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EIP-1921: dType Functions Extension Source

AuthorLoredana Cirstea, Christian Tzurcanu
Discussions-Tohttps://github.com/ethereum/EIPs/issues/1921
StatusStagnant
TypeStandards Track
CategoryERC
Created2019-04-06
Requires 1900

Simple Summary

In the context of dType, the Decentralized Type System described in EIP-1900, we are proposing to add support for registering functions (with a preference for pure and view) in the dType Registry.

Abstract

This proposal is part of a series of EIPs focused on expanding the concept of a Decentralized Type System, as explained in EIP-1900. The current EIP specifies the data definitions and interfaces needed to support registering individual smart contract functions, as entries in the dType Registry.

Motivation

In order to evolve the EVM into a Singleton Operating System, we need a way to register, find and address contract functions that we want to run in an automated way. This implies having access to all the data needed to run the function inside the EVM.

Aside from the above motivation, there are also near future benefits for this proposal. Having a globally available, non-custodial functions registry, will democratize the development of tools, such as those targeting: blockchain data analysis (e.g. block explorers), smart contract IDEs, security analysis of smart contracts.

Registering new smart contract functions can be done through the same consensus mechanism as EIP-1900 mentions, in order to avoid burdening the chain state with redundant or improper records.

Specification

This specification targets pure and view functions.

For each function, we can store:

  • name - type string unique function name, as defined in EIP-1900; required
  • types - the type data and label of each input, as defined in EIP-1900; required
  • outputs - the type data and label of each output; required
  • contractAddress - type address - smart contract where the function resides, as defined in EIP-1900; optional for interfaces
  • source - type bytes32 - reference to an external file containing the function source code, as defined in EIP-1900; optional

Therefore, this proposal adds outputs to the EIP-1900 type registration definition.

An example of a function registration object for the dType registry is:

{
    "name": "setStaked",
    "types": [
        {"name": "TypeA", "label": "typeA", "relation":0, "dimensions":[]}
    ],
    "typeChoice": 4,
    "contractAddress": <address of the deployed smart contract where the function is defined>,
    "source": <bytes32 hash for referencing source files>,
    "outputs": [
        {"name": "TypeB", "label": "typeB", "relation":0, "dimensions":[]}
    ]
}

The above object will be passed to <dType registry>.insert({...})

An additional setOutputs function is proposed for the dType registry:

function setOutputs(
    bytes32 identifier,
    dTypes[] memory outputs
)
    public
  • identifier - type bytes32, the type’s identifier, as defined in EIP-1900
  • outputs - type dTypes, as defined in EIP-1900

Implementation Suggestions

In the dType registry implementation, outputs can be stored in a mapping:

mapping(bytes32 => dTypes[]) public outputs;

Rationale

The suggestion to treat each pure or view function as a separate entity instead of having a contract-based approach allows us to:

  • have a global context of readily available functions
  • scale designs through functional programming patterns rather than contract-encapsulated logic (which can be successfully used to scale development efforts independently)
  • bidirectionally connect functions with the types they use, making automation easier
  • cherry-pick functions from already deployed contracts if the other contract functions do not pass community consensus
  • have scope-restricted improvements - instead of redeploying entire contracts, we can just redeploy the new function versions that we want to be added to the registry
  • enable fine-grained auditing of individual functions, for the common good
  • enable testing directly on a production chain, without state side-effects

The proposal to store the minimum ABI information on-chain, for each function, allows us to:

  • enable on-chain automation (e.g. function chaining and composition)
  • be backward compatible in case the function signature format changes (e.g. from bytes4 to bytes32): multiple signature calculation functions can be registered with dType. Examples:
function getSignatureBytes4(bytes32 identifier)
    view
    public
    returns (bytes4 signature)

function getSignatureBytes32(bytes32 identifier)
    view
    public
    returns (bytes32 signature)
  • identifier - the type’s identifier, as defined in EIP-1900
  • signature - the function’s signature

Concerns about this design might be:

  • redundancy of storing contractAddress for each function that is part of the same contract

We think that state/storage cost will be compensated through DRYness across the chain, due to reusing types and functions that have already been registered and are now easy to find. Other state/storage cost calculations will be added once the specification and implementation are closer to be finalized.

Note that the input and output types are based on types that have already been registered. This lowers the amount of ABI information needed to be stored for each function and enables developers to aggregate and find functions that use the same types for their I/O. This can be a powerful tool for interoperability and smart contract composition.

Backwards Compatibility

This proposal does not affect extant Ethereum standards or implementations. Registering functions for existing contract deployments should be fully supported.

Test Cases

Will be added.

Implementation

In-work implementation examples can be found at https://github.com/pipeos-one/dType. This proposal will be updated with an appropriate implementation when consensus is reached on the specifications.

Copyright and related rights waived via CC0.

Citation

Please cite this document as:

Loredana Cirstea, Christian Tzurcanu, "EIP-1921: dType Functions Extension," Ethereum Improvement Proposals, no. 1921, April 2019. [Online serial]. Available: https://eips.ethereum.org/EIPS/eip-1921.