody may
|
|
need to be anonymised, it isn't possible for a contract to access identity information from inside the sandbox.
|
|
Therefore it cannot generate a complete message that includes human meaningful identity names even if the node
|
|
itself does have this information.
|
|
|
|
To solve this the transaction is provided to the device along with the X.509 certificate chains linking the
|
|
pseudonymous public keys to the long term identity certificates, which for transactions involving the user should
|
|
always be available (as they by definition know who their trading counterparties are). The device can verify those
|
|
certificate chains to build up a mapping of index to human readable name. The messages placed inside a transaction
|
|
may contain numeric indexes of the public keys required by the commands using backslash syntax, and the device must
|
|
perform the message substitution before rendering. Care must be taken to ensure that the X.500 names issued to
|
|
network participants do not contain text chosen to deliberately confuse users, e.g. names that contain quote marks,
|
|
partial instructions, special symbols and so on. This can be enforced at the network permissioning level.
|
|
|
|
\subsubsection{Multi-lingual support}
|
|
|
|
The contract is expected to generate a human readable version of the transaction. This should be in English, by
|
|
convention. In theory, we could define the transaction format to support messages in different languages, and if
|
|
the contract supported that the right language could then be picked by the signing device. However, care must be
|
|
taken to ensure that the message the user sees in alternative languages is correctly translated and not subject to
|
|
ambiguity or confusion, as otherwise exploitable confusion attacks may arise.
|
|
|
|
\subsection{Data distribution groups}
|
|
|
|
By default, distribution of transaction data is defined by app-provided flows (see~\cref{sec:flows}). Flows specify
|
|
when and to which peers transactions should be sent. Typically these destinations will be calculated based on the
|
|
content of the states and the available identity lookup certificates, as the intended use case of financial data
|
|
usually contains the identities of the relevant parties within it. Sometimes though, the set of parties that should
|
|
receive data isn't known ahead of time and may change after a transaction has been created. For these cases partial
|
|
data visibility is not a good fit and an alternative mechanism is needed.
|
|
|
|
A data distribution group (DDG) is created by generating a keypair and a self-signed certificate for it. Groups are
|
|
identified internally by their public key and may be given string names in the certificate, but nothing in the
|
|
software assumes the name is unique: it's intended only for human consumption and it may conflict with other
|
|
independent groups. In case of conflict user interfaces disambiguate by appending a few characters of the base58
|
|
encoded public key to the name like so: "My popular group name (a4T)". As groups are not globally visible anyway,
|
|
it is unlikely that conflicts will be common or require many code letters to deconflict, and some groups may not
|
|
even be intended for human consumption at all.
|
|
|
|
Once a group is created other nodes can be invited to join it by using an invitation flow. Membership can be either
|
|
read only or read/write. To add a node as read-only, the certificate i.e. pubkey alone is sent. To add a node as
|
|
read/write the certificate and private key are sent. A future elaboration on the design may support giving each
|
|
member a separate private key which would allow tracing who added transactions to a group, but this is left for
|
|
future work. In either case the node records in its local database which other nodes it has invited to the group
|
|
once they accept the invitation.
|
|
|
|
When the invite is received the target node runs the other side of the flow as normal, which may either
|
|
automatically accept membership if it's configured to trust the inviting node, or send a message to a message queue
|
|
for processing by an external system, or kick it up to a human administrator for approval. Invites to groups the
|
|
node is already a member of are rejected. The accepting node also records which node invited it. So, there ends up
|
|
being a two-way recorded relationship between inviter and invitee stored in their vaults. Finally the inviter side
|
|
of the invitation flow pushes a list of all the transaction IDs that exist in the group and the invitee side
|
|
resolves all of them. The end result is that all the transactions that are in the group are sent to the new node
|
|
(along with all dependencies).
|
|
|
|
Note that this initial download is potentially infinite if transactions are added to the group as fast or faster
|
|
than the new node is downloading and checking them. Thus whilst it may be tempting to try and expose a notion of
|
|
`doneness' to the act of joining a group, it's better to see the act of joining as happening at a specific point in
|
|
time and the resultant flood of transaction data as an ongoing stream, rather than being like a traditional file
|
|
download.
|
|
|
|
When a transaction is sent to the vault, it always undergoes a relevancy test, regardless of whether it is in a
|
|
group or not (see~\cref{sec:vault}). This test is extended to check also for the signatures of any groups the node
|
|
is a member of. If there's a match then the transaction's states are all considered relevant. In addition, the
|
|
vault looks up which nodes it invited to this group, and also which nodes invited it, removes any nodes that have
|
|
recently sent us this transaction and then kicks off a \texttt{PropagateTransactionToGroup} flow with each of them.
