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// Copyright 2017-2020 Parity Technologies (UK) Ltd.
// This file is part of Polkadot.
// Polkadot is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Polkadot is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Polkadot. If not, see <http://www.gnu.org/licenses/>.
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//!
//! The point of this module is to allow parachain projects to offer the ability to help fund a
//! deposit for the parachain. When the parachain is retired, the funds may be returned.
//!
//! Contributing funds is permissionless. Each fund has a child-trie which stores all
//! contributors account IDs together with the amount they contributed; the root of this can then be
//! used by the parachain to allow contributors to prove that they made some particular contribution
//! to the project (e.g. to be rewarded through some token or badge). The trie is retained for later
//! (efficient) redistribution back to the contributors.
//!
//! Contributions must be of at least `MinContribution` (to account for the resources taken in
//! tracking contributions), and may never tally greater than the fund's `cap`, set and fixed at the
//! time of creation. The `create` call may be used to create a new fund. In order to do this, then
//! a deposit must be paid of the amount `SubmissionDeposit`. Substantial resources are taken on
//! the main trie in tracking a fund and this accounts for that.
//!
//! Funds may be set up during an auction period; their closing time is fixed at creation (as a
//! block number) and if the fund is not successful by the closing time, then it will become *retired*.
//! Funds may span multiple auctions, and even auctions that sell differing periods. However, for a
//! fund to be active in bidding for an auction, it *must* have had *at least one bid* since the end
//! of the last auction. Until a fund takes a further bid following the end of an auction, then it
//! will be inactive.
//!
//! Contributors may get a refund of their contributions from retired funds. After a period (`RetirementPeriod`)
//! the fund may be dissolved entirely. At this point any non-refunded contributions are considered
//! `orphaned` and are disposed of through the `OrphanedFunds` handler (which may e.g. place them
//! into the treasury).
//!
//! Funds may accept contributions at any point before their success or retirement. When a parachain
//! slot auction enters its ending period, then parachains will each place a bid; the bid will be
//! raised once per block if the parachain had additional funds contributed since the last bid.
//!
//! Funds may set their deploy data (the code hash and head data of their parachain) at any point.
//! It may only be done once and once set cannot be changed. Good procedure would be to set them
//! ahead of receiving any contributions in order that contributors may verify that their parachain
//! contains all expected functionality. However, this is not enforced and deploy data may happen
//! at any point, even after a slot has been successfully won or, indeed, never.
//!
//! Funds that are successful winners of a slot may have their slot claimed through the `onboard`
//! call. This may only be done once and must be after the deploy data has been fixed. Successful
//! funds remain tracked (in the `Funds` storage item and the associated child trie) as long as
//! the parachain remains active. Once it does not, it is up to the parachain to ensure that the
//! funds are returned to this module's fund sub-account in order that they be redistributed back to
//! contributors. *Retirement* may be initiated by any account (using the `begin_retirement` call)
//! once the parachain is removed from the its slot.
//!
//! @WARNING: For funds to be returned, it is imperative that this module's account is provided as
//! the offboarding account for the slot. In the case that a parachain supplemented these funds in
//! order to win a later auction, then it is the parachain's duty to ensure that the right amount of
//! funds ultimately end up in module's fund sub-account.
decl_module, decl_storage, decl_event, decl_error, ensure,
storage::child,
Currency, Get, OnUnbalanced, ExistenceRequirement::AllowDeath
use sp_runtime::{ModuleId, DispatchResult,
traits::{AccountIdConversion, Hash, Saturating, Zero, CheckedAdd, Bounded}
use parity_scale_codec::{Encode, Decode};
use primitives::v1::{Id as ParaId, HeadData};
<<T as slots::Config>::Currency as Currency<<T as frame_system::Config>::AccountId>>::Balance;
#[allow(dead_code)]
pub type NegativeImbalanceOf<T> =
<<T as slots::Config>::Currency as Currency<<T as frame_system::Config>::AccountId>>::NegativeImbalance;
pub trait Config: slots::Config {
type Event: From<Event<Self>> + Into<<Self as frame_system::Config>::Event>;
/// ModuleID for the crowdloan module. An appropriate value could be ```ModuleId(*b"py/cfund")```
/// The amount to be held on deposit by the owner of a crowdloan.
