// Copyright 2019-2021 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 .
//! Runtime module that allows sending and receiving messages using lane concept:
//!
//! 1) the message is sent using `send_message()` call;
//! 2) every outbound message is assigned nonce;
//! 3) the messages are stored in the storage;
//! 4) external component (relay) delivers messages to bridged chain;
//! 5) messages are processed in order (ordered by assigned nonce);
//! 6) relay may send proof-of-delivery back to this chain.
//!
//! Once message is sent, its progress can be tracked by looking at module events.
//! The assigned nonce is reported using `MessageAccepted` event. When message is
//! delivered to the the bridged chain, it is reported using `MessagesDelivered` event.
//!
//! **IMPORTANT NOTE**: after generating weights (custom `WeighInfo` implementation) for
//! your runtime (where this module is plugged to), please add test for these weights.
//! The test should call the `ensure_weights_are_correct` function from this module.
//! If this test fails with your weights, then either weights are computed incorrectly,
//! or some benchmarks assumptions are broken for your runtime.
#![cfg_attr(not(feature = "std"), no_std)]
// Generated by `decl_event!`
#![allow(clippy::unused_unit)]
pub use inbound_lane::StoredInboundLaneData;
pub use outbound_lane::StoredMessagePayload;
pub use weights::WeightInfo;
pub use weights_ext::{
ensure_able_to_receive_confirmation, ensure_able_to_receive_message,
ensure_weights_are_correct, WeightInfoExt, EXPECTED_DEFAULT_MESSAGE_LENGTH,
EXTRA_STORAGE_PROOF_SIZE,
};
use crate::{
inbound_lane::{InboundLane, InboundLaneStorage},
outbound_lane::{OutboundLane, OutboundLaneStorage, ReceivalConfirmationResult},
};
use bp_messages::{
source_chain::{
DeliveryConfirmationPayments, LaneMessageVerifier, SendMessageArtifacts, TargetHeaderChain,
},
target_chain::{
DeliveryPayments, DispatchMessage, MessageDispatch, ProvedLaneMessages, ProvedMessages,
SourceHeaderChain,
},
total_unrewarded_messages, DeliveredMessages, InboundLaneData, InboundMessageDetails, LaneId,
MessageKey, MessageNonce, MessagePayload, MessagesOperatingMode, OutboundLaneData,
OutboundMessageDetails, UnrewardedRelayersState,
};
use bp_runtime::{BasicOperatingMode, ChainId, OwnedBridgeModule, PreComputedSize, Size};
use codec::{Decode, Encode, MaxEncodedLen};
use frame_support::{dispatch::PostDispatchInfo, ensure, fail, traits::Get};
use sp_runtime::traits::UniqueSaturatedFrom;
use sp_std::{cell::RefCell, marker::PhantomData, prelude::*};
mod inbound_lane;
mod outbound_lane;
mod weights_ext;
pub mod weights;
#[cfg(feature = "runtime-benchmarks")]
pub mod benchmarking;
#[cfg(test)]
mod mock;
pub use pallet::*;
/// The target that will be used when publishing logs related to this pallet.
pub const LOG_TARGET: &str = "runtime::bridge-messages";
#[frame_support::pallet]
pub mod pallet {
use super::*;
use bp_messages::{ReceivalResult, ReceivedMessages};
use bp_runtime::RangeInclusiveExt;
use frame_support::pallet_prelude::*;
use frame_system::pallet_prelude::*;
#[pallet::config]
pub trait Config: frame_system::Config {
// General types
/// The overarching event type.
type RuntimeEvent: From>
+ IsType<::RuntimeEvent>;
/// Benchmarks results from runtime we're plugged into.
type WeightInfo: WeightInfoExt;
/// Gets the chain id value from the instance.
#[pallet::constant]
type BridgedChainId: Get;
/// Get all active outbound lanes that the message pallet is serving.
type ActiveOutboundLanes: Get<&'static [LaneId]>;
/// Maximal number of unrewarded relayer entries at inbound lane. Unrewarded means that the
/// relayer has delivered messages, but either confirmations haven't been delivered back to
/// the source chain, or we haven't received reward confirmations yet.