|
|
The other side of this flow checks if the transaction is already known, if not requests it, checks that it is
|
|
indeed signed by the group in question, resolves it and then assuming success, sends it to the vault. In this way a
|
|
transaction added by any member of the group propagates up and down the membership tree until all the members have
|
|
seen it. Propagation is idempotent -- if the vault has already seen a transaction before then it isn't processed
|
|
again.
|
|
|
|
The structure we have so far has some advantages and one big disadvantage. The advantages are:
|
|
|
|
\begin{itemize}
|
|
\item [Simplicity] The core data model is unchanged. Access control is handled using existing tools like signatures, certificates and flows.
|
|
\item [Privacy] It is possible to join a group without the other members being aware that you have done so. It is possible to create groups without non-members knowing the group exists.
|
|
\item [Scalability] Groups are not registered in any central directory. A group that exists between four parties imposes costs only on those four.
|
|
\item [Performance] Groups can be created as fast as you can generate keypairs and invite other nodes to join you.
|
|
\item [Responsibility] For every member of the group there is always a node that has a responsibility for sending you
|
|
new data under the protocol (the inviting node). Unlike with Kademlia style distributed hash tables, or Bitcoin style
|
|
global broadcast, you can never find yourself in a position where you didn't receive data yet nobody has violated the
|
|
protocol. There are no points at which you pick a random selection of nodes and politely ask them to do something for
|
|
you, hoping that they'll choose to stick around.
|
|
\end{itemize}
|
|
|
|
The big disadvantage is that it's brittle. If you have a membership tree and a node goes offline for a while, then
|
|
propagation of data will split and back up in the outbound queues of the parents and children of the offline node
|
|
until it comes back.
|
|
|
|
To strengthen groups we can add a new feature, membership broadcasts. Members of the group that have write access
|
|
may choose to sign a membership announcement and propagate it through the tree. These announcements are recorded in
|
|
the local database of each node in the group. Nodes may include these announced members when sending newly added
|
|
transactions. This converts the membership tree to a graph that may contain cycles, but infinite propagation loops
|
|
are not possible because nodes ignore announcements of new transactions/attachments they've already received.
|
|
Whether a group prefers privacy or availability may be hinted in the certificate that defines it: if availability
|
|
is preferred, this is a signal that members should always announce themselves (which would lead to a mesh).
|
|
|
|
The resulting arrangement may appear similar to a gossip network. However the underlying membership tree structure
|
|
remains. Thus when all nodes are online (or online enough) messages are guaranteed to propagate to everyone in the
|
|
network. You can't get situations where a part of the group has become split from the rest without anyone being
|
|
aware of that fact; an unlikely but possible occurrence in a gossip network. It also isn't like a distributed hash
|
|
table where data isn't fully replicated, so we avoid situations where data has been added to the group but stops
|
|
being available due to node outages. It is always possible to reason about the behaviour of the network and always
|
|
possible to assign responsibility if something goes wrong.
|
|
|
|
Note that it is not possible to remove members after they have been added to a group. We could provide a remove
|
|
announcement but it'd be advisory only: nothing stops nodes from ignoring it. It is also not possible to enumerate
|
|
members of a group because there is no requirement to do a membership broadcast when you join and no way to enforce
|
|
such a requirement.
|
|
|
|
% TODO: Nothing related to data distribution groups is implemented.
|
|
|
|
%\subsection{Merging networks}
|
|
%
|
|
%Because there is no single block chain, it is theoretically possible to merge two independent networks together by simply
|
|
%establishing two-way connectivity between their nodes then configuring each side to trust each other's network operators
|
|
%(and by extension their network parameters, certificate authorities and so on).
|
|
%
|
|
%This ability may seem pointless: isn't the goal of a decentralised ledger to have a single global database for
|
|
%everyone? It is, but a practical route to reaching this end state is still required. It is often the case that
|
|
%organisations perceived by consumers as being a single company are in fact many different entities cross-licensing
|
|
%branding, striking deals with each other and doing internal trades with each other. This sort of setup can occur
|
|
%for regulatory reasons, tax reasons, due to a history of mergers or just through a sheer masochistic love of
|
|
%paperwork. Very large companies can therefore experience all the same synchronisation problems a decentralised
|
|
%ledger is intended to fix but purely within the bounds of that organisation. In this situation the main problem to
|
|
%tackle is not malicious actors but rather heterogenous IT departments, varying software development practices,
|
|
%unlinked user directories and so on. Such organisations can benefit from gaining experience with the technology
|
|
%internally and cleaning up their own internal views of the world before tackling the larger problem of
|
|
%synchronising with the wider world as well.
