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pezkuwi-subxt/substrate/frame/vesting/src/lib.rs
T
Gavin Wood 643d2b669f Introduce OnSetCode type into system config trait. (#8496)
* Introduce OnSetCode type into system config trait.

* Docs.

* Fixes

* Fixes
2021-04-01 12:20:24 +00:00

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Rust

// This file is part of Substrate.
// Copyright (C) 2019-2021 Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! # Vesting Pallet
//!
//! - [`Config`]
//! - [`Call`]
//!
//! ## Overview
//!
//! A simple pallet providing a means of placing a linear curve on an account's locked balance. This
//! pallet ensures that there is a lock in place preventing the balance to drop below the *unvested*
//! amount for any reason other than transaction fee payment.
//!
//! As the amount vested increases over time, the amount unvested reduces. However, locks remain in
//! place and explicit action is needed on behalf of the user to ensure that the amount locked is
//! equivalent to the amount remaining to be vested. This is done through a dispatchable function,
//! either `vest` (in typical case where the sender is calling on their own behalf) or `vest_other`
//! in case the sender is calling on another account's behalf.
//!
//! ## Interface
//!
//! This pallet implements the `VestingSchedule` trait.
//!
//! ### Dispatchable Functions
//!
//! - `vest` - Update the lock, reducing it in line with the amount "vested" so far.
//! - `vest_other` - Update the lock of another account, reducing it in line with the amount
//! "vested" so far.
#![cfg_attr(not(feature = "std"), no_std)]
mod benchmarking;
pub mod weights;
use sp_std::prelude::*;
use sp_std::fmt::Debug;
use codec::{Encode, Decode};
use sp_runtime::{RuntimeDebug, traits::{
StaticLookup, Zero, AtLeast32BitUnsigned, MaybeSerializeDeserialize, Convert
}};
use frame_support::{ensure, pallet_prelude::*};
use frame_support::traits::{
Currency, LockableCurrency, VestingSchedule, WithdrawReasons, LockIdentifier,
ExistenceRequirement, Get,
};
use frame_system::{ensure_signed, ensure_root, pallet_prelude::*};
pub use weights::WeightInfo;
pub use pallet::*;
type BalanceOf<T> = <<T as Config>::Currency as Currency<<T as frame_system::Config>::AccountId>>::Balance;
type MaxLocksOf<T> = <<T as Config>::Currency as LockableCurrency<<T as frame_system::Config>::AccountId>>::MaxLocks;
const VESTING_ID: LockIdentifier = *b"vesting ";
/// Struct to encode the vesting schedule of an individual account.
#[derive(Encode, Decode, Copy, Clone, PartialEq, Eq, RuntimeDebug)]
pub struct VestingInfo<Balance, BlockNumber> {
/// Locked amount at genesis.
pub locked: Balance,
/// Amount that gets unlocked every block after `starting_block`.
pub per_block: Balance,
/// Starting block for unlocking(vesting).
pub starting_block: BlockNumber,
}
impl<
Balance: AtLeast32BitUnsigned + Copy,
BlockNumber: AtLeast32BitUnsigned + Copy,
> VestingInfo<Balance, BlockNumber> {
/// Amount locked at block `n`.
pub fn locked_at<
BlockNumberToBalance: Convert<BlockNumber, Balance>
>(&self, n: BlockNumber) -> Balance {
// Number of blocks that count toward vesting
// Saturating to 0 when n < starting_block
let vested_block_count = n.saturating_sub(self.starting_block);
let vested_block_count = BlockNumberToBalance::convert(vested_block_count);
// Return amount that is still locked in vesting
let maybe_balance = vested_block_count.checked_mul(&self.per_block);
if let Some(balance) = maybe_balance {
self.locked.saturating_sub(balance)
} else {
Zero::zero()
}
}
}
#[frame_support::pallet]
pub mod pallet {
use super::*;
#[pallet::config]
pub trait Config: frame_system::Config {
/// The overarching event type.
type Event: From<Event<Self>> + IsType<<Self as frame_system::Config>::Event>;
/// The currency trait.
type Currency: LockableCurrency<Self::AccountId>;
/// Convert the block number into a balance.
type BlockNumberToBalance: Convert<Self::BlockNumber, BalanceOf<Self>>;
/// The minimum amount transferred to call `vested_transfer`.