type SubmissionDeposit: Get<BalanceOf<Self>>;
/// The minimum amount that may be contributed into a crowdloan. Should almost certainly be at
/// least ExistentialDeposit.
type MinContribution: Get<BalanceOf<Self>>;
/// The period of time (in blocks) after an unsuccessful crowdloan ending when
/// contributors are able to withdraw their funds. After this period, their funds are lost.
type RetirementPeriod: Get<Self::BlockNumber>;
/// What to do with funds that were not withdrawn.
type OrphanedFunds: OnUnbalanced<NegativeImbalanceOf<Self>>;
/// Max number of storage keys to remove per extrinsic call.
type RemoveKeysLimit: Get<u32>;
}
/// Simple index for identifying a fund.
pub type FundIndex = u32;
#[derive(Encode, Decode, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "std", derive(Debug))]
pub enum LastContribution<BlockNumber> {
Never,
PreEnding(slots::AuctionIndex),
Ending(BlockNumber),
}
#[derive(Encode, Decode, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "std", derive(Debug))]
struct DeployData<Hash> {
code_hash: Hash,
code_size: u32,
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initial_head_data: HeadData,
}
#[derive(Encode, Decode, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "std", derive(Debug))]
#[codec(dumb_trait_bound)]
pub struct FundInfo<AccountId, Balance, Hash, BlockNumber> {
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/// The parachain that this fund has funded, if there is one. As long as this is `Some`, then
/// the funds may not be withdrawn and the fund cannot be dissolved.
parachain: Option<ParaId>,
/// The owning account who placed the deposit.
owner: AccountId,
/// The amount of deposit placed.
deposit: Balance,
/// The total amount raised.
raised: Balance,
/// Block number after which the funding must have succeeded. If not successful at this number
/// then everyone may withdraw their funds.
end: BlockNumber,
/// A hard-cap on the amount that may be contributed.
cap: Balance,
/// The most recent block that this had a contribution. Determines if we make a bid or not.
/// If this is `Never`, this fund has never received a contribution.
/// If this is `PreEnding(n)`, this fund received a contribution sometime in auction
/// number `n` before the ending period.
/// If this is `Ending(n)`, this fund received a contribution during the current ending period,
/// where `n` is how far into the ending period the contribution was made.
last_contribution: LastContribution<BlockNumber>,
/// First slot in range to bid on; it's actually a LeasePeriod, but that's the same type as
/// BlockNumber.
first_slot: BlockNumber,
/// Last slot in range to bid on; it's actually a LeasePeriod, but that's the same type as
/// BlockNumber.
last_slot: BlockNumber,
/// The deployment data associated with this fund, if any. Once set it may not be reset. First
/// is the code hash, second is the code size, third is the initial head data.
deploy_data: Option<DeployData<Hash>>,
trait Store for Module<T: Config> as Crowdloan {
map hasher(twox_64_concat) FundIndex
=> Option<FundInfo<T::AccountId, BalanceOf<T>, T::Hash, T::BlockNumber>>;
/// The total number of funds that have so far been allocated.
FundCount get(fn fund_count): FundIndex;
/// The funds that have had additional contributions during the last block. This is used
/// in order to determine which funds should submit new or updated bids.
NewRaise get(fn new_raise): Vec<FundIndex>;
/// The number of auctions that have entered into their ending period so far.
EndingsCount get(fn endings_count): slots::AuctionIndex;
}
}
decl_event! {
pub enum Event<T> where
<T as frame_system::Config>::AccountId,
/// Create a new crowdloaning campaign. [fund_index]
/// Contributed to a crowd sale. [who, fund_index, amount]
Contributed(AccountId, FundIndex, Balance),
/// Withdrew full balance of a contributor. [who, fund_index, amount]
Withdrew(AccountId, FundIndex, Balance),
/// Fund is placed into retirement. [fund_index]
/// Fund is partially dissolved, i.e. there are some left over child
/// keys that still need to be killed. [fund_index]
PartiallyDissolved(FundIndex),
/// Fund is dissolved. [fund_index]
/// The deploy data of the funded parachain is setted. [fund_index]
/// Onboarding process for a winning parachain fund is completed. [find_index, parachain_id]
/// The result of trying to submit a new bid to the Slots pallet.