|
|
%
|
|
%When merging networks, both sides must trust that each other's notaries have never signed double spends. When
|
|
%merging an organisation-private network into the global ledger it should be possible to simply rely on incentives
|
|
%to provide this guarantee: there is no point in a company double spending against itself. However, if more evidence
|
|
%is desired, a standalone notary could be run against a hardware security module with audit logging enabled. The
|
|
%notary itself would simply use a private database and run on a single machine, with the logs exported to the people
|
|
%running a global network for asynchronous post-hoc verification.
|
|
|
|
\subsection{Guaranteed data distribution}
|
|
|
|
In any global consensus system the user is faced with the question of whether they have the latest state of the
|
|
database. Programmers working with block chains often make the simplifying assumption that because there is no
|
|
formal map of miner locations and thus transactions are distributed to miners via broadcast, that they can listen
|
|
to the stream of broadcasts and learn if they have the latest data. Alas, nothing stops someone privately providing
|
|
a miner who has a known location with a transaction that they agree not to broadcast. The first time the rest of
|
|
the network finds out about this transaction is when a block containing it is broadcast. When used to do double
|
|
spending fraud this type of attack is known as a Finney Attack\cite{FinneyAttack}. Proof-of-work based systems rely
|
|
on aligned incentives to discourage such attacks: to quote the Bitcoin white paper, \emph{``He ought to find it
|
|
more profitable to play by the rules ... than to undermine the system and the validity of his own wealth.''} In
|
|
practice this approach appears to work well enough most of the time, given that miners typically do not accept
|
|
privately submitted transactions.
|
|
|
|
In a system without global broadcast things are very different: the notary clusters \emph{must} accept transactions
|
|
directly and there is no mechanism to ensure that everyone sees that the transaction is occurring. Sometimes this
|
|
doesn't matter: most transactions are irrelevant for you and having to download them just wastes resources. But
|
|
occasionally you do wish to become aware that the ledger state has been changed by someone else. A simple example
|
|
is an option contract in which you wish to expire the option unless the counterparty has already exercised it. Their
|
|
exercising the option must not require the seller to sign off on it, as it may be advantageous for the seller to
|
|
refuse if it would cause them to lose money. Whilst the seller would discover if the buyer had exercised the option
|
|
when they attempted to expire it, due to the notary informing them that their expiry transaction was a double
|
|
spend, it is preferable to find out immediately.
|
|
|
|
The obvious way to implement this is to give notaries the responsibility for ensuring all interested parties find
|
|
out about a transaction. However, this would require the notaries to know who the involved parties actually are,
|
|
which would create an undesirable privacy leak. It would also place extra network load on the notaries who would
|
|
frequently be sending transaction data to parties that may already have it, or may simply not care. In many cases
|
|
there may be no requirement for the notary to act as a trusted third party for data distribution purposes, as
|
|
game-theoretic assumptions or legal assurances are sufficiently strong that peers can be trusted to deliver
|
|
transaction data as part of their regular flows.
|
|
|
|
To solve this, app developers can choose whether to request transaction distribution by the notary or not. This
|
|
works by simply piggybacking on the standard identity lookup flows (see~\cref{sec:identity}). If a node
|
|
wishes to be informed by the notary when a state is consumed, it can send the certificates linking the random keys
|
|
in the state to the notary cluster, which then stores it in the local databases as per usual. Once the notary
|
|
cluster has committed the transaction, key identities are looked up and any which resolve successfully are sent
|
|
copies of the transaction. In normal operation the notary is not provided with the certificates linking the random
|
|
keys to the long term identity keys and thus does not know who is involved with the operation (assuming source IP
|
|
address obfuscation would be implemented, see~\cref{subsec:privacy-upgrades}).
|
|
|
|
\subsection{Privacy upgrades}\label{subsec:privacy-upgrades}
|
|
|
|
Corda has been designed with the future integration of additional privacy technologies in mind. Of all potential
|
|
upgrades, three are particularly worth a mention.
|
|
|
|
\paragraph{Secure hardware.}Although we narrow the scope of data propagation to only nodes that need to see that
|
|
data, `need' can still be an unintuitive concept in a decentralised database where often data is required only to
|
|
perform security checks. We have successfully experimented with running contract verification inside a secure
|
|
enclave protected JVM using Intel SGX\texttrademark~, an implementation of the `trusted computing'
|
|
concept\cite{mitchell2005trusted}, and this work is now being integrated with the platform.
|
|
See~\cref{subsec:global-ledger-encryption}.
