// Copyright 2017 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 .
//! Main parachains logic. For now this is just the determination of which validators do what.
use rstd::prelude::*;
use codec::Slicable;
use runtime_primitives::traits::{Hashing, BlakeTwo256, Executable, RefInto, MaybeEmpty};
use primitives::parachain::{Id, Chain, DutyRoster, CandidateReceipt};
use {system, session};
use substrate_runtime_support::{StorageValue, StorageMap};
use substrate_runtime_support::dispatch::Result;
#[cfg(any(feature = "std", test))]
use rstd::marker::PhantomData;
#[cfg(any(feature = "std", test))]
use {runtime_io, runtime_primitives};
pub trait Trait: system::Trait + session::Trait {
/// The position of the set_heads call in the block.
const SET_POSITION: u32;
type PublicAux: RefInto + MaybeEmpty;
}
decl_module! {
/// Parachains module.
pub struct Module;
/// Call type for parachains.
#[cfg_attr(feature = "std", derive(Serialize, Deserialize))]
pub enum Call where aux: ::PublicAux {
// provide candidate receipts for parachains, in ascending order by id.
fn set_heads(aux, heads: Vec) -> Result = 0;
}
/// Private calls for parachains.
#[cfg_attr(feature = "std", derive(Serialize, Deserialize))]
pub enum PrivCall {
fn register_parachain(id: Id, code: Vec, initial_head_data: Vec) -> Result = 0;
fn deregister_parachain(id: Id) -> Result = 1;
}
}
decl_storage! {
trait Store for Module;
// Vector of all parachain IDs.
pub Parachains get(active_parachains): b"para:chains" => default Vec;
// The parachains registered at present.
pub Code get(parachain_code): b"para:code" => map [ Id => Vec ];
// The heads of the parachains registered at present. these are kept sorted.
pub Heads get(parachain_head): b"para:head" => map [ Id => Vec ];
// Did the parachain heads get updated in this block?
DidUpdate: b"para:did" => default bool;
}
impl Module {
/// Calculate the current block's duty roster using system's random seed.
pub fn calculate_duty_roster() -> DutyRoster {
let parachains = Self::active_parachains();
let parachain_count = parachains.len();
let validator_count = >::validator_count() as usize;
let validators_per_parachain = if parachain_count != 0 { (validator_count - 1) / parachain_count } else { 0 };
let mut roles_val = (0..validator_count).map(|i| match i {
i if i < parachain_count * validators_per_parachain => {
let idx = i / validators_per_parachain;
Chain::Parachain(parachains[idx].clone())
}
_ => Chain::Relay,
}).collect::>();
let mut roles_gua = roles_val.clone();
let mut random_seed = system::Module::::random_seed().to_vec();
random_seed.extend(b"validator_role_pairs");
let mut seed = BlakeTwo256::hash(&random_seed);
// shuffle
for i in 0..(validator_count - 1) {
// 8 bytes of entropy used per cycle, 32 bytes entropy per hash
let offset = (i * 8 % 32) as usize;
// number of roles remaining to select from.
let remaining = (validator_count - i) as usize;
// 4 * 2 32-bit ints per 256-bit seed.
let val_index = u32::decode(&mut &seed[offset..offset + 4]).expect("using 4 bytes for a 32-bit quantity") as usize % remaining;
let gua_index = u32::decode(&mut &seed[offset + 4..offset + 8]).expect("using 4 bytes for a 32-bit quantity") as usize % remaining;
if offset == 24 {
// into the last 8 bytes - rehash to gather new entropy
seed = BlakeTwo256::hash(&seed);
}
// exchange last item with randomly chosen first.
roles_val.swap(remaining - 1, val_index);
roles_gua.swap(remaining - 1, gua_index);
}
DutyRoster {
validator_duty: roles_val,
guarantor_duty: roles_gua,
}
}
/// Register a parachain with given code.