HandleBidResult(FundIndex, DispatchResult),
pub enum Error for Module<T: Config> {
/// Last slot must be greater than first slot.
LastSlotBeforeFirstSlot,
/// The last slot cannot be more then 3 slots after the first slot.
LastSlotTooFarInFuture,
/// The campaign ends before the current block number. The end must be in the future.
CannotEndInPast,
/// There was an overflow.
Overflow,
/// The contribution was below the minimum, `MinContribution`.
ContributionTooSmall,
/// Invalid fund index.
InvalidFundIndex,
/// Contributions exceed maximum amount.
CapExceeded,
/// The contribution period has already ended.
ContributionPeriodOver,
/// The origin of this call is invalid.
InvalidOrigin,
/// Deployment data for a fund can only be set once. The deployment data for this fund
/// already exists.
ExistingDeployData,
/// Deployment data has not been set for this fund.
UnsetDeployData,
/// This fund has already been onboarded.
AlreadyOnboard,
/// This crowdloan does not correspond to a parachain.
NotParachain,
/// This parachain still has its deposit. Implies that it has already been offboarded.
ParaHasDeposit,
/// Funds have not yet been returned.
FundsNotReturned,
/// Fund has not yet retired.
FundNotRetired,
/// There are no contributions stored in this crowdloan.
/// This crowdloan has an active parachain and cannot be dissolved.
HasActiveParachain,
/// The retirement period has not ended.
InRetirementPeriod,
}
}
pub struct Module<T: Config> for enum Call where origin: T::Origin {
type Error = Error<T>;
const ModuleId: ModuleId = T::ModuleId::get();
/// Create a new crowdloaning campaign for a parachain slot deposit for the current auction.
fn create(origin,
#[compact] cap: BalanceOf<T>,
#[compact] first_slot: T::BlockNumber,
#[compact] last_slot: T::BlockNumber,
#[compact] end: T::BlockNumber
) {
let owner = ensure_signed(origin)?;
ensure!(first_slot < last_slot, Error::<T>::LastSlotBeforeFirstSlot);
ensure!(last_slot <= first_slot + 3u32.into(), Error::<T>::LastSlotTooFarInFuture);
ensure!(end > <frame_system::Module<T>>::block_number(), Error::<T>::CannotEndInPast);
let next_index = index.checked_add(1).ok_or(Error::<T>::Overflow)?;
let deposit = T::SubmissionDeposit::get();
T::Currency::transfer(&owner, &Self::fund_account_id(index), deposit, AllowDeath)?;
FundCount::put(next_index);
<Funds<T>>::insert(index, FundInfo {
parachain: None,
owner,
deposit,
raised: Zero::zero(),
end,
cap,
last_contribution: LastContribution::Never,
first_slot,
last_slot,
deploy_data: None,
});
Self::deposit_event(RawEvent::Created(index));
}
/// Contribute to a crowd sale. This will transfer some balance over to fund a parachain
/// slot. It will be withdrawable in two instances: the parachain becomes retired; or the
/// slot is unable to be purchased and the timeout expires.
#[weight = 0]
fn contribute(origin, #[compact] index: FundIndex, #[compact] value: BalanceOf<T>) {
let who = ensure_signed(origin)?;
ensure!(value >= T::MinContribution::get(), Error::<T>::ContributionTooSmall);
let mut fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
fund.raised = fund.raised.checked_add(&value).ok_or(Error::<T>::Overflow)?;
ensure!(fund.raised <= fund.cap, Error::<T>::CapExceeded);
let now = <frame_system::Module<T>>::block_number();
ensure!(fund.end > now, Error::<T>::ContributionPeriodOver);
T::Currency::transfer(&who, &Self::fund_account_id(index), value, AllowDeath)?;
let balance = Self::contribution_get(index, &who);
let balance = balance.saturating_add(value);
Self::contribution_put(index, &who, &balance);
if <slots::Module<T>>::is_ending(now).is_some() {
match fund.last_contribution {
// In ending period; must ensure that we are in NewRaise.