|
|
|
|
\paragraph{Mix networks.}Some nodes may be in the position of learning about transactions that aren't directly
|
|
related to trades they are doing, for example notaries or regulator nodes. Even when key randomisation is used
|
|
these nodes can still learn valuable identity information by simply examining the source IP addresses or the
|
|
authentication certificates of the nodes sending the data for notarisation. The traditional cryptographic solution
|
|
to this problem is a \emph{mix network}\cite{Chaum:1981:UEM:358549.358563}. The most famous mix network is Tor, but
|
|
a more appropriate design for Corda would be that of an anonymous remailer. In a mix network a message is
|
|
repeatedly encrypted in an onion-like fashion using keys owned by a small set of randomly selected nodes. Each
|
|
layer in the onion contains the address of the next `hop'. Once the message is delivered to the first hop, it
|
|
decrypts it to reveal the next encrypted layer and forwards it onwards. The return path operates in a similar
|
|
fashion. Adding a mix network to the Corda protocol would allow users to opt-in to a privacy upgrade, at the cost
|
|
of higher latencies and more exposure to failed network nodes.
|
|
|
|
\paragraph{Zero knowledge proofs.}The holy grail of privacy in decentralised database systems is the use of zero
|
|
knowledge proofs to convince a peer that a transaction is valid, without revealing the contents of the transaction
|
|
to them. Although these techniques are not yet practical for execution of general purpose smart contracts, enormous
|
|
progress has been made in recent years and we have designed our data model on the assumption that we will one day
|
|
wish to migrate to the use of \emph{zero knowledge succinct non-interactive arguments of knowledge}\cite{184425}
|
|
(`zkSNARKs'). These algorithms allow for the calculation of a fixed-size mathematical proof that a program was
|
|
correctly executed with a mix of public and private inputs. Programs can be expressed either directly as a system
|
|
of low-degree multivariate polynomials encoding an algebraic constraint system, or by execution on a simple
|
|
simulated CPU (`vnTinyRAM') which is itself implemented as a large pre-computed set of constraints. Because the
|
|
program is shared the combination of an agreed upon function (i.e. a smart contract) along with private input data
|
|
is sufficient to verify correctness, as long as the prover's program may recursively verify other proofs, i.e. the
|
|
proofs of the input transactions. The BCTV zkSNARK algorithms rely on recursive proof composition for the execution
|
|
of vnTinyRAM opcodes, so this is not a problem. The most obvious integration with Corda would require tightly
|
|
written assembly language versions of common smart contracts (e.g. cash) to be written by hand and aligned with the
|
|
JVM versions. Less obvious but more powerful integrations would involve the addition of a vnTinyRAM backend to an
|
|
ahead of time JVM bytecode compiler, such as Graal\cite{Graal}, or a direct translation of Graal's graph based
|
|
intermediate representation into systems of constraints. Direct translation of an SSA-form compiler IR to
|
|
constraints would be best integrated with recent research into `scalable probabilistically checkable
|
|
proofs'\cite{cryptoeprint:2016:646}, and is an open research problem.
|
|
|
|
\subsection{Machine identity}\label{subsec:machine-identity}
|
|
|
|
On-ledger transactions may sometimes be intimately connected to the state of physical objects. Consider the example
|
|
of an electric car being plugged into a recharging port. The owner of the port wishes to bill the owner of the
|
|
vehicle for consumed power, but in a manner that minimises trust. Minimising trust is useful as it allows the
|
|
owner of the recharging port to do without any expensive brand-building and keeps enrollment overheads for the
|
|
vehicle owners low. The result would be an open access charging network. To achieve this various security and
|
|
privacy requirements should be met, for example:
|
|
|
|
\begin{itemize}
|
|
\item The recharging port may over-bill the vehicle owner.
|
|
\item The vehicle owner may misreport their identity, in order that someone else incurs the costs.
|
|
\item The machine being plugged in might not be a vehicle at all, which could be problematic if the business
|
|
model of the port owner assumes a temporary stop by the driver (for instance, nearby shops may be
|
|
subsidising power).
|
|
\item The vehicle owner may not pay.
|
|
\item Vehicle manufacturers should not learn anything about where the drivers are going.
|
|
\end{itemize}
|
|
|
|
Solving this requires authenticated data from identified sensors to be integrated with the flows and states of an
|
|
application. One way to do this would be for the manufacturer to embed a key pair into the sensors and then issuing
|
|
a sub-certificate at the factory which chains to the manufacturer's identity. Device-specific connectivity to the
|
|
manufacturer node would allow the sensors to be reached via the flow framework, and they can then act as oracles
|
|
for the state of the physical system e.g. how much power has flowed through the recharging cable. The identity
|
|
framework solves the question of device authenticity, filtered transactions solve the question of how to check and
|
|
sign transactions on lower power devices, and the flow framework solves the challenge of having nodes contact
|
|
sensors or vice-versa across potentially multiple layers of routers, proxies, message queues etc. Because the Corda
|
|
protocol is built on top of standard AMQP, a subset of it can be implemented in C++ for lightweight devices without
|
|
much CPU power. A prototype of such a library already exists.