/// Fails if given ID is already used.
pub fn register_parachain(id: Id, code: Vec, initial_head_data: Vec) -> Result {
let mut parachains = Self::active_parachains();
match parachains.binary_search(&id) {
Ok(_) => fail!("Parachain already exists"),
Err(idx) => parachains.insert(idx, id),
}
>::insert(id, code);
>::put(parachains);
>::insert(id, initial_head_data);
Ok(())
}
/// Deregister a parachain with given id
pub fn deregister_parachain(id: Id) -> Result {
let mut parachains = Self::active_parachains();
match parachains.binary_search(&id) {
Ok(idx) => { parachains.remove(idx); }
Err(_) => {}
}
>::remove(id);
>::remove(id);
>::put(parachains);
Ok(())
}
fn set_heads(aux: &::PublicAux, heads: Vec) -> Result {
ensure!(aux.is_empty(), "set_heads must not be signed");
ensure!(!>::exists(), "Parachain heads must be updated only once in the block");
ensure!(
>::extrinsic_index() == T::SET_POSITION,
"Parachain heads update extrinsic must be at position {} in the block"
// , T::SET_POSITION
);
let active_parachains = Self::active_parachains();
let mut iter = active_parachains.iter();
// perform this check before writing to storage.
for head in &heads {
ensure!(
iter.find(|&p| p == &head.parachain_index).is_some(),
"Submitted candidate for unregistered or out-of-order parachain {}"
// , head.parachain_index.into_inner()
);
}
for head in heads {
let id = head.parachain_index.clone();
>::insert(id, head.head_data.0);
}
>::put(true);
Ok(())
}
}
impl Executable for Module {
fn execute() {
assert!(::DidUpdate::take(), "Parachain heads must be updated once in the block");
}
}
/// Parachains module genesis configuration.
#[cfg(any(feature = "std", test))]
#[derive(Serialize, Deserialize)]
#[serde(rename_all = "camelCase")]
#[serde(deny_unknown_fields)]
pub struct GenesisConfig {
/// The initial parachains, mapped to code.
pub parachains: Vec<(Id, Vec)>,
/// Phantom data.
#[serde(skip)]
pub phantom: PhantomData,
}
#[cfg(any(feature = "std", test))]
impl Default for GenesisConfig {
fn default() -> Self {
GenesisConfig {
parachains: Vec::new(),
phantom: PhantomData,
}
}
}
#[cfg(any(feature = "std", test))]
impl runtime_primitives::BuildStorage for GenesisConfig
{
fn build_storage(mut self) -> ::std::result::Result {
use std::collections::HashMap;
use runtime_io::twox_128;
use codec::Slicable;
self.parachains.sort_unstable_by_key(|&(ref id, _)| id.clone());
self.parachains.dedup_by_key(|&mut (ref id, _)| id.clone());
let only_ids: Vec<_> = self.parachains.iter().map(|&(ref id, _)| id).cloned().collect();
let mut map: HashMap<_, _> = map![
twox_128(>::key()).to_vec() => only_ids.encode()
];
for (id, code) in self.parachains {
let key = twox_128(&>::key_for(&id)).to_vec();
map.insert(key, code.encode());
}
Ok(map.into())
}
}
#[cfg(test)]
mod tests {
use super::*;
use runtime_io::with_externalities;
use substrate_primitives::H256;
use runtime_primitives::BuildStorage;
use runtime_primitives::traits::{HasPublicAux, Identity, BlakeTwo256};
use runtime_primitives::testing::{Digest, Header};
use {consensus, timestamp};
#[derive(Clone, Eq, PartialEq)]
pub struct Test;
impl HasPublicAux for Test {
type PublicAux = u64;
}
impl consensus::Trait for Test {
type PublicAux = ::PublicAux;
type SessionKey = u64;
}
impl system::Trait for Test {
type Index = u64;
type BlockNumber = u64;
type Hash = H256;
type Hashing = BlakeTwo256;
type Digest = Digest;
type AccountId = u64;