///
/// This constant limits maximal number of entries in the `InboundLaneData::relayers`. Keep
/// in mind that the same relayer account may take several (non-consecutive) entries in this
/// set.
type MaxUnrewardedRelayerEntriesAtInboundLane: Get;
/// Maximal number of unconfirmed messages at inbound lane. Unconfirmed means that the
/// message has been delivered, but either confirmations haven't been delivered back to the
/// source chain, or we haven't received reward confirmations for these messages yet.
///
/// This constant limits difference between last message from last entry of the
/// `InboundLaneData::relayers` and first message at the first entry.
///
/// There is no point of making this parameter lesser than
/// MaxUnrewardedRelayerEntriesAtInboundLane, because then maximal number of relayer entries
/// will be limited by maximal number of messages.
///
/// This value also represents maximal number of messages in single delivery transaction.
/// Transaction that is declaring more messages than this value, will be rejected. Even if
/// these messages are from different lanes.
type MaxUnconfirmedMessagesAtInboundLane: Get;
/// Maximal encoded size of the outbound payload.
#[pallet::constant]
type MaximalOutboundPayloadSize: Get;
/// Payload type of outbound messages. This payload is dispatched on the bridged chain.
type OutboundPayload: Parameter + Size;
/// Payload type of inbound messages. This payload is dispatched on this chain.
type InboundPayload: Decode;
/// Identifier of relayer that deliver messages to this chain. Relayer reward is paid on the
/// bridged chain.
type InboundRelayer: Parameter + MaxEncodedLen;
/// Delivery payments.
type DeliveryPayments: DeliveryPayments;
// Types that are used by outbound_lane (on source chain).
/// Target header chain.
type TargetHeaderChain: TargetHeaderChain;
/// Message payload verifier.
type LaneMessageVerifier: LaneMessageVerifier;
/// Delivery confirmation payments.
type DeliveryConfirmationPayments: DeliveryConfirmationPayments;
// Types that are used by inbound_lane (on target chain).
/// Source header chain, as it is represented on target chain.
type SourceHeaderChain: SourceHeaderChain;
/// Message dispatch.
type MessageDispatch: MessageDispatch<
Self::AccountId,
DispatchPayload = Self::InboundPayload,
>;
}
/// Shortcut to messages proof type for Config.
pub type MessagesProofOf =
<>::SourceHeaderChain as SourceHeaderChain>::MessagesProof;
/// Shortcut to messages delivery proof type for Config.
pub type MessagesDeliveryProofOf =
<>::TargetHeaderChain as TargetHeaderChain<
>::OutboundPayload,
::AccountId,
>>::MessagesDeliveryProof;
#[pallet::pallet]
pub struct Pallet(PhantomData<(T, I)>);
impl, I: 'static> OwnedBridgeModule for Pallet {
const LOG_TARGET: &'static str = LOG_TARGET;
type OwnerStorage = PalletOwner;
type OperatingMode = MessagesOperatingMode;
type OperatingModeStorage = PalletOperatingMode;
}
#[pallet::hooks]
impl, I: 'static> Hooks> for Pallet
where
u32: TryFrom<::BlockNumber>,
{
fn on_idle(_block: T::BlockNumber, remaining_weight: Weight) -> Weight {
// we'll need at least to read outbound lane state, kill a message and update lane state
let db_weight = T::DbWeight::get();
if !remaining_weight.all_gte(db_weight.reads_writes(1, 2)) {
return Weight::zero()
}
// messages from lane with index `i` in `ActiveOutboundLanes` are pruned when
// `System::block_number() % lanes.len() == i`. Otherwise we need to read lane states on
// every block, wasting the whole `remaining_weight` for nothing and causing starvation
// of the last lane pruning
let active_lanes = T::ActiveOutboundLanes::get();
let active_lanes_len = (active_lanes.len() as u32).into();
let active_lane_index = u32::unique_saturated_from(
frame_system::Pallet::::block_number() % active_lanes_len,
);
let active_lane_id = active_lanes[active_lane_index as usize];
// first db read - outbound lane state
let mut active_lane = outbound_lane::(active_lane_id);
let mut used_weight = db_weight.reads(1);
// and here we'll have writes
used_weight += active_lane.prune_messages(db_weight, remaining_weight - used_weight);
// we already checked we have enough `remaining_weight` to cover this `used_weight`
used_weight
}
}
#[pallet::call]
impl, I: 'static> Pallet {
/// Change `PalletOwner`.