|
|
|
|
\subsection{Data streams}\label{subsec:data-streams}
|
|
|
|
Transaction attachments are available to contract logic during verification. As a result they suffer from various
|
|
constraints: they must be ZIP files, they must fit in memory on all nodes, they must obey various security
|
|
properties, they must be propagated everywhere the transaction itself is, and so on. Sometimes it's desirable to
|
|
attach raw data files to transactions that are \emph{not} used in forming consensus, but rather are only included
|
|
for audit trail and signing purposes. This can be done today by just including the hash of a data file in a state
|
|
but it would be convenient if the protocol took care of sending the underlying data between nodes and making it
|
|
available to application developers. \emph{Data streams} are a proposed feature that allows Java
|
|
\texttt{InputStream} objects to be added to transactions. The RPC client library is enhanced to support sending
|
|
streams across RPC/MQ connections, and the node incrementally hashes the contents of the stream and stores it
|
|
locally, embedding the final hash into the transaction where it will be covered by a signature. The data is then
|
|
streamed across the peer-to-peer network without ever being stored fully in memory, and the stream is checked
|
|
against the included transaction hash to ensure it matches.
|
|
|
|
Importantly, the stream is transmitted only one hop: it isn't copied as part of transaction resolution. This makes
|
|
the feature ideal for various kinds of file that would be inappropriate to place in attachments, such as:
|
|
|
|
\begin{itemize}
|
|
\item Large PDFs, like scans of paper documents.
|
|
\item Audio recordings of employee conversations for compliance with trader surveillance rules.
|
|
\item Spreadsheets containing underlying trade models.
|
|
\item Photos, videos or 3D models of the items being transacted, for later use in dispute resolution.
|
|
\end{itemize}
|
|
|
|
\subsection{Human interaction}
|
|
|
|
As well as multi-party protocols, a common need is to model flows with higher level business processes which may
|
|
include human interaction. This would be helpful for:
|
|
|
|
\begin{itemize}
|
|
\item Gaining approval to proceed with a ledger change if it meets certain criteria, like being too large
|
|
to automatically authorise.
|
|
\item Requesting simple pieces of information from users, like files, prices, quantities etc.
|
|
\item Notifying people of work they need to do.
|
|
\end{itemize}
|
|
|
|
Today such tasks can be achieved by splitting a flow up and having UI logic update shared database tables. However,
|
|
this would be much more convenient if flows could send and receive messages with people and not just other nodes.
|
|
Whilst no replacement for a full GUI, many common tasks could be handled in this way.
|
|
|
|
We propose a design based on message queues. The flow API would be extended to support sending and receiving serialised
|
|
objects (or raw strings) on internal queues. A library of adapter processes can then be configured to listen on these
|
|
queues and take requests from them, with the responses (if required) being placed back on a dedicated response queue.
|
|
These adapters could, for example, create tickets in an internal ticketing system, push notifications to a smartphone
|
|
app, update in-house applications, post to shared chatrooms and so on.
|
|
|
|
Individuals and groups of individuals within an organisation could be modelled as parties that can be looked up via a
|
|
directory service, similar to how parties can be resolved from the network map. Note that there'd be no requirement
|
|
for users to have keys in this scheme: whether a user has a key and signs transactions or whether they just instruct
|
|
the app about what to do is up to the application developer.
|
|
|
|
\subsection{Global ledger encryption}\label{subsec:global-ledger-encryption}
|
|
|
|
All distributed ledger systems require nodes to cross-check each others changes to the ledger by verifying
|
|
transactions, but this inherently exposes data to peers that would be best kept private. Scenario specific
|
|
`ad-hoc' techniques can reduce leakage by homomorphically encrypting amounts and obfuscating identities
|
|
(see~\cref{subsec:confidential-identities}), but they impose great complexity on application developers and
|
|
don't provide a universal solution: most research has focused on tokens and provides limited or no value to
|
|
non-token states.
|
|
|
|
This section outlines a design for a platform upgrade which encrypts all transaction data, leaving only individual
|
|
states exposed to authorised parties. The encrypted transactions are still verified and thus ledger integrity is
|
|
still assured. This section provides details on the design which is being implemented at the moment.
|
|
|
|
\subsubsection{Intel SGX}\label{subsec:sgx}
|
|
|
|
Intel \emph{Software Guard Extensions}\cite{SGX} is a new feature supported in the latest generation of Intel CPUs.
|
|
It allows applications to create so-called \emph{enclaves}. Enclaves have the following useful properties:
|
|
|
|
\begin{itemize}
|
|
\item They have isolated memory spaces which are accessible to nothing except code running in the enclave
|
|
itself.
