// Copyright 2017-2019 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 . //! # Balances Module //! //! The Balances module provides functionality for handling accounts and balances. //! //! - [`balances::Trait`](./trait.Trait.html) //! - [`Call`](./enum.Call.html) //! - [`Module`](./struct.Module.html) //! //! ## Overview //! //! The Balances module provides functions for: //! //! - Getting and setting free balances. //! - Retrieving total, reserved and unreserved balances. //! - Repatriating a reserved balance to a beneficiary account that exists. //! - Transferring a balance between accounts (when not reserved). //! - Slashing an account balance. //! - Account creation and removal. //! - Managing total issuance. //! - Setting and managing locks. //! //! ### Terminology //! //! - **Existential Deposit:** The minimum balance required to create or keep an account open. This prevents //! "dust accounts" from filling storage. //! - **Total Issuance:** The total number of units in existence in a system. //! - **Reaping an account:** The act of removing an account by resetting its nonce. Happens after its balance is set //! to zero. //! - **Free Balance:** The portion of a balance that is not reserved. The free balance is the only balance that matters //! for most operations. When this balance falls below the existential deposit, most functionality of the account is //! removed. When both it and the reserved balance are deleted, then the account is said to be dead. //! - **Reserved Balance:** Reserved balance still belongs to the account holder, but is suspended. Reserved balance //! can still be slashed, but only after all the free balance has been slashed. If the reserved balance falls below the //! existential deposit then it and any related functionality will be deleted. When both it and the free balance are //! deleted, then the account is said to be dead. //! - **Imbalance:** A condition when some funds were credited or debited without equal and opposite accounting //! (i.e. a difference between total issuance and account balances). Functions that result in an imbalance will //! return an object of the `Imbalance` trait that can be managed within your runtime logic. (If an imbalance is //! simply dropped, it should automatically maintain any book-keeping such as total issuance.) //! - **Lock:** A freeze on a specified amount of an account's free balance until a specified block number. Multiple //! locks always operate over the same funds, so they "overlay" rather than "stack". //! - **Vesting:** Similar to a lock, this is another, but independent, liquidity restriction that reduces linearly //! over time. //! //! ### Implementations //! //! The Balances module provides implementations for the following traits. If these traits provide the functionality //! that you need, then you can avoid coupling with the Balances module. //! //! - [`Currency`](../srml_support/traits/trait.Currency.html): Functions for dealing with a //! fungible assets system. //! - [`ReservableCurrency`](../srml_support/traits/trait.ReservableCurrency.html): //! Functions for dealing with assets that can be reserved from an account. //! - [`LockableCurrency`](../srml_support/traits/trait.LockableCurrency.html): Functions for //! dealing with accounts that allow liquidity restrictions. //! - [`Imbalance`](../srml_support/traits/trait.Imbalance.html): Functions for handling //! imbalances between total issuance in the system and account balances. Must be used when a function //! creates new funds (e.g. a reward) or destroys some funds (e.g. a system fee). //! - [`MakePayment`](../srml_support/traits/trait.MakePayment.html): Simple trait designed //! for hooking into a transaction payment. //! - [`IsDeadAccount`](../srml_system/trait.IsDeadAccount.html): Determiner to say whether a //! given account is unused. //! //! ## Interface //! //! ### Dispatchable Functions //! //! - `transfer` - Transfer some liquid free balance to another account. //! - `set_balance` - Set the balances of a given account. The origin of this call must be root. //! //! ### Public Functions //! //! - `vesting_balance` - Get the amount that is currently being vested and cannot be transferred out of this account. //! //! ## Usage //! //! The following examples show