///
/// May only be called either by root, or by `PalletOwner`.
#[pallet::call_index(0)]
#[pallet::weight((T::DbWeight::get().reads_writes(1, 1), DispatchClass::Operational))]
pub fn set_owner(origin: OriginFor, new_owner: Option) -> DispatchResult {
>::set_owner(origin, new_owner)
}
/// Halt or resume all/some pallet operations.
///
/// May only be called either by root, or by `PalletOwner`.
#[pallet::call_index(1)]
#[pallet::weight((T::DbWeight::get().reads_writes(1, 1), DispatchClass::Operational))]
pub fn set_operating_mode(
origin: OriginFor,
operating_mode: MessagesOperatingMode,
) -> DispatchResult {
>::set_operating_mode(origin, operating_mode)
}
/// Receive messages proof from bridged chain.
///
/// The weight of the call assumes that the transaction always brings outbound lane
/// state update. Because of that, the submitter (relayer) has no benefit of not including
/// this data in the transaction, so reward confirmations lags should be minimal.
///
/// The call fails if:
///
/// - the pallet is halted;
///
/// - the call origin is not `Signed(_)`;
///
/// - there are too many messages in the proof;
///
/// - the proof verification procedure returns an error - e.g. because header used to craft
/// proof is not imported by the associated finality pallet;
///
/// - the `dispatch_weight` argument is not sufficient to dispatch all bundled messages.
///
/// The call may succeed, but some messages may not be delivered e.g. if they are not fit
/// into the unrewarded relayers vector.
#[pallet::call_index(2)]
#[pallet::weight(T::WeightInfo::receive_messages_proof_weight(proof, *messages_count, *dispatch_weight))]
pub fn receive_messages_proof(
origin: OriginFor,
relayer_id_at_bridged_chain: T::InboundRelayer,
proof: MessagesProofOf,
messages_count: u32,
dispatch_weight: Weight,
) -> DispatchResultWithPostInfo {
Self::ensure_not_halted().map_err(Error::::BridgeModule)?;
let relayer_id_at_this_chain = ensure_signed(origin)?;
// reject transactions that are declaring too many messages
ensure!(
MessageNonce::from(messages_count) <= T::MaxUnconfirmedMessagesAtInboundLane::get(),
Error::::TooManyMessagesInTheProof
);
// why do we need to know the weight of this (`receive_messages_proof`) call? Because
// we may want to return some funds for not-dispatching (or partially dispatching) some
// messages to the call origin (relayer). And this is done by returning actual weight
// from the call. But we only know dispatch weight of every messages. So to refund
// relayer because we have not dispatched Message, we need to:
//
// ActualWeight = DeclaredWeight - Message.DispatchWeight
//
// The DeclaredWeight is exactly what's computed here. Unfortunately it is impossible
// to get pre-computed value (and it has been already computed by the executive).
let declared_weight = T::WeightInfo::receive_messages_proof_weight(
&proof,
messages_count,
dispatch_weight,
);
let mut actual_weight = declared_weight;
// verify messages proof && convert proof into messages
let messages = verify_and_decode_messages_proof::<
T::SourceHeaderChain,
T::InboundPayload,
>(proof, messages_count)
.map_err(|err| {
log::trace!(target: LOG_TARGET, "Rejecting invalid messages proof: {:?}", err,);
Error::::InvalidMessagesProof
})?;
// dispatch messages and (optionally) update lane(s) state(s)
let mut total_messages = 0;
let mut valid_messages = 0;
let mut messages_received_status = Vec::with_capacity(messages.len());
let mut dispatch_weight_left = dispatch_weight;
for (lane_id, lane_data) in messages {
let mut lane = inbound_lane::(lane_id);
// subtract extra storage proof bytes from the actual PoV size - there may be
// less unrewarded relayers than the maximal configured value
let lane_extra_proof_size_bytes = lane.storage().extra_proof_size_bytes();
actual_weight = actual_weight.set_proof_size(
actual_weight.proof_size().saturating_sub(lane_extra_proof_size_bytes),
);
if let Some(lane_state) = lane_data.lane_state {
let updated_latest_confirmed_nonce = lane.receive_state_update(lane_state);