|
|
\item Enclave RAM is encrypted and decrypted on the fly by the CPU core, which has anti-tamper
|
|
circuitry in it. Thus physical access to the hardware is not sufficient to be able to read enclave memory.
|
|
\item Enclaves have an identity, being either the hash of the code that is loaded into them at creation time
|
|
or the public key that signed the enclave.
|
|
\item This identity can be reported over a network to third parties via a process named \emph{remote attestation}.\
|
|
The CPU generates a data structure signed by a key that can be traced back to Intel's fabrication plants.
|
|
\item Enclaves can deterministically derive secret keys that mix together a unique, hidden per-CPU key and the
|
|
enclave identity itself; by implication enclaves can derive keys that no other software on the system can
|
|
access. These keys can be bound to remote attestations.
|
|
\end{itemize}
|
|
|
|
Combining these features enables enclaves to act almost like secure self-defending computers embedded inside other
|
|
untrusted hosts. A client (``Alice'') can challenge an untrusted host machine (``Bob'') to create an enclave with a
|
|
pre-agreed code hash or code signer. Bob can then prove to Alice the enclave is running by showing her a remote
|
|
attestation `report': a data structure which includes both her challenge and an enclave key, collectively signed by
|
|
an Intel approved key. Alice and the enclave can now execute a key agreement protocol like Elliptic
|
|
Curve Diffie-Hellman to compute a shared AES key that Bob doesn't know, and in this way establish an encrypted
|
|
channel to the enclave. Other parties can repeat this procedure and thus end up with a secure shared computational
|
|
space in which they can collaborate together.
|
|
|
|
SGX enclaves are secure as long as the SGX implementation in the CPU is secure, the software running inside the
|
|
enclave is secure (e.g. no buffer overflows) and as long as side-channel attacks are sufficiently mitigated. Other
|
|
software and hardware running on the host such as the operating system, other apps, the BIOS, video chips and so on
|
|
are considered to be untrusted. By implication enclaves can't access the operating system or any hardware directly:
|
|
they may communicate only by sending messages to the untrusted host software which ask it to do work. Enclaves thus
|
|
need to encrypt and sign any data entering/leaving the enclave.
|
|
|
|
SGX is designed with a sophisticated versioning scheme that allows it to be re-secured in case flaws in the
|
|
technology are found; as of writing this ``TCB recovery'' process has been used several times\footnote{See slide 18
|
|
in \href{https://www.slideshare.net/DesmondYuen/intel-software-guard-extension}{this presentation} for more
|
|
information on TCB recovery.}.
|
|
|
|
A remote attestation report can be attached to a piece of data to create a \emph{signature of attestation} (SoA).
|
|
Such a signature is conceptually like a normal digital signature and in fact may contain a regular digital signature
|
|
as part of its structure, however, whereas a normal digital signature proves a particular party signed the message,
|
|
a signature of attestation proves that a piece of software signed the message. Thus a SoA transmits arbitrary
|
|
semantic meaning that would otherwise need to be obtained via trusting a third party, such as an oracle.
|
|
|
|
An objection may be raised that there's still a third party involved in this scheme, namely Intel. But this
|
|
is not a worrying problem because in any software system you implicitly trust the CPU to calculate results
|
|
correctly anyway, and modern CPUs certainly have sufficient flexibility in their microcode architecture to detect
|
|
particular code sequences and calculate the wrong answer when found. Thus minimising the number of trusted parties
|
|
to \emph{only} the CPU vendor is still a major step forward from the status quo.
|
|
|
|
\subsubsection{Attestation vs verification models}
|
|
|
|
SGX enclaves can be used in two different ways to provide ledger privacy. We name these different approaches the
|
|
\emph{attestation model} and the \emph{verification model}, after what desirable attribute you lose if the
|
|
enclave's security is breached.
|
|
|
|
Consider a scenario in which Alice wishes to transfer a state to Bob. Alice has herself received the state from
|
|
Zack, a third party Bob should not learn anything about. The state contains complex structured business data thus
|
|
rendering token-specific privacy techniques insufficient.
|
|
|
|
\paragraph{Attestation model.}The simplest way to use SGX is for Alice to create an enclave on her own computer that
|
|
knows how to deserialize and verify transactions. Enclaves produce \emph{signatures of validity}, which are
|
|
signatures of attestation by an enclave binary marked as trusted by the Corda network operator and which sign over
|
|
the Merkle root of the verified transaction. This implies the enclave must include a small SGX compatible JVM (such
|
|
a JVM has been built). Alice feeds a transaction to the enclave along with signatures of validity for each of the
|
|
transaction's inputs, and a new signature of validity is produced by the enclave which can be checked by
|
|
any third party to convince themselves that a genuine Corda verification enclave was used.