type Header = Header;
}
impl session::Trait for Test {
type ConvertAccountIdToSessionKey = Identity;
type OnSessionChange = ();
}
impl timestamp::Trait for Test {
const TIMESTAMP_SET_POSITION: u32 = 0;
type Moment = u64;
}
impl Trait for Test {
const SET_POSITION: u32 = 0;
type PublicAux = ::PublicAux;
}
type Parachains = Module;
fn new_test_ext(parachains: Vec<(Id, Vec)>) -> runtime_io::TestExternalities {
let mut t = system::GenesisConfig::::default().build_storage().unwrap();
t.extend(consensus::GenesisConfig::{
code: vec![],
authorities: vec![1, 2, 3],
}.build_storage().unwrap());
t.extend(session::GenesisConfig::{
session_length: 1000,
validators: vec![1, 2, 3, 4, 5, 6, 7, 8],
broken_percent_late: 100,
}.build_storage().unwrap());
t.extend(GenesisConfig::{
parachains: parachains,
phantom: PhantomData,
}.build_storage().unwrap());
t
}
#[test]
fn active_parachains_should_work() {
let parachains = vec![
(5u32.into(), vec![1,2,3]),
(100u32.into(), vec![4,5,6]),
];
with_externalities(&mut new_test_ext(parachains), || {
assert_eq!(Parachains::active_parachains(), vec![5u32.into(), 100u32.into()]);
assert_eq!(Parachains::parachain_code(&5u32.into()), Some(vec![1,2,3]));
assert_eq!(Parachains::parachain_code(&100u32.into()), Some(vec![4,5,6]));
});
}
#[test]
fn register_deregister() {
let parachains = vec![
(5u32.into(), vec![1,2,3]),
(100u32.into(), vec![4,5,6]),
];
with_externalities(&mut new_test_ext(parachains), || {
assert_eq!(Parachains::active_parachains(), vec![5u32.into(), 100u32.into()]);
assert_eq!(Parachains::parachain_code(&5u32.into()), Some(vec![1,2,3]));
assert_eq!(Parachains::parachain_code(&100u32.into()), Some(vec![4,5,6]));
Parachains::register_parachain(99u32.into(), vec![7,8,9], vec![1, 1, 1]).unwrap();
assert_eq!(Parachains::active_parachains(), vec![5u32.into(), 99u32.into(), 100u32.into()]);
assert_eq!(Parachains::parachain_code(&99u32.into()), Some(vec![7,8,9]));
Parachains::deregister_parachain(5u32.into()).unwrap();
assert_eq!(Parachains::active_parachains(), vec![99u32.into(), 100u32.into()]);
assert_eq!(Parachains::parachain_code(&5u32.into()), None);
});
}
#[test]
fn duty_roster_works() {
let parachains = vec![
(0u32.into(), vec![]),
(1u32.into(), vec![]),
];
with_externalities(&mut new_test_ext(parachains), || {
let check_roster = |duty_roster: &DutyRoster| {
assert_eq!(duty_roster.validator_duty.len(), 8);
assert_eq!(duty_roster.guarantor_duty.len(), 8);
for i in (0..2).map(Id::from) {
assert_eq!(duty_roster.validator_duty.iter().filter(|&&j| j == Chain::Parachain(i)).count(), 3);
assert_eq!(duty_roster.guarantor_duty.iter().filter(|&&j| j == Chain::Parachain(i)).count(), 3);
}
assert_eq!(duty_roster.validator_duty.iter().filter(|&&j| j == Chain::Relay).count(), 2);
assert_eq!(duty_roster.guarantor_duty.iter().filter(|&&j| j == Chain::Relay).count(), 2);
};
system::Module::::set_random_seed([0u8; 32].into());
let duty_roster_0 = Parachains::calculate_duty_roster();
check_roster(&duty_roster_0);
system::Module::::set_random_seed([1u8; 32].into());
let duty_roster_1 = Parachains::calculate_duty_roster();
check_roster(&duty_roster_1);
assert!(duty_roster_0 != duty_roster_1);
system::Module::::set_random_seed([2u8; 32].into());
let duty_roster_2 = Parachains::calculate_duty_roster();
check_roster(&duty_roster_2);
assert!(duty_roster_0 != duty_roster_2);
assert!(duty_roster_1 != duty_roster_2);
});
}
}