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// Copyright 2017-2018 Parity Technologies (UK) Ltd.
// This file is part of Substrate.
// Substrate 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.
// Substrate 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 Substrate. If not, see <http://www.gnu.org/licenses/>.
//! Balances: Handles balances.
#![cfg_attr(not(feature = "std"), no_std)]
#[cfg(feature = "std")]
#[macro_use]
extern crate serde_derive;
#[macro_use]
extern crate parity_codec as codec;
extern crate sr_primitives as primitives;
extern crate srml_system as system;
#[cfg(test)]
extern crate sr_io as runtime_io;
#[cfg(test)]
extern crate substrate_primitives;
use rstd::prelude::*;
use rstd::{cmp, result};
use codec::{Encode, Decode, Codec, Input, Output, HasCompact};
use runtime_support::{StorageValue, StorageMap, Parameter};
use runtime_support::dispatch::Result;
use primitives::traits::{Zero, One, SimpleArithmetic, OnFinalise, MakePayment,
As, Lookup, Member, CheckedAdd, CheckedSub, CurrentHeight, BlockNumberToHash};
use address::Address as RawAddress;
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mod mock;
pub mod address;
mod tests;
/// Number of account IDs stored per enum set.
const ENUM_SET_SIZE: usize = 64;
/// The byte to identify intention to reclaim an existing account index.
const RECLAIM_INDEX_MAGIC: usize = 0x69;
pub type Address<T> = RawAddress<<T as system::Trait>::AccountId, <T as Trait>::AccountIndex>;
/// The account with the given id was killed.
pub trait OnFreeBalanceZero<AccountId> {
/// The account was the given id was killed.
fn on_free_balance_zero(who: &AccountId);
}
impl<AccountId> OnFreeBalanceZero<AccountId> for () {
fn on_free_balance_zero(_who: &AccountId) {}
}
impl<
AccountId,
X: OnFreeBalanceZero<AccountId>,
Y: OnFreeBalanceZero<AccountId>,
> OnFreeBalanceZero<AccountId> for (X, Y) {
fn on_free_balance_zero(who: &AccountId) {
X::on_free_balance_zero(who);
Y::on_free_balance_zero(who);
}
}
/// Trait for a hook to get called when some balance has been minted, causing dilution.
pub trait OnDilution<Balance> {
/// Some `portion` of the total balance just "grew" by `minted`. `portion` is the pre-growth
/// amount (it doesn't take account of the recent growth).
fn on_dilution(minted: Balance, portion: Balance);
impl<Balance> OnDilution<Balance> for () {
fn on_dilution(_minted: Balance, _portion: Balance) {}
/// Determinator for whether a given account is able to transfer balance.
pub trait EnsureAccountLiquid<AccountId> {
/// Returns `Ok` iff the account is able to transfer funds normally. `Err(...)`
/// with the reason why not otherwise.
fn ensure_account_liquid(who: &AccountId) -> Result;
}
impl<AccountId> EnsureAccountLiquid<AccountId> for () {
fn ensure_account_liquid(_who: &AccountId) -> Result { Ok(()) }
}
pub trait Trait: system::Trait {
/// The balance of an account.
type Balance: Parameter + SimpleArithmetic + Codec + Default + Copy + As<Self::AccountIndex> + As<usize> + As<u64>;
/// Type used for storing an account's index; implies the maximum number of accounts the system
/// can hold.
type AccountIndex: Parameter + Member + Codec + Default + SimpleArithmetic + As<u8> + As<u16> + As<u32> + As<u64> + As<usize> + Copy;
/// A function which is invoked when the free-balance has fallen below the existential deposit and
/// has been reduced to zero.
///
/// Gives a chance to clean up resources associated with the given account.
type OnFreeBalanceZero: OnFreeBalanceZero<Self::AccountId>;
/// A function that returns true iff a given account can transfer its funds to another account.
type EnsureAccountLiquid: EnsureAccountLiquid<Self::AccountId>;
type Event: From<Event<Self>> + Into<<Self as system::Trait>::Event>;
}
decl_module! {
pub struct Module<T: Trait> for enum Call where origin: T::Origin {
fn transfer(origin, dest: RawAddress<T::AccountId, T::AccountIndex>, value: <T::Balance as HasCompact>::Type) -> Result;
fn set_balance(who: RawAddress<T::AccountId, T::AccountIndex>, free: <T::Balance as HasCompact>::Type, reserved: <T::Balance as HasCompact>::Type) -> Result;
pub enum Event<T> where
<T as system::Trait>::AccountId,
<T as Trait>::AccountIndex,
<T as Trait>::Balance
{
/// A new account was created.