|
|
|
|
In the attestation model transaction data doesn't move between peers at all. Only signatures of validity are
|
|
transmitted over the peer-to-peer network. This has the following advantages:
|
|
|
|
\begin{itemize}
|
|
\item Some countries have regulations that forbid transmission of financial data, even encrypted, outside their
|
|
own borders. The attestation model can handle such cases.
|
|
\item Transaction resolution and verification becomes much faster, as only one transaction must be checked
|
|
instead of an arbitrarily deep dependency graph.
|
|
\item It becomes possible for nodes to check transactions `from the future' and thus maybe survive mandatory
|
|
software upgrades imposed by the network operator, as transaction verification can be outsourced to
|
|
third party enclaves.
|
|
\item Side channel attacks on the verification enclave are much less serious, because Alice would only be
|
|
attacking her own transaction. She never has other party's transaction data.
|
|
\item Signatures of validity allow a non-validating notary to be upgraded to being `semi-validating', thus
|
|
blocking denial-of-state attacks without leaking private data to the notary.
|
|
\item It is relatively simple to implement.
|
|
\end{itemize}
|
|
|
|
Unfortunately the attestation model has one large disadvantage that makes it undesirable to support as the
|
|
only available model: if a flaw in the enclave or SGX itself is found, it becomes possible for an attacker to edit
|
|
the ledger as they see fit. Because nodes aren't actually cross checking each other any more, but placing full
|
|
confidence in the enclave to assert validity, anyone who can forge signatures of validity could create money out of
|
|
thin air. This security model is thus the same as for zero knowledge proofs, for which algorithmic failures are
|
|
also unauditable.
|
|
|
|
In practice both a verification enclave and SGX itself are complex systems that are unlikely to be bug free. Flaws
|
|
will be found and fixed over the lifetime of the system, and the design of SGX anticipates that. Indeed, such flaws
|
|
have already been found. In the attestation model the ledger cannot recover from a discovered flaw: doubt over
|
|
the integrity of the database would persist permanently.
|
|
|
|
This problem motivates the desire for a second model.
|
|
|
|
\paragraph{Verification model.}This model is significantly more complex. In it, Bob uses remote attestation to
|
|
convince Alice that he is running an enclave that can verify third party transaction data without leaking it to
|
|
him. Once convinced, Alice encrypts Zack's transaction to the enclave and sends it to Bob's computer. Bob then
|
|
feeds the encrypted transaction to the enclave, and the enclave signals to Bob that it believes the transaction to
|
|
be valid.
|
|
|
|
The complexity stems from the recursive nature of this process. Alice received the transaction from Zack, who may
|
|
in turn have obtained the state via a transaction with Yvonne, thus neither Alice nor Zack may actually have a
|
|
cleartext copy of the transaction Bob needs. Moreover Bob must be able to verify the chain of custody leading
|
|
through Alice, Zack and Yvonne using the regular transaction resolution process
|
|
(see section~\cref{subsec:data-visibility-and-dependency-resolution}). Thus Alice, Zack and Yvonne must all have
|
|
enclaves themselves or be using an outsourced third party enclave, as with SGX it theoretically doesn't matter
|
|
who owns the actual hardware on which they run. These enclaves establish encrypted channels between each other
|
|
along the chain of custody and also save encrypted transactions to their local storage.
|
|
|
|
A simplified version of the protocol looks like this:
|
|
|
|
\begin{enumerate}
|
|
\item Alice constructs a new transaction consuming a state she previously received and outputting a new state,
|
|
newly involving Bob, with arbitrary adjustments to the state in question. The transaction input points
|
|
to the transaction Alice received the state in from Zack.
|
|
\item Bob checks the inputs to see if he already knows about the chain of custody. He doesn't, so he
|
|
instantiates his enclave and sends a remote attestation of it to Alice. The attestation includes an enclave
|
|
specific encryption key.
|
|
\item Alice checks the attestation and sees that the enclave Bob is running is one agreed beforehand
|
|
to be usable for transaction checking. Typically this agreement would occur via the network parameters
|
|
mechanism as it must be acceptable to every node in the network (the set of allowed enclaves is a
|
|
consensus rule).
|
|
\item Alice now instructs her own enclave to load the requested transaction ID from her encrypted local storage
|
|
and \emph{re}-encrypt it to the key of Bob's enclave. She sends the newly re-encrypted version to Bob,
|
|
who then stores it. This process iteratively repeats until the dependency graph is fully explored and Bob
|
|
has encrypted versions of all the transactions in the chains of custody.