#[pallet::constant]
type MinVestedTransfer: Get<BalanceOf<Self>>;
/// Weight information for extrinsics in this pallet.
type WeightInfo: WeightInfo;
}
/// Information regarding the vesting of a given account.
#[pallet::storage]
#[pallet::getter(fn vesting)]
pub type Vesting<T: Config> = StorageMap<
_,
Blake2_128Concat,
T::AccountId,
VestingInfo<BalanceOf<T>, T::BlockNumber>,
>;
#[pallet::pallet]
#[pallet::generate_store(pub(super) trait Store)]
pub struct Pallet<T>(_);
#[pallet::genesis_config]
pub struct GenesisConfig<T: Config> {
pub vesting: Vec<(T::AccountId, T::BlockNumber, T::BlockNumber, BalanceOf<T>)>,
}
#[cfg(feature = "std")]
impl<T: Config> Default for GenesisConfig<T> {
fn default() -> Self {
GenesisConfig {
vesting: Default::default(),
}
}
}
#[pallet::genesis_build]
impl<T: Config> GenesisBuild<T> for GenesisConfig<T> {
fn build(&self) {
use sp_runtime::traits::Saturating;
// Generate initial vesting configuration
// * who - Account which we are generating vesting configuration for
// * begin - Block when the account will start to vest
// * length - Number of blocks from `begin` until fully vested
// * liquid - Number of units which can be spent before vesting begins
for &(ref who, begin, length, liquid) in self.vesting.iter() {
let balance = T::Currency::free_balance(who);
assert!(!balance.is_zero(), "Currencies must be init'd before vesting");
// Total genesis `balance` minus `liquid` equals funds locked for vesting
let locked = balance.saturating_sub(liquid);
let length_as_balance = T::BlockNumberToBalance::convert(length);
let per_block = locked / length_as_balance.max(sp_runtime::traits::One::one());
Vesting::<T>::insert(who, VestingInfo {
locked: locked,
per_block: per_block,
starting_block: begin
});
let reasons = WithdrawReasons::TRANSFER | WithdrawReasons::RESERVE;
T::Currency::set_lock(VESTING_ID, who, locked, reasons);
}
}
}
#[pallet::event]
#[pallet::generate_deposit(pub(super) fn deposit_event)]
#[pallet::metadata(T::AccountId = "AccountId", BalanceOf<T> = "Balance")]
pub enum Event<T: Config> {
/// The amount vested has been updated. This could indicate more funds are available. The
/// balance given is the amount which is left unvested (and thus locked).
/// \[account, unvested\]
VestingUpdated(T::AccountId, BalanceOf<T>),
/// An \[account\] has become fully vested. No further vesting can happen.
VestingCompleted(T::AccountId),
}
/// Error for the vesting pallet.
#[pallet::error]
pub enum Error<T> {
/// The account given is not vesting.
NotVesting,
/// An existing vesting schedule already exists for this account that cannot be clobbered.
ExistingVestingSchedule,
/// Amount being transferred is too low to create a vesting schedule.
AmountLow,
}
#[pallet::hooks]
impl<T: Config> Hooks<BlockNumberFor<T>> for Pallet<T> {}
#[pallet::call]
impl<T: Config> Pallet<T> {
/// Unlock any vested funds of the sender account.
///
/// The dispatch origin for this call must be _Signed_ and the sender must have funds still
/// locked under this pallet.
///
/// Emits either `VestingCompleted` or `VestingUpdated`.
///
/// # <weight>
/// - `O(1)`.