NewAccount(AccountId, AccountIndex, NewAccountOutcome),
/// An account was reaped.
ReapedAccount(AccountId),
/// Transfer succeeded (from, to, value, fees).
Transfer(AccountId, AccountId, Balance, Balance),
}
);
decl_storage! {
trait Store for Module<T: Trait> as Balances {
/// The total amount of stake on the system.
pub TotalIssuance get(total_issuance) build(|config: &GenesisConfig<T>| {
config.balances.iter().fold(Zero::zero(), |acc: T::Balance, &(_, n)| acc + n)
}): T::Balance;
/// The minimum amount allowed to keep an account open.
pub ExistentialDeposit get(existential_deposit) config(): T::Balance;
/// The amount credited to a destination's account whose index was reclaimed.
pub ReclaimRebate get(reclaim_rebate) config(): T::Balance;
/// The fee required to make a transfer.
pub TransferFee get(transfer_fee) config(): T::Balance;
/// The fee required to create an account. At least as big as ReclaimRebate.
pub CreationFee get(creation_fee) config(): T::Balance;
/// The next free enumeration set.
pub NextEnumSet get(next_enum_set) build(|config: &GenesisConfig<T>| {
T::AccountIndex::sa(config.balances.len() / ENUM_SET_SIZE)
}): T::AccountIndex;
pub EnumSet get(enum_set): map T::AccountIndex => Vec<T::AccountId>;
/// The 'free' balance of a given account.
///
/// This is the only balance that matters in terms of most operations on tokens. It is
/// alone used to determine the balance when in the contract execution environment. When this
/// balance falls below the value of `ExistentialDeposit`, then the 'current account' is
/// deleted: specifically `FreeBalance`. Furthermore, `OnFreeBalanceZero` callback
/// is invoked, giving a chance to external modules to cleanup data associated with
/// the deleted account.
///
/// `system::AccountNonce` is also deleted if `ReservedBalance` is also zero (it also gets
/// collapsed to zero if it ever becomes less than `ExistentialDeposit`.
pub FreeBalance get(free_balance) build(|config: &GenesisConfig<T>| config.balances.clone()): map T::AccountId => T::Balance;
/// The amount of the balance of a given account that is externally reserved; this can still get
/// slashed, but gets slashed last of all.
///
/// This balance is a 'reserve' balance that other subsystems use in order to set aside tokens
/// that are still 'owned' by the account holder, but which are suspendable. (This is different
/// and wholly unrelated to the `Bondage` system used in the staking module.)
///
/// When this balance falls below the value of `ExistentialDeposit`, then this 'reserve account'
/// is deleted: specifically, `ReservedBalance`.
///
/// `system::AccountNonce` is also deleted if `FreeBalance` is also zero (it also gets
/// collapsed to zero if it ever becomes less than `ExistentialDeposit`.
pub ReservedBalance get(reserved_balance): map T::AccountId => T::Balance;
// Payment stuff.
/// The fee to be paid for making a transaction; the base.
pub TransactionBaseFee get(transaction_base_fee) config(): T::Balance;
/// The fee to be paid for making a transaction; the per-byte portion.
pub TransactionByteFee get(transaction_byte_fee) config(): T::Balance;
}
add_extra_genesis {
config(balances): Vec<(T::AccountId, T::Balance)>;
build(|storage: &mut primitives::StorageMap, config: &GenesisConfig<T>| {
let ids: Vec<_> = config.balances.iter().map(|x| x.0.clone()).collect();
for i in 0..(ids.len() + ENUM_SET_SIZE - 1) / ENUM_SET_SIZE {
storage.insert(GenesisConfig::<T>::hash(&<EnumSet<T>>::key_for(T::AccountIndex::sa(i))).to_vec(),
ids[i * ENUM_SET_SIZE..ids.len().min((i + 1) * ENUM_SET_SIZE)].to_owned().encode());
}
});
}
}
/// Whatever happened about the hint given when creating the new account.
#[cfg_attr(feature = "std", derive(Serialize, Deserialize, Debug))]
#[derive(Encode, Decode, PartialEq, Eq, Clone, Copy)]
pub enum NewAccountOutcome {
NoHint,
GoodHint,
BadHint,
}
/// Outcome of a balance update.
pub enum UpdateBalanceOutcome {
/// Account balance was simply updated.
