// Copyright 2019-2020 Parity Technologies (UK) Ltd.
// This file is part of Parity Bridges Common.
// Parity Bridges Common 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.
// Parity Bridges Common 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 Parity Bridges Common. If not, see .
//! The Substrate Node Template runtime. This can be compiled with `#[no_std]`, ready for Wasm.
#![cfg_attr(not(feature = "std"), no_std)]
// `construct_runtime!` does a lot of recursion and requires us to increase the limit to 256.
#![recursion_limit = "256"]
// Runtime-generated enums
#![allow(clippy::large_enum_variant)]
// Runtime-generated DecodeLimit::decode_all_With_depth_limit
#![allow(clippy::unnecessary_mut_passed)]
// Make the WASM binary available.
#[cfg(feature = "std")]
include!(concat!(env!("OUT_DIR"), "/wasm_binary.rs"));
pub mod exchange;
#[cfg(feature = "runtime-benchmarks")]
pub mod benches;
pub mod kovan;
pub mod rialto;
use codec::{Decode, Encode};
use pallet_grandpa::{fg_primitives, AuthorityId as GrandpaId, AuthorityList as GrandpaAuthorityList};
use sp_api::impl_runtime_apis;
use sp_consensus_aura::sr25519::AuthorityId as AuraId;
use sp_core::{crypto::KeyTypeId, OpaqueMetadata};
use sp_runtime::traits::{
BlakeTwo256, Block as BlockT, IdentifyAccount, IdentityLookup, NumberFor, OpaqueKeys, Saturating, Verify,
};
use sp_runtime::{
create_runtime_str, generic, impl_opaque_keys,
transaction_validity::{TransactionSource, TransactionValidity},
ApplyExtrinsicResult, MultiSignature,
};
use sp_std::prelude::*;
#[cfg(feature = "std")]
use sp_version::NativeVersion;
use sp_version::RuntimeVersion;
// A few exports that help ease life for downstream crates.
pub use frame_support::{
construct_runtime, parameter_types,
traits::{Currency, ExistenceRequirement, Imbalance, KeyOwnerProofSystem, Randomness},
weights::{IdentityFee, RuntimeDbWeight, Weight},
StorageValue,
};
pub use pallet_balances::Call as BalancesCall;
pub use pallet_bridge_currency_exchange::Call as BridgeCurrencyExchangeCall;
pub use pallet_bridge_eth_poa::Call as BridgeEthPoACall;
pub use pallet_timestamp::Call as TimestampCall;
#[cfg(any(feature = "std", test))]
pub use sp_runtime::BuildStorage;
pub use sp_runtime::{Perbill, Permill};
/// An index to a block.
pub type BlockNumber = u32;
/// Alias to 512-bit hash when used in the context of a transaction signature on the chain.
pub type Signature = MultiSignature;
/// Some way of identifying an account on the chain. We intentionally make it equivalent
/// to the public key of our transaction signing scheme.
pub type AccountId = <::Signer as IdentifyAccount>::AccountId;
/// The type for looking up accounts. We don't expect more than 4 billion of them, but you
/// never know...
pub type AccountIndex = u32;
/// Balance of an account.
pub type Balance = u128;
/// Index of a transaction in the chain.
pub type Index = u32;
/// A hash of some data used by the chain.
pub type Hash = sp_core::H256;
/// Digest item type.
pub type DigestItem = generic::DigestItem;
/// Opaque types. These are used by the CLI to instantiate machinery that don't need to know
/// the specifics of the runtime. They can then be made to be agnostic over specific formats
/// of data like extrinsics, allowing for them to continue syncing the network through upgrades
/// to even the core data structures.
pub mod opaque {
use super::*;
pub use sp_runtime::OpaqueExtrinsic as UncheckedExtrinsic;
/// Opaque block header type.
pub type Header = generic::Header;
/// Opaque block type.
pub type Block = generic::Block;
/// Opaque block identifier type.
pub type BlockId = generic::BlockId;
}
impl_opaque_keys! {
pub struct SessionKeys {
pub aura: Aura,
pub grandpa: Grandpa,
}
}
/// This runtime version.