LastContribution::Ending(n) if n == now => {
// do nothing - already in NewRaise
}
_ => {
fund.last_contribution = LastContribution::Ending(now);
}
}
} else {
let endings_count = Self::endings_count();
match fund.last_contribution {
LastContribution::PreEnding(a) if a == endings_count => {
// Not in ending period and no auctions have ended ending since our
// previous bid which was also not in an ending period.
// `NewRaise` will contain our ID still: Do nothing.
}
_ => {
// Not in ending period; but an auction has been ending since our previous
// bid, or we never had one to begin with. Add bid.
fund.last_contribution = LastContribution::PreEnding(endings_count);
}
}
}
<Funds<T>>::insert(index, &fund);
Self::deposit_event(RawEvent::Contributed(who, index, value));
}
/// Set the deploy data of the funded parachain if not already set. Once set, this cannot
/// be changed again.
///
/// - `origin` must be the fund owner.
/// - `index` is the fund index that `origin` owns and whose deploy data will be set.
/// - `code_hash` is the hash of the parachain's Wasm validation function.
/// - `initial_head_data` is the parachain's initial head data.
#[weight = 0]
fn fix_deploy_data(origin,
#[compact] index: FundIndex,
code_hash: T::Hash,
code_size: u32,
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initial_head_data: HeadData,
) {
let who = ensure_signed(origin)?;
let mut fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
ensure!(fund.owner == who, Error::<T>::InvalidOrigin); // must be fund owner
ensure!(fund.deploy_data.is_none(), Error::<T>::ExistingDeployData);
fund.deploy_data = Some(DeployData { code_hash, code_size, initial_head_data });
<Funds<T>>::insert(index, &fund);
Self::deposit_event(RawEvent::DeployDataFixed(index));
}
/// Complete onboarding process for a winning parachain fund. This can be called once by
/// any origin once a fund wins a slot and the fund has set its deploy data (using
/// `fix_deploy_data`).
///
/// - `index` is the fund index that `origin` owns and whose deploy data will be set.
/// - `para_id` is the parachain index that this fund won.
#[weight = 0]
fn onboard(origin,
#[compact] index: FundIndex,
let mut fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
let DeployData { code_hash, code_size, initial_head_data }
= fund.clone().deploy_data.ok_or(Error::<T>::UnsetDeployData)?;
ensure!(fund.parachain.is_none(), Error::<T>::AlreadyOnboard);
let fund_origin = frame_system::RawOrigin::Signed(Self::fund_account_id(index)).into();
<slots::Module<T>>::fix_deploy_data(
fund_origin,
index,
para_id,
code_hash,
code_size,
initial_head_data,
)?;
<Funds<T>>::insert(index, &fund);
Self::deposit_event(RawEvent::Onboarded(index, para_id));
}
/// Note that a successful fund has lost its parachain slot, and place it into retirement.
#[weight = 0]
fn begin_retirement(origin, #[compact] index: FundIndex) {
let mut fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
let parachain_id = fund.parachain.take().ok_or(Error::<T>::NotParachain)?;
// No deposit information implies the parachain was off-boarded
ensure!(<slots::Module<T>>::deposits(parachain_id).len() == 0, Error::<T>::ParaHasDeposit);
let account = Self::fund_account_id(index);
// Funds should be returned at the end of off-boarding
ensure!(T::Currency::free_balance(&account) >= fund.raised, Error::<T>::FundsNotReturned);
// This fund just ended. Withdrawal period begins.
let now = <frame_system::Module<T>>::block_number();
fund.end = now;
<Funds<T>>::insert(index, &fund);
Self::deposit_event(RawEvent::Retiring(index));
}
/// Withdraw full balance of a contributor to an unsuccessful or off-boarded fund.