Updated,
/// The update has led to killing of the account.
AccountKilled,
}
impl<T: Trait> Module<T> {
/// Deposit one of this module's events.
fn deposit_event(event: Event<T>) {
<system::Module<T>>::deposit_event(<T as Trait>::Event::from(event).into());
}
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// PUBLIC IMMUTABLES
/// The combined balance of `who`.
pub fn total_balance(who: &T::AccountId) -> T::Balance {
Self::free_balance(who) + Self::reserved_balance(who)
}
/// Some result as `slash(who, value)` (but without the side-effects) assuming there are no
/// balance changes in the meantime and only the reserved balance is not taken into account.
pub fn can_slash(who: &T::AccountId, value: T::Balance) -> bool {
Self::free_balance(who) >= value
}
/// Same result as `reserve(who, value)` (but without the side-effects) assuming there
/// are no balance changes in the meantime.
pub fn can_reserve(who: &T::AccountId, value: T::Balance) -> bool {
if T::EnsureAccountLiquid::ensure_account_liquid(who).is_ok() {
Self::free_balance(who) >= value
} else {
false
}
}
/// Lookup an T::AccountIndex to get an Id, if there's one there.
pub fn lookup_index(index: T::AccountIndex) -> Option<T::AccountId> {
let enum_set_size = Self::enum_set_size();
let set = Self::enum_set(index / enum_set_size);
let i: usize = (index % enum_set_size).as_();
set.get(i).map(|x| x.clone())
}
/// `true` if the account `index` is ready for reclaim.
pub fn can_reclaim(try_index: T::AccountIndex) -> bool {
let enum_set_size = Self::enum_set_size();
let try_set = Self::enum_set(try_index / enum_set_size);
let i = (try_index % enum_set_size).as_();
i < try_set.len() && Self::total_balance(&try_set[i]).is_zero()
}
/// Lookup an address to get an Id, if there's one there.
pub fn lookup_address(a: address::Address<T::AccountId, T::AccountIndex>) -> Option<T::AccountId> {
match a {
address::Address::Id(i) => Some(i),
address::Address::Index(i) => Self::lookup_index(i),
}
}
// PUBLIC DISPATCH
/// Transfer some liquid free balance to another staker.
pub fn transfer(origin: T::Origin, dest: Address<T>, value: <T::Balance as HasCompact>::Type) -> Result {
let value = value.into();
let from_balance = Self::free_balance(&transactor);
let to_balance = Self::free_balance(&dest);
let would_create = to_balance.is_zero();
let fee = if would_create { Self::creation_fee() } else { Self::transfer_fee() };
let liability = match value.checked_add(&fee) {
Some(l) => l,
None => return Err("got overflow after adding a fee to value"),
};
let new_from_balance = match from_balance.checked_sub(&liability) {
Some(b) => b,
None => return Err("balance too low to send value"),
};
if would_create && value < Self::existential_deposit() {
return Err("value too low to create account");
}
T::EnsureAccountLiquid::ensure_account_liquid(&transactor)?;
// NOTE: total stake being stored in the same type means that this could never overflow
// but better to be safe than sorry.
let new_to_balance = match to_balance.checked_add(&value) {
Some(b) => b,
None => return Err("destination balance too high to receive value"),
};
Self::set_free_balance(&transactor, new_from_balance);
Self::decrease_total_stake_by(fee);
Self::set_free_balance_creating(&dest, new_to_balance);
Self::deposit_event(RawEvent::Transfer(transactor, dest, value, fee));
}
Ok(())
}
/// Set the balances of a given account.
fn set_balance(who: Address<T>, free: <T::Balance as HasCompact>::Type, reserved: <T::Balance as HasCompact>::Type) -> Result {
let who = Self::lookup(who)?;
Self::set_free_balance(&who, free.into());
Self::set_reserved_balance(&who, reserved.into());
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Ok(())
}
// PUBLIC MUTABLES (DANGEROUS)
/// Set the free balance of an account to some new value.
///
/// Will enforce ExistentialDeposit law, anulling the account as needed.