/// - DbWeight: 2 Reads, 2 Writes
/// - Reads: Vesting Storage, Balances Locks, [Sender Account]
/// - Writes: Vesting Storage, Balances Locks, [Sender Account]
/// # </weight>
#[pallet::weight(T::WeightInfo::vest_locked(MaxLocksOf::<T>::get())
.max(T::WeightInfo::vest_unlocked(MaxLocksOf::<T>::get()))
)]
pub fn vest(origin: OriginFor<T>) -> DispatchResult {
let who = ensure_signed(origin)?;
Self::update_lock(who)
}
/// Unlock any vested funds of a `target` account.
///
/// The dispatch origin for this call must be _Signed_.
///
/// - `target`: The account whose vested funds should be unlocked. Must have funds still
/// locked under this pallet.
///
/// Emits either `VestingCompleted` or `VestingUpdated`.
///
/// # <weight>
/// - `O(1)`.
/// - DbWeight: 3 Reads, 3 Writes
/// - Reads: Vesting Storage, Balances Locks, Target Account
/// - Writes: Vesting Storage, Balances Locks, Target Account
/// # </weight>
#[pallet::weight(T::WeightInfo::vest_other_locked(MaxLocksOf::<T>::get())
.max(T::WeightInfo::vest_other_unlocked(MaxLocksOf::<T>::get()))
)]
pub fn vest_other(origin: OriginFor<T>, target: <T::Lookup as StaticLookup>::Source) -> DispatchResult {
ensure_signed(origin)?;
Self::update_lock(T::Lookup::lookup(target)?)
}
/// Create a vested transfer.
///
/// The dispatch origin for this call must be _Signed_.
///
/// - `target`: The account that should be transferred the vested funds.
/// - `amount`: The amount of funds to transfer and will be vested.
/// - `schedule`: The vesting schedule attached to the transfer.
///
/// Emits `VestingCreated`.
///
/// # <weight>
/// - `O(1)`.
/// - DbWeight: 3 Reads, 3 Writes
/// - Reads: Vesting Storage, Balances Locks, Target Account, [Sender Account]
/// - Writes: Vesting Storage, Balances Locks, Target Account, [Sender Account]
/// # </weight>
#[pallet::weight(T::WeightInfo::vested_transfer(MaxLocksOf::<T>::get()))]
pub fn vested_transfer(
origin: OriginFor<T>,
target: <T::Lookup as StaticLookup>::Source,
schedule: VestingInfo<BalanceOf<T>, T::BlockNumber>,
) -> DispatchResult {
let transactor = ensure_signed(origin)?;
ensure!(schedule.locked >= T::MinVestedTransfer::get(), Error::<T>::AmountLow);
let who = T::Lookup::lookup(target)?;
ensure!(!Vesting::<T>::contains_key(&who), Error::<T>::ExistingVestingSchedule);
T::Currency::transfer(&transactor, &who, schedule.locked, ExistenceRequirement::AllowDeath)?;
Self::add_vesting_schedule(&who, schedule.locked, schedule.per_block, schedule.starting_block)
.expect("user does not have an existing vesting schedule; q.e.d.");
Ok(())
}
/// Force a vested transfer.
///
/// The dispatch origin for this call must be _Root_.
///
/// - `source`: The account whose funds should be transferred.
/// - `target`: The account that should be transferred the vested funds.
/// - `amount`: The amount of funds to transfer and will be vested.
/// - `schedule`: The vesting schedule attached to the transfer.
///
/// Emits `VestingCreated`.
///
/// # <weight>
/// - `O(1)`.
