General Purpose Atomic Crosschain Transactions Protocol
This repo contains the General Purpose Atomic Crosschain Transactions (GPACT) protocol implementation and associated protocols. It contains Solidity contracts, Java library code, test code, and example code. It contains Docker files to run multiple blockchains using Hyperledger Besu so that the entire system can be run on a laptop computer. The GPACT Protocol is described in this paper: https://arxiv.org/abs/2011.12783.
Crosschain Protocol Layers
GPACT forms part of an overall crosschain protocol stack as shown in the diagram below. The links in the table below will take you to implementations of those parts of the protocol stack.
| Crosschain Protocol Layer | GPACT (Atomic Updates) |
SFC (Not Atomic Updates) |
|---|---|---|
| Crosschain Application Layer | Examples: Conditional Execution Hotel Train problem (3 blockchains) Read across chains ERC 20 Bridge Trade-Finance (5 blockchains) Write across chains |
Examples: ERC 20 Bridge ERC 721 Bridge Write across chains |
| Applications: ERC 20 Bridge |
Applications: ERC 20 Bridge ERC 721 Bridge |
|
| Helper contracts: Lockable storage |
||
| Crosschain Function Call Layer | Interfaces: Solidity Contracts, Java SDK | |
| General Purpose Atomic Crosschain Transaction (GPACT): Solidity Contracts, Java SDK |
Simple Function Call (SFC):
Solidity Contracts,
Java SDK |
|
| Crosschain Messaging Layer |
Interfaces:
Solidity Contracts,
Java SDK |
|
|
Messaging implementations: Event Attestation: Solidity Contracts, Java SDK Transaction Receipt Root Transfer: Solidity Contracts, Java SDK Event Relay: Solidity Contracts Services: Relayer / Attestor |
||
Applications use the Crosschain Function Call code to execute function calls across blockchains. Crosschain Function Call code uses Crosschain Message Verification to ensure information from one blockchain is trusted on another blockchain. The layers of the protocol stack are separated by interfaces. Using common interfaces allows applications to use a variety of crosschain function call implementations, and for crosschain function call implementations to use a variety of crosschain messaging implementations. Importantly, this allows for different crosschain messaging systems to be used for different blockchains and rollups. It allows applications to choose use lighter weight non-atomic function call approaches (which may be less costly and have lower latency) for low cost and less important transactions and fully atomic protocols such as GPACT for more important business critical transactions.
Applications that are written for atomic crosschain function protocols will be different to non-atomic function call protocols, because the non-atomic implementations need to handle failures where an execution occurs on a source blockchain by not a destination blockchain.
It is expected that more Crosschain Messaging and Crosschain Function Call implementations will be written. Additionally, more example application code will be written. Please get in contact if you are interested in writing an implementation or an example.
GPACT
The General Purpose Atomic Crosschain Transaction protocol is a blockchain technology that allows function calls across blockchains that either updates state on all blockchains or discards state updates on all blockchains. The function calls can update state on each blockchain and return values across blockchains. The protocol enables applications to access information and utilise functionality that resides on one blockchain from other blockchains. Unlike previous atomic crosschain protocols that only offer atomic asset swaps, this protocol allows for general purpose application logic.
The figure above shows a logical representation of a crosschain call graph using the protocol.
A trade finance application creates a crosschain function
call that goes across five contracts on five blockchains to execute a trade for a shipment of goods.
The Root Transaction executes the entry point function, the executeTrade function in the
Trade Wallet contract on the Wallet blockchain. The Trade Wallet contract could be a
multi-signatory wallet that parties to a shipment have to submit a transaction to, indicating that they agree
a shipment for a certain quantity of goods has been made and should be paid for. The
executeTrade function calls the shipment function in the Logic contract on the Terms blockchain
to determine the price that should be paid and to affect the transfer of stock and payment. The
shipment function calls the getPrice function on the Oracle contract on the Price Oracle
blockchain to determine the price that should be paid for the goods, then calls the transfer
function on the Balances contract on the Finance blockchain to affect the payment, and finally
calls the delivery function on the Stock contract on the Logistics blockchain to register the
changed ownership of the goods.
It could be argued that some of the contracts could exist on the one blockchain, thus reducing
the need for crosschain transactions. However, the Finance blockchain and the Logistics
blockchain in particular could be consortium blockchains involving different participants.
The Price Oracle blockchain could be operated by a consortium that charged for access to the
information. Government regulators could require the logic on the Terms blockchain visible to
them, but the participants in the trade wallet on the Wallet blockchain may wish to remain
anonymous. A crosschain transaction capability is needed to meet these requirements.