how to use the Balances module in your custom module. //! //! ### Examples from the SRML //! //! The Contract module uses the `Currency` trait to handle gas payment, and its types inherit from `Currency`: //! //! ``` //! use srml_support::traits::Currency; //! # pub trait Trait: system::Trait { //! # type Currency: Currency; //! # } //! //! pub type BalanceOf = <::Currency as Currency<::AccountId>>::Balance; //! pub type NegativeImbalanceOf = <::Currency as Currency<::AccountId>>::NegativeImbalance; //! //! # fn main() {} //! ``` //! //! The Staking module uses the `LockableCurrency` trait to lock a stash account's funds: //! //! ``` //! use srml_support::traits::{WithdrawReasons, LockableCurrency}; //! use primitives::traits::Bounded; //! pub trait Trait: system::Trait { //! type Currency: LockableCurrency; //! } //! # struct StakingLedger { //! # stash: ::AccountId, //! # total: <::Currency as srml_support::traits::Currency<::AccountId>>::Balance, //! # phantom: std::marker::PhantomData, //! # } //! # const STAKING_ID: [u8; 8] = *b"staking "; //! //! fn update_ledger( //! controller: &T::AccountId, //! ledger: &StakingLedger //! ) { //! T::Currency::set_lock( //! STAKING_ID, //! &ledger.stash, //! ledger.total, //! T::BlockNumber::max_value(), //! WithdrawReasons::all() //! ); //! // >::insert(controller, ledger); // Commented out as we don't have access to Staking's storage here. //! } //! # fn main() {} //! ``` //! //! ## Genesis config //! //! The Balances module depends on the [`GenesisConfig`](./struct.GenesisConfig.html). #![cfg_attr(not(feature = "std"), no_std)] use rstd::prelude::*; use rstd::{cmp, result}; use parity_codec::{Codec, Encode, Decode}; use srml_support::{StorageValue, StorageMap, Parameter, decl_event, decl_storage, decl_module}; use srml_support::traits::{ UpdateBalanceOutcome, Currency, OnFreeBalanceZero, MakePayment, OnUnbalanced, WithdrawReason, WithdrawReasons, LockIdentifier, LockableCurrency, ExistenceRequirement, Imbalance, SignedImbalance, ReservableCurrency }; use srml_support::dispatch::Result; use primitives::traits::{ Zero, SimpleArithmetic, StaticLookup, Member, CheckedAdd, CheckedSub, MaybeSerializeDebug, Saturating }; use system::{IsDeadAccount, OnNewAccount, ensure_signed}; mod mock; mod tests; pub use self::imbalances::{PositiveImbalance, NegativeImbalance}; pub trait Subtrait: system::Trait { /// The balance of an account. type Balance: Parameter + Member + SimpleArithmetic + Codec + Default + Copy + MaybeSerializeDebug + From; /// A function that 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; /// Handler for when a new account is created. type OnNewAccount: OnNewAccount; } pub trait Trait: system::Trait { /// The balance of an account. type Balance: Parameter + Member + SimpleArithmetic + Codec + Default + Copy + MaybeSerializeDebug + From; /// A function that 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; /// Handler for when a new account is created. type OnNewAccount: OnNewAccount; /// Handler for the unbalanced reduction when taking transaction fees. type TransactionPayment: OnUnbalanced>; /// Handler for the unbalanced reduction when taking fees associated with balance /// transfer (which may also include account creation). type TransferPayment: OnUnbalanced>; /// Handler for the unbalanced reduction when removing a dust account. type DustRemoval: OnUnbalanced>; /// The overarching event type. type Event: From> + Into<::Event>; } impl, I: Instance> Subtrait for T { type Balance = T::Balance; type OnFreeBalanceZero = T::OnFreeBalanceZero; type OnNewAccount = T::OnNewAccount; } decl_event!( pub enum Event where ::AccountId, >::Balance { /// A new account was created. NewAccount(AccountId, Balance), /// An account was reaped. ReapedAccount(AccountId), /// Transfer succeeded (from, to, value, fees). Transfer(AccountId, AccountId, Balance, Balance), } ); /// Struct to encode the vesting schedule of an individual account. #[derive(Encode, Decode, Copy, Clone, PartialEq, Eq)] #[cfg_attr(feature = "std", derive(Debug))] pub struct VestingSchedule { /// Locked amount at genesis. pub offset: Balance, /// Amount that gets unlocked every block from genesis. pub per_block: Balance, } impl VestingSchedule { /// Amount locked at block `n`. pub fn locked_at(&self, n: BlockNumber) -> Balance where Balance: From { if let Some(x) = Balance::from(n).checked_mul(&self.per_block) { self.offset.max(x) - x } else { Zero::zero() } } } #[derive(Encode, Decode, Clone, PartialEq, Eq)] #[cfg_attr(feature = "std", derive(Debug))] pub struct BalanceLock { pub id: LockIdentifier, pub amount: Balance, pub until: BlockNumber, pub reasons: WithdrawReasons, } decl_storage! { trait Store for Module, I: Instance=DefaultInstance> as Balances { /// The total units issued in the system. pub TotalIssuance get(total_issuance) build(|config: &GenesisConfig| { config.balances.iter().fold(Zero::zero(), |acc: T::Balance, &(_, n)| acc + n) }): T::Balance; /// The minimum amount required to keep an account open. pub ExistentialDeposit get(existential_deposit) 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. pub CreationFee get(creation_fee) config(): T::Balance; /// 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; /// Information regarding the vesting of a given account. pub Vesting get(vesting) build(|config: &GenesisConfig| { config.vesting.iter().filter_map(|&(ref who, begin, length)| { let begin = >::from(begin); let length = >::from(length); config.balances.iter() .find(|&&(ref w, _)| w == who) .map(|&(_, balance)| { // <= begin it should be >= balance // >= begin+length it should be <= 0 let per_block = balance / length.max(primitives::traits::One::one()); let offset = begin * per_block + balance; (who.clone(), VestingSchedule { offset, per_block }) }) }).collect::>() }): map T::AccountId => Option>; /// The 'free' balance of a given account. /// /// This is the only balance that matters in terms of most operations on tokens. It /// alone is 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`. Further, the `OnFreeBalanceZero` callback /// is invoked, giving a chance to external modules to clean up 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| 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. /// /// 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; /// Any liquidity locks on some account balances. pub Locks get(locks): map T::AccountId => Vec>; } add_extra_genesis { config(balances): Vec<(T::AccountId, T::Balance)>; config(vesting): Vec<(T::AccountId, T::BlockNumber, T::BlockNumber)>; // begin, length } extra_genesis_skip_phantom_data_field; } decl_module! { pub struct Module, I: Instance = DefaultInstance> for enum Call where origin: T::Origin { fn deposit_event() = default; /// Transfer some liquid free balance to another account. /// /// `transfer` will set the `FreeBalance` of the sender and receiver. /// It will decrease the total issuance of the system by the `TransferFee`. /// If the sender's account is below the existential deposit as a result /// of the transfer, the account will be reaped. /// /// The dispatch origin for this call must be `Signed` by the transactor. /// /// # /// - Dependent on arguments but not critical, given proper implementations for /// input config types. See related functions below. /// - It contains a limited number of reads and writes internally and no complex computation. /// /// Related functions: /// /// - `ensure_can_withdraw` is always called internally but has a bounded complexity. /// - Transferring balances to accounts that did not exist before will cause /// `T::OnNewAccount::on_new_account` to be called. /// - Removing enough funds from an account will trigger /// `T::DustRemoval::on_unbalanced` and `T::OnFreeBalanceZero::on_free_balance_zero`. /// /// # pub fn transfer( origin, dest: ::Source, #[compact] value: T::Balance ) { let transactor = ensure_signed(origin)?; let dest = T::Lookup::lookup(dest)?; >::transfer(&transactor, &dest, value)?; } /// Set the balances of a given account. /// /// This will alter `FreeBalance` and `ReservedBalance` in storage. /// If the new free or reserved balance is below the existential deposit, /// it will also decrease the total issuance of the system (`TotalIssuance`) /// and reset the account nonce (`system::AccountNonce`). /// /// The dispatch origin for this call is `root`. /// /// # /// - Independent of the arguments. /// - Contains a limited number of reads and writes. /// # fn set_balance( who: ::Source, #[compact] free: T::Balance, #[compact] reserved: T::Balance ) { let who = T::Lookup::lookup(who)?; Self::set_free_balance(&who, free); Self::set_reserved_balance(&who, reserved); } } } impl, I: Instance> Module { // PUBLIC IMMUTABLES /// Get the amount that is currently being vested and cannot be transferred out of this account. pub fn vesting_balance(who: &T::AccountId) -> T::Balance { if let Some(v) = Self::vesting(who) { Self::free_balance(who) .min(v.locked_at::(>::block_number())) } else { Zero::zero() } } // PRIVATE MUTABLES /// Set the reserved balance of an account to some new value. Will enforce `ExistentialDeposit` /// law, annulling 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. /// /// NOTE: LOW-LEVEL: This will not attempt to maintain total issuance. It is expected that /// the caller will do this. fn set_reserved_balance(who: &T::AccountId, balance: T::Balance) -> UpdateBalanceOutcome { if balance < Self::existential_deposit() { >::insert(who, balance); Self::on_reserved_too_low(who); UpdateBalanceOutcome::AccountKilled } else { >::insert(who, balance); UpdateBalanceOutcome::Updated } } /// Set the free balance of an account to some new value. Will enforce `ExistentialDeposit` /// law, annulling 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. /// /// NOTE: LOW-LEVEL: This will not attempt to maintain total issuance. It is expected that /// the caller will do this. fn set_free_balance(who: &T::AccountId, balance: T::Balance) -> UpdateBalanceOutcome { // Commented out for now - but consider it instructive. // assert!(!Self::total_balance(who).is_zero()); // assert!(Self::free_balance(who) > Self::existential_deposit()); if balance < Self::existential_deposit() { >::insert(who, balance); Self::on_free_too_low(who); UpdateBalanceOutcome::AccountKilled } else { >::insert(who, balance); UpdateBalanceOutcome::Updated } } /// Register a new account (with existential balance). /// /// This just calls appropriate hooks. It doesn't (necessarily) make any state changes. fn new_account(who: &T::AccountId, balance: T::Balance) { T::OnNewAccount::on_new_account(&who); Self::deposit_event(RawEvent::NewAccount(who.clone(), balance.clone())); } /// Unregister an account. /// /// This just removes the nonce and leaves an event. fn reap_account(who: &T::AccountId) { >::remove(who); Self::deposit_event(RawEvent::ReapedAccount(who.clone())); } /// Account's free balance has dropped below existential deposit. Kill its /// free side and the account completely if its reserved size is already dead. /// /// Will maintain total issuance. fn on_free_too_low(who: &T::AccountId) { let dust = >::take(who); >::remove(who); // underflow should never happen, but if it does, there's not much we can do about it. if !dust.is_zero() { T::DustRemoval::on_unbalanced(NegativeImbalance::new(dust)); } T::OnFreeBalanceZero::on_free_balance_zero(who); if Self::reserved_balance(who).is_zero() { Self::reap_account(who); } } /// Account's reserved balance has dropped below existential deposit. Kill its /// reserved side and the account completely if its free size is already dead. /// /// Will maintain total issuance. fn on_reserved_too_low(who: &T::AccountId) { let dust = >::take(who); // underflow should never happen, but it if does, there's nothing to be done here. if !dust.is_zero() { T::DustRemoval::on_unbalanced(NegativeImbalance::new(dust)); } if Self::free_balance(who).is_zero() { Self::reap_account(who); } } } // wrapping these imbalances in a private module is necessary to ensure absolute privacy // of the inner member. mod imbalances { use super::{ result, Subtrait, DefaultInstance, Imbalance, Trait, Zero, Instance, Saturating, StorageValue, }; use rstd::mem; /// Opaque, move-only struct with private fields that serves as a token denoting that /// funds have been created without any equal and opposite accounting. #[must_use] pub struct PositiveImbalance, I: Instance=DefaultInstance>(T::Balance); impl, I: Instance> PositiveImbalance { /// Create a new positive imbalance from a balance. pub fn new(amount: T::Balance) -> Self { PositiveImbalance(amount) } } /// Opaque, move-only struct with private fields that serves as a token denoting that /// funds have been destroyed without any equal and opposite accounting. #[must_use] pub struct NegativeImbalance, I: Instance=DefaultInstance>(T::Balance); impl, I: Instance> NegativeImbalance { /// Create a new negative imbalance from a balance. pub fn new(amount: T::Balance) -> Self { NegativeImbalance(amount) } } impl, I: Instance> Imbalance for PositiveImbalance { type Opposite = NegativeImbalance; fn zero() -> Self { Self(Zero::zero()) } fn drop_zero(self) -> result::Result<(), Self> { if self.0.is_zero() { Ok(()) } else { Err(self) } } fn split(self, amount: T::Balance) -> (Self, Self) { let first = self.0.min(amount); let second = self.0 - first; mem::forget(self); (Self(first), Self(second)) } fn merge(mut self, other: Self) -> Self { self.0 = self.0.saturating_add(other.0); mem::forget(other); self } fn subsume(&mut self, other: Self) { self.0 = self.0.saturating_add(other.0); mem::forget(other); } fn offset(self, other: Self::Opposite) -> result::Result { let (a, b) = (self.0, other.0); mem::forget((self, other)); if a >= b { Ok(Self(a - b)) } else { Err(NegativeImbalance::new(b - a)) } } fn peek(&self) -> T::Balance { self.0.clone() } } impl, I: Instance> Imbalance for NegativeImbalance { type Opposite = PositiveImbalance; fn zero() -> Self { Self(Zero::zero()) } fn drop_zero(self) -> result::Result<(), Self> { if self.0.is_zero() { Ok(()) } else { Err(self) } } fn split(self, amount: T::Balance) -> (Self, Self) { let first = self.0.min(amount); let second = self.0 - first; mem::forget(self); (Self(first), Self(second)) } fn merge(mut self, other: Self) -> Self { self.0 = self.0.saturating_add(other.0); mem::forget(other); self } fn subsume(&mut self, other: Self) { self.0 = self.0.saturating_add(other.0); mem::forget(other); } fn offset(self, other: Self::Opposite) -> result::Result { let (a, b) = (self.0, other.0); mem::forget((self, other)); if a >= b { Ok(Self(a - b)) } else { Err(PositiveImbalance::new(b - a)) } } fn peek(&self) -> T::Balance { self.0.clone() } } impl, I: Instance> Drop for PositiveImbalance { /// Basic drop handler will just square up the total issuance. fn drop(&mut self) { , I>>::mutate( |v| *v = v.saturating_add(self.0) ); } } impl, I: Instance> Drop for NegativeImbalance { /// Basic drop handler will just square up the total issuance. fn drop(&mut self) { , I>>::mutate( |v| *v = v.saturating_sub(self.0) ); } } } // TODO: #2052 // Somewhat ugly hack in order to gain access to module's `increase_total_issuance_by` // using only the Subtrait (which defines only the types that are not dependent // on Positive/NegativeImbalance). Subtrait must be used otherwise we end up with a // circular dependency with Trait having some types be dependent on PositiveImbalance // and PositiveImbalance itself depending back on Trait for its Drop impl (and thus // its type declaration). // This works as long as `increase_total_issuance_by` doesn't use the Imbalance // types (basically for charging fees). // This should eventually be refactored so that the three type items that do // depend on the Imbalance type (TransactionPayment, TransferPayment, DustRemoval) // are placed in their own SRML module. struct ElevatedTrait, I: Instance>(T, I); impl, I: Instance> Clone for ElevatedTrait { fn clone(&self) -> Self { unimplemented!() } } impl, I: Instance> PartialEq for ElevatedTrait { fn eq(&self, _: &Self) -> bool { unimplemented!() } } impl, I: Instance> Eq for ElevatedTrait {} impl, I: Instance> system::Trait for ElevatedTrait { type Origin = T::Origin; type Index = T::Index; type BlockNumber = T::BlockNumber; type Hash = T::Hash; type Hashing = T::Hashing; type Digest = T::Digest; type AccountId = T::AccountId; type Lookup = T::Lookup; type Header = T::Header; type Event = (); type Log = T::Log; } impl, I: Instance> Trait for ElevatedTrait { type Balance = T::Balance; type OnFreeBalanceZero = T::OnFreeBalanceZero; type OnNewAccount = T::OnNewAccount; type Event = (); type TransactionPayment = (); type TransferPayment = (); type DustRemoval = (); } impl, I: Instance> Currency for Module where T::Balance: MaybeSerializeDebug { type Balance = T::Balance; type PositiveImbalance = PositiveImbalance; type NegativeImbalance = NegativeImbalance; fn total_balance(who: &T::AccountId) -> Self::Balance { Self::free_balance(who) + Self::reserved_balance(who) } fn can_slash(who: &T::AccountId, value: Self::Balance) -> bool { Self::free_balance(who) >= value } fn