/// - DbWeight: 4 Reads, 4 Writes
/// - Reads: Vesting Storage, Balances Locks, Target Account, Source Account
/// - Writes: Vesting Storage, Balances Locks, Target Account, Source Account
/// # </weight>
#[pallet::weight(T::WeightInfo::force_vested_transfer(MaxLocksOf::<T>::get()))]
pub fn force_vested_transfer(
origin: OriginFor<T>,
source: <T::Lookup as StaticLookup>::Source,
target: <T::Lookup as StaticLookup>::Source,
schedule: VestingInfo<BalanceOf<T>, T::BlockNumber>,
) -> DispatchResult {
ensure_root(origin)?;
ensure!(schedule.locked >= T::MinVestedTransfer::get(), Error::<T>::AmountLow);
let target = T::Lookup::lookup(target)?;
let source = T::Lookup::lookup(source)?;
ensure!(!Vesting::<T>::contains_key(&target), Error::<T>::ExistingVestingSchedule);
T::Currency::transfer(&source, &target, schedule.locked, ExistenceRequirement::AllowDeath)?;
Self::add_vesting_schedule(&target, schedule.locked, schedule.per_block, schedule.starting_block)
.expect("user does not have an existing vesting schedule; q.e.d.");
Ok(())
}
}
}
impl<T: Config> Pallet<T> {
/// (Re)set or remove the pallet's currency lock on `who`'s account in accordance with their
/// current unvested amount.
fn update_lock(who: T::AccountId) -> DispatchResult {
let vesting = Self::vesting(&who).ok_or(Error::<T>::NotVesting)?;
let now = <frame_system::Pallet<T>>::block_number();
let locked_now = vesting.locked_at::<T::BlockNumberToBalance>(now);
if locked_now.is_zero() {
T::Currency::remove_lock(VESTING_ID, &who);
Vesting::<T>::remove(&who);
Self::deposit_event(Event::<T>::VestingCompleted(who));
} else {
let reasons = WithdrawReasons::TRANSFER | WithdrawReasons::RESERVE;
T::Currency::set_lock(VESTING_ID, &who, locked_now, reasons);
Self::deposit_event(Event::<T>::VestingUpdated(who, locked_now));
}
Ok(())
}
}
impl<T: Config> VestingSchedule<T::AccountId> for Pallet<T> where
BalanceOf<T>: MaybeSerializeDeserialize + Debug
{
type Moment = T::BlockNumber;
type Currency = T::Currency;
/// Get the amount that is currently being vested and cannot be transferred out of this account.
fn vesting_balance(who: &T::AccountId) -> Option<BalanceOf<T>> {
if let Some(v) = Self::vesting(who) {
let now = <frame_system::Pallet<T>>::block_number();
let locked_now = v.locked_at::<T::BlockNumberToBalance>(now);
Some(T::Currency::free_balance(who).min(locked_now))
} else {
None
}
}
/// Adds a vesting schedule to a given account.
///
/// If there already exists a vesting schedule for the given account, an `Err` is returned
/// and nothing is updated.
///
/// On success, a linearly reducing amount of funds will be locked. In order to realise any
/// reduction of the lock over time as it diminishes, the account owner must use `vest` or
/// `vest_other`.
///
/// Is a no-op if the amount to be vested is zero.
fn add_vesting_schedule(
who: &T::AccountId,
locked: BalanceOf<T>,
per_block: BalanceOf<T>,
starting_block: T::BlockNumber
) -> DispatchResult {
if locked.is_zero() { return Ok(()) }
if Vesting::<T>::contains_key(who) {
Err(Error::<T>::ExistingVestingSchedule)?
}
let vesting_schedule = VestingInfo {
locked,
per_block,
starting_block
};
Vesting::<T>::insert(who, vesting_schedule);
// it can't fail, but even if somehow it did, we don't really care.
let res = Self::update_lock(who.clone());
debug_assert!(res.is_ok());
Ok(())
}
/// Remove a vesting schedule for a given account.
fn remove_vesting_schedule(who: &T::AccountId) {
Vesting::<T>::remove(who);
// it can't fail, but even if somehow it did, we don't really care.