if let Some(updated_latest_confirmed_nonce) = updated_latest_confirmed_nonce {
log::trace!(
target: LOG_TARGET,
"Received lane {:?} state update: latest_confirmed_nonce={}",
lane_id,
updated_latest_confirmed_nonce,
);
}
}
let mut lane_messages_received_status =
ReceivedMessages::new(lane_id, Vec::with_capacity(lane_data.messages.len()));
for mut message in lane_data.messages {
debug_assert_eq!(message.key.lane_id, lane_id);
total_messages += 1;
// ensure that relayer has declared enough weight for dispatching next message
// on this lane. We can't dispatch lane messages out-of-order, so if declared
// weight is not enough, let's move to next lane
let message_dispatch_weight = T::MessageDispatch::dispatch_weight(&mut message);
if message_dispatch_weight.any_gt(dispatch_weight_left) {
log::trace!(
target: LOG_TARGET,
"Cannot dispatch any more messages on lane {:?}. Weight: declared={}, left={}",
lane_id,
message_dispatch_weight,
dispatch_weight_left,
);
fail!(Error::::InsufficientDispatchWeight);
}
let receival_result = lane.receive_message::(
&relayer_id_at_bridged_chain,
&relayer_id_at_this_chain,
message.key.nonce,
message.data,
);
// note that we're returning unspent weight to relayer even if message has been
// rejected by the lane. This allows relayers to submit spam transactions with
// e.g. the same set of already delivered messages over and over again, without
// losing funds for messages dispatch. But keep in mind that relayer pays base
// delivery transaction cost anyway. And base cost covers everything except
// dispatch, so we have a balance here.
let unspent_weight = match &receival_result {
ReceivalResult::Dispatched(dispatch_result) => {
valid_messages += 1;
dispatch_result.unspent_weight
},
ReceivalResult::InvalidNonce |
ReceivalResult::TooManyUnrewardedRelayers |
ReceivalResult::TooManyUnconfirmedMessages => message_dispatch_weight,
};
lane_messages_received_status.push(message.key.nonce, receival_result);
let unspent_weight = unspent_weight.min(message_dispatch_weight);
dispatch_weight_left -= message_dispatch_weight - unspent_weight;
actual_weight = actual_weight.saturating_sub(unspent_weight);
}
messages_received_status.push(lane_messages_received_status);
}
// let's now deal with relayer payments
T::DeliveryPayments::pay_reward(
relayer_id_at_this_chain,
total_messages,
valid_messages,
actual_weight,
);
log::debug!(
target: LOG_TARGET,
"Received messages: total={}, valid={}. Weight used: {}/{}.",
total_messages,
valid_messages,
actual_weight,
declared_weight,
);
Self::deposit_event(Event::MessagesReceived(messages_received_status));
Ok(PostDispatchInfo { actual_weight: Some(actual_weight), pays_fee: Pays::Yes })
}
/// Receive messages delivery proof from bridged chain.
#[pallet::call_index(3)]
#[pallet::weight(T::WeightInfo::receive_messages_delivery_proof_weight(
proof,
relayers_state,
))]
pub fn receive_messages_delivery_proof(
origin: OriginFor,
proof: MessagesDeliveryProofOf,
mut relayers_state: UnrewardedRelayersState,
) -> DispatchResultWithPostInfo {
Self::ensure_not_halted().map_err(Error::::BridgeModule)?;
let proof_size = proof.size();
let confirmation_relayer = ensure_signed(origin)?;
let (lane_id, lane_data) = T::TargetHeaderChain::verify_messages_delivery_proof(proof)
.map_err(|err| {
log::trace!(
target: LOG_TARGET,
"Rejecting invalid messages delivery proof: {:?}",
err,
);
Error::::InvalidMessagesDeliveryProof
})?;
// verify that the relayer has declared correct `lane_data::relayers` state
// (we only care about total number of entries and messages, because this affects call
// weight)
ensure!(
total_unrewarded_messages(&lane_data.relayers).unwrap_or(MessageNonce::MAX) ==
relayers_state.total_messages &&
lane_data.relayers.len() as MessageNonce ==
relayers_state.unrewarded_relayer_entries,
Error::::InvalidUnrewardedRelayersState
);
// the `last_delivered_nonce` field may also be used by the signed extension. Even
// though providing wrong value isn't critical, let's also check it here.