#[weight = 0]
fn withdraw(origin, who: T::AccountId, #[compact] index: FundIndex) {
ensure_signed(origin)?;
let mut fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
ensure!(fund.parachain.is_none(), Error::<T>::FundNotRetired);
let now = <frame_system::Module<T>>::block_number();
// `fund.end` can represent the end of a failed crowdsale or the beginning of retirement
ensure!(now >= fund.end, Error::<T>::FundNotEnded);
let balance = Self::contribution_get(index, &who);
ensure!(balance > Zero::zero(), Error::<T>::NoContributions);
// Avoid using transfer to ensure we don't pay any fees.
let fund_account = Self::fund_account_id(index);
T::Currency::transfer(&fund_account, &who, balance, AllowDeath)?;
Self::contribution_kill(index, &who);
fund.raised = fund.raised.saturating_sub(balance);
<Funds<T>>::insert(index, &fund);
Self::deposit_event(RawEvent::Withdrew(who, index, balance));
}
/// Remove a fund after either: it was unsuccessful and it timed out; or it was successful
/// but it has been retired from its parachain slot. This places any deposits that were not
/// withdrawn into the treasury.
#[weight = 0]
fn dissolve(origin, #[compact] index: FundIndex) {
let fund = Self::funds(index).ok_or(Error::<T>::InvalidFundIndex)?;
ensure!(fund.parachain.is_none(), Error::<T>::HasActiveParachain);
let now = <frame_system::Module<T>>::block_number();
ensure!(
now >= fund.end.saturating_add(T::RetirementPeriod::get()),
Error::<T>::InRetirementPeriod
// Try killing the crowdloan child trie
match Self::crowdloan_kill(index) {
child::KillOutcome::AllRemoved => {
let account = Self::fund_account_id(index);
T::Currency::transfer(&account, &fund.owner, fund.deposit, AllowDeath)?;
// Remove all other balance from the account into orphaned funds.
let (imbalance, _) = T::Currency::slash(&account, BalanceOf::<T>::max_value());
T::OrphanedFunds::on_unbalanced(imbalance);
Self::deposit_event(RawEvent::Dissolved(index));
},
child::KillOutcome::SomeRemaining => {
Self::deposit_event(RawEvent::PartiallyDissolved(index));
}
}
fn on_initialize(n: T::BlockNumber) -> frame_support::weights::Weight {
if let Some(n) = <slots::Module<T>>::is_ending(n) {
let auction_index = <slots::Module<T>>::auction_counter();
if n.is_zero() {
// first block of ending period.
EndingsCount::mutate(|c| *c += 1);
}
for (fund, index) in NewRaise::take().into_iter().filter_map(|i| Self::funds(i).map(|f| (f, i))) {
let bidder = slots::Bidder::New(slots::NewBidder {
who: Self::fund_account_id(index),
/// FundIndex and slots::SubId happen to be the same type (u32). If this
/// ever changes, then some sort of conversion will be needed here.
sub: index,
});
// Care needs to be taken by the crowdloan creator that this function will succeed given
// the crowdloaning configuration. We do some checks ahead of time in crowdloan `create`.
let result = <slots::Module<T>>::handle_bid(
bidder,
auction_index,
fund.first_slot,
fund.last_slot,
fund.raised,
);
Self::deposit_event(RawEvent::HandleBidResult(index, result));
impl<T: Config> Module<T> {
/// The account ID of the fund pot.
///
/// This actually does computation. If you need to keep using it, then make sure you cache the
/// value and only call this once.
pub fn fund_account_id(index: FundIndex) -> T::AccountId {
T::ModuleId::get().into_sub_account(index)
pub fn id_from_index(index: FundIndex) -> child::ChildInfo {
buf.extend_from_slice(&index.to_le_bytes()[..]);
child::ChildInfo::new_default(T::Hashing::hash(&buf[..]).as_ref())
pub fn contribution_put(index: FundIndex, who: &T::AccountId, balance: &BalanceOf<T>) {
who.using_encoded(|b| child::put(&Self::id_from_index(index), b, balance));
}
pub fn contribution_get(index: FundIndex, who: &T::AccountId) -> BalanceOf<T> {
who.using_encoded(|b| child::get_or_default::<BalanceOf<T>>(
}
pub fn contribution_kill(index: FundIndex, who: &T::AccountId) {
who.using_encoded(|b| child::kill(&Self::id_from_index(index), b));
pub fn crowdloan_kill(index: FundIndex) -> child::KillOutcome {
child::kill_storage(&Self::id_from_index(index), Some(T::RemoveKeysLimit::get()))
}
}
#[cfg(test)]
mod tests {
use super::*;
use std::{collections::HashMap, cell::RefCell};
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use frame_support::{
impl_outer_origin, impl_outer_event, assert_ok, assert_noop, parameter_types,
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traits::{OnInitialize, OnFinalize},
};
use primitives::v1::{Id as ParaId, ValidationCode};
// The testing primitives are very useful for avoiding having to work with signatures
// or public keys. `u64` is used as the `AccountId` and no `Signature`s are requried.