let res = Self::update_lock(who.clone());
debug_assert!(res.is_ok());
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate as pallet_vesting;
use frame_support::{assert_ok, assert_noop, parameter_types};
use sp_core::H256;
use sp_runtime::{
testing::Header,
traits::{BlakeTwo256, IdentityLookup, Identity, BadOrigin},
};
use frame_system::RawOrigin;
type UncheckedExtrinsic = frame_system::mocking::MockUncheckedExtrinsic<Test>;
type Block = frame_system::mocking::MockBlock<Test>;
frame_support::construct_runtime!(
pub enum Test where
Block = Block,
NodeBlock = Block,
UncheckedExtrinsic = UncheckedExtrinsic,
{
System: frame_system::{Pallet, Call, Config, Storage, Event<T>},
Balances: pallet_balances::{Pallet, Call, Storage, Config<T>, Event<T>},
Vesting: pallet_vesting::{Pallet, Call, Storage, Event<T>, Config<T>},
}
);
parameter_types! {
pub const BlockHashCount: u64 = 250;
pub BlockWeights: frame_system::limits::BlockWeights =
frame_system::limits::BlockWeights::simple_max(1024);
}
impl frame_system::Config for Test {
type BaseCallFilter = ();
type BlockWeights = ();
type BlockLength = ();
type DbWeight = ();
type Origin = Origin;
type Index = u64;
type BlockNumber = u64;
type Hash = H256;
type Call = Call;
type Hashing = BlakeTwo256;
type AccountId = u64;
type Lookup = IdentityLookup<Self::AccountId>;
type Header = Header;
type Event = Event;
type BlockHashCount = BlockHashCount;
type Version = ();
type PalletInfo = PalletInfo;
type AccountData = pallet_balances::AccountData<u64>;
type OnNewAccount = ();
type OnKilledAccount = ();
type SystemWeightInfo = ();
type SS58Prefix = ();
type OnSetCode = ();
}
parameter_types! {
pub const MaxLocks: u32 = 10;
}
impl pallet_balances::Config for Test {
type Balance = u64;
type DustRemoval = ();
type Event = Event;
type ExistentialDeposit = ExistentialDeposit;
type AccountStore = System;
type MaxLocks = MaxLocks;
type WeightInfo = ();
}
parameter_types! {
pub const MinVestedTransfer: u64 = 256 * 2;
pub static ExistentialDeposit: u64 = 0;
}
impl Config for Test {
type Event = Event;
type Currency = Balances;
type BlockNumberToBalance = Identity;
type MinVestedTransfer = MinVestedTransfer;
type WeightInfo = ();
}
pub struct ExtBuilder {
existential_deposit: u64,
}
impl Default for ExtBuilder {
fn default() -> Self {
Self {
existential_deposit: 1,
}
}
}
impl ExtBuilder {
pub fn existential_deposit(mut self, existential_deposit: u64) -> Self {
self.existential_deposit = existential_deposit;
self
}
pub fn build(self) -> sp_io::TestExternalities {
EXISTENTIAL_DEPOSIT.with(|v| *v.borrow_mut() = self.existential_deposit);
let mut t = frame_system::GenesisConfig::default().build_storage::<Test>().unwrap();
pallet_balances::GenesisConfig::<Test> {
balances: vec![
(1, 10 * self.existential_deposit),
(2, 20 * self.existential_deposit),
(3, 30 * self.existential_deposit),
(4, 40 * self.existential_deposit),
(12, 10 * self.existential_deposit)
],
}.assimilate_storage(&mut t).unwrap();
pallet_vesting::GenesisConfig::<Test> {
vesting: vec![
(1, 0, 10, 5 * self.existential_deposit),
(2, 10, 20, 0),
(12, 10, 20, 5 * self.existential_deposit)
],
}.assimilate_storage(&mut t).unwrap();
let mut ext = sp_io::TestExternalities::new(t);
ext.execute_with(|| System::set_block_number(1));
ext
}
}
#[test]
fn check_vesting_status() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user1_free_balance = Balances::free_balance(&1);
let user2_free_balance = Balances::free_balance(&2);
let user12_free_balance = Balances::free_balance(&12);