total_issuance() -> Self::Balance { >::get() } fn minimum_balance() -> Self::Balance { Self::existential_deposit() } fn free_balance(who: &T::AccountId) -> Self::Balance { >::get(who) } // # // Despite iterating over a list of locks, they are limited by the number of // lock IDs, which means the number of runtime modules that intend to use and create locks. // # fn ensure_can_withdraw( who: &T::AccountId, _amount: T::Balance, reason: WithdrawReason, new_balance: T::Balance, ) -> Result { match reason { WithdrawReason::Reserve | WithdrawReason::Transfer if Self::vesting_balance(who) > new_balance => return Err("vesting balance too high to send value"), _ => {} } let locks = Self::locks(who); if locks.is_empty() { return Ok(()) } let now = >::block_number(); if locks.into_iter() .all(|l| now >= l.until || new_balance >= l.amount || !l.reasons.contains(reason) ) { Ok(()) } else { Err("account liquidity restrictions prevent withdrawal") } } fn transfer(transactor: &T::AccountId, dest: &T::AccountId, value: Self::Balance) -> Result { 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) { None => return Err("balance too low to send value"), Some(b) => b, }; if would_create && value < Self::existential_deposit() { return Err("value too low to create account"); } Self::ensure_can_withdraw(transactor, value, WithdrawReason::Transfer, new_from_balance)?; // 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"), }; if transactor != dest { Self::set_free_balance(transactor, new_from_balance); if !>::exists(dest) { Self::new_account(dest, new_to_balance); } Self::set_free_balance(dest, new_to_balance); T::TransferPayment::on_unbalanced(NegativeImbalance::new(fee)); Self::deposit_event(RawEvent::Transfer(transactor.clone(), dest.clone(), value, fee)); } Ok(()) } fn withdraw( who: &T::AccountId, value: Self::Balance, reason: WithdrawReason, liveness: ExistenceRequirement, ) -> result::Result { if let Some(new_balance) = Self::free_balance(who).checked_sub(&value) { if liveness == ExistenceRequirement::KeepAlive && new_balance < Self::existential_deposit() { return Err("payment would kill account") } Self::ensure_can_withdraw(who, value, reason, new_balance)?; Self::set_free_balance(who, new_balance); Ok(NegativeImbalance::new(value)) } else { Err("too few free funds in account") } } fn slash( who: &T::AccountId, value: Self::Balance ) -> (Self::NegativeImbalance, Self::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); let remaining_slash = value - free_slash; // NOTE: `slash()` prefers free balance, but assumes that reserve balance can be drawn // from in extreme circumstances. `can_slash()` should be used prior to `slash()` to avoid having // to draw from reserved funds, however we err on the side of punishment if things are inconsistent // or `can_slash` wasn't used appropriately. if !remaining_slash.is_zero() { let reserved_balance = Self::reserved_balance(who); let reserved_slash = cmp::min(reserved_balance, remaining_slash); Self::set_reserved_balance(who, reserved_balance - reserved_slash); (NegativeImbalance::new(free_slash + reserved_slash), remaining_slash - reserved_slash) } else { (NegativeImbalance::new(value), Zero::zero()) } } fn deposit_into_existing( who: &T::AccountId, value: Self::Balance ) -> result::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); Ok(PositiveImbalance::new(value)) } fn deposit_creating( who: &T::AccountId, value: Self::Balance, ) -> Self::PositiveImbalance { let (imbalance, _) = Self::make_free_balance_be(who, Self::free_balance(who) + value); if let SignedImbalance::Positive(p) = imbalance { p } else { // Impossible, but be defensive. Self::PositiveImbalance::zero() } } fn make_free_balance_be(who: &T::AccountId, balance: T::Balance) -> ( SignedImbalance, UpdateBalanceOutcome ) { let original = Self::free_balance(who); if balance < Self::existential_deposit() && original.is_zero() { // If we're attempting to set an existing account to less than ED, then // bypass the entire operation. It's a no-op if you follow it through, but // since this is an instance where we might account for a negative imbalance // (in the dust cleaner of set_free_balance) before we account for its actual // equal and opposite cause (returned as an Imbalance), then in the // instance that there's no other accounts on the system at all, we might // underflow the issuance and our arithmetic will be off. return ( SignedImbalance::Positive(Self::PositiveImbalance::zero()), UpdateBalanceOutcome::AccountKilled, ) } let imbalance = if original <= balance { SignedImbalance::Positive(PositiveImbalance::new(balance - original)) } else { SignedImbalance::Negative(NegativeImbalance::new(original - balance)) }; // 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). let outcome = if balance < >::existential_deposit() { Self::set_free_balance(who, balance); UpdateBalanceOutcome::AccountKilled } else { if !