/// In that case it will return `AccountKilled`.
pub fn set_reserved_balance(who: &T::AccountId, balance: T::Balance) -> UpdateBalanceOutcome {
if balance < Self::existential_deposit() {
<ReservedBalance<T>>::insert(who, balance);
Self::on_reserved_too_low(who);
UpdateBalanceOutcome::AccountKilled
} else {
<ReservedBalance<T>>::insert(who, balance);
UpdateBalanceOutcome::Updated
}
}
/// Set the free balance of an account to some new value. Will enforce ExistentialDeposit
/// law anulling the account as needed.
///
/// Doesn't do any preparatory work for creating a new account, so should only be used when it
/// is known that the account already exists.
///
/// Returns if the account was successfully updated or update has led to killing of the account.
pub fn set_free_balance(who: &T::AccountId, balance: T::Balance) -> UpdateBalanceOutcome {
// Commented out for no - but consider it instructive.
// assert!(!Self::total_balance(who).is_zero());
if balance < Self::existential_deposit() {
<FreeBalance<T>>::insert(who, balance);
Self::on_free_too_low(who);
UpdateBalanceOutcome::AccountKilled
} else {
<FreeBalance<T>>::insert(who, balance);
UpdateBalanceOutcome::Updated
}
}
/// Set the free balance on an account to some new value.
///
/// Same as [`set_free_balance`], but will create a new account.
///
/// Returns if the account was successfully updated or update has led to killing of the account.
///
/// [`set_free_balance`]: #method.set_free_balance
pub fn set_free_balance_creating(who: &T::AccountId, balance: T::Balance) -> UpdateBalanceOutcome {
let ed = <Module<T>>::existential_deposit();
// If the balance is too low, then the account is reaped.
// NOTE: There are two balances for every account: `reserved_balance` and
// `free_balance`. This contract subsystem only cares about the latter: whenever
// the term "balance" is used *here* it should be assumed to mean "free balance"
// in the rest of the module.
// Free balance can never be less than ED. If that happens, it gets reduced to zero
// and the account information relevant to this subsystem is deleted (i.e. the
// account is reaped).
// NOTE: This is orthogonal to the `Bondage` value that an account has, a high
// value of which makes even the `free_balance` unspendable.
// TODO: enforce this for the other balance-altering functions.
if balance < ed {
Self::set_free_balance(who, balance);
UpdateBalanceOutcome::AccountKilled
} else {
if !<FreeBalance<T>>::exists(who) {
let outcome = Self::new_account(&who, balance);
let credit = match outcome {
NewAccountOutcome::GoodHint => balance + <Module<T>>::reclaim_rebate(),
_ => balance,
};
Self::set_free_balance(who, credit);
Self::increase_total_stake_by(credit - balance);
Self::set_free_balance(who, balance);
}
UpdateBalanceOutcome::Updated
}
}
/// Adds up to `value` to the free balance of `who`. If `who` doesn't exist, it is created.
///
/// This is a sensitive function since it circumvents any fees associated with account
/// setup. Ensure it is only called by trusted code.
///
/// NOTE: This assumes that the total stake remains unchanged after this operation. If
/// you mean to actually mint value into existence, then use `reward` instead.
pub fn increase_free_balance_creating(who: &T::AccountId, value: T::Balance) -> UpdateBalanceOutcome {
Self::set_free_balance_creating(who, Self::free_balance(who) + value)
}
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/// Deducts up to `value` from the combined balance of `who`, preferring to deduct from the
/// free balance. This function cannot fail.
///
/// As much funds up to `value` will be deducted as possible. If this is less than `value`,
/// then `Some(remaining)` will be returned. Full completion is given by `None`.
pub fn slash(who: &T::AccountId, value: T::Balance) -> Option<T::Balance> {
let free_balance = Self::free_balance(who);
let free_slash = cmp::min(free_balance, value);
Self::set_free_balance(who, free_balance - free_slash);
Self::decrease_total_stake_by(free_slash);
if free_slash < value {
Self::slash_reserved(who, value - free_slash)
} else {
None
}
}
/// Adds up to `value` to the free balance of `who`.
///
/// If `who` doesn't exist, nothing is done and an Err returned.
pub fn reward(who: &T::AccountId, value: T::Balance) -> Result {
if Self::total_balance(who).is_zero() {
return Err("beneficiary account must pre-exist");
}
Self::set_free_balance(who, Self::free_balance(who) + value);
Self::increase_total_stake_by(value);
Ok(())
}
/// Moves `value` from balance to reserved balance.
