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// Copyright 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/>.
//! Smart-contract module for runtime; Allows deployment and execution of smart-contracts
//! expressed in WebAssembly.
//! This module provides an ability to create smart-contract accounts and send them messages.
//! A smart-contract is an account with associated code and storage. When such an account receives a message,
//! the code associated with that account gets executed.
//!
//! The code is allowed to alter the storage entries of the associated account,
//! create smart-contracts or send messages to existing smart-contracts.
//!
//! For any actions invoked by the smart-contracts fee must be paid. The fee is paid in gas.
//! Gas is bought upfront up to the, specified in transaction, limit. Any unused gas is refunded
//! after the transaction (regardless of the execution outcome). If all gas is used,
//! then changes made for the specific call or create are reverted (including balance transfers).
//!
//! Failures are typically not cascading. That, for example, means that if contract A calls B and B errors
//! somehow, then A can decide if it should proceed or error.
//!
//! # Interaction with the system
//!
//! ## Finalization
//!
//! This module requires performing some finalization steps at the end of the block. If not performed
//! the module will have incorrect behavior.
//!
//! Call [`Module::execute`] at the end of the block. The order in relation to
//! the other module doesn't matter.
//!
//! ## Account killing
//!
//! When `staking` module determines that account is dead (e.g. account's balance fell below
//! exsistential deposit) then it reaps the account. That will lead to deletion of the associated
//! code and storage of the account.
//!
//! [`Module::execute`]: struct.Module.html#impl-OnFinalise
#![cfg_attr(not(feature = "std"), no_std)]
#[cfg(feature = "std")]
#[macro_use]
extern crate serde_derive;
#[macro_use]
extern crate parity_codec_derive;
extern crate parity_wasm;
extern crate pwasm_utils;
extern crate parity_codec as codec;
extern crate sr_io as runtime_io;
extern crate sr_sandbox as sandbox;
extern crate srml_balances as balances;
extern crate srml_system as system;
extern crate sr_primitives as runtime_primitives;
extern crate substrate_primitives;
#[cfg(test)]
#[macro_use]
extern crate assert_matches;
#[cfg(test)]
extern crate wabt;
mod account_db;
mod double_map;
mod exec;
mod vm;
mod gas;
#[cfg(test)]
mod tests;
use exec::ExecutionContext;
use account_db::{AccountDb, OverlayAccountDb};
use double_map::StorageDoubleMap;
use rstd::prelude::*;
use rstd::marker::PhantomData;
use codec::{Codec, HasCompact};
use runtime_primitives::traits::{Hash, As, SimpleArithmetic};
use runtime_support::dispatch::Result;
use runtime_support::{Parameter, StorageMap, StorageValue};
pub trait Trait: balances::Trait {
/// Function type to get the contract address given the creator.
type DetermineContractAddress: ContractAddressFor<Self::AccountId>;
// As<u32> is needed for wasm-utils
type Gas: Parameter + Default + Codec + SimpleArithmetic + Copy + As<Self::Balance> + As<u64> + As<u32>;
/// The overarching event type.
type Event: From<Event<Self>> + Into<<Self as system::Trait>::Event>;
pub trait ContractAddressFor<AccountId: Sized> {
fn contract_address_for(code: &[u8], data: &[u8], origin: &AccountId) -> AccountId;
/// Simple contract address determintator.
///
/// Address calculated from the code (of the constructor), input data to the constructor
/// and account id which requested the account creation.
///
/// Formula: `blake2_256(blake2_256(code) + blake2_256(data) + origin)`
pub struct SimpleAddressDeterminator<T: Trait>(PhantomData<T>);
impl<T: Trait> ContractAddressFor<T::AccountId> for SimpleAddressDeterminator<T>
where
T::AccountId: From<T::Hash> + AsRef<[u8]>
{
fn contract_address_for(code: &[u8], data: &[u8], origin: &T::AccountId) -> T::AccountId {
let code_hash = T::Hashing::hash(code);
let data_hash = T::Hashing::hash(data);
let mut buf = Vec::new();
buf.extend_from_slice(code_hash.as_ref());
buf.extend_from_slice(data_hash.as_ref());
buf.extend_from_slice(origin.as_ref());
T::Hashing::hash(&buf[..]).into()
}
}
decl_module! {
/// Contracts module.
pub struct Module<T: Trait> for enum Call where origin: T::Origin {
// TODO: Change AccountId to staking::Address
fn call(
value: <T::Balance as HasCompact>::Type,
gas_limit: <T::Gas as HasCompact>::Type,
) -> Result;
value: <T::Balance as HasCompact>::Type,
gas_limit: <T::Gas as HasCompact>::Type,
) -> Result;
fn on_finalise() {
<GasSpent<T>>::kill();
}
decl_event! {
pub enum Event<T>
where
<T as balances::Trait>::Balance,
<T as system::Trait>::AccountId
{
/// Transfer happened `from` -> `to` with given `value` as part of a `message-call` or `create`.