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traits::{BlakeTwo256, IdentityLookup},
mod runtime_common_slots {
pub use crate::slots::Event;
}
mod runtime_common_crowdloan {
pub use crate::crowdloan::Event;
}
impl_outer_event! {
pub enum Event for Test {
frame_system<T>,
pallet_balances<T>,
pallet_treasury<T>,
runtime_common_slots<T>,
runtime_common_crowdloan<T>,
}
}
// For testing the module, we construct most of a mock runtime. This means
// first constructing a configuration type (`Test`) which `impl`s each of the
// configuration traits of modules we want to use.
#[derive(Clone, Eq, PartialEq)]
pub struct Test;
parameter_types! {
pub const BlockHashCount: u32 = 250;
}
impl frame_system::Config for Test {
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type BaseCallFilter = ();
type BlockWeights = ();
type BlockLength = ();
type DbWeight = ();
type Origin = Origin;
type Call = ();
type Index = u64;
type BlockNumber = u64;
type Hash = H256;
type Hashing = BlakeTwo256;
type AccountId = u64;
type Lookup = IdentityLookup<Self::AccountId>;
type Header = Header;
type BlockHashCount = BlockHashCount;
type Version = ();
type PalletInfo = ();
type AccountData = pallet_balances::AccountData<u64>;
type OnKilledAccount = ();
type SystemWeightInfo = ();
type SS58Prefix = ();
impl pallet_balances::Config for Test {
type ExistentialDeposit = ExistentialDeposit;
type MaxLocks = ();
}
parameter_types! {
pub const ProposalBond: Permill = Permill::from_percent(5);
pub const ProposalBondMinimum: u64 = 1;
pub const SpendPeriod: u64 = 2;
pub const Burn: Permill = Permill::from_percent(50);
pub const TreasuryModuleId: ModuleId = ModuleId(*b"py/trsry");
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}
impl pallet_treasury::Config for Test {
type Currency = pallet_balances::Module<Test>;
type ApproveOrigin = frame_system::EnsureRoot<u64>;
type RejectOrigin = frame_system::EnsureRoot<u64>;
type ProposalBond = ProposalBond;
type ProposalBondMinimum = ProposalBondMinimum;
type SpendPeriod = SpendPeriod;
type Burn = Burn;
type BurnDestination = ();
}
thread_local! {
pub static PARACHAIN_COUNT: RefCell<u32> = RefCell::new(0);
pub static PARACHAINS:
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RefCell<HashMap<u32, (ValidationCode, HeadData)>> = RefCell::new(HashMap::new());
const MAX_CODE_SIZE: u32 = 100;
const MAX_HEAD_DATA_SIZE: u32 = 10;
impl Registrar<u64> for TestParachains {
fn new_id() -> ParaId {
PARACHAIN_COUNT.with(|p| {
*p.borrow_mut() += 1;
(*p.borrow() - 1).into()
})
}
fn head_data_size_allowed(head_data_size: u32) -> bool {
head_data_size <= MAX_HEAD_DATA_SIZE
}
fn code_size_allowed(code_size: u32) -> bool {
code_size <= MAX_CODE_SIZE
}
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code: ValidationCode,
initial_head_data: HeadData,
if p.borrow().contains_key(&id.into()) {
p.borrow_mut().insert(id.into(), (code, initial_head_data));
fn deregister_para(id: ParaId) -> DispatchResult {
if !p.borrow().contains_key(&id.into()) {
p.borrow_mut().remove(&id.into());
Ok(())
})
}
}
parameter_types!{
pub const LeasePeriod: u64 = 10;
pub const EndingPeriod: u64 = 3;
}
impl slots::Config for Test {
type Currency = Balances;
type Parachains = TestParachains;
type LeasePeriod = LeasePeriod;
type EndingPeriod = EndingPeriod;