ensure!(
lane_data.last_delivered_nonce() == relayers_state.last_delivered_nonce,
Error::::InvalidUnrewardedRelayersState
);
// mark messages as delivered
let mut lane = outbound_lane::(lane_id);
let last_delivered_nonce = lane_data.last_delivered_nonce();
let confirmed_messages = match lane.confirm_delivery(
relayers_state.total_messages,
last_delivered_nonce,
&lane_data.relayers,
) {
ReceivalConfirmationResult::ConfirmedMessages(confirmed_messages) =>
Some(confirmed_messages),
ReceivalConfirmationResult::NoNewConfirmations => None,
ReceivalConfirmationResult::TryingToConfirmMoreMessagesThanExpected(
to_confirm_messages_count,
) => {
log::trace!(
target: LOG_TARGET,
"Messages delivery proof contains too many messages to confirm: {} vs declared {}",
to_confirm_messages_count,
relayers_state.total_messages,
);
fail!(Error::::TryingToConfirmMoreMessagesThanExpected);
},
error => {
log::trace!(
target: LOG_TARGET,
"Messages delivery proof contains invalid unrewarded relayers vec: {:?}",
error,
);
fail!(Error::::InvalidUnrewardedRelayers);
},
};
if let Some(confirmed_messages) = confirmed_messages {
// emit 'delivered' event
let received_range = confirmed_messages.begin..=confirmed_messages.end;
Self::deposit_event(Event::MessagesDelivered {
lane_id,
messages: confirmed_messages,
});
// if some new messages have been confirmed, reward relayers
let actually_rewarded_relayers = T::DeliveryConfirmationPayments::pay_reward(
lane_id,
lane_data.relayers,
&confirmation_relayer,
&received_range,
);
// update relayers state with actual numbers to compute actual weight below
relayers_state.unrewarded_relayer_entries = sp_std::cmp::min(
relayers_state.unrewarded_relayer_entries,
actually_rewarded_relayers,
);
relayers_state.total_messages = sp_std::cmp::min(
relayers_state.total_messages,
received_range.checked_len().unwrap_or(MessageNonce::MAX),
);
};
log::trace!(
target: LOG_TARGET,
"Received messages delivery proof up to (and including) {} at lane {:?}",
last_delivered_nonce,
lane_id,
);
// because of lags, the inbound lane state (`lane_data`) may have entries for
// already rewarded relayers and messages (if all entries are duplicated, then
// this transaction must be filtered out by our signed extension)
let actual_weight = T::WeightInfo::receive_messages_delivery_proof_weight(
&PreComputedSize(proof_size as usize),
&relayers_state,
);
Ok(PostDispatchInfo { actual_weight: Some(actual_weight), pays_fee: Pays::Yes })
}
}
#[pallet::event]
#[pallet::generate_deposit(pub(super) fn deposit_event)]
pub enum Event, I: 'static = ()> {
/// Message has been accepted and is waiting to be delivered.
MessageAccepted { lane_id: LaneId, nonce: MessageNonce },
/// Messages have been received from the bridged chain.
MessagesReceived(
Vec<
ReceivedMessages<
>::DispatchLevelResult,
>,
>,
),
/// Messages in the inclusive range have been delivered to the bridged chain.
MessagesDelivered { lane_id: LaneId, messages: DeliveredMessages },
}
#[pallet::error]
pub enum Error {
/// Pallet is not in Normal operating mode.
NotOperatingNormally,
/// The outbound lane is inactive.
InactiveOutboundLane,
/// The message is too large to be sent over the bridge.
MessageIsTooLarge,
/// Message has been treated as invalid by chain verifier.
MessageRejectedByChainVerifier,
/// Message has been treated as invalid by lane verifier.
MessageRejectedByLaneVerifier,
/// Submitter has failed to pay fee for delivering and dispatching messages.
FailedToWithdrawMessageFee,
/// The transaction brings too many messages.
TooManyMessagesInTheProof,
/// Invalid messages has been submitted.
InvalidMessagesProof,
/// Invalid messages delivery proof has been submitted.
InvalidMessagesDeliveryProof,
/// The bridged chain has invalid `UnrewardedRelayers` in its storage (fatal for the lane).