assert_eq!(user1_free_balance, 256 * 10); // Account 1 has free balance
assert_eq!(user2_free_balance, 256 * 20); // Account 2 has free balance
assert_eq!(user12_free_balance, 256 * 10); // Account 12 has free balance
let user1_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 128, // Vesting over 10 blocks
starting_block: 0,
};
let user2_vesting_schedule = VestingInfo {
locked: 256 * 20,
per_block: 256, // Vesting over 20 blocks
starting_block: 10,
};
let user12_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_eq!(Vesting::vesting(&1), Some(user1_vesting_schedule)); // Account 1 has a vesting schedule
assert_eq!(Vesting::vesting(&2), Some(user2_vesting_schedule)); // Account 2 has a vesting schedule
assert_eq!(Vesting::vesting(&12), Some(user12_vesting_schedule)); // Account 12 has a vesting schedule
// Account 1 has only 128 units vested from their illiquid 256 * 5 units at block 1
assert_eq!(Vesting::vesting_balance(&1), Some(128 * 9));
// Account 2 has their full balance locked
assert_eq!(Vesting::vesting_balance(&2), Some(user2_free_balance));
// Account 12 has only their illiquid funds locked
assert_eq!(Vesting::vesting_balance(&12), Some(user12_free_balance - 256 * 5));
System::set_block_number(10);
assert_eq!(System::block_number(), 10);
// Account 1 has fully vested by block 10
assert_eq!(Vesting::vesting_balance(&1), Some(0));
// Account 2 has started vesting by block 10
assert_eq!(Vesting::vesting_balance(&2), Some(user2_free_balance));
// Account 12 has started vesting by block 10
assert_eq!(Vesting::vesting_balance(&12), Some(user12_free_balance - 256 * 5));
System::set_block_number(30);
assert_eq!(System::block_number(), 30);
assert_eq!(Vesting::vesting_balance(&1), Some(0)); // Account 1 is still fully vested, and not negative
assert_eq!(Vesting::vesting_balance(&2), Some(0)); // Account 2 has fully vested by block 30
assert_eq!(Vesting::vesting_balance(&12), Some(0)); // Account 2 has fully vested by block 30
});
}
#[test]
fn unvested_balance_should_not_transfer() {
ExtBuilder::default()
.existential_deposit(10)
.build()
.execute_with(|| {
let user1_free_balance = Balances::free_balance(&1);
assert_eq!(user1_free_balance, 100); // Account 1 has free balance
// Account 1 has only 5 units vested at block 1 (plus 50 unvested)
assert_eq!(Vesting::vesting_balance(&1), Some(45));
assert_noop!(
Balances::transfer(Some(1).into(), 2, 56),
pallet_balances::Error::<Test, _>::LiquidityRestrictions,
); // Account 1 cannot send more than vested amount
});
}
#[test]
fn vested_balance_should_transfer() {
ExtBuilder::default()
.existential_deposit(10)
.build()
.execute_with(|| {
let user1_free_balance = Balances::free_balance(&1);
assert_eq!(user1_free_balance, 100); // Account 1 has free balance
// Account 1 has only 5 units vested at block 1 (plus 50 unvested)
assert_eq!(Vesting::vesting_balance(&1), Some(45));
assert_ok!(Vesting::vest(Some(1).into()));
assert_ok!(Balances::transfer(Some(1).into(), 2, 55));
});
}
#[test]
fn vested_balance_should_transfer_using_vest_other() {
ExtBuilder::default()
.existential_deposit(10)
.build()
.execute_with(|| {
let user1_free_balance = Balances::free_balance(&1);
assert_eq!(user1_free_balance, 100); // Account 1 has free balance
// Account 1 has only 5 units vested at block 1 (plus 50 unvested)
assert_eq!(Vesting::vesting_balance(&1), Some(45));
assert_ok!(Vesting::vest_other(Some(2).into(), 1));
assert_ok!(Balances::transfer(Some(1).into(), 2, 55));
});
}
#[test]
fn extra_balance_should_transfer() {
ExtBuilder::default()