type Randomness = RandomnessCollectiveFlip;
}
parameter_types! {
pub const SubmissionDeposit: u64 = 1;
pub const MinContribution: u64 = 10;
pub const RetirementPeriod: u64 = 5;
pub const CrowdloanModuleId: ModuleId = ModuleId(*b"py/cfund");
pub const RemoveKeysLimit: u32 = 10;
impl Config for Test {
type SubmissionDeposit = SubmissionDeposit;
type MinContribution = MinContribution;
type RetirementPeriod = RetirementPeriod;
type OrphanedFunds = Treasury;
type ModuleId = CrowdloanModuleId;
type RemoveKeysLimit = RemoveKeysLimit;
type System = frame_system::Module<Test>;
type Balances = pallet_balances::Module<Test>;
type Treasury = pallet_treasury::Module<Test>;
type RandomnessCollectiveFlip = pallet_randomness_collective_flip::Module<Test>;
use pallet_balances::Error as BalancesError;
use slots::Error as SlotsError;
// This function basically just builds a genesis storage key/value store according to
// our desired mockup.
pub fn new_test_ext() -> sp_io::TestExternalities {
let mut t = frame_system::GenesisConfig::default().build_storage::<Test>().unwrap();
pallet_balances::GenesisConfig::<Test>{
balances: vec![(1, 1000), (2, 2000), (3, 3000), (4, 4000)],
}.assimilate_storage(&mut t).unwrap();
t.into()
}
fn run_to_block(n: u64) {
while System::block_number() < n {
Crowdloan::on_finalize(System::block_number());
Treasury::on_finalize(System::block_number());
Slots::on_finalize(System::block_number());
Balances::on_finalize(System::block_number());
System::on_finalize(System::block_number());
System::set_block_number(System::block_number() + 1);
System::on_initialize(System::block_number());
Balances::on_initialize(System::block_number());
Slots::on_initialize(System::block_number());
Treasury::on_initialize(System::block_number());
Crowdloan::on_initialize(System::block_number());
}
}
#[test]
fn basic_setup_works() {
new_test_ext().execute_with(|| {
assert_eq!(System::block_number(), 0);
assert_eq!(Crowdloan::fund_count(), 0);
assert_eq!(Crowdloan::funds(0), None);
assert_eq!(Crowdloan::new_raise(), empty);
assert_eq!(Crowdloan::contribution_get(0, &1), 0);
assert_eq!(Crowdloan::endings_count(), 0);
});
}
#[test]
fn create_works() {
new_test_ext().execute_with(|| {
// Now try to create a crowdloan campaign
assert_ok!(Crowdloan::create(Origin::signed(1), 1000, 1, 4, 9));
assert_eq!(Crowdloan::fund_count(), 1);
// This is what the initial `fund_info` should look like
let fund_info = FundInfo {
parachain: None,
owner: 1,
deposit: 1,
raised: 0,
// 5 blocks length + 3 block ending period + 1 starting block
end: 9,
cap: 1000,
last_contribution: LastContribution::Never,
first_slot: 1,
last_slot: 4,
deploy_data: None,
};
assert_eq!(Crowdloan::funds(0), Some(fund_info));
// User has deposit removed from their free balance
assert_eq!(Balances::free_balance(1), 999);
// Deposit is placed in crowdloan free balance
assert_eq!(Balances::free_balance(Crowdloan::fund_account_id(0)), 1);
// No new raise until first contribution
let empty: Vec<FundIndex> = Vec::new();
});
}
#[test]
fn create_handles_basic_errors() {
new_test_ext().execute_with(|| {
Crowdloan::create(Origin::signed(1), 1000, 4, 1, 9),
Error::<Test>::LastSlotBeforeFirstSlot
);
assert_noop!(
Crowdloan::create(Origin::signed(1), 1000, 1, 5, 9),
Error::<Test>::LastSlotTooFarInFuture
);