pub const VERSION: RuntimeVersion = RuntimeVersion {
spec_name: create_runtime_str!("bridge-node"),
impl_name: create_runtime_str!("bridge-node"),
authoring_version: 1,
spec_version: 1,
impl_version: 1,
apis: RUNTIME_API_VERSIONS,
transaction_version: 1,
};
pub const MILLISECS_PER_BLOCK: u64 = 6000;
pub const SLOT_DURATION: u64 = MILLISECS_PER_BLOCK;
// These time units are defined in number of blocks.
pub const MINUTES: BlockNumber = 60_000 / (MILLISECS_PER_BLOCK as BlockNumber);
pub const HOURS: BlockNumber = MINUTES * 60;
pub const DAYS: BlockNumber = HOURS * 24;
/// The version information used to identify this runtime when compiled natively.
#[cfg(feature = "std")]
pub fn native_version() -> NativeVersion {
NativeVersion {
runtime_version: VERSION,
can_author_with: Default::default(),
}
}
parameter_types! {
pub const BlockHashCount: BlockNumber = 250;
pub const MaximumBlockWeight: Weight = 2_000_000_000_000;
pub const ExtrinsicBaseWeight: Weight = 10_000_000;
pub const AvailableBlockRatio: Perbill = Perbill::from_percent(75);
/// Assume 10% of weight for average on_initialize calls.
pub MaximumExtrinsicWeight: Weight = AvailableBlockRatio::get()
.saturating_sub(Perbill::from_percent(10)) * MaximumBlockWeight::get();
pub const MaximumBlockLength: u32 = 5 * 1024 * 1024;
pub const Version: RuntimeVersion = VERSION;
pub const DbWeight: RuntimeDbWeight = RuntimeDbWeight {
read: 60_000_000, // ~0.06 ms = ~60 µs
write: 200_000_000, // ~0.2 ms = 200 µs
};
}
impl frame_system::Trait for Runtime {
/// The basic call filter to use in dispatchable.
type BaseCallFilter = ();
/// The identifier used to distinguish between accounts.
type AccountId = AccountId;
/// The aggregated dispatch type that is available for extrinsics.
type Call = Call;
/// The lookup mechanism to get account ID from whatever is passed in dispatchers.
type Lookup = IdentityLookup;
/// The index type for storing how many extrinsics an account has signed.
type Index = Index;
/// The index type for blocks.
type BlockNumber = BlockNumber;
/// The type for hashing blocks and tries.
type Hash = Hash;
/// The hashing algorithm used.
type Hashing = BlakeTwo256;
/// The header type.
type Header = generic::Header;
/// The ubiquitous event type.
type Event = Event;
/// The ubiquitous origin type.
type Origin = Origin;
/// Maximum number of block number to block hash mappings to keep (oldest pruned first).
type BlockHashCount = BlockHashCount;
/// Maximum weight of each block.
type MaximumBlockWeight = MaximumBlockWeight;
/// The weight of database operations that the runtime can invoke.
type DbWeight = DbWeight;
/// The weight of the overhead invoked on the block import process, independent of the
/// extrinsics included in that block.
type BlockExecutionWeight = ();
/// The base weight of any extrinsic processed by the runtime, independent of the
/// logic of that extrinsic. (Signature verification, nonce increment, fee, etc...)
type ExtrinsicBaseWeight = ExtrinsicBaseWeight;
/// The maximum weight that a single extrinsic of `Normal` dispatch class can have,
/// idependent of the logic of that extrinsics. (Roughly max block weight - average on
/// initialize cost).
type MaximumExtrinsicWeight = MaximumExtrinsicWeight;
/// Maximum size of all encoded transactions (in bytes) that are allowed in one block.
type MaximumBlockLength = MaximumBlockLength;
/// Portion of the block weight that is available to all normal transactions.
type AvailableBlockRatio = AvailableBlockRatio;
/// Version of the runtime.
type Version = Version;
/// Converts a module to the index of the module in `construct_runtime!`.