InvalidUnrewardedRelayers,
/// The relayer has declared invalid unrewarded relayers state in the
/// `receive_messages_delivery_proof` call.
InvalidUnrewardedRelayersState,
/// The cumulative dispatch weight, passed by relayer is not enough to cover dispatch
/// of all bundled messages.
InsufficientDispatchWeight,
/// The message someone is trying to work with (i.e. increase fee) is not yet sent.
MessageIsNotYetSent,
/// The number of actually confirmed messages is going to be larger than the number of
/// messages in the proof. This may mean that this or bridged chain storage is corrupted.
TryingToConfirmMoreMessagesThanExpected,
/// Error generated by the `OwnedBridgeModule` trait.
BridgeModule(bp_runtime::OwnedBridgeModuleError),
}
/// Optional pallet owner.
///
/// Pallet owner has a right to halt all pallet operations and then resume it. If it is
/// `None`, then there are no direct ways to halt/resume pallet operations, but other
/// runtime methods may still be used to do that (i.e. democracy::referendum to update halt
/// flag directly or call the `halt_operations`).
#[pallet::storage]
#[pallet::getter(fn module_owner)]
pub type PalletOwner, I: 'static = ()> = StorageValue<_, T::AccountId>;
/// The current operating mode of the pallet.
///
/// Depending on the mode either all, some, or no transactions will be allowed.
#[pallet::storage]
#[pallet::getter(fn operating_mode)]
pub type PalletOperatingMode, I: 'static = ()> =
StorageValue<_, MessagesOperatingMode, ValueQuery>;
/// Map of lane id => inbound lane data.
#[pallet::storage]
pub type InboundLanes, I: 'static = ()> =
StorageMap<_, Blake2_128Concat, LaneId, StoredInboundLaneData, ValueQuery>;
/// Map of lane id => outbound lane data.
#[pallet::storage]
pub type OutboundLanes, I: 'static = ()> = StorageMap<
Hasher = Blake2_128Concat,
Key = LaneId,
Value = OutboundLaneData,
QueryKind = ValueQuery,
OnEmpty = GetDefault,
MaxValues = MaybeOutboundLanesCount,
>;
/// All queued outbound messages.
#[pallet::storage]
pub type OutboundMessages, I: 'static = ()> =
StorageMap<_, Blake2_128Concat, MessageKey, StoredMessagePayload>;
#[pallet::genesis_config]
pub struct GenesisConfig, I: 'static = ()> {
/// Initial pallet operating mode.
pub operating_mode: MessagesOperatingMode,
/// Initial pallet owner.
pub owner: Option,
/// Dummy marker.
pub phantom: sp_std::marker::PhantomData,
}
#[cfg(feature = "std")]
impl, I: 'static> Default for GenesisConfig {
fn default() -> Self {
Self {
operating_mode: Default::default(),
owner: Default::default(),
phantom: Default::default(),
}
}
}
#[pallet::genesis_build]
impl, I: 'static> GenesisBuild for GenesisConfig {
fn build(&self) {
PalletOperatingMode::::put(self.operating_mode);
if let Some(ref owner) = self.owner {
PalletOwner::::put(owner);
}
}
}
impl, I: 'static> Pallet {
/// Get stored data of the outbound message with given nonce.
pub fn outbound_message_data(lane: LaneId, nonce: MessageNonce) -> Option {
OutboundMessages::::get(MessageKey { lane_id: lane, nonce }).map(Into::into)
}
/// Prepare data, related to given inbound message.
pub fn inbound_message_data(
lane: LaneId,
payload: MessagePayload,
outbound_details: OutboundMessageDetails,
) -> InboundMessageDetails {
let mut dispatch_message = DispatchMessage {
key: MessageKey { lane_id: lane, nonce: outbound_details.nonce },
data: payload.into(),
};
InboundMessageDetails {
dispatch_weight: T::MessageDispatch::dispatch_weight(&mut dispatch_message),
}
}
/// Return inbound lane data.
pub fn inbound_lane_data(lane: LaneId) -> InboundLaneData {
InboundLanes::::get(lane).0
}
}
/// Get-parameter that returns number of active outbound lanes that the pallet maintains.
pub struct MaybeOutboundLanesCount(PhantomData<(T, I)>);
impl, I: 'static> Get