// Cannot create a crowdloan without some deposit funds
Crowdloan::create(Origin::signed(1337), 1000, 1, 3, 9),
BalancesError::<Test, _>::InsufficientBalance
);
});
}
#[test]
fn contribute_works() {
new_test_ext().execute_with(|| {
// Set up a crowdloan
assert_ok!(Crowdloan::create(Origin::signed(1), 1000, 1, 4, 9));
assert_eq!(Balances::free_balance(1), 999);
assert_eq!(Balances::free_balance(Crowdloan::fund_account_id(0)), 1);
assert_eq!(Crowdloan::contribution_get(0, &1), 0);
// User 1 contributes to their own crowdloan
assert_ok!(Crowdloan::contribute(Origin::signed(1), 0, 49));
// User 1 has spent some funds to do this, transfer fees **are** taken
assert_eq!(Crowdloan::contribution_get(0, &1), 49);
// Contributions appear in free balance of crowdloan
assert_eq!(Balances::free_balance(Crowdloan::fund_account_id(0)), 50);
// Crowdloan is added to NewRaise
assert_eq!(Crowdloan::new_raise(), vec![0]);
// Last contribution time recorded
assert_eq!(fund.last_contribution, LastContribution::PreEnding(0));
assert_eq!(fund.raised, 49);
});
}
#[test]
fn contribute_handles_basic_errors() {
new_test_ext().execute_with(|| {
// Cannot contribute to non-existing fund
assert_noop!(Crowdloan::contribute(Origin::signed(1), 0, 49), Error::<Test>::InvalidFundIndex);
// Cannot contribute below minimum contribution
assert_noop!(Crowdloan::contribute(Origin::signed(1), 0, 9), Error::<Test>::ContributionTooSmall);
// Set up a crowdloan
assert_ok!(Crowdloan::create(Origin::signed(1), 1000, 1, 4, 9));
assert_ok!(Crowdloan::contribute(Origin::signed(1), 0, 101));
assert_noop!(Crowdloan::contribute(Origin::signed(2), 0, 900), Error::<Test>::CapExceeded);
// Move past end date
run_to_block(10);
// Cannot contribute to ended fund
assert_noop!(Crowdloan::contribute(Origin::signed(1), 0, 49), Error::<Test>::ContributionPeriodOver);
});
}
#[test]
fn fix_deploy_data_works() {
new_test_ext().execute_with(|| {
// Set up a crowdloan
assert_ok!(Crowdloan::create(Origin::signed(1), 1000, 1, 4, 9));
assert_eq!(Balances::free_balance(1), 999);
// Add deploy data
<Test as frame_system::Config>::Hash::default(),
asynchronous rob
committed
vec![0].into()
// Confirm deploy data is stored correctly
assert_eq!(
fund.deploy_data,
Some(DeployData {
code_hash: <Test as frame_system::Config>::Hash::default(),
code_size: 0,
asynchronous rob
committed
initial_head_data: vec![0].into(),
});
}
#[test]
fn fix_deploy_data_handles_basic_errors() {
new_test_ext().execute_with(|| {
// Set up a crowdloan
assert_ok!(Crowdloan::create(Origin::signed(1), 1000, 1, 4, 9));
assert_eq!(Balances::free_balance(1), 999);
// Cannot set deploy data by non-owner
<Test as frame_system::Config>::Hash::default(),
asynchronous rob
committed
vec![0].into()),
Error::<Test>::InvalidOrigin
);
// Cannot set deploy data to an invalid index
<Test as frame_system::Config>::Hash::default(),
asynchronous rob
committed
vec![0].into()),
Error::<Test>::InvalidFundIndex
);
// Cannot set deploy data after it already has been set
<Test as frame_system::Config>::Hash::default(),
asynchronous rob
committed
vec![0].into(),
<Test as frame_system::Config>::Hash::default(),
asynchronous rob
committed
vec![1].into()),
Error::<Test>::ExistingDeployData
);
});
}
#[test]
fn onboard_works() {
new_test_ext().execute_with(|| {