///
/// If the free balance is lower than `value`, then no funds will be moved and an `Err` will
/// be returned to notify of this. This is different behaviour to `unreserve`.
pub fn reserve(who: &T::AccountId, value: T::Balance) -> Result {
let b = Self::free_balance(who);
if b < value {
return Err("not enough free funds")
}
T::EnsureAccountLiquid::ensure_account_liquid(who)?;
Self::set_reserved_balance(who, Self::reserved_balance(who) + value);
Self::set_free_balance(who, b - value);
Ok(())
}
/// Moves up to `value` from reserved balance to balance. This function cannot fail.
///
/// As much funds up to `value` will be deducted as possible. If this is less than `value`,
/// then `Some(remaining)` will be returned. Full completion is given by `None`.
/// NOTE: This is different to `reserve`.
pub fn unreserve(who: &T::AccountId, value: T::Balance) -> Option<T::Balance> {
let b = Self::reserved_balance(who);
let actual = cmp::min(b, value);
Self::set_free_balance(who, Self::free_balance(who) + actual);
Self::set_reserved_balance(who, b - actual);
if actual == value {
None
} else {
Some(value - actual)
}
}
/// Deducts up to `value` from reserved balance of `who`. This function cannot fail.
///
/// As much funds up to `value` will be deducted as possible. If this is less than `value`,
/// then `Some(remaining)` will be returned. Full completion is given by `None`.
pub fn slash_reserved(who: &T::AccountId, value: T::Balance) -> Option<T::Balance> {
let b = Self::reserved_balance(who);
let slash = cmp::min(b, value);
Self::set_reserved_balance(who, b - slash);
Self::decrease_total_stake_by(slash);
if value == slash {
None
} else {
Some(value - slash)
}
}
/// Moves up to `value` from reserved balance of account `slashed` to free balance of account
/// `beneficiary`. `beneficiary` must exist for this to succeed. If it does not, `Err` will be
/// returned.
///
/// As much funds up to `value` will be moved as possible. If this is less than `value`, then
/// `Ok(Some(remaining))` will be returned. Full completion is given by `Ok(None)`.
pub fn repatriate_reserved(
slashed: &T::AccountId,
beneficiary: &T::AccountId,
value: T::Balance
) -> result::Result<Option<T::Balance>, &'static str> {
if Self::total_balance(beneficiary).is_zero() {
return Err("beneficiary account must pre-exist");
}
let b = Self::reserved_balance(slashed);
let slash = cmp::min(b, value);
Self::set_free_balance(beneficiary, Self::free_balance(beneficiary) + slash);
Self::set_reserved_balance(slashed, b - slash);
if value == slash {
Ok(None)
} else {
Ok(Some(value - slash))
}
}
fn enum_set_size() -> T::AccountIndex {
T::AccountIndex::sa(ENUM_SET_SIZE)
}
/// Register a new account (with existential balance).
fn new_account(who: &T::AccountId, balance: T::Balance) -> NewAccountOutcome {
let enum_set_size = Self::enum_set_size();
let next_set_index = Self::next_enum_set();
let reclaim_index_magic = T::AccountIndex::sa(RECLAIM_INDEX_MAGIC);
let reclaim_index_modulus = T::AccountIndex::sa(256usize);
let quantization = T::AccountIndex::sa(256usize);
// A little easter-egg for reclaiming dead indexes..
let ret = {
// we quantise the number of accounts so it stays constant over a reasonable
// period of time.
let quantized_account_count: T::AccountIndex = (next_set_index * enum_set_size / quantization + One::one()) * quantization;
// then modify the starting balance to be modulo this to allow it to potentially
// identify an account index for reuse.
let maybe_try_index = balance % <T::Balance as As<T::AccountIndex>>::sa(quantized_account_count * reclaim_index_modulus);
let maybe_try_index = As::<T::AccountIndex>::as_(maybe_try_index);
// this identifier must end with magic byte 0x69 to trigger this check (a minor
// optimisation to ensure we don't check most unintended account creations).
if maybe_try_index % reclaim_index_modulus == reclaim_index_magic {
// reuse is probably intended. first, remove magic byte.
let try_index = maybe_try_index / reclaim_index_modulus;
// then check to see if this balance identifies a dead account index.
let set_index = try_index / enum_set_size;
let mut try_set = Self::enum_set(set_index);
let item_index = (try_index % enum_set_size).as_();
if item_index < try_set.len() {
if Self::total_balance(&try_set[item_index]).is_zero() {
// yup - this index refers to a dead account. can be reused.
