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Implementation of common patterns used for NEAR smart contracts.

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NEAR Smart Contracts Plugins

Implementation of common patterns used for NEAR smart contracts. Macros provided by default assumes the contract is using near-sdk-rs and #[near] macro.

Plugins

Documentation and implementation details of each plugin can be found in the source code, primarily in the traits which define plugin behavior. Events emitted by each plugin are also described in the source code of each macro. Each event follows NEP-297.

The following sections provide an overview of all available plugins. More examples and usage patterns are available in tests and demo contracts.

Basic access control mechanism that allows only an authorized account id to call certain methods. Note this account id can belong either to a regular user, or it could be a contract (a DAO for example).

This contract provides an example of using Ownable. It is compiled, deployed on chain and interacted with in integration tests.

Documentation of all methods provided by the derived implementation of Ownable is available in the definition of the trait.

Allow contracts to implement an emergency stop mechanism that can be triggered by an authorized account. Pauses can be used granularly to only limit certain features.

Using the Pausable plugin requires the contract to be AccessControllable in order to manage permissions. Roles allowing accounts to call certain methods can be granted and revoked via the AccessControllable plugin.

This contract provides an example of using Pausable. It is compiled, deployed on chain and interacted with in integration tests.

Documentation of all methods provided by Pausable is available in the definition of the trait.

Allows a contract to be upgraded without requiring a full access key. Optionally a staging duration can be set, which defines the minimum duration that must pass before staged code can be deployed. The staging duration is a safety mechanism to protect users that interact with the contract, giving them time to opt-out before an unfavorable update is deployed.

Using the Upgradable plugin requires a contract to be AccessControllable to handle authorization for calling Upgradable methods to stage or deploy updates (listed below).

To upgrade the contract, first call up_stage_code passing the binary as first argument serialized as borsh. Then call up_deploy_code.

To set a staging duration, call up_init_staging_duration. After initialization the staging duration can be updated by calling up_stage_update_staging_duration followed by up_apply_update_staging_duration. Updating the staging duration is itself subject to a delay: at least the currently set staging duration must pass before a staged update can be applied.

This contract provides an example of using Upgradable. It is compiled, deployed on chain and interacted with in integration tests.

Documentation of all methods provided by Upgradable is available in the definition of the trait.

Enables role-based access control for contract methods. A method with restricted access can only be called successfully by accounts that have been granted one of the whitelisted roles. If a restricted method is called by an account with insufficient permissions, it panics.

Each role is managed by admins who may grant the role to accounts and revoke it from them. In addition, there are super admins that have admin permissions for every role. The sets of accounts that are (super) admins and grantees are stored in the contract's state.

This contract provides an example of using AccessControllable. It is compiled, deployed on chain and interacted with in integration tests.

Documentation of all methods provided by AccessControllable is available in the definition of the trait.

Internal Architecture

Each plugin's functionality is described by a trait defined in near-plugins/src/<plugin_name>.rs. The trait's methods will be available on contracts that use the corresponding plugin, whereas the implementation of the trait is provided by procedural macros.

The code that is generated for a trait implementation is based on near-plugins-derive/src/<plugin_name.rs>. To inspect the code generated for your particular smart contract, cargo-expand can be helpful.

Testing

Tests should verify that once the macros provided by this crate are expanded, the contract they are used in has the intended functionality. Integration tests are utilized for that purpose:

  • A contract using the plugin is contained in near-plugins-derive/tests/contracts/<plugin_name>/.
  • This contract is used in near-plugins-derive/tests/<plugin_name>.rs which:
    • Compiles and deploys the contract on chain via near-workspaces.
    • Sends transactions to the deployed contract to verify plugin functionality.

Traits and their implementations

Traits doesn't contain any implementation, even though some interfaces are self-contained enough to have it. It is this way since near macro from near-sdk-rs will only expose as public methods those that are implemented during the trait implementation for the contract.

In the documentation all comments under Default Implementation makes remarks about the current implementation derived automatically from macros. They can be changed if the trait is manually implemented rather than deriving the macro.

Contributor Notes

Contracts used in tests set channel = <MSRV> in their rust-toolchain to make tests ensure that plugins are compatible with the MSRV. Developers working on this repo might want to locally set channel = <MSRV> in the root ./rust-toolchain to surface incompabilities with the MSRV early on.

Why not commit channel = <MSRV> to ./rust-toolchain? As a library crate we should leave the choice of the channel to users. Moreover, users should rather use a recent channel instead of the MSRV.

When compiling tests for the first time on a machine using the MSRV 1.69.0, an error might occur due to some dependencies of near-workspaces requiring a higher version of Rust. You can execute ./script/fix-dependencies.sh to install a compatible version of these dependencies. The comments in that script provide additional information.

Roadmap

  • Factory upgrades: Allow upgrading all deployed contracts from the factory fetching binary upstream.
  • Events ergonomics. Event macro that can be used in the following way:
#[derive(Serialize, Event(standard="nepXXX", version="1.0.1", action="transfer"))]
struct Transfer { 
    value: u64
}

/// In the contract
let transfer = Transfer { value: 1 };
transfer.emit(); // At this step the event is serialized and the log is emitted.
  • Allow deriving plugins privately, i.e. without making the methods public. This will allow developers to create custom logic on top of the plugin without modifying source code.