///
/// This type is being generated by `construct_runtime!`.
type ModuleToIndex = ModuleToIndex;
/// What to do if a new account is created.
type OnNewAccount = ();
/// What to do if an account is fully reaped from the system.
type OnKilledAccount = ();
/// The data to be stored in an account.
type AccountData = pallet_balances::AccountData;
/// Weight information for the extrinsics of this pallet.
type SystemWeightInfo = ();
}
impl pallet_aura::Trait for Runtime {
type AuthorityId = AuraId;
}
type Rialto = pallet_bridge_eth_poa::Instance1;
impl pallet_bridge_eth_poa::Trait for Runtime {
type AuraConfiguration = rialto::BridgeAuraConfiguration;
type FinalityVotesCachingInterval = rialto::FinalityVotesCachingInterval;
type ValidatorsConfiguration = rialto::BridgeValidatorsConfiguration;
type PruningStrategy = rialto::PruningStrategy;
type OnHeadersSubmitted = ();
}
type Kovan = pallet_bridge_eth_poa::Instance2;
impl pallet_bridge_eth_poa::Trait for Runtime {
type AuraConfiguration = kovan::BridgeAuraConfiguration;
type FinalityVotesCachingInterval = kovan::FinalityVotesCachingInterval;
type ValidatorsConfiguration = kovan::BridgeValidatorsConfiguration;
type PruningStrategy = kovan::PruningStrategy;
type OnHeadersSubmitted = ();
}
type RialtoCurrencyExchange = pallet_bridge_currency_exchange::Instance1;
impl pallet_bridge_currency_exchange::Trait for Runtime {
type OnTransactionSubmitted = ();
type PeerBlockchain = rialto::RialtoBlockchain;
type PeerMaybeLockFundsTransaction = exchange::EthTransaction;
type RecipientsMap = bp_currency_exchange::IdentityRecipients;
type Amount = Balance;
type CurrencyConverter = bp_currency_exchange::IdentityCurrencyConverter;
type DepositInto = DepositInto;
}
type KovanCurrencyExchange = pallet_bridge_currency_exchange::Instance2;
impl pallet_bridge_currency_exchange::Trait for Runtime {
type OnTransactionSubmitted = ();
type PeerBlockchain = kovan::KovanBlockchain;
type PeerMaybeLockFundsTransaction = exchange::EthTransaction;
type RecipientsMap = bp_currency_exchange::IdentityRecipients;
type Amount = Balance;
type CurrencyConverter = bp_currency_exchange::IdentityCurrencyConverter;
type DepositInto = DepositInto;
}
impl pallet_bridge_call_dispatch::Trait for Runtime {
type Event = Event;
type MessageId = (bp_message_lane::LaneId, bp_message_lane::MessageNonce);
type Call = Call;
}
pub struct DepositInto;
impl bp_currency_exchange::DepositInto for DepositInto {
type Recipient = AccountId;
type Amount = Balance;
fn deposit_into(recipient: Self::Recipient, amount: Self::Amount) -> bp_currency_exchange::Result<()> {
// let balances module make all checks for us (it won't allow depositing lower than existential
// deposit, balance overflow, ...)
let deposited = as Currency>::deposit_creating(&recipient, amount);
// I'm dropping deposited here explicitly to illustrate the fact that it'll update `TotalIssuance`
// on drop
let deposited_amount = deposited.peek();
drop(deposited);
// we have 3 cases here:
// - deposited == amount: success
// - deposited == 0: deposit has failed and no changes to storage were made
// - deposited != 0: (should never happen in practice) deposit has been partially completed
match deposited_amount {
_ if deposited_amount == amount => {
frame_support::debug::trace!(
target: "runtime",
"Deposited {} to {:?}",
amount,
recipient,
);
Ok(())
}
_ if deposited_amount == 0 => {
frame_support::debug::error!(
target: "runtime",
"Deposit of {} to {:?} has failed",
amount,
recipient,
);
Err(bp_currency_exchange::Error::DepositFailed)
}
_ => {
frame_support::debug::error!(
target: "runtime",
"Deposit of {} to {:?} has partially competed. {} has been deposited",
amount,
recipient,
deposited_amount,
);
// we can't return DepositFailed error here, because storage changes were made
Err(bp_currency_exchange::Error::DepositPartiallyFailed)
}
}
}
}
impl pallet_grandpa::Trait for Runtime {
type Event = Event;
type Call = Call;
type KeyOwnerProofSystem = ();
type KeyOwnerProof = >::Proof;
type KeyOwnerIdentification =
>::IdentificationTuple;
type HandleEquivocation = ();
}
parameter_types! {
pub const MinimumPeriod: u64 = SLOT_DURATION / 2;
}
impl pallet_timestamp::Trait for Runtime {
/// A timestamp: milliseconds since the unix epoch.