.existential_deposit(10)
.build()
.execute_with(|| {
assert_ok!(Balances::transfer(Some(3).into(), 1, 100));
assert_ok!(Balances::transfer(Some(3).into(), 2, 100));
let user1_free_balance = Balances::free_balance(&1);
assert_eq!(user1_free_balance, 200); // Account 1 has 100 more free balance than normal
let user2_free_balance = Balances::free_balance(&2);
assert_eq!(user2_free_balance, 300); // Account 2 has 100 more free balance than normal
// Account 1 has only 5 units vested at block 1 (plus 150 unvested)
assert_eq!(Vesting::vesting_balance(&1), Some(45));
assert_ok!(Vesting::vest(Some(1).into()));
assert_ok!(Balances::transfer(Some(1).into(), 3, 155)); // Account 1 can send extra units gained
// Account 2 has no units vested at block 1, but gained 100
assert_eq!(Vesting::vesting_balance(&2), Some(200));
assert_ok!(Vesting::vest(Some(2).into()));
assert_ok!(Balances::transfer(Some(2).into(), 3, 100)); // Account 2 can send extra units gained
});
}
#[test]
fn liquid_funds_should_transfer_with_delayed_vesting() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user12_free_balance = Balances::free_balance(&12);
assert_eq!(user12_free_balance, 2560); // Account 12 has free balance
// Account 12 has liquid funds
assert_eq!(Vesting::vesting_balance(&12), Some(user12_free_balance - 256 * 5));
// Account 12 has delayed vesting
let user12_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_eq!(Vesting::vesting(&12), Some(user12_vesting_schedule));
// Account 12 can still send liquid funds
assert_ok!(Balances::transfer(Some(12).into(), 3, 256 * 5));
});
}
#[test]
fn vested_transfer_works() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user3_free_balance = Balances::free_balance(&3);
let user4_free_balance = Balances::free_balance(&4);
assert_eq!(user3_free_balance, 256 * 30);
assert_eq!(user4_free_balance, 256 * 40);
// Account 4 should not have any vesting yet.
assert_eq!(Vesting::vesting(&4), None);
// Make the schedule for the new transfer.
let new_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_ok!(Vesting::vested_transfer(Some(3).into(), 4, new_vesting_schedule));
// Now account 4 should have vesting.
assert_eq!(Vesting::vesting(&4), Some(new_vesting_schedule));
// Ensure the transfer happened correctly.
let user3_free_balance_updated = Balances::free_balance(&3);
assert_eq!(user3_free_balance_updated, 256 * 25);
let user4_free_balance_updated = Balances::free_balance(&4);
assert_eq!(user4_free_balance_updated, 256 * 45);
// Account 4 has 5 * 256 locked.
assert_eq!(Vesting::vesting_balance(&4), Some(256 * 5));
System::set_block_number(20);
assert_eq!(System::block_number(), 20);
// Account 4 has 5 * 64 units vested by block 20.
assert_eq!(Vesting::vesting_balance(&4), Some(10 * 64));
System::set_block_number(30);
assert_eq!(System::block_number(), 30);
// Account 4 has fully vested.
assert_eq!(Vesting::vesting_balance(&4), Some(0));
});
}
#[test]
fn vested_transfer_correctly_fails() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user2_free_balance = Balances::free_balance(&2);
let user4_free_balance = Balances::free_balance(&4);
assert_eq!(user2_free_balance, 256 * 20);
assert_eq!(user4_free_balance, 256 * 40);
// Account 2 should already have a vesting schedule.
let user2_vesting_schedule = VestingInfo {
locked: 256 * 20,
per_block: 256, // Vesting over 20 blocks
starting_block: 10,
};
assert_eq!(Vesting::vesting(&2), Some(user2_vesting_schedule));
// The vesting schedule we will try to create, fails due to pre-existence of schedule.