>::exists(who) { Self::new_account(&who, balance); } Self::set_free_balance(who, balance); UpdateBalanceOutcome::Updated }; (imbalance, outcome) } } impl, I: Instance> ReservableCurrency for Module where T::Balance: MaybeSerializeDebug { fn can_reserve(who: &T::AccountId, value: Self::Balance) -> bool { Self::free_balance(who) .checked_sub(&value) .map_or(false, |new_balance| Self::ensure_can_withdraw(who, value, WithdrawReason::Reserve, new_balance).is_ok() ) } fn reserved_balance(who: &T::AccountId) -> Self::Balance { >::get(who) } fn reserve(who: &T::AccountId, value: Self::Balance) -> result::Result<(), &'static str> { let b = Self::free_balance(who); if b < value { return Err("not enough free funds") } let new_balance = b - value; Self::ensure_can_withdraw(who, value, WithdrawReason::Reserve, new_balance)?; Self::set_reserved_balance(who, Self::reserved_balance(who) + value); Self::set_free_balance(who, new_balance); Ok(()) } fn unreserve(who: &T::AccountId, value: Self::Balance) -> Self::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); value - actual } fn slash_reserved( who: &T::AccountId, value: Self::Balance ) -> (Self::NegativeImbalance, Self::Balance) { let b = Self::reserved_balance(who); let slash = cmp::min(b, value); // underflow should never happen, but it if does, there's nothing to be done here. Self::set_reserved_balance(who, b - slash); (NegativeImbalance::new(slash), value - slash) } fn repatriate_reserved( slashed: &T::AccountId, beneficiary: &T::AccountId, value: Self::Balance, ) -> result::Result { 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); Ok(value - slash) } } impl, I: Instance> LockableCurrency for Module where T::Balance: MaybeSerializeDebug { type Moment = T::BlockNumber; fn set_lock( id: LockIdentifier, who: &T::AccountId, amount: T::Balance, until: T::BlockNumber, reasons: WithdrawReasons, ) { let now = >::block_number(); let mut new_lock = Some(BalanceLock { id, amount, until, reasons }); let mut locks = Self::locks(who).into_iter().filter_map(|l| if l.id == id { new_lock.take() } else if l.until > now { Some(l) } else { None }).collect::>(); if let Some(lock) = new_lock { locks.push(lock) } >::insert(who, locks); } fn extend_lock( id: LockIdentifier, who: &T::AccountId, amount: T::Balance, until: T::BlockNumber, reasons: WithdrawReasons, ) { let now = >::block_number(); let mut new_lock = Some(BalanceLock { id, amount, until, reasons }); let mut locks = Self::locks(who).into_iter().filter_map(|l| if l.id == id { new_lock.take().map(|nl| { BalanceLock { id: l.id, amount: l.amount.max(nl.amount), until: l.until.max(nl.until), reasons: l.reasons | nl.reasons, } }) } else if l.until > now { Some(l) } else { None }).collect::>(); if let Some(lock) = new_lock { locks.push(lock) } >::insert(who, locks); } fn remove_lock( id: LockIdentifier, who: &T::AccountId, ) { let now = >::block_number(); let locks = Self::locks(who).into_iter().filter_map(|l| if l.until > now && l.id != id { Some(l) } else { None }).collect::>(); >::insert(who, locks); } } impl, I: Instance> MakePayment for Module { fn make_payment(transactor: &T::AccountId, encoded_len: usize) -> Result { let encoded_len = T::Balance::from(encoded_len as u32); let transaction_fee = Self::transaction_base_fee() + Self::transaction_byte_fee() * encoded_len; let imbalance = Self::withdraw( transactor, transaction_fee, WithdrawReason::TransactionPayment, ExistenceRequirement::KeepAlive )?; T::TransactionPayment::on_unbalanced(imbalance); Ok(()) } } impl, I: Instance> IsDeadAccount for Module where T::Balance: MaybeSerializeDebug { fn is_dead_account(who: &T::AccountId) -> bool { Self::total_balance(who).is_zero() } }