type Moment = u64;
type OnTimestampSet = Aura;
type MinimumPeriod = MinimumPeriod;
type WeightInfo = ();
}
parameter_types! {
pub const ExistentialDeposit: u128 = 500;
}
impl pallet_balances::Trait for Runtime {
/// The type for recording an account's balance.
type Balance = Balance;
/// The ubiquitous event type.
type Event = Event;
type DustRemoval = ();
type ExistentialDeposit = ExistentialDeposit;
type AccountStore = System;
type WeightInfo = ();
}
parameter_types! {
pub const TransactionBaseFee: Balance = 0;
pub const TransactionByteFee: Balance = 1;
}
impl pallet_transaction_payment::Trait for Runtime {
type Currency = pallet_balances::Module;
type OnTransactionPayment = ();
type TransactionByteFee = TransactionByteFee;
type WeightToFee = IdentityFee;
type FeeMultiplierUpdate = ();
}
impl pallet_sudo::Trait for Runtime {
type Event = Event;
type Call = Call;
}
parameter_types! {
pub const Period: BlockNumber = 4;
pub const Offset: BlockNumber = 0;
}
impl pallet_session::Trait for Runtime {
type Event = Event;
type ValidatorId = ::AccountId;
type ValidatorIdOf = ();
type ShouldEndSession = pallet_session::PeriodicSessions;
type NextSessionRotation = pallet_session::PeriodicSessions;
type SessionManager = ShiftSessionManager;
type SessionHandler = ::KeyTypeIdProviders;
type Keys = SessionKeys;
type DisabledValidatorsThreshold = ();
type WeightInfo = ();
}
pub struct ShiftSessionManager;
impl ShiftSessionManager {
/// Select validators for session.
fn select_validators(
session_index: sp_staking::SessionIndex,
available_validators: &[AccountId],
) -> Vec {
let available_validators_count = available_validators.len();
let count = sp_std::cmp::max(1, 2 * available_validators_count / 3);
let offset = session_index as usize % available_validators_count;
let end = offset + count;
let session_validators = match end.overflowing_sub(available_validators_count) {
(wrapped_end, false) if wrapped_end != 0 => available_validators[offset..]
.iter()
.chain(available_validators[..wrapped_end].iter())
.cloned()
.collect(),
_ => available_validators[offset..end].to_vec(),
};
session_validators
}
}
impl pallet_session::SessionManager for ShiftSessionManager {
fn end_session(_: sp_staking::SessionIndex) {}
fn start_session(_: sp_staking::SessionIndex) {}
fn new_session(session_index: sp_staking::SessionIndex) -> Option> {
// can't access genesis config here :/
if session_index == 0 || session_index == 1 {
return None;
}
// the idea that on first call (i.e. when session 1 ends) we're reading current
// set of validators from session module (they are initial validators) and save
// in our 'local storage'.
// then for every session we select (deterministically) 2/3 of these initial
// validators to serve validators of new session
let available_validators = sp_io::storage::get(b":available_validators")
.and_then(|validators| Decode::decode(&mut &validators[..]).ok())
.unwrap_or_else(|| {
let validators = >::validators();
sp_io::storage::set(b":available_validators", &validators.encode());
validators
});
Some(Self::select_validators(session_index, &available_validators))
}
}
construct_runtime!(
pub enum Runtime where
Block = Block,
NodeBlock = opaque::Block,
UncheckedExtrinsic = UncheckedExtrinsic
{
BridgeRialto: pallet_bridge_eth_poa::::{Module, Call, Config, Storage, ValidateUnsigned},
BridgeKovan: pallet_bridge_eth_poa::::{Module, Call, Config, Storage, ValidateUnsigned},
BridgeRialtoCurrencyExchange: pallet_bridge_currency_exchange::::{Module, Call},
BridgeKovanCurrencyExchange: pallet_bridge_currency_exchange::::{Module, Call},
BridgeCallDispatch: pallet_bridge_call_dispatch::{Module, Event},
System: frame_system::{Module, Call, Config, Storage, Event},
RandomnessCollectiveFlip: pallet_randomness_collective_flip::{Module, Call, Storage},
Timestamp: pallet_timestamp::{Module, Call, Storage, Inherent},
Aura: pallet_aura::{Module, Config, Inherent},
Grandpa: pallet_grandpa::{Module, Call, Storage, Config, Event},
Balances: pallet_balances::{Module, Call, Storage, Config, Event},
TransactionPayment: pallet_transaction_payment::{Module, Storage},
Sudo: pallet_sudo::{Module, Call, Config, Storage, Event},
Session: pallet_session::{Module, Call, Storage, Event, Config},
}
);
/// The address format for describing accounts.