Transfer(AccountId, AccountId, Balance),
}
}
trait Store for Module<T: Trait> as Contract {
/// The fee required to create a contract. At least as big as staking's ReclaimRebate.
ContractFee get(contract_fee) config(): T::Balance = T::Balance::sa(21);
/// The fee charged for a call into a contract.
CallBaseFee get(call_base_fee) config(): T::Gas = T::Gas::sa(135);
/// The fee charged for a create of a contract.
CreateBaseFee get(create_base_fee) config(): T::Gas = T::Gas::sa(175);
/// The price of one unit of gas.
GasPrice get(gas_price) config(): T::Balance = T::Balance::sa(1);
/// The maximum nesting level of a call/create stack.
/// The maximum amount of gas that could be expended per block.
BlockGasLimit get(block_gas_limit) config(): T::Gas = T::Gas::sa(1_000_000);
/// Gas spent so far in this block.
/// The code associated with an account.
pub CodeOf: map T::AccountId => Vec<u8>; // TODO Vec<u8> values should be optimised to not do a length prefix.
// TODO: consider storing upper-bound for contract's gas limit in fixed-length runtime
// code in contract itself and use that.
/// The storage items associated with an account/key.
///
/// TODO: keys should also be able to take AsRef<KeyType> to ensure Vec<u8>s can be passed as &[u8]
pub(crate) struct StorageOf<T>(::rstd::marker::PhantomData<T>);
impl<T: Trait> double_map::StorageDoubleMap for StorageOf<T> {
const PREFIX: &'static [u8] = b"con:sto:";
type Key1 = T::AccountId;
type Key2 = Vec<u8>;
type Value = Vec<u8>;
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());
}
/// Make a call to a specified account, optionally transferring some balance.
fn call(
value: <T::Balance as HasCompact>::Type,
gas_limit: <T::Gas as HasCompact>::Type,
data: Vec<u8>,
) -> Result {
let value = value.into();
let gas_limit = gas_limit.into();
// Pay for the gas upfront.
//
// NOTE: it is very important to avoid any state changes before
// paying for the gas.
let mut gas_meter = gas::buy_gas::<T>(&origin, gas_limit)?;
let mut ctx = ExecutionContext {
depth: 0,
overlay: OverlayAccountDb::<T>::new(&account_db::DirectAccountDb),
let mut output_data = Vec::new();
let result = ctx.call(origin.clone(), dest, value, &mut gas_meter, &data, &mut output_data);
if let Ok(_) = result {
// Commit all changes that made it thus far into the persistant storage.
account_db::DirectAccountDb.commit(ctx.overlay.into_change_set());
// Then deposit all events produced.
ctx.events.into_iter().for_each(Self::deposit_event);
// Refund cost of the unused gas.
//
// NOTE: this should go after the commit to the storage, since the storage changes
// can alter the balance of the caller.
gas::refund_unused_gas::<T>(&origin, gas_meter);
/// Create a new contract, optionally transfering some balance to the created account.
///
///
/// - the destination address is computed based on the sender and hash of the code.
/// - account is created at the computed address.
/// - the `ctor_code` is executed in the context of the newly created account. Buffer returned
/// after the execution is saved as the `code` of the account. That code will be invoked
/// upon any message received by this account.
fn create(
endowment: <T::Balance as HasCompact>::Type,
gas_limit: <T::Gas as HasCompact>::Type,
ctor_code: Vec<u8>,
data: Vec<u8>,
) -> Result {
let endowment = endowment.into();
let gas_limit = gas_limit.into();
// Pay for the gas upfront.
//
// NOTE: it is very important to avoid any state changes before
// paying for the gas.
let mut gas_meter = gas::buy_gas::<T>(&origin, gas_limit)?;
let mut ctx = ExecutionContext {
depth: 0,
overlay: OverlayAccountDb::<T>::new(&account_db::DirectAccountDb),
let result = ctx.create(origin.clone(), endowment, &mut gas_meter, &ctor_code, &data);
if let Ok(_) = result {
// Commit all changes that made it thus far into the persistant storage.
account_db::DirectAccountDb.commit(ctx.overlay.into_change_set());
// Then deposit all events produced.
ctx.events.into_iter().for_each(Self::deposit_event);
// Refund cost of the unused gas.
//
// NOTE: this should go after the commit to the storage, since the storage changes
// can alter the balance of the caller.
gas::refund_unused_gas::<T>(&origin, gas_meter);
impl<T: Trait> balances::OnFreeBalanceZero<T::AccountId> for Module<T> {
fn on_free_balance_zero(who: &T::AccountId) {
<CodeOf<T>>::remove(who);
<StorageOf<T>>::remove_prefix(who.clone());