let new_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_noop!(
Vesting::vested_transfer(Some(4).into(), 2, new_vesting_schedule),
Error::<Test>::ExistingVestingSchedule,
);
// Fails due to too low transfer amount.
let new_vesting_schedule_too_low = VestingInfo {
locked: 256 * 1,
per_block: 64,
starting_block: 10,
};
assert_noop!(
Vesting::vested_transfer(Some(3).into(), 4, new_vesting_schedule_too_low),
Error::<Test>::AmountLow,
);
// Verify no currency transfer happened.
assert_eq!(user2_free_balance, 256 * 20);
assert_eq!(user4_free_balance, 256 * 40);
});
}
#[test]
fn force_vested_transfer_works() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user3_free_balance = Balances::free_balance(&3);
let user4_free_balance = Balances::free_balance(&4);
assert_eq!(user3_free_balance, 256 * 30);
assert_eq!(user4_free_balance, 256 * 40);
// Account 4 should not have any vesting yet.
assert_eq!(Vesting::vesting(&4), None);
// Make the schedule for the new transfer.
let new_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_noop!(Vesting::force_vested_transfer(Some(4).into(), 3, 4, new_vesting_schedule), BadOrigin);
assert_ok!(Vesting::force_vested_transfer(RawOrigin::Root.into(), 3, 4, new_vesting_schedule));
// Now account 4 should have vesting.
assert_eq!(Vesting::vesting(&4), Some(new_vesting_schedule));
// Ensure the transfer happened correctly.
let user3_free_balance_updated = Balances::free_balance(&3);
assert_eq!(user3_free_balance_updated, 256 * 25);
let user4_free_balance_updated = Balances::free_balance(&4);
assert_eq!(user4_free_balance_updated, 256 * 45);
// Account 4 has 5 * 256 locked.
assert_eq!(Vesting::vesting_balance(&4), Some(256 * 5));
System::set_block_number(20);
assert_eq!(System::block_number(), 20);
// Account 4 has 5 * 64 units vested by block 20.
assert_eq!(Vesting::vesting_balance(&4), Some(10 * 64));
System::set_block_number(30);
assert_eq!(System::block_number(), 30);
// Account 4 has fully vested.
assert_eq!(Vesting::vesting_balance(&4), Some(0));
});
}
#[test]
fn force_vested_transfer_correctly_fails() {
ExtBuilder::default()
.existential_deposit(256)
.build()
.execute_with(|| {
let user2_free_balance = Balances::free_balance(&2);
let user4_free_balance = Balances::free_balance(&4);
assert_eq!(user2_free_balance, 256 * 20);
assert_eq!(user4_free_balance, 256 * 40);
// Account 2 should already have a vesting schedule.
let user2_vesting_schedule = VestingInfo {
locked: 256 * 20,
per_block: 256, // Vesting over 20 blocks
starting_block: 10,
};
assert_eq!(Vesting::vesting(&2), Some(user2_vesting_schedule));
// The vesting schedule we will try to create, fails due to pre-existence of schedule.
let new_vesting_schedule = VestingInfo {
locked: 256 * 5,
per_block: 64, // Vesting over 20 blocks
starting_block: 10,
};
assert_noop!(
Vesting::force_vested_transfer(RawOrigin::Root.into(), 4, 2, new_vesting_schedule),
Error::<Test>::ExistingVestingSchedule,
);
// Fails due to too low transfer amount.
let new_vesting_schedule_too_low = VestingInfo {
locked: 256 * 1,
per_block: 64,
starting_block: 10,
};
assert_noop!(
Vesting::force_vested_transfer(RawOrigin::Root.into(), 3, 4, new_vesting_schedule_too_low),
Error::<Test>::AmountLow,
);
// Verify no currency transfer happened.
assert_eq!(user2_free_balance, 256 * 20);
assert_eq!(user4_free_balance, 256 * 40);
});
}
}