Finance
This module includes primitives for financial systems.
Vesting component
The VestingComponent manages the gradual release of ERC-20 tokens to a designated beneficiary based on a predefined vesting schedule. The implementing contract must implement the OwnableComponent, where the contract owner is regarded as the vesting beneficiary. This structure allows ownership rights of both the contract and the vested tokens to be assigned and transferred.
Any assets transferred to this contract will follow the vesting schedule as if they were locked from the beginning of the vesting period. As a result, if the vesting has already started, a portion of the newly transferred tokens may become immediately releasable. |
By setting the duration to 0, it’s possible to configure this contract to behave like an asset timelock that holds tokens for a beneficiary until a specified date. |
Vesting schedule
The VestingSchedule trait defines the logic for calculating the vested amount based on a given timestamp. This logic is not part of the VestingComponent, so any contract implementing the VestingComponent must provide its own implementation of the VestingSchedule trait.
There’s a ready-made implementation of the VestingSchedule trait available named LinearVestingSchedule. It incorporates a cliff period by returning 0 vested amount until the cliff ends. After the cliff, the vested amount is calculated as directly proportional to the time elapsed since the beginning of the vesting schedule. |
Usage
The contract must integrate VestingComponent and OwnableComponent as dependencies. The contract’s constructor
should initialize both components. Core vesting parameters, such as beneficiary
, start
, duration
and cliff_duration
, are passed as arguments to the constructor and set at the time of deployment.
The implementing contract must provide an implementation of the VestingSchedule trait. This can be achieved either by importing a ready-made LinearVestingSchedule implementation or by defining a custom one.
Here’s an example of a simple vesting wallet contract with a LinearVestingSchedule, where the vested amount is calculated as being directly proportional to the time elapsed since the start of the vesting period.
#[starknet::contract]
mod LinearVestingWallet {
use openzeppelin_access::ownable::OwnableComponent;
use openzeppelin_finance::vesting::{VestingComponent, LinearVestingSchedule};
use starknet::ContractAddress;
component!(path: OwnableComponent, storage: ownable, event: OwnableEvent);
component!(path: VestingComponent, storage: vesting, event: VestingEvent);
#[abi(embed_v0)]
impl OwnableMixinImpl = OwnableComponent::OwnableMixinImpl<ContractState>;
impl OwnableInternalImpl = OwnableComponent::InternalImpl<ContractState>;
#[abi(embed_v0)]
impl VestingImpl = VestingComponent::VestingImpl<ContractState>;
impl VestingInternalImpl = VestingComponent::InternalImpl<ContractState>;
#[storage]
struct Storage {
#[substorage(v0)]
ownable: OwnableComponent::Storage,
#[substorage(v0)]
vesting: VestingComponent::Storage
}
#[event]
#[derive(Drop, starknet::Event)]
enum Event {
#[flat]
OwnableEvent: OwnableComponent::Event,
#[flat]
VestingEvent: VestingComponent::Event
}
#[constructor]
fn constructor(
ref self: ContractState,
beneficiary: ContractAddress,
start: u64,
duration: u64,
cliff_duration: u64
) {
self.ownable.initializer(beneficiary);
self.vesting.initializer(start, duration, cliff_duration);
}
}
A vesting schedule will often follow a custom formula. In such cases, the VestingSchedule trait is useful. To support a custom vesting schedule, the contract must provide an implementation of the calculate_vested_amount function based on the desired formula.
When using a custom VestingSchedule implementation, the LinearVestingSchedule must be excluded from the imports. |
If there are additional parameters required for calculations, which are stored in the contract’s storage, you can access them using self.get_contract() .
|
Here’s an example of a vesting wallet contract with a custom VestingSchedule implementation, where tokens are vested in a number of steps.
#[starknet::contract]
mod StepsVestingWallet {
use openzeppelin_access::ownable::OwnableComponent;
use openzeppelin_finance::vesting::VestingComponent::VestingScheduleTrait;
use openzeppelin_finance::vesting::VestingComponent;
use starknet::ContractAddress;
use starknet::storage::{StoragePointerReadAccess, StoragePointerWriteAccess};
component!(path: OwnableComponent, storage: ownable, event: OwnableEvent);
component!(path: VestingComponent, storage: vesting, event: VestingEvent);
#[abi(embed_v0)]
impl OwnableMixinImpl = OwnableComponent::OwnableMixinImpl<ContractState>;
impl OwnableInternalImpl = OwnableComponent::InternalImpl<ContractState>;
#[abi(embed_v0)]
impl VestingImpl = VestingComponent::VestingImpl<ContractState>;
impl VestingInternalImpl = VestingComponent::InternalImpl<ContractState>;
#[storage]
struct Storage {
total_steps: u64,
#[substorage(v0)]
ownable: OwnableComponent::Storage,
#[substorage(v0)]
vesting: VestingComponent::Storage
}
#[event]
#[derive(Drop, starknet::Event)]
enum Event {
#[flat]
OwnableEvent: OwnableComponent::Event,
#[flat]
VestingEvent: VestingComponent::Event
}
#[constructor]
fn constructor(
ref self: ContractState,
total_steps: u64,
beneficiary: ContractAddress,
start: u64,
duration: u64,
cliff: u64,
) {
self.total_steps.write(total_steps);
self.ownable.initializer(beneficiary);
self.vesting.initializer(start, duration, cliff);
}
impl VestingSchedule of VestingScheduleTrait<ContractState> {
fn calculate_vested_amount(
self: @VestingComponent::ComponentState<ContractState>,
token: ContractAddress,
total_allocation: u256,
timestamp: u64,
start: u64,
duration: u64,
cliff: u64,
) -> u256 {
if timestamp < cliff {
0
} else if timestamp >= start + duration {
total_allocation
} else {
let total_steps = self.get_contract().total_steps.read();
let vested_per_step = total_allocation / total_steps.into();
let step_duration = duration / total_steps;
let current_step = (timestamp - start) / step_duration;
let vested_amount = vested_per_step * current_step.into();
vested_amount
}
}
}
}
Interface
Here is the full interface of a standard contract implementing the vesting functionality:
#[starknet::interface]
pub trait VestingABI<TState> {
// IVesting
fn start(self: @TState) -> u64;
fn cliff(self: @TState) -> u64;
fn duration(self: @TState) -> u64;
fn end(self: @TState) -> u64;
fn released(self: @TState, token: ContractAddress) -> u256;
fn releasable(self: @TState, token: ContractAddress) -> u256;
fn vested_amount(self: @TState, token: ContractAddress, timestamp: u64) -> u256;
fn release(ref self: TState, token: ContractAddress) -> u256;
// IOwnable
fn owner(self: @TState) -> ContractAddress;
fn transfer_ownership(ref self: TState, new_owner: ContractAddress);
fn renounce_ownership(ref self: TState);
// IOwnableCamelOnly
fn transferOwnership(ref self: TState, newOwner: ContractAddress);
fn renounceOwnership(ref self: TState);
}