try_set[item_index] = who.clone();
<EnumSet<T>>::insert(set_index, try_set);
Self::deposit_event(RawEvent::NewAccount(who.clone(), try_index, NewAccountOutcome::GoodHint));
return NewAccountOutcome::GoodHint
}
}
NewAccountOutcome::BadHint
} else {
NewAccountOutcome::NoHint
}
};
// insert normally as a back up
let mut set_index = next_set_index;
// defensive only: this loop should never iterate since we keep NextEnumSet up to date later.
let mut set = loop {
let set = Self::enum_set(set_index);
if set.len() < ENUM_SET_SIZE {
break set;
}
set_index += One::one();
};
let index = T::AccountIndex::sa(set_index.as_() * ENUM_SET_SIZE + set.len());
// update set.
set.push(who.clone());
// keep NextEnumSet up to date
if set.len() == ENUM_SET_SIZE {
<NextEnumSet<T>>::put(set_index + One::one());
}
// write set.
<EnumSet<T>>::insert(set_index, set);
Self::deposit_event(RawEvent::NewAccount(who.clone(), index, ret));
ret
}
fn reap_account(who: &T::AccountId) {
<system::AccountNonce<T>>::remove(who);
Self::deposit_event(RawEvent::ReapedAccount(who.clone()));
}
/// Kill an account's free portion.
fn on_free_too_low(who: &T::AccountId) {
Self::decrease_total_stake_by(Self::free_balance(who));
<FreeBalance<T>>::remove(who);
T::OnFreeBalanceZero::on_free_balance_zero(who);
if Self::reserved_balance(who).is_zero() {
Self::reap_account(who);
}
}
/// Kill an account's reserved portion.
fn on_reserved_too_low(who: &T::AccountId) {
Self::decrease_total_stake_by(Self::reserved_balance(who));
<ReservedBalance<T>>::remove(who);
if Self::free_balance(who).is_zero() {
Self::reap_account(who);
}
}
/// Increase TotalIssuance by Value.
pub fn increase_total_stake_by(value: T::Balance) {
if let Some(v) = <Module<T>>::total_issuance().checked_add(&value) {
<TotalIssuance<T>>::put(v);
}
}
/// Decrease TotalIssuance by Value.
pub fn decrease_total_stake_by(value: T::Balance) {
if let Some(v) = <Module<T>>::total_issuance().checked_sub(&value) {
<TotalIssuance<T>>::put(v);
}
}
pub fn lookup(a: address::Address<T::AccountId, T::AccountIndex>) -> result::Result<T::AccountId, &'static str> {
match a {
address::Address::Id(i) => Ok(i),
address::Address::Index(i) => <Module<T>>::lookup_index(i).ok_or("invalid account index"),
}
}
impl<T: Trait> OnFinalise<T::BlockNumber> for Module<T> {
fn on_finalise(_n: T::BlockNumber) {
pub struct ChainContext<T>(::rstd::marker::PhantomData<T>);
impl<T> Default for ChainContext<T> {
fn default() -> Self {
ChainContext(::rstd::marker::PhantomData)
}
}
impl<T: Trait> Lookup for ChainContext<T> {
type Source = address::Address<T::AccountId, T::AccountIndex>;
type Target = T::AccountId;
fn lookup(&self, a: Self::Source) -> result::Result<Self::Target, &'static str> {
<Module<T>>::lookup(a)
}
}
impl<T: Trait> CurrentHeight for ChainContext<T> {
fn current_height(&self) -> Self::BlockNumber {
<system::Module<T>>::block_number()
}
}
impl<T: Trait> BlockNumberToHash for ChainContext<T> {
type BlockNumber = T::BlockNumber;
type Hash = T::Hash;
fn block_number_to_hash(&self, n: Self::BlockNumber) -> Option<Self::Hash> {
Some(<system::Module<T>>::block_hash(n))
}
}
impl<T: Trait> MakePayment<T::AccountId> for Module<T> {
fn make_payment(transactor: &T::AccountId, encoded_len: usize) -> Result {
let b = Self::free_balance(transactor);
let transaction_fee = Self::transaction_base_fee() + Self::transaction_byte_fee() * <T::Balance as As<u64>>::sa(encoded_len as u64);
if b < transaction_fee + Self::existential_deposit() {
return Err("not enough funds for transaction fee");
}
Self::set_free_balance(transactor, b - transaction_fee);
Self::decrease_total_stake_by(transaction_fee);
Ok(())
}
}