pub type Address = AccountId;
/// Block header type as expected by this runtime.
pub type Header = generic::Header;
/// Block type as expected by this runtime.
pub type Block = generic::Block;
/// A Block signed with a Justification
pub type SignedBlock = generic::SignedBlock;
/// BlockId type as expected by this runtime.
pub type BlockId = generic::BlockId;
/// The SignedExtension to the basic transaction logic.
pub type SignedExtra = (
frame_system::CheckSpecVersion,
frame_system::CheckTxVersion,
frame_system::CheckGenesis,
frame_system::CheckEra,
frame_system::CheckNonce,
frame_system::CheckWeight,
pallet_transaction_payment::ChargeTransactionPayment,
);
/// The payload being signed in transactions.
pub type SignedPayload = generic::SignedPayload;
/// Unchecked extrinsic type as expected by this runtime.
pub type UncheckedExtrinsic = generic::UncheckedExtrinsic;
/// Extrinsic type that has already been checked.
pub type CheckedExtrinsic = generic::CheckedExtrinsic;
/// Executive: handles dispatch to the various modules.
pub type Executive =
frame_executive::Executive, Runtime, AllModules>;
impl_runtime_apis! {
impl sp_api::Core for Runtime {
fn version() -> RuntimeVersion {
VERSION
}
fn execute_block(block: Block) {
Executive::execute_block(block)
}
fn initialize_block(header: &::Header) {
Executive::initialize_block(header)
}
}
impl sp_api::Metadata for Runtime {
fn metadata() -> OpaqueMetadata {
Runtime::metadata().into()
}
}
impl sp_block_builder::BlockBuilder for Runtime {
fn apply_extrinsic(extrinsic: ::Extrinsic) -> ApplyExtrinsicResult {
Executive::apply_extrinsic(extrinsic)
}
fn finalize_block() -> ::Header {
Executive::finalize_block()
}
fn inherent_extrinsics(data: sp_inherents::InherentData) -> Vec<::Extrinsic> {
data.create_extrinsics()
}
fn check_inherents(
block: Block,
data: sp_inherents::InherentData,
) -> sp_inherents::CheckInherentsResult {
data.check_extrinsics(&block)
}
fn random_seed() -> ::Hash {
RandomnessCollectiveFlip::random_seed()
}
}
impl frame_system_rpc_runtime_api::AccountNonceApi for Runtime {
fn account_nonce(account: AccountId) -> Index {
System::account_nonce(account)
}
}
impl bp_eth_poa::RialtoHeaderApi for Runtime {
fn best_block() -> (u64, bp_eth_poa::H256) {
let best_block = BridgeRialto::best_block();
(best_block.number, best_block.hash)
}
fn finalized_block() -> (u64, bp_eth_poa::H256) {
let finalized_block = BridgeRialto::finalized_block();
(finalized_block.number, finalized_block.hash)
}
fn is_import_requires_receipts(header: bp_eth_poa::Header) -> bool {
BridgeRialto::is_import_requires_receipts(header)
}
fn is_known_block(hash: bp_eth_poa::H256) -> bool {
BridgeRialto::is_known_block(hash)
}
}
impl bp_eth_poa::KovanHeaderApi for Runtime {
fn best_block() -> (u64, bp_eth_poa::H256) {
let best_block = BridgeKovan::best_block();
(best_block.number, best_block.hash)
}
fn finalized_block() -> (u64, bp_eth_poa::H256) {
let finalized_block = BridgeKovan::finalized_block();
(finalized_block.number, finalized_block.hash)
}
fn is_import_requires_receipts(header: bp_eth_poa::Header) -> bool {
BridgeKovan::is_import_requires_receipts(header)
}
fn is_known_block(hash: bp_eth_poa::H256) -> bool {
BridgeKovan::is_known_block(hash)
}
}
impl bp_currency_exchange::RialtoCurrencyExchangeApi for Runtime {
fn filter_transaction_proof(proof: exchange::EthereumTransactionInclusionProof) -> bool {
BridgeRialtoCurrencyExchange::filter_transaction_proof(&proof)
}
}
impl bp_currency_exchange::KovanCurrencyExchangeApi for Runtime {