|
|
\item Bob now feeds these encrypted transactions to his enclave, oldest first. The enclave runs the contract
|
|
logic and does all the other tasks involved in verifying transaction validity, until the dependencies
|
|
of Alice's new transaction are fully verified. Bob can now verify Alice's transaction and be convinced
|
|
it is valid. Bob stores the new transaction locally so it can be encrypted to the next enclave in the
|
|
chain.
|
|
\end{enumerate}
|
|
|
|
The above description is incomplete in many ways. A real implementation will hide \emph{all} transactions and
|
|
expose only states via the node's API - the head of the chain is never special in such a design. Enclaves need to
|
|
store data locally under different keys than the ones used for communication, implying another re-encryption step.
|
|
Unlike the attestation model the verification model doesn't improve the speed or scaling of the resolution
|
|
process, and encrypted data still moves between nodes. And side channel attacks must be mitigated, as Bob could
|
|
attempt to learn things about the contents of encrypted transactions by taking careful measurements of the
|
|
enclave's execution as it validates the chain of custody.
|
|
|
|
Despite these disadvantages, the verification model comes with a major improvement: breaches of enclave security
|
|
allow private data to be accessed but do \emph{not} grant any special write privileges. As data gets progressively
|
|
less valuable as it ages this means recovery from breaches happens naturally and organically; eventually none of
|
|
the data exposed by a breach matters much any more, and at any rate, a breach only reverts the system to the level
|
|
of security it had pre-SGX. Therefore trading can continue even in the event of a zero-day exploit being
|
|
discovered. In contrast, if data integrity is lost there is no way to recover it (illegally minted money may
|
|
continue to circulate for years).
|
|
|
|
\paragraph{Mixed mode.}The two modes can be combined in the same network. For example, the attestation model can be used
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if data were to cross borders with verification being the default for when data would stay within a country.
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Semi-validating notaries could operate in a network for which other nodes are running verification. The
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exact blend of security tradeoffs a group of nodes may tolerate can be set by the network operator via its usual
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governance processes. Mixed mode is also useful during incremental rollout of ledger encryption to an already live
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Corda network.
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\paragraph{Other uses.}Enclaves can provide neutral meeting grounds in which shared calculations or negotiations
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can occur. By integrating enclave messaging and remote attestation with the flow and identity frameworks, enclave
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programming becomes significantly easier. With this type of framework integration enclaves would be exposed to
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CorDapp developers as, essentially, deterministic programmatic organisations. Enclaves would be able to communicate
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with counterparties, sign transactions, keep secrets, hold assets and potentially even move themselves around
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between generic hosting providers, whilst convincing human-operated organisations that they will behave honestly.
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Autonomous agents running inside node enclaves may also be trusted to have access to the globally encrypted ledger
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in order to derive economic statistics, detect trading optimisations and potentially speculate on the markets
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directly.
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\section{Conclusion}\label{sec:conclusion}
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We have presented Corda, a decentralised database designed for industrial use cases. It allows for a consistent
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data set to be decentralised amongst many mutually distrusting nodes, with smart contracts running on the JVM providing
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access control and schema definitions. A novel continuation-based persistence framework assists developers with
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coordinating the flow of data across the network. An identity management system ensures that parties always know
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who they are interacting with. Notaries ensure algorithmic agility with respect to distributed consensus systems, and
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the system operates without mining or chains of blocks.
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A standard type system is provided for the modelling of business logic. The design considers security throughout:
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it supports the integration of secure signing devices for transaction authorisation, secure enclaves for
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transaction processing, composite keys for expressing complex authorisation policies, and is based on binary
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protocols with length-prefixed buffers throughout for the systematic avoidance of common buffer management
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exploits. Users may analyse ledger data relevant to them by issuing ordinary SQL queries against mature database
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engines, and may craft complex multi-party transactions with ease in programming languages that are already
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familiar to them.
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Finally, we have laid out a roadmap of future work intended to enhance the platform's privacy, security, robustness
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and flexibility.
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\section{Acknowledgements}
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The authors would like to thank James Carlyle, Shams Asari, Rick Parker, Andras Slemmer, Ross
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Nicoll, Andrius Dagys, Matthew Nesbit, Jose Coll, Katarzyna Streich, Clinton Alexander, Patrick Kuo, Richard Green,
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Ian Grigg, Mark Oldfield and Roger Willis for their insights and contributions to this design. We would also like
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to thank Sofus Mortesen for his work on the universal contract DSL, and the numerous architects and subject matter
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experts at financial institutions around the world who contributed their knowledge, requirements and ideas. Thanks
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also to the authors of the many frameworks, protocols and components we have built upon.
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Finally, we would like to thank Satoshi Nakamoto. Without him none of it would have been possible.
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\bibliographystyle{unsrt}
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\bibliography{Ref}
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\end{document}
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