fn filter_transaction_proof(proof: exchange::EthereumTransactionInclusionProof) -> bool {
BridgeKovanCurrencyExchange::filter_transaction_proof(&proof)
}
}
impl sp_transaction_pool::runtime_api::TaggedTransactionQueue for Runtime {
fn validate_transaction(
source: TransactionSource,
tx: ::Extrinsic,
) -> TransactionValidity {
Executive::validate_transaction(source, tx)
}
}
impl sp_offchain::OffchainWorkerApi for Runtime {
fn offchain_worker(header: &::Header) {
Executive::offchain_worker(header)
}
}
impl sp_consensus_aura::AuraApi for Runtime {
fn slot_duration() -> u64 {
Aura::slot_duration()
}
fn authorities() -> Vec {
Aura::authorities()
}
}
impl sp_session::SessionKeys for Runtime {
fn generate_session_keys(seed: Option>) -> Vec {
SessionKeys::generate(seed)
}
fn decode_session_keys(
encoded: Vec,
) -> Option, sp_core::crypto::KeyTypeId)>> {
SessionKeys::decode_into_raw_public_keys(&encoded)
}
}
impl fg_primitives::GrandpaApi for Runtime {
fn grandpa_authorities() -> GrandpaAuthorityList {
Grandpa::grandpa_authorities()
}
fn submit_report_equivocation_unsigned_extrinsic(
equivocation_proof: fg_primitives::EquivocationProof<
::Hash,
NumberFor,
>,
key_owner_proof: fg_primitives::OpaqueKeyOwnershipProof,
) -> Option<()> {
let key_owner_proof = key_owner_proof.decode()?;
Grandpa::submit_unsigned_equivocation_report(
equivocation_proof,
key_owner_proof,
)
}
fn generate_key_ownership_proof(
_set_id: fg_primitives::SetId,
_authority_id: GrandpaId,
) -> Option {
// NOTE: this is the only implementation possible since we've
// defined our key owner proof type as a bottom type (i.e. a type
// with no values).
None
}
}
#[cfg(feature = "runtime-benchmarks")]
impl frame_benchmarking::Benchmark for Runtime {
fn dispatch_benchmark(
pallet: Vec,
benchmark: Vec,
lowest_range_values: Vec,
highest_range_values: Vec,
steps: Vec,
repeat: u32,
extra: bool,
) -> Result, sp_runtime::RuntimeString> {
use frame_benchmarking::{Benchmarking, BenchmarkBatch, TrackedStorageKey, add_benchmark};
let mut batches = Vec::::new();
let whitelist: Vec = vec![
// Block Number
hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef702a5c1b19ab7a04f536c519aca4983ac").to_vec().into(),
// Execution Phase
hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef7ff553b5a9862a516939d82b3d3d8661a").to_vec().into(),
// Event Count
hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef70a98fdbe9ce6c55837576c60c7af3850").to_vec().into(),
// System Events
hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef780d41e5e16056765bc8461851072c9d7").to_vec().into(),
// Caller 0 Account
hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef7b99d880ec681799c0cf30e8886371da946c154ffd9992e395af90b5b13cc6f295c77033fce8a9045824a6690bbf99c6db269502f0a8d1d2a008542d5690a0749").to_vec().into(),
];
let params = (&pallet, &benchmark, &lowest_range_values, &highest_range_values, &steps, repeat, &whitelist, extra);
use pallet_bridge_currency_exchange::benchmarking::{
Module as BridgeCurrencyExchangeBench,
Trait as BridgeCurrencyExchangeTrait,
ProofParams as BridgeCurrencyExchangeProofParams,
};
impl BridgeCurrencyExchangeTrait for Runtime {
fn make_proof(
proof_params: BridgeCurrencyExchangeProofParams,
) -> crate::exchange::EthereumTransactionInclusionProof {
use bp_currency_exchange::DepositInto;
if proof_params.recipient_exists {
>::DepositInto::deposit_into(
proof_params.recipient.clone(),
ExistentialDeposit::get(),
).unwrap();
}
let (transaction, receipt) = crate::exchange::prepare_ethereum_transaction(
&proof_params.recipient,
|tx| {
// our runtime only supports transactions where data is exactly 32 bytes long
// (receiver key)
// => we are ignoring `transaction_size_factor` here
tx.value = (ExistentialDeposit::get() * 10).into();
},
);
let transactions = sp_std::iter::repeat((transaction, receipt))
.take(1 + proof_params.proof_size_factor as usize)
.collect::>();
let block_hash = crate::exchange::prepare_environment_for_claim::(&transactions);
crate::exchange::EthereumTransactionInclusionProof {
block: block_hash,
index: 0,
proof: transactions,
}
}
}
add_benchmark!(params, batches, pallet_bridge_eth_poa, BridgeKovan);
add_benchmark!(
params,
batches,
pallet_bridge_currency_exchange,
BridgeCurrencyExchangeBench::
);
if batches.is_empty() { return Err("Benchmark not found for this pallet.".into()) }
Ok(batches)
}
}
}
#[cfg(test)]
mod tests {
use super::*;
use bp_currency_exchange::DepositInto;
#[test]
fn shift_session_manager_works() {
let acc1 = AccountId::from([1u8; 32]);
let acc2 = AccountId::from([2u8; 32]);
let acc3 = AccountId::from([3u8; 32]);
let acc4 = AccountId::from([4u8; 32]);
let acc5 = AccountId::from([5u8; 32]);
let all_accs = vec![acc1.clone(), acc2.clone(), acc3.clone(), acc4.clone(), acc5.clone()];
// at least 1 validator is selected
assert_eq!(
ShiftSessionManager::select_validators(0, &[acc1.clone()]),
vec![acc1.clone()],
);
// at session#0, shift is also 0
assert_eq!(
ShiftSessionManager::select_validators(0, &all_accs),
vec![acc1.clone(), acc2.clone(), acc3.clone()],
);
// at session#1, shift is also 1
assert_eq!(
ShiftSessionManager::select_validators(1, &all_accs),
vec![acc2.clone(), acc3.clone(), acc4.clone()],
);
// at session#3, we're wrapping
assert_eq!(
ShiftSessionManager::select_validators(3, &all_accs),
vec![acc4, acc5, acc1.clone()],
);
// at session#5, we're starting from the beginning again
assert_eq!(
ShiftSessionManager::select_validators(5, &all_accs),
vec![acc1, acc2, acc3],
);
}
fn run_deposit_into_test(test: impl Fn(AccountId) -> Balance) {
let mut ext: sp_io::TestExternalities = SystemConfig::default().build_storage::().unwrap().into();
ext.execute_with(|| {
// initially issuance is zero
assert_eq!(
as Currency>::total_issuance(),
0,
);
// create account
let account: AccountId = [1u8; 32].into();
let initial_amount = ExistentialDeposit::get();
let deposited =
as Currency>::deposit_creating(&account, initial_amount);
drop(deposited);
assert_eq!(
as Currency>::total_issuance(),
initial_amount,
);
assert_eq!(
as Currency>::free_balance(&account),
initial_amount,
);
// run test
let total_issuance_change = test(account);
// check that total issuance has changed by `run_deposit_into_test`
assert_eq!(
as Currency>::total_issuance(),
initial_amount + total_issuance_change,
);
});
}
#[test]
fn deposit_into_existing_account_works() {
run_deposit_into_test(|existing_account| {
let initial_amount =
as Currency>::free_balance(&existing_account);
let additional_amount = 10_000;
>::DepositInto::deposit_into(
existing_account.clone(),
additional_amount,
)
.unwrap();
assert_eq!(
as Currency>::free_balance(&existing_account),
initial_amount + additional_amount,
);
additional_amount
});
}
#[test]
fn deposit_into_new_account_works() {
run_deposit_into_test(|_| {
let initial_amount = 0;
let additional_amount = ExistentialDeposit::get() + 10_000;
let new_account: AccountId = [42u8; 32].into();
>::DepositInto::deposit_into(
new_account.clone(),
additional_amount,
)
.unwrap();
assert_eq!(
as Currency>::free_balance(&new_account),
initial_amount + additional_amount,
);
additional_amount
});
}
}